COM5: Reinforcements

Written on 21 March 2017.

Motivation

fib Commission 5 (COM5) gathers a balanced mix of experts coming from various fields (academics, owners, suppliers, government agencies and testing laboratories) who are volunteering their work into several task groups aiming to provide knowledge and information to students and the professional workforce for the best use of concrete.

Scope and objective of technical work

The scope of COM5 is to promote the technology for reinforcing and prestressing materials and systems and to improve their quality. This includes aspects from design, production, testing, up to the installation and final use of these materials and systems. The scope also includes maintaining and improving dialogue between producers, specifiers, and users of these materials and systems.

Finally, COM5 encourages new research and developments within its scope.

Commission Chair
Antonio Caballero

Deputy Chair
Hermann Weiher

First name	Last name	Country	Affiliation
Hans Rudolf	Ganz	Switzerland	Ganz Consulting
Josée	Bastien	Canada	University Laval
Akio	Kasuga	Japan	Sumitomo Mitsui Construction Co., Ltd
Ulf	Nürnberger	Germany	University of Stuttgart
Kiyotaka	Hosoi	Japan	Shinko Wire Company Ltd
Pedro	Almeida	Brazil	Sao Paulo University
Larry	Krauser	United States	General Technologies, Inc.
Tommaso	Ciccone	Italy	TENSA (Tensacciai s.r.l.)
Werner	Brand	Germany	DYWIDAG-Systems International
Antonio	Caballero	Switzerland	Screening Eagle Technologies AG
Carol	Hayek	United States	CCL
Randall	Poston	United States	Pivot Engineers
Christian	Gläser	Germany	DYWIDAG-Systems International
Teddy	Theryo	United States	BCC Engineering
David	Fernández-Ordóñez	Switzerland	fib
Theodore	Neff	United States	General Technologies, Inc.
Jaime	Gálvez Ruiz	Spain	Universidad Politecnica de Madrid
Hiroshi	Mutsuyoshi	Japan	Saitama University , Fac. of Eng.
Hermann	Weiher	Germany	matrics engineering GmbH
Alex	Gutsch	Germany	MPA Braunschweig
Stijn	Matthys	Belgium	Ghent University
Shinya	Ikehata	Japan	Central Nippon Expressway Co Ltd
Sven	Junge	Germany	ISB Institut für Stahlbetonbewehrung e.V.
Behzad	Manshadi	Switzerland	-
Ladin	Camci	United Kingdom	CARES (Certification Authority for Reinforcing Steels)
Hirokazu	Katsuda	Japan	Sumitomo Electric Industries, Ltd.
Guillermo	Ramirez	Switzerland	VSL International Ltd
Cesare	Prevedini	Brazil	Protende Sistemas e Métodos de Construcoes
Reggie H.	Holt	United States	Federal Highway Administration
Gregory	Hunsicker	United States	OnPoint Engineering and Technology LLC
Xiaomeng	Wang	Switzerland	BBR VT international Ltd.
Albert	Delgado	United States	General Technologies, Inc.
Ivica	Zivanovic	France	Freyssinet

TG5.1 - FRP Reinforcement for concrete structures

The main objectives of TG5.1 are:

The elaboration of design guidelines in accordance with the design format of the fib Model Code for Concrete Structures 2010 (“fib MC2010”) and Eurocode 2.
Link with other initiatives regarding material testing and characterisation & development of standard test methods.
Participation in the international forum in the field of advanced composite reinforcement, stimulating the use of FRP for concrete structures.
Guidance on practical execution of concrete structures reinforced/prestressed/strengthened by FRP.

Convener
Stijn Matthys

WP5.1.1 - Strengthening by FRP

FRP as externally applied reinforcement for strengthening existing concrete members has not only the benefit of being non-susceptible to corrosion and high strength, but also the easy-of-application and effectiveness as a repair/strengthening/retrofitting technique. Over the last decades externally bonded FRP reinforcement has become increasingly popular in practice, with thousands of applications worldwide. This is largely due to the pre-normative work of fib T5.1 in this respect. Next to more recent work on externally bonded FRP, focus is also on novel types of FRP strengthening systems, including near surface mounted FRP and textile reinforced mortar.

This working party finished a comprehensive Bulletin 90, after which the work focussed on the following topics:

Introduction of strengthening by FRP in the Model Code 2020
Introduction of strengthening by FRP in the upcoming Eurocode 2
Development of design examples in follow-up of B90 and in support of MC2020.

Convener
Stjin Matthys

Convener
Thanasys Triantafillou

First name	Last name	Country	Affiliation
David	Fernández-Ordóñez	Switzerland	fib
Leonardo	Todisco	Spain	E.T.S.I. Caminos, Canales y Puertos
Ted	Donchev	United Kingdom	Kingston University
Stijn	Matthys	Belgium	Ghent University
Nicola	Nistico	Italy	Sapienza Università di Roma
Eva	Oller Ibars	Spain	Technical University of Catalonia
Mohammadali	Rezazadeh	Portugal	University of Minho
José Manuel	de Sena Cruz	Portugal	University of Minho
Eythor	Thorhallsson	Iceland	Reykjavik University
Raphael	JANIV	France	-
György L.	Balázs	Hungary	Budapest Univ. of Techn. & Economics
Luís	Correia	Portugal	University of Minho
Ines	Costa	Portugal	CiviTest, Portugal
Tommaso	D’Antino	Italy	Politecnico di Milano
Marco	Damiani	Italy	Universita La Sapienza di Roma
Joaquim	A. O. Barros	Portugal	Universidade do Minho
Salvador	Dias	Portugal	University of Minho
David	Escolano Margarit	United Kingdom	The University of Sheffield
Renata	Kotynia	Poland	Lodz University of Technology
Thanasis	Triantafillou	Greece	University of Patras
Antonio	Nanni	Italy	Univ. degli Studi di Napoli Federico II
Diana	Petkova	United Kingdom	Kingston University
Theodoros	Rousakis	Greece	Democritus University of Thrace
André	Weber	Germany	Schöck Bauteile GmbH
Yoshiaki	Yamamoto	Japan	-
Katarzyna	Zdanowicz	Germany	Technische Universität Dresden

WP5.1.2 - Internal FRP reinforcement

FRP reinforcements have the benefit of being non-susceptible to corrosion and having high strength. Design of internal FRP reinforcement is largely driven by durability and serviceability limit state considerations, whereas ultimate limit state is often not governing given the relative high strength of FRP. Structural applications of FRP internal reinforcement, considering also cost aspects, are mainly associated to niche applications in which the advantages of using FRP rebars can make large difference (durability of concrete structures in more pronounced exposure conditions, structures where magnetic neutrality is essential, etc.). Although FRP reinforcement has been well established, its extend of adoption in practice is still underutilized.

This working party has the ambition to have a successor of Bulletin 40, next to other activities that stimulate the use of FRP reinforcement in pratice:

Int University of Sheffield roduction of internal FRP reinforcement in the Model Code 2020
Introduction of internal FRP reinforcement in the upcoming Eurocode 2
Development of design examples in follow-up of Bulletin 40 and MC2020
Renewed state-of-the-art report, as a successor of Bulletin 40 and as background document towards MC2020 and the new Eurocode 2.

Convener
Maurizio Guadagnini

Convener
Luis Torres

First name	Last name	Country	Affiliation
Maurizio	Guadagnini	United Kingdom	University of Sheffield
Lluis	Torres	Spain	University of Girona
David	Fernández-Ordóñez	Switzerland	fib
Erkan	Akpinar	Turkey	Kocaeli University
Marta	Baena	Spain	University of Girona
György L.	Balázs	Hungary	Budapest Univ. of Techn. & Economics
Gabriele	Balconi	Italy	Sireg Geotech s.r.l.
Bryan	Barragan	France	OCV Chambery International
Cristina	Barris	Spain	Universitat de Girona
Veronica	Bertolli	Italy	-
Antonio	Bilotta	Italy	University of Naples Federico II
Nora	Bies	Germany	TU Kaiserslautern
Valter	Carvelli	Italy	Politecnico di Milano
Paolo	Casadei	Italy	Sireg Geotech s.r.l.
Simon	Chołostiakow	United Kingdom	City University London
Christoph	Czaderski-Forchmann	Switzerland	EMPA, Structural Engineering
Tommaso	D’Antino	Italy	Politecnico di Milano
Joaquim	A. O. Barros	Portugal	Universidade do Minho
Ted	Donchev	United Kingdom	Kingston University
David	Escolano Margarit	United Kingdom	The University of Sheffield
Annalisa	Franco	Italy	Italian National Research Council
Douglas	Gremel	United States	Owens Corning
Viktor	Gribniak	Lithuania	Vilnius Gediminas Technical University
Tomislav	Kisicek	Croatia	University of Zagreb
Renata	Kotynia	Poland	Lodz University of Technology
Lampros	Koutas	Greece	University of Thessaly
B.	Kriekemans	Belgium	Fortius
Marianoela	Leone	Italy	Universita del Salento
Stijn	Matthys	Belgium	Ghent University
Tom	Molkens	Belgium	KU Leuven
Khaled	Mohamed	Canada	-
Antonio	Nanni	Italy	Univ. degli Studi di Napoli Federico II
Emidio	Nigro	Italy	Università degli Studi di Napoli Federico II
Eva	Oller Ibars	Spain	Technical University of Catalonia
Stavroula (S.J.)	Pantazopoulou	Canada	The Lassonde Faculty of Engineering, York University
Diana	Petkova	United Kingdom	Kingston University
Francesca	Roscini	Italy	University of Sheffield
José Manuel	de Sena Cruz	Portugal	University of Minho
Sándor	Sólyom	Hungary	Budapest Univ. of Techn. & Economics
Souzana	Tastani	Greece	Democritus University of Thrace
Nicolae	Taranu	Romania	Technical University of Iasi
Eythor	Thorhallsson	Iceland	Reykjavik University
Niki	Trochoutsou	United Kingdom	University of Sheffield
Ana	Veljkovic	Italy	Politecnico di Milano
Mark	Verbaten	Netherlands	ABT bv
André	Weber	Germany	Schöck Bauteile GmbH
Katarzyna	Zdanowicz	Germany	Technische Universität Dresden
Yu	Zheng	China	-

WP5.1.3 - Prestressing with FRP

FRP reinforcements have the benefit of being non-susceptible to corrosion and having high strength. To utilize the high strength of FRP, it is of particular interest to also use them in prestressing applications. This results in prestressed concrete structures, making use of FRP prestressing reinforcement, with a unique combination of high-end mechanical and durability performance.

The proposed bulletin would be a state-of-the-art report which special focus on the two different topics:

Prestressed FRP for new structures
Prestressing of FRP for strengthening purpose of RC and PC

Convener
Renata Kotynia

Convener
Christoph Czadersky

First name	Last name	Country	Affiliation
Renata	Kotynia	Poland	Lodz University of Technology
Christoph	Czaderski-Forchmann	Switzerland	EMPA, Structural Engineering
David	Fernández-Ordóñez	Switzerland	fib
Veronica	Bertolli	Italy	-
György L.	Balázs	Hungary	Budapest Univ. of Techn. & Economics
Erkan	Akpinar	Turkey	Kocaeli University
Marta	Baena	Spain	University of Girona
Bryan	Barragan	France	OCV Chambery International
Cristina	Barris	Spain	Universitat de Girona
Antonio	Bilotta	Italy	University of Naples Federico II
Valter	Carvelli	Italy	Politecnico di Milano
Dionysios	Bournas	United Kingdom	Nottingham University
Paolo	Casadei	Italy	Sireg Geotech s.r.l.
Francesca	Ceroni	Italy	Universitá degli Studi di Napoli Parthenope
Luís	Correia	Portugal	University of Minho
Tommaso	D’Antino	Italy	Politecnico di Milano
Joaquim	A. O. Barros	Portugal	Universidade do Minho
Halldor Gunnar	Dadason	Iceland	Reykjavik University, Orbicon Artic
Ciro	Del Vecchio	Italy	-
David	Escolano Margarit	United Kingdom	The University of Sheffield
Ted	Donchev	United Kingdom	Kingston University
Marta	Del Zoppo	Italy	University of Naples Federico II
Marco	Di Ludovico	Italy	University of Naples
Reyes	Garcia Lopez	United Kingdom	School of Engineering, University of Warwick
Maurizio	Guadagnini	United Kingdom	University of Sheffield
Tomislav	Kisicek	Croatia	University of Zagreb
Kaloyana	Kostova	United Kingdom	National Composites Centre
Ivana	Krajnović	Belgium	Ghent University
Stijn	Matthys	Belgium	Ghent University
Azer	Maazoun	Belgium	Ghent University
Gian Piero	Lignola	Italy	University of Naples Federico II
Tom	Molkens	Belgium	KU Leuven
Emidio	Nigro	Italy	Università degli Studi di Napoli Federico II
Eva	Oller Ibars	Spain	Technical University of Catalonia
Stavroula (S.J.)	Pantazopoulou	Canada	The Lassonde Faculty of Engineering, York University
Niek	Pouwels	Netherlands	ABT
Alessandro	Proia	Belgium	Ghent University
Andrea	Prota	Italy	Universita di Napoli Federico II
José Manuel	de Sena Cruz	Portugal	University of Minho
Theodoros	Rousakis	Greece	Democritus University of Thrace
Sándor	Sólyom	Hungary	Budapest Univ. of Techn. & Economics
Javad	Shayanfar	Portugal	University of Minho
Souzana	Tastani	Greece	Democritus University of Thrace
Eythor	Thorhallsson	Iceland	Reykjavik University
Georgia	Thermou	United Kingdom	University of Nottingham
Simone	Tomai	United Kingdom	Richter Associates Ltd
Lluis	Torres	Spain	University of Girona
Niki	Trochoutsou	United Kingdom	University of Sheffield
Thanasis	Triantafillou	Greece	University of Patras
Ana	Veljkovic	Italy	Politecnico di Milano
Mark	Verbaten	Netherlands	ABT bv
Muhammad Arslan	Yaqub	Belgium	Ghent University
Yu	Zheng	China	-

First name	Last name	Country	Affiliation
György L.	Balázs	Hungary	Budapest Univ. of Techn. & Economics
Francesca	Ceroni	Italy	Universitá degli Studi di Napoli Parthenope
Stavroula (S.J.)	Pantazopoulou	Canada	The Lassonde Faculty of Engineering, York University
Emidio	Nigro	Italy	Università degli Studi di Napoli Federico II
Andreea	Serbescu	United Kingdom	University of Sheffield+ Amey consulting
Dionysios	Bournas	United Kingdom	Nottingham University
Cristina	Barris	Spain	Universitat de Girona
Valter	Carvelli	Italy	Politecnico di Milano
Tommaso	D’Antino	Italy	Politecnico di Milano
Emmanuel	Ferrier	France	Université Lyon 1
Reyes	Garcia Lopez	United Kingdom	School of Engineering, University of Warwick
Tomislav	Kisicek	Croatia	University of Zagreb
Nicola	Nistico	Italy	Sapienza Università di Roma
Alessandro	Proia	Belgium	Ghent University
José Manuel	de Sena Cruz	Portugal	University of Minho
Ted	Donchev	United Kingdom	Kingston University
Christoforos	Kolyvas	Greece	FYFE EUROPE S.A.
Douglas	Gremel	United States	Owens Corning
Antonio	Nanni	Italy	Univ. degli Studi di Napoli Federico II
Maria Rosaria	Pecce	Italy	University of Naples Federico II
Andrea	Prota	Italy	Universita di Napoli Federico II
Thierry	Berset	Switzerland	SIKA Services AG
Konrad	Zilch	Germany	TU München
Antonio	Bilotta	Italy	University of Naples Federico II
Carlos	Ospina	United States	Simpson, Gumpertz & Heger Inc.
Eythor	Thorhallsson	Iceland	Reykjavik University
André	Weber	Germany	Schöck Bauteile GmbH
Szymon	Cholostiakow	United Kingdom	University of Sheffield
Thanasis	Triantafillou	Greece	University of Patras
Eva	Oller Ibars	Spain	Technical University of Catalonia
David	Fernández-Ordóñez	Switzerland	fib
Lluis	Torres	Spain	University of Girona
B.	Kriekemans	Belgium	Fortius
Sándor	Sólyom	Hungary	Budapest Univ. of Techn. & Economics
Vanessa	Buchin Roulie	Switzerland	VSL INTERNATIONAL
Viktor	Gribniak	Lithuania	Vilnius Gediminas Technical University
Tamon	Ueda	China	Shenzhen University
Stijn	Matthys	Belgium	Ghent University
Renata	Kotynia	Poland	Lodz University of Technology
Vesna	Raicic	United Kingdom	University of Bath
Ana	Veljkovic	Italy	Politecnico di Milano
Maurizio	Guadagnini	United Kingdom	University of Sheffield
Theodoros	Rousakis	Greece	Democritus University of Thrace
Lampros	Koutas	Greece	University of Thessaly
Joaquim	A. O. Barros	Portugal	Universidade do Minho
Georgia	Thermou	United Kingdom	University of Nottingham
Mark	Verbaten	Netherlands	ABT bv
Yu	Zheng	China	-
Marta	Del Zoppo	Italy	University of Naples Federico II
Erkan	Akpinar	Turkey	Kocaeli University
Marta	Baena	Spain	University of Girona
Bryan	Barragan	France	OCV Chambery International
Jian-Fei	Chen	Taiwan, Province of China	Southern University of Science and Technology
Mihaela Anca	Ciupala	United Kingdom	University of East London
Halldor Gunnar	Dadason	Iceland	Reykjavik University, Orbicon Artic
Marco	Di Ludovico	Italy	University of Naples
David	Escolano Margarit	United Kingdom	The University of Sheffield
Sorin-Codrut	Florut	Romania	Politehnica University of Timisoara
Ivana	Krajnović	Belgium	Ghent University
Marianoela	Leone	Italy	Universita del Salento
Ali	M. Mohaghegh	Germany	E. ON Climate & Renewables GmbH
Azer	Maazoun	Belgium	Ghent University
Niek	Pouwels	Netherlands	ABT
Francesca	Roscini	Italy	University of Sheffield
Roman	Sedlmair	Germany	Karlsruher Institut für Technology (KIT)
Souzana	Tastani	Greece	Democritus University of Thrace
Niki	Trochoutsou	United Kingdom	University of Sheffield
Muhammad Arslan	Yaqub	Belgium	Ghent University
Katarzyna	Zdanowicz	Germany	Technische Universität Dresden
Robert	Garke	Germany	Halfen
Nora	Bies	Germany	TU Kaiserslautern
Gian Piero	Lignola	Italy	University of Naples Federico II
Mohammadali	Rezazadeh	Portugal	University of Minho
Christoph	Czaderski-Forchmann	Switzerland	EMPA, Structural Engineering
Luís	Correia	Portugal	University of Minho
Ciro	Del Vecchio	Italy	-
Gabriele	Balconi	Italy	Sireg Geotech s.r.l.
Paolo	Casadei	Italy	Sireg Geotech s.r.l.
Marco	Damiani	Italy	Universita La Sapienza di Roma
Annalisa	Franco	Italy	Italian National Research Council
Peng	Gao	China	Hefei University of Technology
Chandan	Gowda	United Kingdom	Atkins Global
Szymon	Grzesiak	Germany	TU Kaiserslautern
Rania	Khattab	United Arab Emirates	Abu Dhabi University
Kaloyana	Kostova	United Kingdom	National Composites Centre
Khaled	Mohamed	Canada	-
Ronald	Niedermeier	Germany	Technische Universität München
Daniel	Pohoryles	Italy	European commission
Javad	Shayanfar	Portugal	University of Minho
Leonardo	Todisco	Spain	E.T.S.I. Caminos, Canales y Puertos
Simone	Tomai	United Kingdom	Richter Associates Ltd
Michel	Van Beek	Netherlands	BeVePro Consultancy
Weiqiang	Wang	China	Hohai University
Yoshiaki	Yamamoto	Japan	-
Özgür	Yurdakul	Czech Republic	Univerzita Pardubice
Đorđe	Čairović	Czech Republic	-
Craig	Giaccio	United Kingdom	Arcadis

TG5.2 - Reinforcing steels and systems

fib Task Group 5.2 (TG5.2) will consider all aspects related to reinforcing steels and systems from design to manufacturing, testing and final installation, use and maintenance. It will initially address several topics considered high priority. TG5.2 will create sub-groups to work on particular subjects.

Areas of interest:

review of the reinforcing steel grades available on the market (strength, ductility, bond, fatigue, durability properties) and relevant concrete structure design codes;
manual for reinforcing materials and systems;
technical report on fabrication of reinforcement;
state of the knowledge on the bond properties of reinforcing steels;
state of the knowledge on the fatigue resistance properties of reinforcing steels.

Convener
Ladin Camci

First name	Last name	Country	Affiliation
Hans Rudolf	Ganz	Switzerland	Ganz Consulting
Ulf	Nürnberger	Germany	University of Stuttgart
Steven	McCabe	United States	Nat. Inst. of Standards & Technologies
Manuel	Elices Calafat	Spain	Universidad Politecnica de Madrid
David	Fernández-Ordóñez	Switzerland	fib
Larry	Krauser	United States	General Technologies, Inc.
John	Cairns	United Kingdom	Heriot-Watt University
Ladin	Camci	United Kingdom	CARES (Certification Authority for Reinforcing Steels)
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart
David	Gustafson	United States	CRSI - Concrete Reinforcing Steel
Sven	Junge	Germany	ISB Institut für Stahlbetonbewehrung e.V.
Dennis	Keogh	United Kingdom	Laing O’Rourke Infrastructure Services
Andrew	Truby	United Kingdom	Truby Stevenson Ltd
Vladyslav	Shekhovtsov	Ukraine	Odesa State Academy of Civil Engineering and Architecture
Emily	Halliwell	United Kingdom	The Concrete Centre
Thierry	Steux	Belgium	-
Matthias	Ryser	Germany	Dr. Vollenweider AG

TG5.3 - Prestressing materials and systems

Since Eugène Freyssinet’s first of use high-strength steel wire for prestressing concrete in the late 1920s, there have been many changes in prestressing systems used around the world. Current systems bear little resemblance to many of the older methods used in the past. Designers and contractors need information regarding these historical practices and materials to evaluate existing prestressed concrete in need of repair and to determine effective strategies to extend service life and enhance performance. Further, as new technologies are developed, they are often used in some countries but not in others.

Task Group 5.3 (TG5.3) has established two goals: 1) to develop a state-of-the-art report describing the evolution and development of prestressing systems and to identify recent innovations and advances, and 2) to develop a new bulletin that provides recommendations for the installation of post-tensioning systems.

Convener
Tommaso Ciccone

First name	Last name	Country	Affiliation
David	Fernández-Ordóñez	Switzerland	fib
Theodore	Neff	United States	General Technologies, Inc.
Tommaso	Ciccone	Italy	TENSA (Tensacciai s.r.l.)
Christian	Gläser	Germany	DYWIDAG-Systems International
Carol	Hayek	United States	CCL
Kiyotaka	Hosoi	Japan	Shinko Wire Company Ltd
Shinya	Ikehata	Japan	Central Nippon Expressway Co Ltd
Larry	Krauser	United States	General Technologies, Inc.
Lev	Zaretsky	Russian Federation	Armasteel Llc
Hirokazu	Katsuda	Japan	Sumitomo Electric Industries, Ltd.
Nadarajah	Surendran	United Kingdom	PRAETER Engineering Ltd
Luca	Civati	Italy	Tensacciai s.r.l.
Jean‐Baptiste	Domage	Switzerland	VSL
Thierry	Steux	Belgium	-
Gregg A.	Freeby	United States	ASBI (American Segmental Bridge Institute)
Gregory	Hunsicker	United States	OnPoint Engineering and Technology LLC
Tony	Johnson	United States	PTI
Derek	Gedling	United Kingdom	PSC

TG5.4 - Recommendations for ground anchor systems

The overall motivation of Task Group 5.4 (TG5.4) is to establish a modern recommendation for the qualification of ground anchor systems.

The main objective of TG5.4 is to prepare a bulletin entitled “Recommendation for ground anchor systems” based on and updating earlier documents such as the “Recommendations for the design and construction of ground anchors”, 1996. The recommendations will include significant content for qualification of ground anchor systems covering prestressed permanent and temporary anchors.

Convener
Matthias Ryser

Co-Convener
Xiaomeng Wang

First name	Last name	Country	Affiliation
Ulf	Nürnberger	Germany	University of Stuttgart
Javier	Ripoll Garcia-Mansilla	Spain	Ripoll Consulting de Ing.
Cyril	Gaucherand	France	Freyssinet
Gosta	Ericson	Sweden	Sweco VBB AB
Mark	Sinclair	Australia	Structural Systems (Civil) Pty Ltd
David	Fernández-Ordóñez	Switzerland	fib
Theodore	Neff	United States	General Technologies, Inc.
Chris	Irvin	United Kingdom	DYWIDAG-SYSTEMS INTERNATIONAL Ltd.
Matthias	Ryser	Germany	Dr. Vollenweider AG
Hermann	Weiher	Germany	matrics engineering GmbH
Philipp	Egger	Switzerland	VSL International LTD
Behzad	Manshadi	Switzerland	-
Adrian	Gnägi	Switzerland	VSL International Ltd.
Toshiro	Kido	Japan	Sumitomo (SEI) Steel Wire Corp.
Xiaomeng	Wang	Switzerland	BBR VT international Ltd.
Andreas	Schiller	Germany	Stahlwerk Annahütte
Matthias	Wild	Germany	DYWIDAG-Systems International

TG5.5 - Cables for cable-supported bridges

fib Bulletin 89, Acceptance of cable systems using prestressing steels, as an update of the previous fib Bulletin 30 was published in 2019.

The goal of Task Group 5.5 (TG5.5) is to work on selected individual topics related to cable systems for a further future update of Bulletin 89. The topics will be addressed one after the other and published in a few individual technical reports before they will be included in a full revision of Bulletin 89.

Workflow and Timeline:

Fire protection and fire testing of cables: 2020 - 2023
Damper/damping requirements: 2022 - 2024
Icing / ice mitigation of cables: 2024 - 2025
Update on inspection technologies of cables
SHMS for cable stayed bridges with post-data processing
Illumination of stay cables
Terrorism protection of cables

A new technical report on fire protection of stay cables is expected to be published in 2023.

Convener
Werner Brand

First name	Last name	Country	Affiliation
Akio	Kasuga	Japan	Sumitomo Mitsui Construction Co., Ltd
Kiyotaka	Hosoi	Japan	Shinko Wire Company Ltd
Christos	Georgakis	Denmark	Aarhus University
Adrian	Tejera	Spain	Tycsa PSC Spain
David	Goodyear	United States	Consultant
Tommaso	Ciccone	Italy	TENSA (Tensacciai s.r.l.)
Werner	Brand	Germany	DYWIDAG-Systems International
Antonio	Caballero	Switzerland	Screening Eagle Technologies AG
Kathy	Meiss	Germany	Stuttgart University of Applied Sciences
David	Fernández-Ordóñez	Switzerland	fib
Theodore	Neff	United States	General Technologies, Inc.
Jan	Winkler	Denmark	Atkins
Hiroshi	Mutsuyoshi	Japan	Saitama University , Fac. of Eng.
Alex	Gutsch	Germany	MPA Braunschweig
Shinya	Ikehata	Japan	Central Nippon Expressway Co Ltd
Manuel	Escamilla García-Galán	Spain	PONTEM
Robert	Widmann	Switzerland	EMPA
Gregory	Hasbrouk	United States	Parsons
Philipp	Egger	Switzerland	VSL International LTD
Haifeng	Fan	Switzerland	BBR Vt International Ltd.
Ivica	Zivanovic	France	Freyssinet
Behzad	Manshadi	Switzerland	-
Hirokazu	Katsuda	Japan	Sumitomo Electric Industries, Ltd.
Sherif	Mohareb	Germany	KLÄHNE BUNG Ingenieure
Felix	Weber	Switzerland	Maurer Switzerland GmbH
Max	Vollmering	Germany	DYWIDAG-Systems Internationa
Don	Bergman	Canada	COWI
Guy	Larose	Canada	RWDI
Andrea	Castiglioni di Caronno	Italy	TENSA (Tensacciai s.r.l.)
Albert	Delgado	United States	General Technologies, Inc.
Runal	Bhattacharyya	India	IASTRUCTE, IRC, MIE

TG5.10 - Inspection and monitoring of reinforced/prestressed concrete structures

Maintenance of aging infrastructure (buildings, bridges, tunnels, etc.) is a significant part of both public, and private-entities’ budgets. The worldwide infrastructure and property maintenance costs are estimated to be EUR 180 billion per year. These costs depend on industry sector, age of the assets and governmental regulations. They highly affect the financial situation of public bodies and the profitability of enterprises.

There is a need to develop a guideline document to cover state-of-the-art inspection method statements, available sensor technologies including emerging digital solutions and remote sensing (e.g. drone inspection).

The required time for the development of this guideline is estimated between two to three years. The rough and high-level schedule is suggested as follows:

First 6 to 9 months focused on building up the team and finalize the definition of the scope and content. Both are interlinked;
Next 12 to 18 months working on developing the content of the different chapters;
Final 6 to 9 months to finalize the first draft, including editorial review, before its submission to the TG 5.10 and C5;
Finally, some time is expected to engage the peer reviewers and answer questions/comments received from the TG 5.10 and C5.

Convener
Antonio Caballero

Convener
Jan Winkler

First name	Last name	Country	Affiliation
Antonio	Caballero	Switzerland	Screening Eagle Technologies AG
Jan	Winkler	Denmark	Atkins
David	Fernández-Ordóñez	Switzerland	fib
Helder Filipe	Moreira de Sousa	Portugal	Brisa Group
Gabriel	Sas	Sweden	Luleå University of Technology
Isaac	Farretas	Denmark	COWI A/S. International Bridges
Sara	Subtil	United Kingdom	Arcadi Consulting (UK) Ltd.
Andrej	Anzlin	Slovenia	Slovenian National Building and Civil Engineering
Chris	Mundell	United Kingdom	ATKINS Limited
Hamed	Layssi	Canada	FprimeC Solutions Inc.
Cosimo	Longo	Italy	Anas S.p.A.
Ruben	Romero	Spain	Freyssinet S.A.U.
Andreas	Castiglioni	Italy	Milano Serravalle S.p.A.
Dara	McDonnell	Australia	Arup
Tohru	Makita	Japan	Central Nippon Expressway Company Limited

TG5.11 - Polymer-duct systems for internal bonded post-tensioning

Re-activate the earlier Task Group for polymer duct systems.

It should be the objective to limit changes to a minimum only where needed. It is also suggested to limit the number of drafting members to a relatively small group to facilitate web-meetings, and subsequently circulate draft changes to a wider group. Since fib Bulletin 75 is referenced in approval procedures in Europe and Florida DOT, it is imperative to have representatives of approval bodies and FDOT actively involved into the review.

Convener
Adrian Gnägi

Co-Convener
Hans Rudolf Ganz

First name	Last name	Country	Affiliation
David	Fernández-Ordóñez	Switzerland	fib
Adrian	Gnägi	Switzerland	VSL International Ltd.
Hans Rudolf	Ganz	Switzerland	Ganz Consulting
Tommaso	Ciccone	Italy	TENSA (Tensacciai s.r.l.)
Gordon	Clark	United Kingdom	Consultant
Haifeng	Fan	Switzerland	BBR Vt International Ltd.
Kiyotaka	Hosoi	Japan	Shinko Wire Company Ltd
Tohru	Makita	Japan	Central Nippon Expressway Company Limited
Teddy	Theryo	United States	BCC Engineering
Lars	Eckfeldt	Germany	Deutsches Institut für Bautechnik (DIBt)
Wilhelm	Schneider	Austria	Austrian Inst. of Constr. Eng. (OIB)
Ivica	Zivanovic	France	Freyssinet
Matthias	Wild	Germany	DYWIDAG-Systems International
Larry	Krauser	United States	General Technologies, Inc.
John	Crigler	United Kingdom	Structural Technologies
Holger	Jung	Germany	P2X GmbH: Producer
V.	Knischewski	Germany	DiBt
Christian	Krebs	Switzerland	Consultant
Klaus	Lanzinger	United States	GTI
Bob	Sward	United States	Structural Technologies

TG5.12 - Ultra-high strength prestressing steels for post-tensioning kits and stay systems

The goal of sustainability involves a consensus among economic, environmental and social factors. Due to climate change, environmental concerns have increased in society. The construction sector is among the most active high environmental impact sectors. Emissions from building and infrastructure construction are expected to form the single largest category of consumption-based emissions for C40 cities between 2017 and 2050, producing 21% of consumption emissions. As this period is critical for reducing greenhouse gas (GHG) emissions in line with keeping global temperature rise to within 1.5ºC above pre-industrial averages, serious action is needed in this area.

Ultra-High Strength Prestressing (UHSP) strands, namely strands with tensile strength of 2060 to 2360 MPa, has the potential to greatly reduce the quantity of steel necessary in concrete structures.

The goal of new proposed Task Group is the development of a guideline where the key aspects of introducing ultra-high strength strands at different prestressing applications (along with post-tensioning and stay cable systems) i.e. crucial material properties and risk of hydrogen induced stress corrosion failure, design recommendation, system and material testing, quality control, etc. are covered.

Convener
Behzad Manshadi

First name	Last name	Country	Affiliation
Behzad	Manshadi	Switzerland	-
David	Fernández-Ordóñez	Switzerland	fib
Matus	Benovic	Slovakia	Industrial Steel Wires EMEA
Tohru	Makita	Japan	Central Nippon Expressway Company Limited
Ulf	Nürnberger	Germany	University of Stuttgart
Chan	Park	Korea, Republic of	COWI Korea
Wilhelm	Schneider	Austria	Austrian Inst. of Constr. Eng. (OIB)
Matthias	Wild	Germany	DYWIDAG-Systems International
Christian	Hagen	Singapore	-
Hirokazu	Katsuda	Japan	Sumitomo Electric Industries, Ltd.
Johann	Kollegger	Austria	Vienna University of Technology
Pierluigi	Colombi	Italy	Politecnico Milano
Haifeng	Fan	Switzerland	BBR Vt International Ltd.
H.	Gil	Korea, Republic of	Korea Expressway Corporation
Bruce	Hong	Korea, Republic of	Kiswire Ltd.
Byul	Shim	Korea, Republic of	DAOR E&C Co., Ltd
Falk	Meyer	Germany	Technische Universität München

TG5.13 - Grouting of tendons in prestressed concrete

Prestressed Concrete is a very efficient form of construction; it takes advantage of the strength of concrete in compression. Developed mainly over the second part of the 20th century, it has proven to be reliable and durable. However, in the 1990's some cause for concern was discovered, first in the UK and followed by many other countries of the world. It appeared that the grout, an important means of protection of the steel against corrosion for internally ducted tendons, was in some cases inadequate.

The goal of new proposed Task Group is the development of a Guide to good practice. As the first proposal, the document will cover the same topics as the original bulletin 20.

Convener
Guillermo Ramírez

First name	Last name	Country	Affiliation
Guillermo	Ramirez	Switzerland	VSL International Ltd
David	Fernández-Ordóñez	Switzerland	fib
Carmen	Andrade	Spain	Centre Internacional de Mètodes Numèrics en l’Ènginyeria (CIMNE)
Tommaso	Ciccone	Italy	TENSA (Tensacciai s.r.l.)
Hans Rudolf	Ganz	Switzerland	Ganz Consulting
Christian	Gläser	Germany	DYWIDAG-Systems International
Behzad	Manshadi	Switzerland	-
Teddy	Theryo	United States	BCC Engineering
Mariela	Cordero Verge	Spain	MK4 WORLD WIDE, S.L.
Brian	Merrill	United States	Wiss, Janney, Elstner Associates, Inc.
Alex	Gutsch	Germany	MPA Braunschweig
Kyoji	Niitani	Japan	Oriental Shiraishi Corporation
Matthias	Wild	Germany	DYWIDAG-Systems International
Byul	Shim	Korea, Republic of	DAOR E&C Co., Ltd
Tatiana	Colomiicenco	Austria	Werba
Jaime	Gálvez Ruiz	Spain	Universidad Politecnica de Madrid
Bruno	Godart	France	-
Stéphane	Gonichon	France	Private
Amparo	Moragues	Spain	UPM
Sylvie	Paulus	France	Aiglon
Tobias	Reinelt	Austria	Werba
Helena	Santana	France	Aiglon
Ivica	Zivanovic	France	Freyssinet

TG5.14 - Durability of post-tensioning tendons

The goal of new proposed Task Group is to update the fib bulletin 33 published in 2005 and merge with the FHWA's technical report "Methodology for risk assessement of post-tensioning tendons.

Convener
Gregory Hunsicker

Co-Convener
Hans-Rudolf Ganz

First name	Last name	Country	Affiliation
Hans Rudolf	Ganz	Switzerland	Ganz Consulting
Gregory	Hunsicker	United States	OnPoint Engineering and Technology LLC
David	Fernández-Ordóñez	Switzerland	fib
Shinya	Ikehata	Japan	Central Nippon Expressway Co Ltd
Reggie H.	Holt	United States	Federal Highway Administration
Will	Potter	United States	Florida Department of Transportation
Teddy	Theryo	United States	BCC Engineering
Luigi	Evangelista	Italy	Italferr SpA
Franco	Lacobini	Italy	Italian Railway - RFI
Walter	Waldis	Switzerland	Swiss Federal Roads Office - FEDRO
Pascal	Massart	Belgium	SPW Mobility and Infrastructure
Adrien	Houel	France	French Ministry of Transports
Gero	Marzahn	Cote d'Ivoire	Germany Federal Ministry for Digital and Transport
Brett	Pielstick	United States	Eisman & Russo
Gordon	Clark	United Kingdom	Consultant
Glenn	Washer	United States	University of Missouri
Christian	Gläser	Germany	DYWIDAG-Systems International
Larry	Krauser	United States	General Technologies, Inc.
Tommaso	Ciccone	Italy	TENSA (Tensacciai s.r.l.)
John	Corven	United States	Hardesty & Hannover Convener
On	Cornelius	United States	-
Edoardo	Proverbio	Italy	University of Messina, Italy

COM4: Concrete & concrete technology

Written on 21 March 2017.

Motivation

The overall motivation of fib Commission 4 (COM4) is to make theoretical and practical developments in the field of concrete and concrete technology, and to present these developments in an understandable and code-type formulated manner. COM4 positions itself at the forefront of new technologies and techniques by considering both fundamental research and practical issues.

Scope and objective of technical work

The aim of COM4 is to collect and to validate information on the properties and behaviour of concrete for structural applications subjected to various types of loading and environmental conditions. The commission focuses its attention both on traditional types of concrete, in particular under unusual conditions, and on new types of concrete and cementitious composites under all types of loading and condition. The properties of the concrete types considered should be formulated in such a way that it is possible to derive behavioural models and design recommendations for practical applications.

Commission Chair
Jean Michel Torrenti

Deputy Chair
Tor Arne Martius-Hammer

First name	Last name	Country	Affiliation
Frank	Dehn	Germany	KIT Karlsruher Institut für Technologie
Steinar	Helland	Norway	S Helland Konsult
Joost	Walraven	Netherlands	Delft University of Technology
Mette	Geiker	Norway	NTNU - Trondheim Norwegian Univ.
Viktor	Mechtcherine	Germany	Technical Univ. Dresden
David	Fernández-Ordóñez	Switzerland	fib
Hans-Dieter	Beushausen	South Africa	University of Cape Town
Harald	Müller	Germany	SMP Ingenieure im Bauwesen GmbH
Steffen	Grünewald	Netherlands	Ghent University
Geert	de Schutter	Belgium	Ghent University
Tamon	Ueda	China	Shenzhen University
Ludger	Lohaus	Germany	Leibniz Universität Hannover
Lucie	Vandewalle	Belgium	KULeuven
Jean Michel	Torrenti	France	Univ Gustave Eiffel
Roman	Wan-Wendner	Belgium	Ghent University
Nikola	Tošić	Spain	Universitat Politècnica de Catalunya
Fragkoulis	Kanavaris	United Kingdom	Arup
Martin	Cyr	France	Université de Toulouse
Tor	Martius-Hammer	Norway	SINTEF AS
Michael	Haist	Germany	Leibniz Universität Hannover
Eduardo	Julio	Portugal	Instituto Superior Tecnico, Universidade de Lisboa
Liberato	Ferrara	Italy	Politecnico di Milano
Jaime	Gálvez Ruiz	Spain	Universidad Politecnica de Madrid

TG4.0 - Code-type Concrete Models

The first target of TG4.0 consists in developing an updated code-type presentation of the constitutive and durability related behaviour of structural concrete for inclusion in MC2020. The basis and point of origin of the AG’s/TG’s work is formed by the existing chapter 5.1 “Concrete” in MC2010. The work of TG4.0 comprises firstly a critical review and an updating of the existing models, further the implementation of new available concrete models, taking into consideration the increase of knowledge by research within the last decade. Major criteria for models being suited are their physical and thermo-dynamical soundness and accuracy as well as practical characteristics like simplicity and operationality. Further, emphasis is placed on concise explanatory notes and well-selected references which will be given as commentary (left-hand column) to the code text.

The second target of TG4.0 consists in preparing a background document (Bulletin) on the concrete models included in the chapter “Concretes” of MC2020. This document will give detailed background information together with the results of analyses and evaluations. Thus, the bulletin will represent a comprehensive summary of the relevant knowledge available to the members of the Task Group 4.0 at the time of its drafting. Moreover, the new bulletin will provide an essential basis for the development of future generations of code-type models related to the characteristics and the behaviour of structural concrete. Further it will offer insights into the complexity of the normative work related to code-type concrete modelling, leading to a better understanding and adequate appreciation of MC2020.

This new Bulletin will be an update of the Bulletin 70 “Code-type models for concrete behaviour – Background of MC2010”, which has been released parallel to MC2010 in 2013.

Convener
Harald Müller

First name	Last name	Country	Affiliation
Harald	Müller	Germany	SMP Ingenieure im Bauwesen GmbH
David	Fernández-Ordóñez	Switzerland	fib
Carmen	Andrade	Spain	Centre Internacional de Mètodes Numèrics en l’Ènginyeria (CIMNE)
Mouna	BOUMAAZA	France	Vinci Construction
Manfred	Curbach	Germany	Technische Univ. Dresden
Avraham	Dancygier	Israel	Technion-Israel Institute of Technology
Frank	Dehn	Germany	KIT Karlsruher Institut für Technologie
Vyatcheslav	Falikman	Russian Federation	Russian Structural Concrete Association
Christoph	Gehlen	Germany	TUM School of Engineering and Design
Michael	Haist	Germany	Leibniz Universität Hannover
Petr	Hajek	Czech Republic	Czech Technical University in Prague
Terje	Kanstad	Norway	The Norwegian Univ.of Science & Tech
Sylvia	Kessler	Germany	Helmut-Schmidt-University/ University of the Federal Armed Forces Hamburg
Lionel	Linger	France	Vinci Construction Grand Projets
Ludger	Lohaus	Germany	Leibniz Universität Hannover
Viktor	Mechtcherine	Germany	Technical Univ. Dresden
Nadja	Oneschkow	Germany	Leibniz University Hannover
Takumi	Shimomura	Japan	Nagaoka Univ. of Technology
Darko	Tasevski	Switzerland	Emch+Berger AG Bern
Jean Michel	Torrenti	France	Univ Gustave Eiffel
Nikola	Tošić	Spain	Universitat Politècnica de Catalunya
Amir	Rahimi	Germany	Bundesanstalt für Wasserbau
Hans-Wolf	Reinhardt	Germany	Universität Stuttgart
Michael	Vogel	Germany	Karlsruher Institut für Technologie (KIT) - Universität (Campus Süd)
Tamon	Ueda	China	Shenzhen University
Joost	Walraven	Netherlands	Delft University of Technology
Roman	Wan-Wendner	Belgium	Ghent University
Peng	Zhang	China	Qingdao University of Technology
Ulrich	Häussler-Combe	Germany	Consultant
Vladislav	Kvitsel	Germany	Karlsruhe Institute of Technology
Kerstin	Speck	Germany	Technische Universität Dresden
Fernando	Acosta	Germany	Züblin AG

TG4.1 - Fibre-reinforced concrete

Model Code 2020 has completed the draft related to the homogenization of FRC to RC and PC design rules,starting from the principles introduced for the first time in Model Code 2010.

Even if the proposed equations are now better harmonized with those controlling the behaviour of the common concrete structures, many aspects, remained out of the code.

These aspects have been already investigated mainly in relation to steel fibres, but we need to extend them to any type of fibres and to hybrid concretes. Moreover, the market has been strongly oriented to sustainability and to the introduction of new matrixes to reduce CO2 emissions and therefore we have to understand which effectiveness can be guaranteed with the adoption of these eco-mixes.

After the publication of the Bulletin 105, we need a special bulletin able to propose other examples of real applications, aimed at checking the effectiveness of the equations introduced and the advantages correlated to sustainability. These examples should be also analysed in other Commissions like the number 1, 3 and 7. When a good proposal concerning the indicated aspects will be achieved, the suggestion is to introduce it, updating the actual draft of Model Code, without waiting for the next edition. To this aim a special role should be played by databases: the database already started by Albert De La Fuente has to be developed, because it could help the evolution of future proposals, making them much more reliable. It has to be enlarged to UHPC where a special need of data is required.

Convener
Marco Di Prisco

First name	Last name	Country	Affiliation
Jan	Vítek	Czech Republic	Metrostav a. s.
Lucie	Vandewalle	Belgium	KULeuven
David	Fernández-Ordóñez	Switzerland	fib
Frank	Dehn	Germany	KIT Karlsruher Institut für Technologie
Pierre	Rossi	France	IFSTTAR
Barzin	Mobasher	United States	Arizona State University
Giovanni	Plizzari	Italy	University of Brescia
Joaquim	A. O. Barros	Portugal	Universidade do Minho
György L.	Balázs	Hungary	Budapest Univ. of Techn. & Economics
Marco	di Prisco	Italy	Politecnico di Milano
Avraham	Dancygier	Israel	Technion-Israel Institute of Technology
Gustavo	Parra-Montesinos	United States	University of Michigan
Ingemar	Löfgren	United Kingdom	-
Nemkumar	Banthia	Canada	Univ. of British Columbia
Bryan	Barragan	France	OCV Chambery International
Billy	Boshoff	South Africa	University of Pretoria
Terje	Kanstad	Norway	The Norwegian Univ.of Science & Tech
Bruno	Massicotte	Canada	Ecole Polytechnique de Montréal
Fausto	Minelli	Italy	University of Brescia
Pedro	Serna Ros	Spain	Univ. Politecnica de Valencia-Icitech
ab	van den bos	Netherlands	NLyse
Elena	Vidal Sarmiento	Spain	Bekaert
Jaime	Gálvez Ruiz	Spain	Universidad Politecnica de Madrid
Juan Carlos	Lancha Fernandez	Spain	PACADAR SA
Ingrid	Lande	Norway	University of Agder
Albert	De la Fuente	Spain	Universitat Politècnica de Catalunya
Ekkehard	Fehling	Germany	IBB Fehling + Jungmann GmbH
François	Toutlemonde	France	Université Gustave Eiffel
Giulio	Zani	Italy	Politecnico di Milano
Joost	Walraven	Netherlands	Delft University of Technology
Johan	Silfwerbrand	Sweden	KTH Royal Institute of Technology
Liberato	Ferrara	Italy	Politecnico di Milano
Martin	Hunger	Germany	BASF Construction Solutions GmbH
Matteo	Colombo	Italy	Politecnico di Milano
Milan	Kalny	Czech Republic	Pontex s.r.o. Prague
Nilüfer	Özyurt	Turkey	Boğaziçi University
Ralf	Winterberg	Malaysia	Managing Director
Sébastien	WOLF	Luxembourg	ArcelorMittal Fibres
Stephen	Foster	Australia	UNSW Australia
Vincent	Oettel	Germany	-
Viktor	Mechtcherine	Germany	Technical Univ. Dresden
Gonzalo	Ruiz	Spain	ETSI Caminos, C. y P. — Universidad de Castilla-La Mancha
Juan	Navarro-Gregori	Spain	Institute of Concrete Science and Technology (ICITECH), Universitat Politècnica de València
Yuri	Karinski	Israel	Technion - Israel Institute of Technology
Nicola	Buratti	Italy	University of Bologna
Rutger	Vrijdaghs	Belgium	KU Leuven
Silvia	Ientile	France	Eiffel University
Tony	Jones	United Kingdom	Concrete centre
Aurelio	Muttoni	Switzerland	École polytechnique fédérale de Lausanne (EPF Lausanne)
Agnieszka	Bigaj-van Vliet	Netherlands	TNO - Buildings, Infrastructures and Maritime
Marios	Soutsos	United Kingdom	n/a
Alessio	Caverzan	Netherlands	Directorate-General Joint Research Centre (JRC)
Peter	Mark	Germany	Ruhr-Universität Bochum
Paul	Vickers	United Kingdom	Thorpe Precast
Serge Auguste	Nana	France	Holcim Innovation Center
Gabriele David	Bocchino	Italy	-
Paolo	Martinelli	Italy	Politecnico di Milano

TG4.3 - Structural design with flowable concrete

Flowable concrete (highly flowable, self-compacting and/or self-levelling) has evolved from a special type to a commonly applied building material. fib Task Group 4.3 (TG4.3) considers three aspects of flowable concrete (FC) for structural design: material properties, production effects and structural boundary conditions. The flow of concrete (initiated by some vibration and/or the weight of concrete) can affect the structural characteristics of hardening or hardened concrete. The mixture composition has to be adjusted and optimised in order to obtain a high flowability. TG4.3 aims at promoting the application of flowable concrete, improving and adapting the concrete design and the production technology and its implementation in guidelines and codes.

Convener
Steffen Grünewald

Co-Convener
Liberato Ferrara

First name	Last name	Country	Affiliation
Frank	Dehn	Germany	KIT Karlsruher Institut für Technologie
Liberato	Ferrara	Italy	Politecnico di Milano
Mouloud	Behloul	France	Lafarge
Ravindra	Gettu	India	Indian Institute of Technology Madras
Bas	Obladen	Netherlands	Strukton Group
Peter	Billberg	Sweden	Strängbetong
Laetitia	Martinie	France	INSA
Nicolas	Roussel	France	IFSTTAR
Bernhard	Freytag	Austria	Technische Universität Graz
Mohamed	Sonebi	Ireland	Queen’s University Belfast
Patrick	Stähli	Switzerland	Concretum Construction Science AG
Filipe	Laranjeira	Spain	Univ. Politecnica de Catalunya
Guido	Bertram	Germany	Grawe + Bertram Ingenieure
Andreas	Leemann	Switzerland	EMPA
Susan	Taylor	Ireland	Queen's University Belfast
Sandra	Nunes	Portugal	University of Porto
On	Spangenberg	Denmark	Technical University of Denmark
Gregor	Fischer	Denmark	Technical University of Denmark
Joost	Walraven	Netherlands	Delft University of Technology
Mette	Geiker	Norway	NTNU - Trondheim Norwegian Univ.
Terje	Kanstad	Norway	The Norwegian Univ.of Science & Tech
Henrik	Stang	Denmark	University of Denmark
Konrad	Zilch	Germany	TU München
Steffen	Grünewald	Netherlands	Ghent University
Wolfram	Schmidt	Germany	BAM - Bundesanstalt für - Materialforschung und -prüfung
John	Cairns	United Kingdom	Heriot-Watt University
David	Fernández-Ordóñez	Switzerland	fib
Bryan	Barragan	France	OCV Chambery International
Harald	Beitzel	Germany	Inst. für Bauverfahrens- und Umwelttechnik
Yasuhiko	Sato	Japan	Waseda University
Lucie	Vandewalle	Belgium	KULeuven
Joaquim	A. O. Barros	Portugal	Universidade do Minho
Marco	di Prisco	Italy	Politecnico di Milano
Tor	Martius-Hammer	Norway	SINTEF AS

TG4.4 - Restoration of heritage in exposed concrete

The activity of Task Group 4.4 is focused in aesthetics of concrete surfaces. The topic is relevant for all exposed concrete structures but holds particular importance in the case of buildings designed by well-known architects. Previous work by this Task Group addressed the issues that need to be considered regarding concrete mix design and casting, aiming at obtaining exposed concrete surfaces with homogenous appearance. A state-of-the-art technical report was prepared with recommendations and guidelines.

Since existing exposed concrete structures are in direct contact with the environment, they are prone to experience degradation faster, and since appearance is a main key-issue, maintenance of this type of structures needs to be properly addressed. In addition, many of these structures have a unique cultural (historical, architectural, technical, other) value, being therefore classified as heritage. For this reason, the repair techniques adopted for current concrete structures may not be adequate in some situations and restoration methods must be adopted instead.

TG 4.4 future work will address the issues that need to be considered regarding conservation and restoration of the built heritage in exposed concrete. The main goal of the Task Group is to publish an fib guide of good practice, including recommendations and guidelines, as well as successful examples that can be assumed as reference case studies.

Convener
Eduardo Julio

First name	Last name	Country	Affiliation
David	Fernández-Ordóñez	Switzerland	fib
Eduardo	Julio	Portugal	Instituto Superior Tecnico, Universidade de Lisboa
Jónatas	Valenca	Portugal	Universidade de Lisboa
Hugo Sérgio	Sousa Costa	Portugal	ISEC - Institute of Engineering of Polytechnic Institute of Coimbra
Robert	Armbruster	United States	The Armbruster Company, Inc.
Elisa	Franzoni	Italy	University of Bologna
Elisabeth	Marie-victoire	France	Laboratoire de Recherche des Monuments Historiques
Myriam	Bouichou	France	Laboratoire de Recherche des Monuments Historiques
Teresa	Cunha - Ferreira	Portugal	University of Porto
Xavier	Hallopeau	France	SECCO Corrosion Consulting
Elsa	Eustáquio	Portugal	Laboratório Nacional de Engenharia Civil
Véronique	Bouteiller	France	University Gustave Eiffel
Helena	Silva	Portugal	Laboratório Nacional de Engenharia Civil, LNEC
Carmen	Andrade	Spain	Centre Internacional de Mètodes Numèrics en l’Ènginyeria (CIMNE)
Claudia	Devaux	France	dda devaux & devaux architects
Ana	Tostões	Portugal	Universidade de Lisboa

TG4.5 - Time-dependent Behavior of Concrete

The primary objective of the task group is to identify limiting aspects during the design of new or assessment of existing structures related to predicting the time-dependent (mechanical) behavior of “new” but also “traditional” concrete types. Based on the identified short-comings the task group will initiate literature reviews, compile/ update consistent databases and update existing model formulations. Where possible the TG will make use of the data already available in the scientific literature. Where this is not the case, the task group will strive to develop research strategies and coordinate research efforts by its members, supported by national or international research funds.

The task group plans to develop databases and calibrated prediction models for the time-dependent mechanical properties of cast concrete including:

Maturity vs. time concepts, applicable to early age and multi-decade predictions
Development of compressive and tensile strength as function of maturity/ time;
Development of Young’s modulus as function of maturity/ time;
Development of fracture energy as function of maturity/ time;
Development of creep and shrinkage as function of maturity/ time;
Empirical relationship between mechanical properties and compressive strength as function of maturity/ time;
Development of stress-strain diagram as function of maturity/ time;
Transport of liquids and gases;
Guidance for the coupled hygro-thermal chemo-mechanical analysis of concrete with relevance to e.g. mass concrete or certain structural components prone to early-age cracking;
Guidance for the time-dependent nonlinear (fracture mechanical) analysis of concrete including advanced constitutive models and strain rate effects;
Time-dependent resistance of concrete subject to sustained load
Time-dependent resistance of concrete subject to fatigue;

Convener
Roman Wan-Wendner

First name	Last name	Country	Affiliation
Guang	Ye	Netherlands	Delft University of Technology
Michael	Haist	Germany	Leibniz Universität Hannover
David	Fernández-Ordóñez	Switzerland	fib
Roman	Wan-Wendner	Belgium	Ghent University
Dara	McDonnell	Australia	Arup
Harald	Müller	Germany	SMP Ingenieure im Bauwesen GmbH
Jan	Vítek	Czech Republic	Metrostav a. s.
Jean Michel	Torrenti	France	Univ Gustave Eiffel
Takumi	Shimomura	Japan	Nagaoka Univ. of Technology
Darko	Tasevski	Switzerland	Emch+Berger AG Bern
Alejandro	Pérez Caldentey	Spain	Universidad Politécnica de Madrid
Nikola	Tošić	Spain	Universitat Politècnica de Catalunya
Jan	Cervenka	Czech Republic	Cervenka Consulting Ltd
Ravi	Patel	Germany	Institute of Building materials (IMB)
Nadja	Oneschkow	Germany	Leibniz University Hannover
Eamon	Stack	Ireland	Banagher Precast
Peter	Takacs	United Kingdom	aecom
Giovanni	Di Luzio	Italy	Politecnico di Milano
Farid	Benboudjema	France	ENS Paris-Saclay, Université Paris-Saclay
Richard	Caron	Germany	KIT
Anja	Klausen	Norway	NTNU
Antonia	Menga	Norway	NTNU
Mohammad	Najeeb Shariff	India	Indian Institute of Technology Bombay
Dirk	Schlicke	Austria	Technische Universität Graz
Thierry	Vidal	France	LMDC (Laboratoire Matériaux et Durabilité des Constructions)
Enrico	Masoero	Italy	Politecnico di Milano
Juan	Garzón	Netherlands	TNO

TG4.7 - Structural Applications of Recycled Aggregate Concrete – Properties, Modeling, and Design

The main objective of the TG is to formulate design recommendations for the structural use of RAC. This will take the form of proposing new or adjusting existing expressions and models for mechanical and structural properties of reinforced and prestressed concrete structures.

To achieve this goal, the TG will first perform a comprehensive critical review of literature alongside a preparation of databases of experimental results regarding mechanical and structural properties of RAC. Where necessary and possible, identified gaps in existing results will be complemented by new studies of TG members within existing or new research projects. Based on this work, the TG will formulate expressions and models for the following:

Physical properties of RAC – density, water absorption, permeability
Mechanical properties – compressive strength, tensile strength, modulus of elasticity, stress–strain relationship, fracture energy, shrinkage, creep
Durability-related properties – carbonation resistance, chloride ingress, freeze-thaw resistance, chemical attack
Structural behavior – flexural strength, shear strength, axial strength, punching strength, seismic resistance, fire resistance, deformation, cracking, bond and anchorage
Fire resistance of RAC and RAC structures – resistance under fire and residual resistance after exposure to elevated temperatures of RAC and reinforced and prestressed RAC members

Convener
Nikola Tošić

Co-Convener
Jean-Michel Torrenti

First name	Last name	Country	Affiliation
Nikola	Tošić	Spain	Universitat Politècnica de Catalunya
Jean Michel	Torrenti	France	Univ Gustave Eiffel
David	Fernández-Ordóñez	Switzerland	fib
Harald	Müller	Germany	SMP Ingenieure im Bauwesen GmbH
Takafumi	Noguchi	Japan	University of Tokyo
Frank	Dehn	Germany	KIT Karlsruher Institut für Technologie
João Nuno	Pacheco	Portugal	CERIS/c5Lab Sustainable Construction Materials Association
Hans-Dieter	Beushausen	South Africa	University of Cape Town
Roman	Wan-Wendner	Belgium	Ghent University
Ivan	Ignjatović	Serbia	University of Belgrade
Albert	De la Fuente	Spain	Universitat Politècnica de Catalunya
Marija	Nedeljković	Netherlands	Rijkswaterstaat
Yahya	Kurama	France	Univ. of Notre Dame
Jiabin	Li	Belgium	KU Leuven
Amor	Ben Fraj	France	CEREMA
George	Wardeh	France	Un. de Cergy-Pontoise
Flavio	Stochino	Italy	Università di Cagliari
Miren	Etxeberria	Spain	UPC Edu
Sindy	Seara-Paz	Spain	Universidade a Coruña
Mirian	Velay-Lizancos	United States	Purdue University
Romildo	Toledo Filho	Brazil	Federal University of Rio de Janeiro
Liberato	Ferrara	Italy	Politecnico di Milano
Samer	Al-Martini	United Arab Emirates	Abu Dhabi University
Elhem	Ghorbel	France	CY Cergy Paris university
Belén	Gonzalez-Fonteboa	Spain	Universidade de Coruña
Enzo	Martinelli	Italy	University of Salerno
Marco	Pepe	Italy	University of Salerno
Jan	Podroužek	Czech Republic	Brno University of Technology
Reem	Sabouni	United Arab Emirates	Abu Dhabi University
Snežana	Marinković	Serbia	University of Belgrade
Ali	Abbas	United Kingdom	University of East London
Fabienne	Robert	France	CERIB
Sivakumar	Kandasami	India	L&T Construction
Boksun	Kim	United Kingdom	University of Plymouth
Dan V.	Bompa	United Kingdom	University of Surrey
Shahria	Alam	Canada	University of British Columbia
Bohuslav	Slánský	Czech Republic	Skanska
Pawel	Sikora	Poland	West Pomeranian University of Technology in Szczecin
Sandrine	Braymand	France	University of Strasbourg
Jean Michel	Mechling	France	Université de Lorraine
Zengfeng	Zhao	China	Tongji University
Débora	Martinello Carlesso	Spain	-
Irene	Josa	United Kingdom	University College London (UCL)
Dora	Foti	Italy	Politecnico di Bari
Arthur	Slobbe	Netherlands	TNO
Juan	Garzón	Netherlands	TNO
Khaled	Hassan	Qatar	IRD (Infrastructure Research & Development)
Cristiano Giuseppe	Coviello	Italy	-
Lucas	Menegatti	Brazil	UFRJ
Ana Sofia	Louro	Portugal	LNEC
Kaihua	Liu	China	-
Marco	Davolio	Italy	Politecnico di Milano
Jean Ayodélé	Adessina	France	Cerema
Sourav	Chakraborty	India	Indian Institute of Technology Hyderabad
KVL	Subramaniam	India	Indian Institute of Technology Hyderabad
Ruben Paul	Borg	Malta	University of Malta
Annkathrin	Sinning	Germany	-
Josef	Hegger	Germany	RWTH Aachen
Martin	Classen	Germany	RWTH Aachen University
Thorsten	Stengel	Germany	-
Peter	Wild	Germany	Munich University of applied sciences
Andrea	Kustermann	Germany	Munich University of applied sciences
Jairo	Andrade	Brazil	Graduate Program in Materials and Engenheering Technology
Wengui	Li	Australia	-
Dario	Coronelli	Italy	Politecnico di Milano
Ricardo	Carrazedo	Brazil	Universidade São Paulo
Jelena	Nikolić	Serbia	University of Belgrade
Svetlana	Kostić	Serbia	University of Belgrade
Qifan	Ren	Portugal	University of Lisbon
Fragkoulis	Kanavaris	United Kingdom	Arup

TG4.8 - Low-carbon concrete structures

Decreasing the environmental impact of concrete structures is an objective put forward by almost all the actors involved in the domain of construction. Although cementitious materials intrinsically involve low embodied energy, their use in large volumes in worldwide construction lead to approximately 8% of global CO2 emissions. Portland cement is the main constituent responsible for the environmental impacts caused by the life cycle of concrete, as it generates on average more than 800 kg CO2/t of clinker.

The task group will have two main objectives:

1- Identify the different ways to obtain low-CO2 concretes among the different possible routes:

Evaluate which ones are rapidly reachable and how far we are from an universal utilization of these concretes.
Define the work to carry out to bring these concrete at an industrial level.
Estimate the scientific, technical and economical obstacles and challenges that could retard the implementation and acceptances of such concretes.

2- Evaluate the consequences of these low-CO2 concretes on the design of concrete structures, in terms of:

Durability, for instance the impact of these new concretes on carbonation and chloride ingress, the most widespread problems facing reinforced concrete worldwide.
Structural design, with the verification of the applicability of the international codes (Eurocodes…). The part concerning creep and shrinkage will be developed in the new COM4/TG Time dependent behavior of concrete.

Convener
Martin Cyr

Co-Convener
Michael Haist

First name	Last name	Country	Affiliation
Martin	Cyr	France	Université de Toulouse
David	Fernández-Ordóñez	Switzerland	fib
Michael	Haist	Germany	Leibniz Universität Hannover
Jean Michel	Torrenti	France	Univ Gustave Eiffel
Taku	Matsuda	Japan	SUMITOMO MITSUI CONSTRUCTION CO., LTD
Zoi	Ralli	Canada	Lassonde School of Engineering
Zengfeng	Zhao	China	Tongji University
Ali	Abbas	United Kingdom	University of East London
Hasanain	Al-Naimi	United Kingdom	University of East London
Shashank	Bishnoi	India	Indian Institute of Technology Delhi
Mouna	BOUMAAZA	France	Vinci Construction
Guillaume	Habert	Switzerland	ETH Zurich
Tor	Martius-Hammer	Norway	SINTEF AS
Rachida	Idir	France	Cerema
Fragkoulis	Kanavaris	United Kingdom	Arup
Tim	Lohmann	United Kingdom	Wentworth House Partnership
Takafumi	Noguchi	Japan	University of Tokyo
Arezki	Tagnit Hamou	Canada	Sherbrooke University
Stefanie	Von Greve-Dierfeld	Switzerland	TFB Technology and Research for Concrete Structures
Brant	Walkley	United Kingdom	University of Sheffield
Roman	Wan-Wendner	Belgium	Ghent University
Eduardo	Julio	Portugal	Instituto Superior Tecnico, Universidade de Lisboa
Hugo Sérgio	Sousa Costa	Portugal	ISEC - Institute of Engineering of Polytechnic Institute of Coimbra
Ricardo Nuno Francisco	do Carmo	Portugal	ISEC - Coimbra Institute of Engineering
Jean-Philippe	Vacher	France	MG Group
Hisham	Hafez	United Kingdom	University of Leeds
Jörg	Unger	Germany	Bundesanstalt für Materialforschung und -prüfung, BAM
Karen	Scrivener	Switzerland	EPFL
Sylvia	Kessler	Germany	Helmut-Schmidt-University/ University of the Federal Armed Forces Hamburg
VANDERLEY	JOHN	Brazil	Polytechnic School
Leandro	Moretti Sanchez	Canada	-
Denny	Coffetti	Italy	University of Bergamo
Felix	Clauß	Germany	-
Mohammed	Hamdallah	Portugal	University of Porto (MBUILD)
Sebastian	Spirkl	Germany	-

COM3: Existing concrete structures

Written on 21 March 2017.

Motivation

The goal of Commission 3 (COM3) is to define appropriate and reliable procedures to establish the safety of existing structures and any associated requirements for interventions to extend the safe operation or working life of such structures.

Scope and objective of technical work

COM3 will deliver this through the preparation of comprehensive guidance for the assessment of existing concrete structures, providing complementary recommendations to those given in the fib Model Code for Concrete Structures 2010 (fib MC2010), which was prepared primarily for the design of new concrete structures. To that end, COM3 will produce documents supporting the development of fib Model Code 2020 (fib MC2020) to be used for the assessment of the present structural performance and the prediction and evaluation of future structural performance of existing concrete structures with or without damage and/or revised operational requirements, together with any associated interventions required to extend their service life. It is envisaged that the documents to be produced could include technical reports, reviews of the state-of-the-art and technical history/evolution, technical guidelines, specifications and recommendations.

Commission Chair
Alfred Strauss

Deputy Chair
Robby Caspeele

First name	Last name	Country	Affiliation
Joost	Walraven	Netherlands	Delft University of Technology
Miroslav	Sykora	Czech Republic	Czech Technical University in Prague
Alfred	Strauss	Austria	BOKU University
Raphael	Steenbergen	Netherlands	TNO Structures and Safety
Giuseppe	Mancini	Italy	Politecnico Torino
Gerrie	Dieteren	Netherlands	TNO
David	Fernández-Ordóñez	Switzerland	fib
Stuart	Matthews	United Kingdom	Matthews Consulting
Sylvia	Kessler	Germany	Helmut-Schmidt-University/ University of the Federal Armed Forces Hamburg
José	Campos e Matos	Portugal	University of Minho
Thomas	Braml	Germany	Universität der Bundeswehr München
Tamon	Ueda	China	Shenzhen University
Robby	Caspeele	Belgium	Ghent University
Dario	Coronelli	Italy	Politecnico di Milano
Agnieszka	Bigaj-van Vliet	Netherlands	TNO - Buildings, Infrastructures and Maritime
Wouter	Botte	Belgium	Ghent University
Takumi	Shimomura	Japan	Nagaoka Univ. of Technology
Kamyab	Zandi	Canada	Timezyx Inc
Maria Pina	Limongelli	Italy	Politecnico di MIlano

TG3.1 - Reliability and safety evaluation: full-probabilistic and semi-probabilistic methods for existing structures

fib Task Group 3.1 (TG3.1) focuses on the reliability and safety evaluation of existing structures and focuses on the development of risk and reliability target levels for assessment and retrofitting, the full-probabilistic modelling of the structural safety and semi-probabilistic assessment methods for existing structures.

The TG aims to (i) resolve pending questions with respect to the full-probabilistic assessment and target safety levels for the assessment and retrofitting of existing structures, and (ii) support the risk and reliability related questions arising due to the developments in TG3.2, TG3.3 and TG3.4.

Initially, attention will be given to developing a technical guideline for assigning target reliabilities and making a suitable risk differentiation for existing and monumental structures, considering both individuals and groups.

Convener
Miroslav Sykora

Co-Convener
Raphaël Steenbergen

First name	Last name	Country	Affiliation
Dimitris	Diamantidis	Germany	Fachhochschule Regensburg
Diego Lorenzo	Allaix	Netherlands	TNO Neitherlands
Miguel	Prieto	Sweden	RISE Research Institutes of Sweden
Marcus	Achenbach	Germany	LGA KdöR
Max	Hendriks	Netherlands	Delft University of Technology
Giuseppe	Mancini	Italy	Politecnico Torino
Jan	Cervenka	Czech Republic	Cervenka Consulting Ltd
Alfred	Strauss	Austria	BOKU University
Miroslav	Sykora	Czech Republic	Czech Technical University in Prague
Raphael	Steenbergen	Netherlands	TNO Structures and Safety
David	Fernández-Ordóñez	Switzerland	fib
Peter	Tanner	Spain	Cesma Ingenieros, SL
José	Campos e Matos	Portugal	University of Minho
Paolo	Castaldo	Italy	Politecnico di Torino
Diego	Gino	Italy	Politecnico di Torino
Christian	Glock	Germany	Technical University of Kaiserslautern
Ramón	Hingorani	Spain	Instituto Eduardo Torroja
Carlos Paul	Lara Sarache	Spain	Instituto Eduardo Torroja
Luis	Neves	United Kingdom	Nottingham University
Wouter	Botte	Belgium	Ghent University
Filippo	Sangiorgio	Sweden	COWI AB
Lukas	Novak	Czech Republic	Brno University of Technology
Aurelio	Muttoni	Switzerland	École polytechnique fédérale de Lausanne (EPF Lausanne)
Mayer	Melhem	Australia	Monash University
Peter	Kotes	Slovakia	University of Zilina
João	André	Portugal	Portuguese National Laboratory for Civil Engineering
Dara	McDonnell	Australia	Arup
Robby	Caspeele	Belgium	Ghent University
Pierre	van der Spuy	South Africa	Stellenbosch University
Marcelo	Melo	Brazil	Casagrande Engenharia
Qianhui	Yu	China	École polytechnique fédérale de Lausanne (EPF Lausanne)
Giorgio	Monti	Italy	Sapienza Università di Roma
Oladimeji	Olalusi	South Africa	University of Kwazulu-Natal

TG3.2 - Modeling of structural performance of existing concrete structures

It is widely understood and accepted that existing concrete structures are different entities to contemporary new concrete structures. There are numerous flexibilities inherent to the process of the design of new concrete structures and in their construction. Existing structures are entities that can, in principle, be interrogated and assessed to establish their actual nature and condition. However, such processes have their difficulties and uncertainties and it is in fact often very difficult to interrogate an existing structure. These difficulties increase when an existing structure has experienced damage or deterioration. Accordingly, substantial and different uncertainties remain with respect to existing structures and these uncertainties need to be taken into account in the structural assessment process.

Convener
Dario Coronelli

Co-Convener
Kamyab Zandi

First name	Last name	Country	Affiliation
Max	Hendriks	Netherlands	Delft University of Technology
Daniel	Dunkelberg	Germany	Pirlet & Partner Ingenieurgesellschaft mbh
Beatrice	Belletti	Italy	Univ. degli Studi di Parma - Engineering and Architecture
Carmen	Andrade	Spain	Centre Internacional de Mètodes Numèrics en l’Ènginyeria (CIMNE)
Zila	Rinaldi	Italy	University of Rome “Tor Vergata”
Alfred	Strauss	Austria	BOKU University
Gerrie	Dieteren	Netherlands	TNO
Daia	Zwicky	Switzerland	Univ. of Applied Sciences Fribourg
Ane	de Boer	Netherlands	Ane de Boer Consultancy
Christis	Chrysostomou	Cyprus	Cyprus University of Technology
Stuart	Matthews	United Kingdom	Matthews Consulting
David	Fernández-Ordóñez	Switzerland	fib
Daniel	Kuchma	United States	University of Illinois
Yuguang	Yang	Netherlands	TU Delft
Francesco	Tondolo	Italy	Politecnico di Torino
Tamon	Ueda	China	Shenzhen University
Hikaru	Nakamura	Japan	Nagoya University
Dario	Coronelli	Italy	Politecnico di Milano
Marta	Del Zoppo	Italy	University of Naples Federico II
Camillo	Nuti	Italy	Università degli Studi Roma Tre
Kamyab	Zandi	Canada	Timezyx Inc
Giuseppe	Di Nunzio	Italy	-
Miguel	Prieto	Sweden	RISE Research Institutes of Sweden
Attila	Vardai	Hungary	NYUGTAN Mernoki Szolgaltato Kft.
Francesca	Vecchi	Italy	University of Parma
Eva	Lantsoght	Ecuador	Universidad San Francisco de Quito
Mohammad Mehdi	Kashani	United Kingdom	University of Southampton
Davide	Lavorato	Italy	Università Roma Tre, Italia
Isabel	Martínez Sierra	Spain	Consejo Superior de Investig. Cientificas
Hyunjin	Ju	Korea, Republic of	Hankyong National University
Kunal	Kansara	United Kingdom	National Composites Centre UK (University of Bristol)
Ivan	Markovic	Switzerland	Eastern Switzerland University of Applied Sciences / Ostschweizer Fachhochschule Rapperswil
Elena	Casprini	Italy	University
Adriano	Castagnone	Italy	-
Lorenzo	FRANCESCHINI	Italy	-
Joost	Walraven	Netherlands	Delft University of Technology
Alberto	Meda	Italy	University of Rome “Tor Vergata”
Zanyar	Mirzaei	Switzerland	Pini Gruppe AG
Fabio	di Carlo	Italy	University of Rome Tor Vergata
Simone	Ravasini	Italy	University of Parma

TG3.3 - Existing Concrete Structures: Life Management, Testing and Structural Health Monitoring

The Task Group 3.3 (TG 3.3) specifies and extends their focus in the framework of Non-Destructive-Testing (NDT) and Structural Health Monitoring (SHM) required for the through-life management of existing concrete structures according to the following:

Concepts for extension of service life of reinforced concrete structures supported by NDT and SHM;
Specific testing/ specific monitoring; testing/ techniques combined with autonomous robotic systems (remote monitoring systems) or based on digital images as well as innovative self-monitoring materials (repair, strengthening);
Monitoring of site-specific load actions (e.g. traffic loads, etc.);
Data management for reinforced concrete structures using NDT/SHM: data reporting and data analysis of NDT/SHM applying AI;
Reliability assessment of NDT/SHM methods applied on reinforced concrete;
Building Information Modelling (BIM) and Digital Twins (DT) for existing concrete structures as a decision-making tool using NDT/SHM data; implementation of SHM in BIM;
Decision-making on structural level to foster the transformation from periodic to predictive/preventive maintenance including the assessment on the environmental impact of the decision: How can NDT/SHM contribute to operate our infrastructure in the most sustainable way?
SHM guidelines for newly designed complex concrete structures concerning their exploitation phase, also including BIM and DT.

Convener
Sylvia Kessler

Co-Convener
Maria Pina Limongelli

First name	Last name	Country	Affiliation
Gabriele	Bertagnoli	Italy	Politecnico di Torino
David	Lehky	Czech Republic	Brno University of Technology
Drahomir	Novak	Czech Republic	Technical University of Brno
Stefan	Maas	Luxembourg	Université du Luxembourg
Thomas	Petraschek	Austria	OBB-Infrastruktur AG
Mark Alexander	Ahrens	Germany	Ruhr-Univ. Bochum
Michael	Hansen	Germany	Leibniz Universität Hannover
Davide	Lavorato	Italy	Università Roma Tre, Italia
Geert	Lombaert	Belgium	University of Leuven
Marian	Ralbosky	Austria	Austrian Research Institute
Joost	Gulikers	Netherlands	Rijkswaterstaat Centre for Infrastructure
Giuseppe	Mancini	Italy	Politecnico Torino
Carmen	Andrade	Spain	Centre Internacional de Mètodes Numèrics en l’Ènginyeria (CIMNE)
Alberto	Meda	Italy	University of Rome “Tor Vergata”
Alfred	Strauss	Austria	BOKU University
Miroslav	Sykora	Czech Republic	Czech Technical University in Prague
Gerrie	Dieteren	Netherlands	TNO
Jonathon	Dyson	Australia	BCRC
Brett	Pielstick	United States	Eisman & Russo
Stuart	Matthews	United Kingdom	Matthews Consulting
David	Fernández-Ordóñez	Switzerland	fib
Sylvia	Kessler	Germany	Helmut-Schmidt-University/ University of the Federal Armed Forces Hamburg
Peter	Tanner	Spain	Cesma Ingenieros, SL
José	Campos e Matos	Portugal	University of Minho
Giorgio	Monti	Italy	Sapienza Università di Roma
Francesco	Tondolo	Italy	Politecnico di Torino
Thomas	Braml	Germany	Universität der Bundeswehr München
Joan	Casas Rius	Spain	Tech. Univ. of Catalunya, UPC-BarcelonaTech
Marcin	Górski	Poland	Silesian University of Technology
Robby	Caspeele	Belgium	Ghent University
Eftychia	Apostolidi	Germany	Technical University Darmstadt
Chris	Hendy	United Kingdom	Atkins
Manfred	Keuser	Germany	BUNG Ingenieure A
Milan	Holicky	Czech Republic	Czech Techn. Univ. of Prague - CVUT
Camillo	Nuti	Italy	Università degli Studi Roma Tre
Marcus	Hoffmann	Austria	Transport Infrastructure Asset Management
Emilio	Bastidas-Arteaga	France	Universite de Nantes
Tamon	Ueda	China	Shenzhen University
Florian	Zimmert	Germany	Bundeswehr University Munich
Frédéric	Duprat	France	INSA Toulouse
A. Emin	Aktan	United States	Drexel University
Jan	Bien	Poland	Wroclaw University of Science and Technology
Véronique	Bouteiller	France	University Gustave Eiffel
Necati	Catbas	United States	University of Central Florida
Mehmet	Celebi	United States	USGS
Eleni	Chatzi	Switzerland	ETH Zurich
Wojciech	De Roeck	Belgium	KU Leuven
Ivan	Duvnjak	Croatia	University of Zagreb
Lennart	Elfgren	Sweden	Luleå University of Technology
Bruno	Godart	France	-
Maria Pina	Limongelli	Italy	Politecnico di MIlano
Franklin	Moon	United States	Rutgers School of Engineering
Luis	Oliveira Santos	Portugal	LNEC
Miguel	Prieto	Sweden	RISE Research Institutes of Sweden
Muhammad Imran	Rafiq	United Kingdom	University of Brighton
Peter	Rosko	Austria	Technical University of Vienna
Franziska	Schmidt	France	IFSTTAR
Sebastian	Thöns	Germany	BAM Federal Inst. for Mat. Research & Testing
Roberto	Torrent	Switzerland	Quali- Ti-Mat Sagl
Jorge	Ley Urzaiz	Spain	INTEMAC
Daniele	Zonta	Italy	University of Trento
Marko	Bartolac	Croatia	University of Zagreb
Ruiz	De Azua	Spain	Kinesia Structural Monitoring
Elsa	Eustáquio	Portugal	Laboratório Nacional de Engenharia Civil
Stefan	Küttenbaum	Germany	Universität der Bundeswehr München
Stefan	Maack	Germany	Bundesanstalt für Materialforschung und -prüfung
Lisa	Ptacek (Mold)	Austria	Universität für Bodenkultur
Jiazeng	Shan	China	Tongji University
Helmut	Wenzel	Austria	VCE
Volkmar	Zabel	Germany	Bauhaus University Weimar
Konrad	Bergmeister	Austria	Univ. Bodenkultur
Giovanni	Volpatti	Switzerland	-
Diogo	Ribeiro	Portugal	University of Porto
Muhammed	Basheer	United Kingdom	University of Leeds
Alois	Vorwagner	Austria	-
Mieszko	Kużawa	Poland	-
Adriano	Castagnone	Italy	-
Els	Verstrynge	Belgium	EKU Leuven
Hélder Manuel	Silva Sousa	Portugal	University of Minho, ISISE, ARISE
Helder Filipe	Moreira de Sousa	Portugal	Brisa Group
Francesca	Marsili	Germany	Helmut-Schmidt-University/ University of the Federal Armed Forces Hamburg
Christian	Kainz	Germany	-
Marco	Civera	Italy	Politecnico di Torino, Department of Structural, Geotechnical and Building Engineering
Cosmin	Popescu	Sweden	Luleå University of Technology
Mario	Torcinaro	Spain	RWE Renewables Iberia
George	Wardeh	France	Un. de Cergy-Pontoise
Danièle	Waldmann-Diederich	Germany	Technical University of Darmstadt

TG3.4 - Selection and implementation of interventions/through-life management activities and measures for concrete structures

The focus will be on the selection and implementation of interventions and through-life management activities and measures for concrete structures. Its final goal is to provide the draft on intervention for the new fib MC2020. The basic procedure is updating “Chapter 9: Conservation” of the fib MC2010, considering recent progress in this field.

The initial focus will be on the preparation of technical guidelines for the selection and implementation of interventions dealing with current major intervention methods.

With respect to through-life management activities and measures for concrete structures, a primary objective will be updating “Chapter 9: Conservation” of the fib MC2010, considering recent technical progress and new ideas.

Convener
Tamon Ueda

Co-Convener
Giuseppe Mancini

First name	Last name	Country	Affiliation
Etsuji	Kikuta	Japan	Civil Engineering Research Institute for Cold Region
Dawei	Zhang	China	Zhejiang University
Philip	McKenna	Ireland	Halcrow Group Ltd., a CH2M HILL Company
Giuseppe	Mancini	Italy	Politecnico Torino
Carmen	Andrade	Spain	Centre Internacional de Mètodes Numèrics en l’Ènginyeria (CIMNE)
Amir	Rahimi	Germany	Bundesanstalt für Wasserbau
Jan	Vítek	Czech Republic	Metrostav a. s.
Lojze	Bevc	Slovenia	ZAG Slovenije
Koichi	Kobayashi	Japan	Gifu University
Jonathon	Dyson	Australia	BCRC
Attila	Vardai	Hungary	NYUGTAN Mernoki Szolgaltato Kft.
Francesco	Bencardino	Italy	University of Calabria
Christoph	Gehlen	Germany	TUM School of Engineering and Design
Frank	Papworth	Australia	BCRC
David	Fernández-Ordóñez	Switzerland	fib
Meini	Su	United Kingdom	University of Manchester
Thanasis	Triantafillou	Greece	University of Patras
Xilin	Lu	China	Tongji University
Costantino	Menna	Italy	University of Naples Federico II
Norbert	Randl	Austria	Carinthia Univ. of Applied Sciences
Hikaru	Nakamura	Japan	Nagoya University
Tamon	Ueda	China	Shenzhen University
Anna	Saetta	Italy	Università Iuav di Venezia
Marco	Savoia	Italy	University of Bologna
Ji-hua	Zhu	China	Shenzhen University
Hugo	Corres Peiretti	Spain	FHECOR Ingenieros Consultores
Marta	Del Zoppo	Italy	University of Naples Federico II
Takumi	Shimomura	Japan	Nagaoka Univ. of Technology
Alessio	Cascardi	Italy	University of Salento
Isabel	Martínez Sierra	Spain	Consejo Superior de Investig. Cientificas
Zanyar	Mirzaei	Switzerland	Pini Gruppe AG

TG3.5 - Forensic engineering

We have an enormous and an ever-increasing heritage of reinforced and prestressed concrete structures, many of which are currently approaching the end of their intended service life. However, there are pressing societal, economic and environmental needs to safely extend the service lives of many of these structures. This poses a delicate and challenging task if we are to make appropriate decisions on the through-life management and care of these constructed assets to achieve this while avoiding transferring an excessive burden onto the next generation. To do this we need a better understanding of the real behaviours of structures, why they may not achieved the required performance and, ultimately, what may cause them to fail.

Convener
Daniele Zonta

Co-Convener
Frank Papworth

First name	Last name	Country	Affiliation
Daniele	Zonta	Italy	University of Trento
ab	van den bos	Netherlands	NLyse
Ehsan	Noroozinejad	Canada	The University of British Columbia (UBC)
Hans-Dieter	Beushausen	South Africa	University of Cape Town
Eugen	Brühwiler	Switzerland	EPFL
Ted	Donchev	United Kingdom	Kingston University
Roberto	Felicetti	Italy	Politecnico di Milano
Frank	Papworth	Australia	BCRC
Alfred	Strauss	Austria	BOKU University
Maria Pina	Limongelli	Italy	Politecnico di MIlano
Fabrizio	Palmisano	Italy	PPV Consulting Studio Palmisano Perilli Associati,
Peter	Robery	United Kingdom	Robery Forensic Engineering Ltd
Branko	Glisic	United States	Princeton University
Johannes	Hübl	Austria	University of Natural Resources and Applied Life Sciences
Necati	Catbas	United States	University of Central Florida
Hani	Nassif	United States	Rutgers University-New Brunswick
Luca	Possidente	Italy	-
Eva	Lantsoght	Ecuador	Universidad San Francisco de Quito
Mattia	Bado	Italy	-
Jörg-Martin	Hohberg	Switzerland	Freelance Auditor
Andreas	Lampropoulos	United Kingdom	University of Brighton
João	André	Portugal	Portuguese National Laboratory for Civil Engineering
ab	van den bos	Netherlands	NLyse
Umesh	Rajeshirke	India	Spectrum Techno Consultants Pvt. Ltd
Fulvio	Parisi	Italy	University of Naples Federico II
Venkataramana	Heggade	India	Indian National Academy of Engineers
Giovanni	Volpatti	Switzerland	-
Leandro	Moretti Sanchez	Canada	-
Christos	Giarlelis	Greece	EQUIDAS Consulting Engineers

COM2: Analysis & design

Written on 21 March 2017.

Motivation

Analysis and design are understood as core tasks of structural engineering. In this field, nine areas of interest have been identified; hence, nine task groups form the basis of the new structure of Commission 2. Today, the analysis – i.e. the detailed investigation of the stress and strain state – has gained in importance, and consequently refined and physically based models and calculation procedures are required. On the other hand, the design of new structures (comprising conception, dimensioning and detailing) still is fundamental for practicing engineers. In general, the respective approaches should be one and the same for the two levels of detail, but more practical and easier to apply for the latter case. Commission 2 supports and follows this line of development of structural engineering.

Scope and objective of technical work

The scope of Commission 2 is to develop models and calculation procedures for the analysis and design of structures and structural members under short term and long term static loading as well as under fatigue, fire and extreme events. Serviceability limit states and ultimate limit states as well as their interaction are considered, and both research results and recommendations for the practical application shall be presented. In the near future the activity of COM2 will focus on new and also on existing structures in order to support the development of the new fib Model Code 2020.

Commission Chair
Jan Vitek

Deputy Chair
Oguzhan Bayrak

First name	Last name	Country	Affiliation
György L.	Balázs	Hungary	Budapest Univ. of Techn. & Economics
Giuseppe	Mancini	Italy	Politecnico Torino
Maria Rosaria	Pecce	Italy	University of Naples Federico II
Joost	Walraven	Netherlands	Delft University of Technology
Mikael	Braestrup	Denmark	Rambøll
Oguzhan	Bayrak	United States	Univ. of Texas at Austin
Manfred	Curbach	Germany	Technische Univ. Dresden
Giovanni	Plizzari	Italy	University of Brescia
Jan	Vítek	Czech Republic	Metrostav a. s.
Walter	Kaufmann	Switzerland	ETH Zürich
John	Cairns	United Kingdom	Heriot-Watt University
David	Fernández-Ordóñez	Switzerland	fib
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart
Viktor	Sigrist	Switzerland	Lucerne School of Engineering and Architecture
Mikael	Hallgren	Sweden	Tyréns Sverige AB
Aurelio	Muttoni	Switzerland	École polytechnique fédérale de Lausanne (EPF Lausanne)
Niels	Høj	Switzerland	HOJ Consulting GmbH
Stephen	Foster	Australia	UNSW Australia
Johann	Kollegger	Austria	Vienna University of Technology
Koichi	Maekawa	Japan	Yokohama National University
Robert	Vollum	United Kingdom	Imperial College London

TG2.1 - Serviceability models

Serviceability limit states (SLS) determine the applicability of concrete structures. When these criteria are met, the concrete structure can function properly during its service life. Correct design according to serviceability limit states is therefore essential for the construction of durable, robust and valuable structures. Violation of the SLS criteria leads to structures that do not function properly and/or to reduced durability, the consequences of which can be recognised very quickly. Therefore, the models for verification of the expected criteria are of primary importance.

The activity of the group is focused on the development of models for analysis of cracks and deformations of concrete structures. Beside the sophisticated numerical models, engineering practice requires practical engineering approaches, which are applicable in codes and in preliminary design stages when important decisions on the conceptual design are accepted. The activity will be focused on new structures and also on existing structures for assessment, rehabilitation or strengthening.

Convener
Jan Vitek

First name	Last name	Country	Affiliation
Francesca	Ceroni	Italy	Universitá degli Studi di Napoli Parthenope
Diane	Gardner	United Kingdom	Cardiff University
Laurie	Lacarrière	France	INSA Toulouse
H. Gintaris	Kaklauskas	Lithuania	Vilnius Gediminas Technical Univ.
Michel	Lorrain	France	INSA
Clare	Burns	Switzerland	Walt+Galmarini AG
Philippe	Bisch	France	Egis Industries
Damir	Tkalčič	Croatia	Civil Engineering Institute of Croatia
Pier	Debernardi	Italy	Politecnico di Torino
Lars	Eckfeldt	Germany	Deutsches Institut für Bautechnik (DIBt)
Matteo	Guiglia	Italy	Politecnico di Torino
Dorian	Borosnyoi-Crawley	New Zealand	WSP Research
Jean-Philippe	Sellin	France	Cerema
Robert	Lark	United Kingdom	Cardiff University
Mamdouh	El-Badry	Canada	University of Calgary
Lukáš	Vráblík	Czech Republic	Novak & Partner Ltd
Maurizio	Taliano	Italy	Politecnico di Torino
Viktor	Gribniak	Lithuania	Vilnius Gediminas Technical University
Amin	Ghali	Canada	University of Calgary
Andor	Windisch	Germany	-
Josko	Ozbolt	Germany	Universität Stuttgart
François	Toutlemonde	France	Université Gustave Eiffel
Maria Rosaria	Pecce	Italy	University of Naples Federico II
Jean Michel	Torrenti	France	Univ Gustave Eiffel
Ekkehard	Fehling	Germany	IBB Fehling + Jungmann GmbH
Vladimir	Cervenka	Czech Republic	Cervenka Consulting
Mario Alberto	Chiorino	Italy	Politecnico di Torino
Alejandro	Pérez Caldentey	Spain	Universidad Politécnica de Madrid
Jan	Vítek	Czech Republic	Metrostav a. s.
David	Fernández-Ordóñez	Switzerland	fib
Olivier	Burdet	Switzerland	EPFL-ENAC-IBETON
Lluis	Torres	Spain	University of Girona
Roman	Wan-Wendner	Belgium	Ghent University
Frédéric	Duprat	France	INSA Toulouse
Antonio	Mari Bernat	Spain	Uni. Politéc. Catalunya
Cristina	Barris	Spain	Universitat de Girona
Alena	Kohoutkova	Czech Republic	Czech Technical University - CVUT
Philippe	Menétrey	Switzerland	IngPhi sa
Eva	Oller Ibars	Spain	Technical University of Catalonia
Tamon	Ueda	China	Shenzhen University
György L.	Balázs	Hungary	Budapest Univ. of Techn. & Economics
Nikola	Tošić	Spain	Universitat Politècnica de Catalunya
Christina	McLeod	South Africa	University of Kwazulu - Natal
Arvydas	Rimkus Vilnius	Lithuania	Gediminas Technical University
Dirk	Schlicke	Austria	Technische Universität Graz
Jean-Jacques	Brioist	France	SIAM, AFGC
Syed Yasir	Alam	France	Ecole Central de Nantes
Reignard	Tan	Norway	NTNU Trondheim
Viet Tue	Nguyen	Austria	TU Graz
Robert	Vollum	United Kingdom	Imperial College London
ab	van den bos	Netherlands	NLyse
Helder Filipe	Moreira de Sousa	Portugal	Brisa Group

WP2.1.1 - Long-term behaviour of prestressed concrete bridges

Some concrete bridges suffer from deflections that are larger than expected. The objective of WP2.1.1 is to explain possible reasons of this phenomenon, to identify factors and finally to propose recommendations for the design of new bridges or as well as the rehabilitation of existing bridges.

Convener
Jan Vitek

First name	Last name	Country	Affiliation
György L.	Balázs	Hungary	Budapest Univ. of Techn. & Economics
Jean-Philippe	Sellin	France	Cerema
Mario Alberto	Chiorino	Italy	Politecnico di Torino
Alejandro	Pérez Caldentey	Spain	Universidad Politécnica de Madrid
Jan	Vítek	Czech Republic	Metrostav a. s.
David	Fernández-Ordóñez	Switzerland	fib
Olivier	Burdet	Switzerland	EPFL-ENAC-IBETON
Roman	Wan-Wendner	Belgium	Ghent University
Antonio	Mari Bernat	Spain	Uni. Politéc. Catalunya
Frédéric	Duprat	France	INSA Toulouse
Mamdouh	El-Badry	Canada	University of Calgary
Robert	Lark	United Kingdom	Cardiff University
Philippe	Menétrey	Switzerland	IngPhi sa
Lukáš	Vráblík	Czech Republic	Novak & Partner Ltd
Cristina	Barris	Spain	Universitat de Girona
Christina	McLeod	South Africa	University of Kwazulu - Natal
Eva	Oller Ibars	Spain	Technical University of Catalonia
Dirk	Schlicke	Austria	Technische Universität Graz

WP2.1.2 - Restrained and imposed deformations

The main objective of Working Party 2.1.2 is to present practical recommendations for the design of reinforced and post-tensioned concrete structures to accommodate the effects of restrained and imposed deformations. This involves looking into the causes of internally-induced and externallyimposed deformations and point out their different influences on the structural behaviour. The WP will assess various effects that may affect the degree of restraint such as superimposed loading and presence of prestressing, and propose modifications to existing design criteria where relevant.

Guidance will be given on the use of nonlinear response analysis for rigorous response prediction.

Convener
Perez Caldentey

First name	Last name	Country	Affiliation
György L.	Balázs	Hungary	Budapest Univ. of Techn. & Economics
Carlos	Bajo Pavia	Spain	Ferrovial Agromán S. A.
José	Câmara	Portugal	Inst. Superior Tecnico
Jean Michel	Torrenti	France	Univ Gustave Eiffel
Jan	Vítek	Czech Republic	Metrostav a. s.
Alejandro	Pérez Caldentey	Spain	Universidad Politécnica de Madrid
David	Fernández-Ordóñez	Switzerland	fib
Lluis	Torres	Spain	University of Girona
Lukáš	Vráblík	Czech Republic	Novak & Partner Ltd
Viktor	Gribniak	Lithuania	Vilnius Gediminas Technical University
Laurie	Lacarrière	France	INSA Toulouse
Antonio	Mari Bernat	Spain	Uni. Politéc. Catalunya
Maurizio	Taliano	Italy	Politecnico di Torino
Hugo	Corres Peiretti	Spain	FHECOR Ingenieros Consultores
Dirk	Schlicke	Austria	Technische Universität Graz

TG2.2 - Ultimate limit state models

Task Group 2.2 was established to evaluate and develop models for the conception, design and analysis of concrete structures. Topics within the scope of the work may include models that deal with the ultimate limit state and with ductility as to their affect on peak and post peak behaviours.

The objective of TG2.2 is to synthesise available results from research, testing and design experience. Therefore, research and development in this field is monitored, documented and evaluated. For the time being, the work is focused on the behaviour of slabs and beams in shear, shear aspects in the design of members reinforced with steel bars, steel fibres or a combination of steel fibres and bars and the punching behaviour of slabs. Moreover, strut-and-tie modelling is treated as a specific method to capture ultimate limit states.

Convener
Aurelio Muttoni

First name	Last name	Country	Affiliation
Steve	Denton	United Kingdom	WSP
Joost	Walraven	Netherlands	Delft University of Technology
Oguzhan	Bayrak	United States	Univ. of Texas at Austin
Josef	Hegger	Germany	RWTH Aachen
Fausto	Minelli	Italy	University of Brescia
Robert	Vollum	United Kingdom	Imperial College London
Miguel	Fernández Ruiz	Spain	Universidad Politécnica de Madrid
David	Fernández-Ordóñez	Switzerland	fib
Aurelio	Muttoni	Switzerland	École polytechnique fédérale de Lausanne (EPF Lausanne)
Miguel	Lourenço	Portugal	JSJ Consulting
Stephen	Foster	Australia	UNSW Australia
Daniel	Kuchma	United States	University of Illinois
Marco	di Prisco	Italy	Politecnico di Milano
Evan	Bentz	Canada	University of Toronto

WP2.2.1 - Shear in beams

WP2.2.1 will prepare a bulletin about shear design and analysis models for beams (physical basis and experimental validation). Several aspects are considered to be treated in the report, including the influence of the member size or of point loads near supports, clear definitions of failure modes, strut-and-tie modelling or nonlinear calculation procedures.

Convener
Oguzhan Bayrak

First name	Last name	Country	Affiliation
Joost	Walraven	Netherlands	Delft University of Technology
Oguzhan	Bayrak	United States	Univ. of Texas at Austin
Beatrice	Belletti	Italy	Univ. degli Studi di Parma - Engineering and Architecture
Josef	Hegger	Germany	RWTH Aachen
Robert	Vollum	United Kingdom	Imperial College London
Miguel	Fernández Ruiz	Spain	Universidad Politécnica de Madrid
Walter	Kaufmann	Switzerland	ETH Zürich
David	Fernández-Ordóñez	Switzerland	fib
Viktor	Sigrist	Switzerland	Lucerne School of Engineering and Architecture
Aurelio	Muttoni	Switzerland	École polytechnique fédérale de Lausanne (EPF Lausanne)
Antonio	Cladera Bohigas	Spain	University of Balearic Islands
Patrick	Huber	Austria	Vienna University of Technology
Trevor	Hrynyk	United States	University of Waterloo
Stephen	Foster	Australia	UNSW Australia
Daniel	Kuchma	United States	University of Illinois
Sung-Gul	Hong	Korea, Republic of	Seoul National University
Boyan	Mihaylov	Belgium	University of Liege
Juan	Sagaseta	United Kingdom	University of Surrey
Almila	Uzel	Turkey	Yeditepe University
Evan	Bentz	Canada	University of Toronto

WP2.2.2 - Shear in members with steel fibres

WP2.2.2 will invite further experts to participate.

Convener
Marco di Prisco

First name	Last name	Country	Affiliation
Fausto	Minelli	Italy	University of Brescia
David	Fernández-Ordóñez	Switzerland	fib
Stephen	Foster	Australia	UNSW Australia
Marco	di Prisco	Italy	Politecnico di Milano

WP2.2.3 - Punching and shear in slabs

WP2.2.3 will invite further experts to participate.

Convener
Aurelio Muttoni

First name	Last name	Country	Affiliation
Maurizio	Orlando	Italy	Università degli Studi di Firenze
Günter	Rombach	Germany	Techn. Univ. of Hamburg-Harburg
António	Ramos	Portugal	NOVA School of Science &Technology
Jaroslav	Halvonik	Slovakia	Slovak University of Technology in Bratislava
Mary Beth	Hueste	United States	Texas A&M University
Dominik	Kueres	Germany	RWTH Aachen University
Rupert	Walkner	Austria	University of Innsbruck
Gustavo	Parra-Montesinos	United States	University of Michigan
Guilherme	Melo	Brazil	Universidade de Brasilia
Joost	Walraven	Netherlands	Delft University of Technology
Oguzhan	Bayrak	United States	Univ. of Texas at Austin
Josef	Hegger	Germany	RWTH Aachen
Robert	Vollum	United Kingdom	Imperial College London
Miguel	Fernández Ruiz	Spain	Universidad Politécnica de Madrid
Anssi	Laaksonen	Finland	Tampere University of Technology
Carlos	Ospina	United States	Simpson, Gumpertz & Heger Inc.
Markus	Vill	Austria	Vill ZT GmbH
David	Fernández-Ordóñez	Switzerland	fib
Mikael	Hallgren	Sweden	Tyréns Sverige AB
Jürgen	Feix	Austria	University of Innsbruck
Aurelio	Muttoni	Switzerland	École polytechnique fédérale de Lausanne (EPF Lausanne)
Linh	Hoang	Denmark	Danmarks Tekniske Universitet
Juan	Sagaseta	United Kingdom	University of Surrey
Hong-Gun	Park	Korea, Republic of	Seoul National University
Maria	Polak	Canada	University of Waterloo
Yuguang	Yang	Netherlands	TU Delft

WP2.2.4 - Strut and tie modelling

WP2.2.4 will address topics such as ordinary and more refined models, the level of approximation concept, an update of the MC2010 provisions, reversal loading and 3D models.

Convener
Lourenço, Miguel Filipe Passos Sério

First name	Last name	Country	Affiliation
João	Almeida	Portugal	Instituto Superior Técnico Lisboa
Miguel	Fernández Ruiz	Spain	Universidad Politécnica de Madrid
Stathis	Bousias	Greece	University of Patras
David	Fernández-Ordóñez	Switzerland	fib
Jaime	Mata-Falcón	Spain	Universitat Politècnica de València
Miguel	Lourenço	Portugal	JSJ Consulting
Boyan	Mihaylov	Belgium	University of Liege
Linh	Hoang	Denmark	Danmarks Tekniske Universitet
Carlos	Meléndez	Spain	Esteyco SA
Duarte	Faria	Switzerland	Muttoni et Fernández, ingénieurs conseils SA
Miguel	Pedrosa Ferreira	Portugal	-
Aurelio	Muttoni	Switzerland	École polytechnique fédérale de Lausanne (EPF Lausanne)

TG2.3 - Fire design of concrete structures

Task Group 2.3 welcomes active members with expertise in theory and practice in relation to fire design of concrete structures. The scope of TG2.3 comprises a discussion of theoretical and practical problems in relation to fire design and the development of the state-of-the-art and best practices for fire design of concrete structures. It is the goal that the results of the task group will not only serve as a reference for the experts within the topic of fire design, but also will be helpful for the members of the fib in general.

The scope of the work of TG2.3 is based on the previous achievements, which include Bulletins 38 and 46 on fire design of concrete structures: materials, modelling, structural behaviour and assessment, as well as contributions to the fib Model Code and various workshops and special sessions on these topics.

In the next phase, TG2.3 will concentrate on a number of topical issues within fire design, with the objective of providing general engineering guidance within these fields. The work is organised in three working parties, with the following titles and scope.

Convener
Ruben Van Coile

First name	Last name	Country	Affiliation
Frank	Dehn	Germany	KIT Karlsruher Institut für Technologie
Patrick	Bamonte	Italy	Politecnico di Milano
Roberto	Felicetti	Italy	Politecnico di Milano
Jean Marc	Franssen	Belgium	Université de Liège
João	Rodrigues	Portugal	University of Coimbra - Polo II
Pietro	Gambarova	Italy	Politecnico di Milano
Venkatesh	Kodur	United States	Michigan State University
Long	Phan	United States	NIST
David	Fernández-Ordóñez	Switzerland	fib
Ruben	Van Coile	Belgium	Ghent University
Luc	Taerwe	Belgium	Ghent University
Cristian	Maluk	Australia	The University of Queensland
Hitesh	Lakhani	Germany	University of Stuttgart
Thomas	Gernay	United States	Johns Hopkins University
Negar	Elhami Khorasani	United States	University at Buffalo
M.Z.	Naser	United States	Clemson University
Frederik	Hänsel	Germany	-
Nataša	Kalaba	France	Cerib
Francesco	Lo Monte	Italy	Politecnico di Milano
Elena	Michelini	Italy	University of Parma
Riccardo	Stucchi	Switzerland	Lombardi SA
Ankit	Agrawal	United States	Integral Research Solutions Group
Tom	Molkens	Belgium	KU Leuven
Moritz	Boxheimer	Germany	Karlsruhe Institute of Technology
Peng	Gao	China	Hefei University of Technology
Katherine	Cashell	United Kingdom	University College London
Urska	Blumauer	Slovenia	Slovenian Building Research Institute

WP2.3.1 - Spalling design

The aim of WP2.3.1 is to prepare a technical report providing guidance on the structural fire engineering design for concrete structures with a high probability and/or sensitive to the occurrence of concrete spalling during or after a fire.

Convener
Cristian Maluk

First name	Last name	Country	Affiliation
Roberto	Felicetti	Italy	Politecnico di Milano
David	Fernández-Ordóñez	Switzerland	fib
João	Rodrigues	Portugal	University of Coimbra - Polo II
Hitesh	Lakhani	Germany	University of Stuttgart
Cristian	Maluk	Australia	The University of Queensland
Long	Phan	United States	NIST

WP2.3.2 - Performance-based fire design

The aim of WP2.3.2 is to summarise, in a technical report, the international state-of-the-art and to discuss it specifically in relation to concrete structures, with the aim of achieving a proposal for its practical application.

Convener
Thomas Gernay

First name	Last name	Country	Affiliation
Jean Marc	Franssen	Belgium	Université de Liège
David	Fernández-Ordóñez	Switzerland	fib
Thomas	Gernay	United States	Johns Hopkins University
Patrick	Bamonte	Italy	Politecnico di Milano
Hitesh	Lakhani	Germany	University of Stuttgart
Cristian	Maluk	Australia	The University of Queensland
Negar	Elhami Khorasani	United States	University at Buffalo
M.Z.	Naser	United States	Clemson University
João	Rodrigues	Portugal	University of Coimbra - Polo II
Ruben	Van Coile	Belgium	Ghent University
Marcus	Achenbach	Germany	LGA KdöR
Mohsen	Roosefid	France	IRSN

WP2.3.3 - Fire resistance of concrete tunnels

The aim of WP2.3.3 is to prepare a technical report concerning structural engineering aspects of fire in tunnels. The main topics to be discussed are the design of concrete tunnels exposed to fire, fire scenario for different tunnels, material for concrete tunnels and design supported by testing.

Convener
Patrick Balmonte

First name	Last name	Country	Affiliation
Patrick	Bamonte	Italy	Politecnico di Milano
Frederik	Hänsel	Germany	-
Nataša	Kalaba	France	Cerib
Francesco	Lo Monte	Italy	Politecnico di Milano
Elena	Michelini	Italy	University of Parma
Riccardo	Stucchi	Switzerland	Lombardi SA
David	Fernández-Ordóñez	Switzerland	fib

WP2.3.4 - Post-fire assessment

The aim of WP2.3.4 is to prepare a technical report the post fire assessment of concrete structures, summarizing the international state-of-the-art and providing actionable guidance on the evaluation of concrete structures following fire exposure.

Convener
Ruben Van Coile

First name	Last name	Country	Affiliation
Ruben	Van Coile	Belgium	Ghent University
Roberto	Felicetti	Italy	Politecnico di Milano
Thomas	Gernay	United States	Johns Hopkins University
Venkatesh	Kodur	United States	Michigan State University
Hitesh	Lakhani	Germany	University of Stuttgart
Tom	Molkens	Belgium	KU Leuven
João	Rodrigues	Portugal	University of Coimbra - Polo II
Ankit	Agrawal	United States	Integral Research Solutions Group
David	Fernández-Ordóñez	Switzerland	fib
Cristian	Maluk	Australia	The University of Queensland

TG2.4 - Computer-based modelling and design

Task Group 2.4 (TG2.4) aims to bridge the gap between complex and advanced analyses and practical design applications. The current state of knowledge on nonlinear methods, thermomechanical analyses as well as the application of holistic 3D building models will be prepared for practical use.

The scope and objectives of TG2.4 are to:

survey the current state of knowledge on computer-based modelling and design;
develop guidance documents related to the application of non-linear computer-based analysis methods for assessing performance and aiding the design of concrete members;
develop guidance documents related to the application of thermomechanical computer-based analysis methods for assessing the cracking risk respectively the mode of cracking and the required minimum reinforcement due to imposed and restrained deformations;
establish frameworks and methods to incorporate the application of holistic 3D building models in the static analysis and design in practice;
provide guidance on the application of computational modelling procedures to post-construction assessments, forensic engineering, and rehabilitation work relating to existing concrete structures.

Moreover, the Task Group 2.4 shall become a platform for researchers and practical users to:

propose criteria for calibrating or validating computer-based procedures employed for concrete structure design or assessment;
discuss the extension of computer-based modelling procedures to structures employing high performance concretes, fibre-reinforced concretes, and composite concrete structures;
work toward integrating computer-based analysis-related provisions within the Model Code.

Convener
Dirk Schlicke

First name	Last name	Country	Affiliation
Daniel	Kuchma	United States	University of Illinois
Laura	Lowes	United States	University of Washington
Stavroula (S.J.)	Pantazopoulou	Canada	The Lassonde Faculty of Engineering, York University
Enrico	Spacone	Italy	Università G. D’Annunzio
Oguzhan	Bayrak	United States	Univ. of Texas at Austin
Manfred	Curbach	Germany	Technische Univ. Dresden
Vladimir	Cervenka	Czech Republic	Cervenka Consulting
Walter	Kaufmann	Switzerland	ETH Zürich
David	Fernández-Ordóñez	Switzerland	fib
Stephen	Foster	Australia	UNSW Australia
Giorgio	Monti	Italy	Sapienza Università di Roma
Maria	Polak	Canada	University of Waterloo
Diego Lorenzo	Allaix	Netherlands	TNO Neitherlands
Mazen	Ayoubi	Germany	Jordahl GmbH
Beatrice	Belletti	Italy	Univ. degli Studi di Parma - Engineering and Architecture
Jaime	Mata-Falcón	Spain	Universitat Politècnica de València
Serhan	Guner	Canada	Morrison Hershfield Ltd
Max	Hendriks	Netherlands	Delft University of Technology
Frank	Vecchio	Canada	University of Toronto
Marius	Weber	Switzerland	ETH Zurich
Bjørn William	Strand	Norway	Multiconsult AS
Evan	Bentz	Canada	University of Toronto
Morten	Engen	Norway	Multiconsult AS
Tetsuya	Ishida	Japan	Department of Civil Engineering
Dirk	Schlicke	Austria	Technische Universität Graz
ab	van den bos	Netherlands	NLyse

WP2.4.1 - Modelling of Fibre Reinforced Concrete Structures

Discrete fibres are being added to cement based materials (Fibre reinforced concrete, FRC) in order to increase the post-cracking residual strength of concrete structures. The fibre reinforcement mechanisms are mainly activated after crack initiation of the binder paste, so modelling the behaviour of FRC requires numerical approaches able of simulating the crack initiation and crack propagation in cement based materials. However, the designers that have the responsibility to design FRC structures face several challenges for selecting the most appropriate constitutive model, such is the case when intended to use sophisticated computer programs based on the finite element method (FEM). The values of the parameters of the constitutive models, and how to assure that these values are representative of the behaviour of the real structure are key aspects that designers face.

The main aim of this WG is to propose reliable methodologies for the application of FEM-based computer models for the design of FRC structures by considering their serviceability and ultimate limit state exigencies.

Convener
Joaquim A. O. Barros

First name	Last name	Country	Affiliation
Joaquim	A. O. Barros	Portugal	Universidade do Minho
David	Fernández-Ordóñez	Switzerland	fib
ab	van den bos	Netherlands	NLyse
Alberto	Carpinteri	Italy	Politecnico di Torino
Alessandro	Fantilli	Italy	Politecnico di Torino
Beatriz	Sanz	Spain	Technical University of Madrid
Erez	GAL	Israel	Ben-Gurion University of the Negev
Frank	Vecchio	Canada	University of Toronto
Jan	Cervenka	Czech Republic	Cervenka Consulting Ltd
Liberato	Ferrara	Italy	Politecnico di Milano
Pierre	Rossi	France	IFSTTAR
Antonio	Caggiano	Germany	Univ. of Buenos Aires/Univ. of Darmstadt
Daniel	Dias-da-Costa	Portugal	The Univ. of Sydney / Univ. of Coimbra
David	Cendon	Spain	Universidad Politécnica de Madrid
Elisa	Poveda Bautista	Spain	University of Castilla-La Mancha
Erik	Schlangen	Netherlands	Delft University of Technology
Gerrit	Neu	Germany	Ruhr University Bochum
Gunther	Meschke	Germany	Ruhr University Bochum
Jaime	Planas	Spain	Technical University of Madrid
Peter	Juhasz	Hungary	JKP Static - Budapest
Massimiliano	Cremonesi	Italy	Politecnico di Milano
Nilüfer	Özyurt	Turkey	Boğaziçi University
Petr	Kabele	Czech Republic	Czech Technical University in Prague
Rena C.	Yu	Spain	University of Castilla-La Mancha
Stamatina	Chasioti	Canada	Yorku University
Ventura	Gouveia	Portugal	Polytechnic Institute of Viseu
Vitor	Cunha	Portugal	University of Minho
Yin	Chi	China	Wuhan University
Luis	Matos	Portugal	University of Minho
Federico	Accornero	China	-

WP2.4.2 - Life-span numerical simulation of concrete structures

Accurate prediction of the durability and long-term performance of concrete structures is a challenging task due to numerous influencing factors involved and their complex combinations. Despite these complexities, the majority of current standard specifications deal with the durability of concrete on the basis of a rather simple, prescriptive approach, where a set of requirements are usually applied to at the design stage and serve mainly as the basis of quality control. The durability and long-term performance of concrete structures are also essential for evaluating sustainability aspects such as the life-cycle emissions of carbon dioxide (CO2). Therefore, we should be able to accurately predict the service life of a structure for given materials and processes. To improve our capability to predict the service life of concrete structures, we intend to use a multi-scale approach taking into account the time-dependent properties of concrete, externally applied loads and exposure environments in a holistic manner. To this end, such analysis models and simulation frameworks are still under development, and we aim to showcase its applicability, calculation procedures, required parameters, and appropriate ways of interpreting the simulation results.

The main scope of WP 2.4.2 is developing accurate and reliable models and simulation frameworks for life-span numerical simulation of concrete structures. The primary objective of the activity is to couple material and structural behaviors with their durability and sustainability. The developed numerical models should cover mechanical behaviors, durability issues, and sustainability aspects such as CO2 emissions.

Convener
Tetsuya Ishida

First name	Last name	Country	Affiliation
Tetsuya	Ishida	Japan	Department of Civil Engineering
David	Fernández-Ordóñez	Switzerland	fib
Motohiro	Ohno	Japan	The University of Tokyo
Farid	Benboudjema	France	ENS Paris-Saclay, Université Paris-Saclay
Shashank	Bishnoi	India	Indian Institute of Technology Delhi
Jie	Dai	China	Henan University of Technology
Fuyuan	Gong	China	Zhejiang University
B.	Suryanto	United Kingdom	Heriot-Watt University Edinburgh
Miguel	Azenha	Portugal	Civil UMinho - Universidade do Minho
Kefei	Li	China	-
Mehboob	Rasul	Japan	Technology Development Division

TG2.5 - Bond and material models

The overall motivation of TG2.5 is to advance theoretical and practical developments in topics related to bond and anchorage of reinforcing and prestressing materials, and to present these developments in an understandable and code-type formulated manner.

TG2.5 undertakes activities which stimulate and advance modelling of the influence of bond and anchorage of reinforcement on structural performance, as well as the development of design provisions related to bond behaviour and detailing of laps and anchorages.

Convener
Giovanni A. Plizzari

First name	Last name	Country	Affiliation
György L.	Balázs	Hungary	Budapest Univ. of Techn. & Economics
Francesca	Ceroni	Italy	Universitá degli Studi di Napoli Parthenope
Pietro	Gambarova	Italy	Politecnico di Milano
Stavroula (S.J.)	Pantazopoulou	Canada	The Lassonde Faculty of Engineering, York University
Maria Antonietta	Aiello	Italy	University of Lecce
Carlo	Pellegrino	Italy	Università di Padova
Flora	Faleschini	Italy	University of Padova
Roman	Sedlmair	Germany	Karlsruher Institut für Technology (KIT)
David	Čitek	Czech Republic	CTU Klokner Institute
Gabriella	Bolzon	Italy	Politecnico di Milano
Akanshu	Sharma	United States	Purdue University
Giovanni	Metelli	Italy	University of Brescia
Karin	Lundgren	Sweden	Chalmers University of Technology
Giovanni	Plizzari	Italy	University of Brescia
John	Cairns	United Kingdom	Heriot-Watt University
Charles	Goodchild	United Kingdom	The Concrete Centre
David	Fernández-Ordóñez	Switzerland	fib
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart
Aurelio	Muttoni	Switzerland	École polytechnique fédérale de Lausanne (EPF Lausanne)
Bruno	Massicotte	Canada	Ecole Polytechnique de Montréal
Dario	Coronelli	Italy	Politecnico di Milano
Marianoela	Leone	Italy	Universita del Salento
Remy	Lequesne	United States	The University of Kansas
Giovanni	Muciaccia	Italy	Politecnico di Milano
Giovacchino	Genesio	Germany	Hilti group
Josipa	Bosnjak	Germany	Universität Stuttgart
Fabrizio	Palmisano	Italy	PPV Consulting Studio Palmisano Perilli Associati,
Juan	Murcia-Delso	Spain	Universitat Politècnica de Catalunya (UPC)
Marc	Koschemann	Germany	Technische Universität Dresden

TG2.6 - Composite steel-concrete construction

Steel-concrete composite construction allows various structural solutions that optimize the performances of the two-component materials through a well-assessed design that takes into account all the particularities of steel and RC constructions as well as interaction problems.

The use of composite construction is widely spread all around the world, and its use for the construction of medium-sized bridges is a very frequent technical choice. In this historical period, the concrete industry must take this into account.

The motivation of the fib TG2.6 is to identify the meaningful characteristics of composite steel- concrete structures with respect to typical aspects of RC structures in order to provide technical knowledge and design provisions.

The activity of the group is focused on the analyses of the structural behaviour of RC parts constituting steel-concrete composite members and the modeling of their interaction with the steel parts.

Convener
Maria Rosaria Pecce

Co-Convener
Antonio Bilotta

First name	Last name	Country	Affiliation
Paolo	Napoli	Italy	Politecnico di Torino
Giovanni	Fabbrocino	Italy	University of Molise
Luigi	di Sarno	Italy	Università degli studi del Sannio
Luigino	Dezi	Italy	Università Politecnica delle Marche
Ciro	Faella	Italy	University of Salerno
Claudio	Amadio	Italy	University of Trieste
Iolanda	del Prete	United Kingdom	BuroHappold Engineering
Dennis	Lam	United Kingdom	University of Bradford
Graziano	Leoni	Italy	University of Camerino
Yong	Wang	United Kingdom	University of Manchester
Riccardo	Zandonini	Italy	University of Trento
Gabriele	Bertagnoli	Italy	Politecnico di Torino
Emidio	Nigro	Italy	Università degli Studi di Napoli Federico II
Ahmed	Elghazouli	United Kingdom	Imperial College London
Giuseppe	Mancini	Italy	Politecnico Torino
Maria Rosaria	Pecce	Italy	University of Naples Federico II
Antonio	Bilotta	Italy	University of Naples Federico II
Alejandro	Pérez Caldentey	Spain	Universidad Politécnica de Madrid
Thanasis	Triantafillou	Greece	University of Patras
David	Fernández-Ordóñez	Switzerland	fib
Roman	Wan-Wendner	Belgium	Ghent University
Enzo	Martinelli	Italy	University of Salerno
Clémence	Le Pourry	France	Ingenova
Meini	Su	United Kingdom	University of Manchester
Hugo	Corres Peiretti	Spain	FHECOR Ingenieros Consultores
Alejandro	Giraldo Soto	Switzerland	-

TG2.7 - Seismic Design

The motivation for the work of Task Group 2.7 (TG2.7) is the promotion of the use and improvement in safety of concrete structures under accidental (e.g. seismic) actions and/or in exposed regions worldwide.

Convener
Paolo Franchin

First name	Last name	Country	Affiliation
Paolo	Franchin	Italy	Sapienza Università di Roma
Andreas	Kappos	United Arab Emirates	Khalifa Univ.
Michael	Fardis	Greece	University of Patras
David	Fernández-Ordóñez	Switzerland	fib
Gian	Calvi	Italy	Universita degli Studi di Pavia
Jesús-Miguel	Bairán	Spain	Universitat Politècnica de Catalunya (UPC-BarcelonaTECH)
Matjaz	Dolsek	Slovenia	Faculty of Civil and Geodetic Engineering
Iunio	Iervolino	Italy	Università degli Studi di Napoli Federico II
Tao	Wang	China	Institute of Engineering Mechanics
Philippe	Bisch	France	Egis Industries
Dionysis	Biskinis	Greece	University of Patras
Xilin	Lu	China	Tongji University
Telemachos	Panagiotakos	Greece	Private
Marko	Marinković	Serbia	University of Belgrade
Xavier	Romão	Portugal	University of Porto
Andrea	Lucchini	Italy	Sapienza University of Rome
Andrea	Marchi	Italy	Sapienza University of Rome
Qiuhong	Zhao	China	Tianjin University
Alper	Ilki	Turkey	ITU - Istanbul Technical University
Shigeki	Unjoh	China	Tohoku University
Koichi	Kusunoki	Japan	University of Tokyo
Juan	Murcia-Delso	Spain	Universitat Politècnica de Catalunya (UPC)
Murat Altug	Erberik	Turkey	Middle East Technical University
Jeena	Jayamon	United States	John A. Martin & Associates, Inc.
André	Furtado	Portugal	CERIS - Instituto Superior Técnico

TG2.8 - Safety and performance concepts

The overall motivation of Task Group 2.8 (TG2.8) is based on the fact that structural systems are typically designed to stay in service for at least several decades. This implies that proper attention must be given to structural performance under various actions, both man-made and environmental, to the methodology of structural analysis and assessment, to material properties, to the inverse identification and monitoring of structural resistance among others. The main focus is the development of a holistic performance based design approach for new and existing structures and infrastructures.

The objective of TG2.8 is to promote and to provide on the basis of the guide to good practice “safety and performance concepts – reliability assessment of concrete structures” the theoretical and practical developments for the performance based design. This includes structural safety, serviceability and reliability, advanced methodology including probabilistic methods, inverse analyses techniques, monitoring methods, and performance and optimised life-cycle cost based design concepts.

Convener
Konrad Berg-meister

Co-convener
Luc Taerwe

First name	Last name	Country	Affiliation
Dirk	Proske	Austria	Universität für Bodenkultur
David	Lehky	Czech Republic	Brno University of Technology
Andrzej	Nowak	United States	University of Nebraska
Dan	Frangopol	United States	Lehigh University
Drahomir	Novak	Czech Republic	Technical University of Brno
Jaime	Fernández Gomez	Spain	Universidad Politecnica de Madrid
Antonino	Recupero	Italy	R & S Engineering
Konrad	Bergmeister	Austria	Univ. Bodenkultur
André	de Chefdebien	France	Rector Lesage
Alfred	Strauss	Austria	BOKU University
Raphael	Steenbergen	Netherlands	TNO Structures and Safety
Ainars	Paeglitis	Latvia	-
C.-A.	Graubner	Germany	Techn. University Darmstadt
David	Fernández-Ordóñez	Switzerland	fib
Hans-Dieter	Beushausen	South Africa	University of Cape Town
Roman	Wan-Wendner	Belgium	Ghent University
José	Campos e Matos	Portugal	University of Minho
Christian	Bucher	Austria	Techn. Univ. Wien
Robby	Caspeele	Belgium	Ghent University
Nick	Zygouris	Greece	Lithos Consulting Engineers
Luc	Taerwe	Belgium	Ghent University

TG2.9 - Fastenings to structural concrete and masonry

The modern fastening technique is employed extensively for the transfer of concentrated loads into concrete and masonry structures. Cast-in-place anchors, placed in the formwork before casting of the concrete, as well as post-installed anchors and reinforcing bars, which are installed in hardened structural concrete or masonry, are equally common. Loads are transferred into the concrete or masonry by mechanical interlock, friction, bond or a combination of these mechanisms. However, independently of the load-transfer mechanism, all anchorages rely on the tensile strength of the concrete or masonry, a fact which must be taken into account in both assessment and design. Despite the widespread use of cast-in-place as well as post-installed anchors and reinforcing bars in construction, the overall level of understanding in the engineering community regarding their behaviour remains quite limited.

In order to improve the general state of knowledge in this field, Task Group 2.9 “Fastenings to Structural Concrete and Masonry” (former Special Activity Group 4) was formed.

The aim of TG2.9 is to collect and discuss the latest research results in the field of fastening technology, to identify new areas of research and to synthesise the research results in harmonised provisions for the design of fastenings.

Convener
Rolf Eligehausen

First name	Last name	Country	Affiliation
Giovanni	Muciaccia	Italy	Politecnico di Milano
Akanshu	Sharma	United States	Purdue University
Yoshiaki	Nakano	Japan	University of Tokyo
Elisabeth	Vintzileou	Greece	National Technical University Athens
Tomoaki	Akiyama	Japan	Tokyo Soil Research CO., LTD
Philipp	Grosser	Liechtenstein	Hilti Corporation
Jörg	Asmus	Germany	IEA GmbH & Co. KG
Yasuhiro	Matsuzaki	Japan	Science University of Tokyo
Rainer	Mallee	Germany	-
Dieter	Lotze	Germany	Universität Stuttgart, Materialprüfungsanstalt Otto-Graf-Institut
Klaus	Block	Germany	fobatec GmbH
Kurt	Stochlia	United States	ICC Evaluation Service
Yasutoshi	Yamamoto	Japan	GAL Building Consultant Office
Matthew	Hoehler	United States	Nat. Inst. of Standards & Technologies
Yoji	Hosokawa	Japan	The Tokyo University
Andra	Hörmann-Gast	United States	ICC Evaluation Service, LLC
Frank	Haüsler	Germany	Halfen GmbH
Anders	Bergkivist	Sweden	Vattenfall
Todd	Davis	United States	Milwaukee School of Engineering
Jay	Dorst	United States	Atlas Consulting Group
Mazen	Ayoubi	Germany	Jordahl GmbH
Shigehiro	Ando	Japan	Sumitomo Osaka Cement
Jean-Paul	Marasco	France	ITW-Spit
Peter	Schillinger	Germany	fischerwerke GmbH & Co. KG
David	Xiong	China	Hilti
Oliver	Zeman	Austria	Universität für Bodenkultur
Feng	Zhu	Germany	Fischerwerke GmbH & Co. KG
Brian	Gerber	United States	IAPMO
Thomas	Kuhn	Germany	Adolf Würth GmbH & Co KG
J. Bret	Turley	United States	Simpson Strong Tie Company, Inc.
Mark	Ziegler	United States	Powers Fasteners Inc.
Thomas	Kolden	United States	Element Materials Technology
Howard	Silverman	United States	ICC - Evaluation Service
Valerie	Rostaind	France	Spit
Philipp	Mahrenholtz	Germany	Stanley Black & Decker Deutschland GmbH
Rasoul	Nilforoush	Sweden	Luleå University of Technology
Andreas	Wendt	United States	Simpson Strong Tie Company, Inc.
Catherina	Thiele	Germany	Technische Universität Kaiserlautern
Pierre	Pimienta	France	CSTB - Centre Scien. et Techn. du Bâtiment
Gerhard	Lange	Germany	Deutsches Institut für Bautechnik
Nicolas	Pinoteau	France	CSTB
Jürgen	Stork	Germany	Consultant
Konrad	Bergmeister	Austria	Univ. Bodenkultur
Jochen	Buhler	Germany	Adolf Würth GmbH & Co KG
Thierry	Guillet	France	CSTB
Jan	Hofmann	Germany	IWB, Universität Stuttgart
Torsten	Rutz	Germany	MKT Metall-Kunststoff-Technik GmbH
John	Silva	United States	Hilti Inc.
Friedrich	Wall	Liechtenstein	Hilti AG
Philipp	Strater	Germany	Chemofast Anchoring GmbH
Ronald	Cook	United States	University of Florida
Longfei	Li	Germany	Dr. Li Anchor Profi GmbH
David	Fernández-Ordóñez	Switzerland	fib
Geoff	Fletcher	Australia	National Precast Concrete Assoc Australia
Norbert	Randl	Austria	Carinthia Univ. of Applied Sciences
Muneomi	Takahashi	Japan	Hilti Japan
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart
Lennart	Elfgren	Sweden	Luleå University of Technology
Jorma	Kinnunen	Finland	Peikko Group Corporation
Roman	Wan-Wendner	Belgium	Ghent University
Jake	Olsenv	United States	Powers Fasteners
Alper	Ilki	Turkey	ITU - Istanbul Technical University
Werner	Fuchs	Germany	Universität Stuttgart
Christoph	Mahrenholtz	Germany	Jordahl GmbH
Jian	Zhao	United States	University of Wisconsin
Thomas	Cebulla	Germany	S&P Software Consulting & Solutions GmbH
Omar	Al-Mansouri	France	CSTB (Centre Scientifique et Technique du Bâtiment)
Thilo	Pregartner	Germany	fischerwerke GmbH & Co. KG
Máté	Tóth	Germany	fischerwerke GmbH & Co. KG
Chiwan	Hsieh	Taiwan, Province of China	National Pingtung University of Science and Technology
Vincent	Chui	United States	ICC-Evaluation Service
Andreas	Beer	Germany	Halfen GmbH
Thomas	Sippel	Finland	Peikko Group Corp.
Adeola	Adediran	United States	Bechtel
Beatrix	Wittstock	Germany	Deutsches Institut für Bautechnik
Ulrike	Kuhlmann	Germany	University of Stuttgart
Thilo	Fröhlich	Germany	University of Stuttgart, Materials Testing Institute (Otto-Graf-Institut)
Boglárka	Bokor	Liechtenstein	Hilti Corporation
Martin	Umminger	Germany	Adolf Würth GmbH & Co. KG
Giovacchino	Genesio	Germany	Hilti group
Andreas	Kummerow	Germany	Deutsches Institut für Bautechnik
Emanuel	Ghermanschi-Lungu	United Kingdom	ECAP
Tilak	Pokharel	Australia	Australian Engineered Fasteners and Anchors Council (AEFAC)

WP2.9.1 - Review of current fib model with a view to MC2010 and model for anchor reinforcement

Revision of the design model for anchorage reinforcement taking into account bond provisions of the fib MC 2010.

Convener
Akanshu Sharma

First name	Last name	Country	Affiliation
Akanshu	Sharma	United States	Purdue University
Jörg	Asmus	Germany	IEA GmbH & Co. KG
Jan	Hofmann	Germany	IWB, Universität Stuttgart
John	Silva	United States	Hilti Inc.
David	Fernández-Ordóñez	Switzerland	fib
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart
Lennart	Elfgren	Sweden	Luleå University of Technology
Thomas	Sippel	Finland	Peikko Group Corp.
Adeola	Adediran	United States	Bechtel
Martin	Umminger	Germany	Adolf Würth GmbH & Co. KG

WP2.9.2 - Open topics in the current design guide

Review of the design provisions for anchorages in respect to inconsistencies and new research results and development of improved design provisions.

Convener
Jürgen Stork

First name	Last name	Country	Affiliation
Rainer	Mallee	Germany	-
Andreas	Wendt	United States	Simpson Strong Tie Company, Inc.
Thilo	Pregartner	Germany	fischerwerke GmbH & Co. KG
Jürgen	Stork	Germany	Consultant
Jochen	Buhler	Germany	Adolf Würth GmbH & Co KG
Friedrich	Wall	Liechtenstein	Hilti AG
Longfei	Li	Germany	Dr. Li Anchor Profi GmbH
David	Fernández-Ordóñez	Switzerland	fib
Akanshu	Sharma	United States	Purdue University
Máté	Tóth	Germany	fischerwerke GmbH & Co. KG
Boglárka	Bokor	Liechtenstein	Hilti Corporation
Martin	Umminger	Germany	Adolf Würth GmbH & Co. KG

WP2.9.3 - Shear lugs

Development of provisions for the design of shear lugs. A proposal for designing fastenings with shear lugs has been accepted by TG2.9 and will be incorporated in the new edition of the fib design guide.

Convener
Ronald Cook

First name	Last name	Country	Affiliation
Harald	Michler	Germany	Technische Universität Dresden
Jürgen	Stork	Germany	Consultant
John	Silva	United States	Hilti Inc.
Ronald	Cook	United States	University of Florida
David	Fernández-Ordóñez	Switzerland	fib
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart

WP2.9.4 - Fatigue loading

Review of the existing simplified design provisions for anchorages under fatigue loading and development of less conservative design provisions.

Convener
Dieter Lotze

Co-convener
Mate Toth

First name	Last name	Country	Affiliation
Dieter	Lotze	Germany	Universität Stuttgart, Materialprüfungsanstalt Otto-Graf-Institut
Klaus	Block	Germany	fobatec GmbH
Jan	Hofmann	Germany	IWB, Universität Stuttgart
Friedrich	Wall	Liechtenstein	Hilti AG
Longfei	Li	Germany	Dr. Li Anchor Profi GmbH
David	Fernández-Ordóñez	Switzerland	fib
Máté	Tóth	Germany	fischerwerke GmbH & Co. KG
Thomas	Sippel	Finland	Peikko Group Corp.
Thilo	Fröhlich	Germany	University of Stuttgart, Materials Testing Institute (Otto-Graf-Institut)
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart
Thilo	Pregartner	Germany	fischerwerke GmbH & Co. KG

WP2.9.5 - Bonded anchors under sustained load

Review of research results on bonded anchors under sustained load and development of provisions for the design of anchorages with bonded anchors and connections with post-installed reinforcement to take into account the negative influence of sustained load. A proposal for design provisions has been accepted by TG2.9 and will be incorporated in the fib design guide.

Convener
Jan Hofmann

Convener
Ronald Cook

First name	Last name	Country	Affiliation
Thierry	Guillet	France	CSTB
Jan	Hofmann	Germany	IWB, Universität Stuttgart
Joachim	Schätzle	Germany	Fischerwerke GmbH & Co. KG
Friedrich	Wall	Liechtenstein	Hilti AG
Ronald	Cook	United States	University of Florida
David	Fernández-Ordóñez	Switzerland	fib
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart
Omar	Al-Mansouri	France	CSTB (Centre Scientifique et Technique du Bâtiment)

WP2.9.6 - Post-installed reinforcement – Harmonisation of rules for reinforced concrete and anchorages with bonded anchors and post-installed reinforcement

Development of a harmonised design concept for connections with bonded anchors and postinstalled reinforcement under static and seismic loading.

Convener
John F. Silva

First name	Last name	Country	Affiliation
Akanshu	Sharma	United States	Purdue University
John	Silva	United States	Hilti Inc.
David	Fernández-Ordóñez	Switzerland	fib
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart
Christoph	Mahrenholtz	Germany	Jordahl GmbH

WP2.9.7 - Splitting of bonded anchors

Development of design provision for bonded anchors to prevent splitting of the concrete member during pretensioning and loading which shall replace the currently required approval tests.

Convener
Jörg Asmus

First name	Last name	Country	Affiliation
Jörg	Asmus	Germany	IEA GmbH & Co. KG
Thierry	Guillet	France	CSTB
Ronald	Cook	United States	University of Florida
David	Fernández-Ordóñez	Switzerland	fib
Andreas	Kummerow	Germany	Deutsches Institut für Bautechnik
Omar	Al-Mansouri	France	CSTB (Centre Scientifique et Technique du Bâtiment)

WP2.9.8 - Required stiffness of baseplates

In general, anchorages are designed under the assumption that the baseplate is stiff. However, no criteria are given in the fib Design Guide to assure a stiff baseplate. These provisions are under development. Furthermore, design rules for fastenings with flexible base plates are being discussed.

Convener
Longfei Li

First name	Last name	Country	Affiliation
Jürgen	Stork	Germany	Consultant
Friedrich	Wall	Liechtenstein	Hilti AG
Ronald	Cook	United States	University of Florida
Longfei	Li	Germany	Dr. Li Anchor Profi GmbH
David	Fernández-Ordóñez	Switzerland	fib
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart
Akanshu	Sharma	United States	Purdue University
Brian	Gerber	United States	IAPMO
Dieter	Lotze	Germany	Universität Stuttgart, Materialprüfungsanstalt Otto-Graf-Institut
Giovanni	Muciaccia	Italy	Politecnico di Milano
Thilo	Pregartner	Germany	fischerwerke GmbH & Co. KG
Feng	Zhu	Germany	Fischerwerke GmbH & Co. KG
Beatrix	Wittstock	Germany	Deutsches Institut für Bautechnik
John	Silva	United States	Hilti Inc.
Clement	Herve	France	EDF
Jörg	Asmus	Germany	IEA GmbH & Co. KG
Omar	Al-Mansouri	France	CSTB (Centre Scientifique et Technique du Bâtiment)
Rainer	Mallee	Germany	-
Boglárka	Bokor	Liechtenstein	Hilti Corporation
Martin	Umminger	Germany	Adolf Würth GmbH & Co. KG

WP2.9.9 - Fire Resistance of anchors and post-installed reinforcement

Development of more refined provisions for the design of anchorages with all types of anchors and of connections with post-installed reinforcement under fire exposure. A proposal for the design of fastenings with post-installed reinforcement under fire exposure has been accepted by TG2.9. These will be incorporated in the fib design guide.

Convener
Thierry Guillet

First name	Last name	Country	Affiliation
Kurt	Stochlia	United States	ICC Evaluation Service
Pierre	Pimienta	France	CSTB - Centre Scien. et Techn. du Bâtiment
Gerhard	Lange	Germany	Deutsches Institut für Bautechnik
Nicolas	Pinoteau	France	CSTB
Thierry	Guillet	France	CSTB
Jan	Hofmann	Germany	IWB, Universität Stuttgart
John	Silva	United States	Hilti Inc.
David	Fernández-Ordóñez	Switzerland	fib
Muneomi	Takahashi	Japan	Hilti Japan
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart
Akanshu	Sharma	United States	Purdue University
Omar	Al-Mansouri	France	CSTB (Centre Scientifique et Technique du Bâtiment)

WP2.9.10 - Evaluation and assessment of existing anchorages

Development of provisions for evaluation and assessment of existing anchorages which are currently not available but urgently needed.

Convener
Lennart Elfgren

First name	Last name	Country	Affiliation
Lennart	Elfgren	Sweden	Luleå University of Technology
Giovanni	Muciaccia	Italy	Politecnico di Milano
Longfei	Li	Germany	Dr. Li Anchor Profi GmbH
Akanshu	Sharma	United States	Purdue University
David	Fernández-Ordóñez	Switzerland	fib
Jörg	Asmus	Germany	IEA GmbH & Co. KG
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart
Yasuhiro	Matsuzaki	Japan	Science University of Tokyo
Rasoul	Nilforoush	Sweden	Luleå University of Technology
John	Silva	United States	Hilti Inc.
Omar	Al-Mansouri	France	CSTB (Centre Scientifique et Technique du Bâtiment)
Thierry	Guillet	France	CSTB
Martin	Umminger	Germany	Adolf Würth GmbH & Co. KG

WP2.9.11 - Steel shear strength of anchorages with stand-off base plate connection

Development of provisions to calculate the design steel shear strength of anchorages with stand-off base plate connections. Design provisions proposed by WP have been accepted by TG2.9 and will be incorporated in the fib design guide.

Convener
Ronald Cook

First name	Last name	Country	Affiliation
Giovanni	Muciaccia	Italy	Politecnico di Milano
Jan	Hofmann	Germany	IWB, Universität Stuttgart
John	Silva	United States	Hilti Inc.
Ronald	Cook	United States	University of Florida
David	Fernández-Ordóñez	Switzerland	fib
Rolf	Eligehausen	Germany	IWB, Universität Stuttgart

WP2.9.12 - Seismic Design

Development of provisions for seismic design of anchorages.

Convener
Giovanni Muciaccia

First name	Last name	Country	Affiliation
Giovanni	Muciaccia	Italy	Politecnico di Milano
Akanshu	Sharma	United States	Purdue University
David	Fernández-Ordóñez	Switzerland	fib
Omar	Al-Mansouri	France	CSTB (Centre Scientifique et Technique du Bâtiment)
Thomas	Sippel	Finland	Peikko Group Corp.
Martin	Umminger	Germany	Adolf Würth GmbH & Co. KG

TG2.10 - Textile reinforced concrete construction and design

New material composites such as textile/carbon reinforced concrete have been developed during the past two decades. Textile reinforced concrete is a composite material where the concrete is reinforced with textile structures instead of classical reinforcement steel. Apart from alcali resistant glass and similar materials, carbon has become the prevalent reinforcement material and lead to the development of so-called carbon concrete. Carbon textile fabrics as well as carbon bars are used as reinforcement material for carbon concrete. Carbon's resistance to corrosion allows an enormous reduction of concrete cover thickness in comparison to classical steel reinforced concrete.

These developments offer new ways in concrete constructions due to the possibility for curved, thinner and more filigree construction components. This might be a starting point for several new research work. Therefore, the work of a task group is considered meaningful. The task group "Textile reinforced concrete" will mainly (not exclusively) deal with carbon reinforcement. The task group may contribute in working out rules and compiling guidelines for the design of constructions made of the new composite material textile/carbon reinforced concrete.

The objective of the proposed task group is construction and design of textile reinforced concrete. Regarding the reinforcement material, carbon is in focus. The aim of the task group is to contribute in working out rules and compiling guidelines for the design of constructions made of textile/carbon reinforced concrete.

Convener
Manfred Curbach

First name	Last name	Country	Affiliation
Frank	Dehn	Germany	KIT Karlsruher Institut für Technologie
Rostislav	Chudoba	Germany	RWTH Aachen University
Erez	GAL	Israel	Ben-Gurion University of the Negev
Alva	Peled	Israel	Ben-Gurion University of the Negev
Michael	Raupach	Germany	RWTH Aachen University
Silke	Scheere	Germany	TU Dresden
Barzin	Mobasher	United States	Arizona State University
Harald	Michler	Germany	Technische Universität Dresden
Giuseppe	Mancini	Italy	Politecnico Torino
Manfred	Curbach	Germany	Technische Univ. Dresden
Josef	Hegger	Germany	RWTH Aachen
Viktor	Mechtcherine	Germany	Technical Univ. Dresden
David	Fernández-Ordóñez	Switzerland	fib
ab	van den bos	Netherlands	NLyse
Thanasis	Triantafillou	Greece	University of Patras
Norbert	Will	Germany	RWTH Aachen University
Tine	Tysmans	Belgium	Vrije Universiteit Brussel (VUB)
Rolf	Alex	Germany	Deutsches Institut für Bautechnik (DIBt)
Birgit	Beckmann	Germany	TU Dresden
Isabella Giorgia	Colombo	Italy	Politecnico di Milano
Arnon	Bentur	Israel	Technion - Israel Institute of Technology
Matteo	Colombo	Italy	Politecnico di Milano
Flavio	De Andrade Silva	Brazil	Pontificia Universidade Católica do Rio de Janeiro
Lars	Eckfeldt	Germany	Deutsches Institut für Bautechnik (DIBt)
Petr	Hajek	Czech Republic	Czech Technical University in Prague
Oliver	Heppes	Germany	Goldbeck Bauelemente Bielefeld SE
Benjamin	Kromoser	Austria	Universität für Bodenkultur Wien
Minoru	Kunieda	Japan	GIfu University
Steffen	Müller	Germany	TU Dresden
Aurelio	Muttoni	Switzerland	École polytechnique fédérale de Lausanne (EPF Lausanne)
Antoine	Naaman	United States	University of Michigan
Corina	Papanikolaou	Greece	University of Patras - VAT Nr 090061075
Miguel	Fernández Ruiz	Spain	Universidad Politécnica de Madrid
Frank	Schladitz	Germany	TU Dresden
Alexander	Schumann	Germany	TU Dresden
Amir	Si Larbi	France	Civil Engineering Department, Ecole Nationale d'ingénieurs de Saint-Etienne
Jan	Wastiels	Belgium	Vrije Universiteit Brussel
Juliane	Wagner	Germany	TU Dresden
Marco	di Prisco	Italy	Politecnico di Milano
Marko	Butler	Germany	TU Dresden
Ulrich	Häußler-Combe	Germany	TU Dresden
Martin	Hunger	Germany	BASF Construction Solutions GmbH
Peter	Jehle	Germany	TU Dresden
Philipp	Preinstorfer	Austria	Technische Universität Wien
Silvio	Weiland	Germany	Loock & Weiland
Josiane	Giese	Germany	Dresden University
Bahman	Ghiassi	United Kingdom	University of Birmingham / School of Engineering
Pietro	Mazzuca	Italy	University of Calabria

TG2.11 - Structures made by digital fabrication

Digital fabrication processes for fabricating concrete-like products, objects and/or structures are typically grouped into three main categories: (i) Layered Extrusion (e.g. contour crafting, concrete printing etc.), (ii) Binder Jetting (e.g. D-shape), (iii) Slip-forming (e.g. smart dynamic casting). However, to date, many important developments have been accomplished for layered extrusion technology, consisting of a digitally controlled moving printing head (or nozzle) that precisely lays down the concrete or mortar material layer-by-layer.

It is clear that the full understanding of the structural performances of digitally fabricated elements represents noteworthy progress in supporting the design of such innovative structures. In this way, reliable structural concepts and assessment methodologies could be integrated within existing international building codes/standards and adapted to the particularities of DFC, providing effective recommendations to the construction industry stakeholders.

The primary objective of the task group is to identify limiting aspects of the current design practice for the implementation of novel, digitally-fabricated concrete structures. Based on that, the task group will address fundamental structural issues related to the particularities of DFC with the final aim of providing effective guidelines for code-compliant applications.

Convener
Costantino Menna

Co-Convener
Domenico Asprone

First name	Last name	Country	Affiliation
Liberato	Ferrara	Italy	Politecnico di Milano
Domenico	Asprone	Italy	University of Naples Federico II
Costantino	Menna	Italy	University of Naples Federico II
Kim	Van Tittelboom	Belgium	University of Ghent
Jaime	Mata-Falcón	Spain	Universitat Politècnica de València
Theo	Salet	Netherlands	Witteveen + Bos Raadgev. Ing.
David	Fernández-Ordóñez	Switzerland	fib
Freek	Bos	Netherlands	Technische Universiteit Eindhoven
Richard	Buswell	United Kingdom	Loughborough University
Sergio	Cavalaro	United Kingdom	Loughborough University
Geert	de Schutter	Belgium	Ghent University
Jacques	Kruger	South Africa	Laboratory Manager & Researcher
Dirk	Lowke	Germany	Technische Universität Braunschweig
Tor	Martius-Hammer	Norway	SINTEF AS
Viktor	Mechtcherine	Germany	Technical Univ. Dresden
Alessandro	Morbi	Italy	ITALCEMENTI S.p.A. - HeidelbergCement Group
Sandro	Moro	Italy	BASF
Venkatesh Naidu	Nerella	Germany	TU-Dresden
Nicolas	Roussel	France	IFSTTAR
Branko	Šavija	Netherlands	Delft University of Technology
Matthieu	Schipper	Netherlands	Delft University of Technology
Erik	Schlangen	Netherlands	Delft University of Technology
Weiqiang	Wang	China	Hohai University
Paulo J.S.	Cruz	Portugal	University of Minho
Lucia	Licciardello	Italy	University of Brescia
Wilson Ricardo	Leal da Silva	Denmark	Teknologisk Institut
Paul	Tykodi	United States	-
Ksenija	Vasilic	Germany	German Society for Concrete and Construction Technology
Navendu	Rai	United Arab Emirates	-
Helder Filipe	Moreira de Sousa	Portugal	Brisa Group

TG2.12 - Protective Concrete Structures against Hazards

Concrete structures are suitable for the development and construction of protective structures against several kinds of hazards, like a blast, missiles, impact or thermal loads. The reasons for such extreme loadings may be different, but the structures under consideration have to provide conditions for safe and relatively comfortable survival of people inside. The TG2.12 will develop documents which specify the conditions of performance of protective structures and conditions for their design.

Convener
Klaas Van Breugel

First name	Last name	Country	Affiliation
Avraham	Dancygier	Israel	Technion-Israel Institute of Technology
Jaap	Weerheijm	Netherlands	TU Delft
Peter	Jäger	Switzerland	Peter Jäger Partner Bauingenieure AG
Klaas	van Breugel	Netherlands	Delft Univ. of Technology
David	Fernández-Ordóñez	Switzerland	fib
Sander	Meijers	Netherlands	Royal Haskoning / DHV
Birgit	Beckmann	Germany	TU Dresden
Alessandro	Stocchi	Germany	Fraunhofer EMI

WP2.12.1

WP2.12.1 Design of structures subjected to impact and explosion

Concrete structures can be subjected to variable actions inducing very high strain rates, generated by several kinds of hazards, like blast, missiles or fragments, impact, in normal conditions or fire. The reasons for such extreme loadings may be different, but the structures investigated have to provide conditions for safe and relatively comfortable survival of people and equipment inside.

According to the TG 2.12 activity, the action group AG12 has rewritten the chapter 30.2.3 on Impact and Explosion. The synthesis introduced in the Model Code requires a background document able to explain the change introduced in relation to Model Code 2010.

The members of the Working Party have prepared a first draft of a bulletin aimed at introducing the background knowledge that explains the main novelties introduced in the indicated chapter. The idea is to discuss the document together with the interested people of the TG 2.12 in order to give the designers who are called to design protective structures a modern and a reliable basic tool.

Convener
Marco Di Prisco

Co-Convener
Ezio Cadoni

First name	Last name	Country	Affiliation
Marco	di Prisco	Italy	Politecnico di Milano
David	Fernández-Ordóñez	Switzerland	fib
Josko	Ozbolt	Germany	Universität Stuttgart
Alejandro	Pérez Caldentey	Spain	Universidad Politécnica de Madrid
Avraham	Dancygier	Israel	Technion-Israel Institute of Technology
Jaap	Weerheijm	Netherlands	TU Delft
Matteo	Colombo	Italy	Politecnico di Milano
JIANGPENG	SHU	Norway	Norwegian University of Science and Technology
Nemkumar	Banthia	Canada	Univ. of British Columbia
Terje	Kanstad	Norway	The Norwegian Univ.of Science & Tech
Gerrie	Dieteren	Netherlands	TNO
Klaas	van Breugel	Netherlands	Delft Univ. of Technology
Manfred	Keuser	Germany	BUNG Ingenieure A
François	Toutlemonde	France	Université Gustave Eiffel
Kim	Johansson	Finland	Concrete Assoc. of Finland
Viktor	Mechtcherine	Germany	Technical Univ. Dresden
Manfred	Curbach	Germany	Technische Univ. Dresden
Barzin	Mobasher	United States	Arizona State University
Ezio	Cadoni	Switzerland	DynaMat SUPSI Laboratory

TG2.13 - Design and assessment for tsunami loading

The primary objective of the task group (TG) is to identify methodologies for: (i) the design of tsunami resistant structures/infrastructure, (ii) the assessment of existing assets against tsunami-induced loads and (iii) the design/assessment of existing assets towards the sequential hazards such as earthquakes and tsunami, or other triggering hazards. Assets under investigation include RC, masonry, steel and composite structures and infrastructure.

The TG plans to face structural issues by focusing on the structural response of reinforced concrete structures and infrastructure under tsunami loading, with main focus on:

The definition and estimation of loads (i.e., hydrostatic and hydrodynamic horizontal and vertical loads induced by a tsunami, such as buoyancy) acting on structural members for design/assessment of structures and infrastructure;
The behaviour of non-structural components, such as infill walls;
The structural analysis methodology for design/assessment;
Performance levels and safety checks at local and global levels.

The fundamental knowledge produced in this framework will support the introduction of reliable design/assessment criteria in the field of tsunami engineering. This will provide an improvement with respect to existing international codes and will represent the first guideline for Europe.

The TG will also address aspects related to the harmonization of tsunami design provisions with existing design provisions for other kind of hazards.

Convener
Rossetto Tiziana

Co-Convener
Del Zoppo Marta

First name	Last name	Country	Affiliation
Tiziana	Rossetto	United Kingdom	University College London
Marta	Del Zoppo	Italy	University of Naples Federico II
Andre	Barbosa	United States	Structural Engineering
Ian	Robertson	United States	University of Hawaii at Manoa
Toshikazu	Kabeyasawa	Japan	Faculty of Urban Environmental Sciences
Ioan	Nistor	Canada	University of Ottawa
Dawn	Lehman	United States	University of Washington
Andrea	Prota	Italy	Universita di Napoli Federico II
Marco	Baiguera	United Kingdom	University of Southampton
Kyriazis	Pitilakis	Greece	Aristotle University of Thessaloniki
Priyan	Dias	Sri Lanka	University of Moratuwa
Katsu	Goda	Canada	Western University
Daniel	Cox	United States	Oregon State University
Gary	Chock	United States	Martin, Chock & Carden, Inc.
Dan	Palermo	Canada	York University
Patricio	Catalan	Chile	-
Cláudia	Reis	Portugal	Instituto Superior Técnico
David	McGovern	United Kingdom	London South Bank University
Taro	Arikawa	Japan	Chuo University
Davide	Wüthrich	Netherlands	-
Jonas	Cels	United Kingdom	-
Andrew	Foster	United Kingdom	-
Ian	Chandler	United Kingdom	HR Wallingford
Marco	Di Ludovico	Italy	University of Naples
Maria Teresa	De Risi	Italy	University of Naples Federico II
Julian	Thamboo	Sri Lanka	South Eastern University of Sri Lanka
Keith	Adams	United Kingdom	-
Angelos	Dimakopoulos	Greece	University Campus, Rio, Patra

TG2.14 - Open-source code development by the fib

The fib has started developing an open-source Python package containing models from the fib Model Code. Github is used as a platform for version control and code collaboration. On the long-term, this package should contain all models in the fib Model Code. When sufficiently mature, the package should be published on PyPI.org to arrange for easy distribution. The package should be published with a license that grants the user flexible rights to use, study, edit and publish the source code, without warranty of any kind.

Primary objective of the TG: serve as a team of core developers or maintainers of the Python package. This includes, but is not limited to:

Contribute code to the package.
Respond to issues that are reported and initiate relevant actions.
Maintain a CI/CD, continuous integration and continuous delivery, pipeline.
Review contributions from the community, and merge these when properly matured.

The fib seeks contributions from the fib and the engineering community as a whole.

Convener
Morten Engen

Co-Convener
Diego Alexandro Talledo

First name	Last name	Country	Affiliation
Morten	Engen	Norway	Multiconsult AS
David	Fernández-Ordóñez	Switzerland	fib
DIEGO ALEJANDRO	TALLEDO	Italy	University IUAV of Venice
Daniel	González de la Morena	Spain	Fhecor
Javier	García Hernando	Spain	Fhecor
Carlos	Mestre	Spain	Fhecor
Alejandro	Pérez Caldentey	Spain	Universidad Politécnica de Madrid
Arthur	Slobbe	Netherlands	TNO
Jemma	Ehsman	Australia	Rio Tinto - Dampier Salt
Gijs	Eumelen	Netherlands	TNO

TG2.15 - Bridges with combined reinforcement

Unbonded – external post-tensioning (PT) tendons are gaining interest world-wide within the concrete bridge community. The ability to address unforeseen issues has always been valued by bridge engineers and unbonded external PT tendons provide bridge designers and owners the flexibility to address these issues through their ability to be replaced while the bridge is in-service. Four countries, France, Germany, Japan, and United States are using this technology to provide tendon replaceability.

The use of unbonded tendons has led to components with both bonded and unbonded prestressing and/or mild reinforcement. Research has shown that the use of mixed reinforcement conditions (i.e. bonded and unbonded PT with and without mild reinforcement) in concrete members has structural implications (UF Report). Most current specifications consider their design approach as conservative for the design of components with mixed reinforcement conditions. However, research has shown that the performance and appropriate design of these members is complex and comprehensive guidance is needed to educate engineers on the design of these unique components. Therefore, there is a great need for clear design guidance to bridge designers on this unique and increasingly popular posttensioned component.

This guidance can have at least four purposes: i) provide background information on the performance of mixed reinforced elements with varying amounts of unbonded to bonded PT ratios, ii) synthesize current codified design methods for members with mixed reinforcement, iii) develop guidance on appropriate analysis methods, and iv) develop design approach for flexural capacity, including resistance factors & associated ductility requirements.

The primary objective of the task group (TG) is to serve as a team of core technical reviewers for the development of this technical report. Expertise in the design of complex concrete elements and experience with design methods for mixed reinforced members is desired.

Convener
John Corven

Co-Convener
Oguzhan Bayrak

First name	Last name	Country	Affiliation
John	Corven	United States	Hardesty & Hannover Convener
Oguzhan	Bayrak	United States	Univ. of Texas at Austin
David	Fernández-Ordóñez	Switzerland	fib
Christian	Gläser	Germany	DYWIDAG-Systems International
Adrian	Gnägi	Switzerland	VSL International Ltd.
Jan	Vítek	Czech Republic	Metrostav a. s.
Hikaru	Nakamura	Japan	Nagoya University
Tommaso	Ciccone	Italy	TENSA (Tensacciai s.r.l.)
Reggie H.	Holt	United States	Federal Highway Administration
Will	Potter	United States	Florida Department of Transportation
Richard	Brice	United States	Washington DOT
Gregory	Hunsicker	United States	OnPoint Engineering and Technology LLC
Ivica	Zivanovic	France	Freyssinet
Jerry	Pfutner	United States	COWI
Dimitrios	Paspastergiou	Switzerland	FEDRO
David	Garber	United States	FHWA

COM1: Concrete structures

Written on 21 March 2017.

Motivation

Commission 1 (COM1) seeks to encourage and develop good practices in the design of concrete structures, with a special emphasis on innovation and imagination. Its work should complement national, regional (e.g. Eurocodes), as well as international codes (e.g. the fib Model Code for Concrete Structures 2010), which in principle give only design specifications.

Scope and objective of technical work

COM1 examines all aspects of specific types of structures, from their structural and architectural design to construction and service life.

COM1 aims to provide state-of-the-art documentation and recommendations for all types of structures where structural concrete plays a significant role. This will apply in priority to fields of development where data and guidelines are not yet available, either new types of structures or implementation of new developments of materials, or a combination of both. COM1 endeavours to promote practices leading to sound, economical, durable and aesthetic design, with special attention to sustainable development principles.

Commission Chair
Alberto Meda

Deputy Chair
Arianna Minoretti

TG1.1 - Bridges

Task Group 1.1 (TG1.1) is dedicated to bridge engineering. All types of bridges are concerned, with a predominance of concrete bridges. Theoretical and practical aspects are treated, as well as construction techniques. Innovations and recent developments but also established good practices are highlighted. Emphasis is placed on bridge architecture and design.

The general objective of the task group is to provide design guides, recommendations, practical design rules and technical advice on bridge design and related construction techniques. Rules of good practice and recommendations for the correct use of materials and techniques are formulated.

Convener
Thierry Delémont

WP1.1.1 - Bridges for high-speed trains

Working Party 1.1.1 (WP 1.1.1) aims to provide guidance for designers of bridges for high speed trains, covering issues such as loads, dynamics, rail deck interaction, wind, slipstream forces, accidental situations, maintenance and inspection, etc. The document will be based on existing guidance edited by the German railway administration. International expertise will broaden the recommendations and bring them to an international level.

Convener
Steffen Marx

First name	Last name	Country	Affiliation
Thomas	Fackler	Germany	Schlaich Bergermann und Partner GmbH
Günter	Seidl	Germany	SSF Ingenieure AG
Patrice	Schmitt	France	SNCF
Steffen	Marx	Germany	-
David	Fernández-Ordóñez	Switzerland	fib
Miguel Angel	Astiz Suarez	Spain	Carlos Fernandez Casado S. L.
Juan	Sobrino	Spain	Pedelta, S. L.
Junling	Sun	China	Sun Engineering Consultants Intl., Inc.

WP1.1.3 - Integral bridges

The scope of WP 1.1.3 is to prepare practical guidelines on semi-integral and integral bridges. The objective of these guidelines is to define the current best practical response to specific problems associated with semi-integral and integral bridges from an international perspective. It will be based on existing guidelines, results from scientific research and feedback from practical experience.

Convener
Alessandro Parlermo

Co-Convener
Jessica Sanderberg

First name	Last name	Country	Affiliation
Murat	Dicleli	Turkey	Middle East Technical University
Philipp	Wenger	Germany	schlaich bergermann partner
Sergio	Breña	United States	University of Massachusetts Amherst
Philippe	Jandin	France	CEREMA
Rémi	Havy	France	ARCADIS
Peter	Collin	Sweden	Luleå University of Technology
Damien	Champenoy	France	CEREMA
João	Almeida	Portugal	Instituto Superior Técnico Lisboa
Michel	Moussard	France	Consultant
Anssi	Laaksonen	Finland	Tampere University of Technology
Steffen	Marx	Germany	-
Alejandro	Pérez Caldentey	Spain	Universidad Politécnica de Madrid
Alessandro	Palermo	New Zealand	The University of Canterbury
Walter	Kaufmann	Switzerland	ETH Zürich
David	Fernández-Ordóñez	Switzerland	fib
Aurelio	Muttoni	Switzerland	École polytechnique fédérale de Lausanne (EPF Lausanne)
Susumu	Inoue	Japan	Osaka Institute of Technology
Marcos	Sanchez	Ireland	ARUP
Jessica	Sandberg	United Kingdom	Atkins
Sotiria	Stefanidou	Greece	Aristote University of Thessaloniki
Petr	Tej	Czech Republic	Czech Technical University
Max	Herbers	Germany	University of Dresden
Moustafa	Al-Ani	New Zealand	-
Bruno	Briseghella	China	Fuzhou University
Habib	Tabatabai	United States	University of Wisconsin-Milwaukee
Jerome	Michel	France	Cerema

WP1.1.4 - Light railway bridges

While road and railway bridges benefit from standards and extensive documentation often published by state agencies, it is not the case for lightweight railway bridges. This can be explained by the variety of systems ranging from LRT (Light Rail Transit) to MRT (Mass Rapid Transit) and the fact that these systems are mainly operating at a city or regional level.

However, from a bridge engineering perspective, common features, particular requirements and good practices for design and construction that specifically apply to these transportation modes can be identified.

The general objective of this working party is to provide a state-of-the-art report for the design of LRT and MRT bridges.

Convener
TBD

First name	Last name	Country	Affiliation
David	Fernández-Ordóñez	Switzerland	fib
Gopal	Srinivasan	United Kingdom	Arup
Sherif	Ezzat	Egypt	econstruct
Huy	Lam	France	Systra
Tatsuya	Nihei	Japan	Railway Technical Research Institute
Chiayu	Chen	Taiwan, Province of China	TYLIN International Group

WP1.1.5 - Management of of prestressed concrete bridges

Over recent years some significant work has gone into inspection and investigation of post-tensioned bridges around the world. This has led to an increase in understanding the methods of inspection to determine the condition of the prestressing tendons and the whole process to assess structural safety. Some bridges of this type have been repaired and others have been replaced. Long term management of such bridges is becoming important to bridge owners around the world and guidance is scarce.

The working party can collect the current state-of-the-art of such processes from the fib’s member countries and prepare a state-of-the-art report with guidance to assist the countries that are still to embark on inspecting their stock of such bridges.

Convener
Peter Paulik

First name	Last name	Country	Affiliation
Bruno	Godart	France	-
Gaute	Nordbotten	Norway	Norwegian Public Roads Administration
Tohru	Makita	Japan	Central Nippon Expressway Company Limited
Teddy	Theryo	United States	BCC Engineering
Jae-Yeol	Cho	Korea, Republic of	Seoul National University
David	Fernández-Ordóñez	Switzerland	fib
Peter	Paulik	Slovakia	Slovak University of Technology in Bratislava
Manuel	Pipa	Portugal	LNEC Lisbon
Chris	Hendy	United Kingdom	Atkins
Fernando	Stucchi	Brazil	ABECE/EGT
Piotr	Gwoździewicz	Poland	Cracow University of Technology
Milan	Kalny	Czech Republic	Pontex s.r.o. Prague
Edo	Vonk	Switzerland	VSL International
Sherif	Ezzat	Egypt	econstruct
Jeanette	Hunter	United Kingdom	Ramboll UK Ltd

WP1.1.6 - Design Loads for long span bridges

The design of long span bridges goes beyond the application range of all the codes of practice and usual construction recommendations. While it is possible to use and extrapolate codes for the design of single elements, it is not the same for the initial definition of data, and especially to fix the loading scheme of the bridge which are not covered by codes.

The goal of the group is to establish a clear philosophy and some basic rules to fix the loading schemes of the bridge in relation to its span length and its typology.

Convener
Thierry Délémont

First name	Last name	Country	Affiliation
David	Fernández-Ordóñez	Switzerland	fib
Thierry	Delemont	Switzerland	T-ingenierie SA
Michel	Virlogeux	France	Virlogeux Consulting
Matthieu	Galland	United Kingdom	Arup
Chan	Park	Korea, Republic of	COWI Korea
Hiroyuki	Uchibori	Japan	Sumitomo Mitsui Construction Co., Ltd.
Fangyin	Zhang	United States	Thornton Tomasetti

First name	Last name	Country	Affiliation
Florent	Imberty	France	Razel SA
Guido	Morgenthal	Germany	Bauhaus University
Akio	Kasuga	Japan	Sumitomo Mitsui Construction Co., Ltd
Peter	Curran	United Kingdom	Ramboll UK
Miguel Angel	Astiz Suarez	Spain	Carlos Fernandez Casado S. L.
Steffen	Marx	Germany	-
Mike	Schlaich	Germany	TU Berlin
David	Fernández-Ordóñez	Switzerland	fib
Thierry	Delemont	Switzerland	T-ingenierie SA
Juan	Sobrino	Spain	Pedelta, S. L.

TG1.2 - Concrete structures in marine environments

Well-designed, well-built concrete structures are particularly suited for the marine environment. Task Group 1.2 has so far focused on structures for oil and gas fields in hostile marine environments (fib Bulletin 50) and on concrete structures in marine environments in general (fib Bulletin 91). A special focus has been done on floating tube bridges to help the designers to consider this promising alternative (fib Bulletin 96).

Significant experience has been gained from the design and construction of offshore concrete structures of the world and concrete has shown the possibility to design durable structures also in aggressive marine environment.

The topic of durability is, nowadays, more and more important, especially considering the goals on sustainability that the community is required to reach. Durable, safe and sustainable floating concrete structures will provide an important alternative in a future with lack of space on land and new technological solutions, for example for renewable energy production, that are continuously approaching the market.

Convener
Arianna Minoretti

WP1.2.1 - Floating concrete structures

In many cases, floating structures have some clear advantages compared to fixed structures. The motivation of the work in this WP is to demonstrate these advantages, and attempt to draw conclusions as to what applications are particularly promising.

The objective of WP1.2.1 is to demonstrate the usefulness of concrete in a modern society where floating structures may be needed. It will identify and consider potential applications of marine floating concrete structures, and then make selections and go into more detail on how the selected applications can be made competitive.

Convener
Tor Ole Olsen

First name	Last name	Country	Affiliation
Tor Ole	Olsen	Norway	Olav Olsen a.s.
Francisco	Esteban Lefler	Spain	FCC Construction
Harald	Rogne	Norway	Olav Olsen
Ove Tobias	Gudmestad	Norway	University of Stavange
Arnstein	Godejord	United States	Arup
Hilde Benedikte	Østlund	Norway	Kværner
Mike	Paschalis	Belgium	BESIX
Wenche	Rettedal	Norway	Statoil
Tom	Wike	Norway	ØKAW
Rolf	Larssen	Norway	Aas Jacobsen
Michel	Vache	France	Doriseng
Kåre	Hjorteset	United States	BergerABAM
Milos	Zich	Czech Republic	Strasky, Husty and Partners
Gordon	Jackson	United Kingdom	Arup Energy
Kjetil	Thorsen	Norway	Snøhetta
Steinar	Helland	Norway	S Helland Konsult
João	Almeida	Portugal	Instituto Superior Técnico Lisboa
Adrian	Gnägi	Switzerland	VSL International Ltd.
Terje	Kanstad	Norway	The Norwegian Univ.of Science & Tech
Milan	Kalny	Czech Republic	Pontex s.r.o. Prague
David	Fernández-Ordóñez	Switzerland	fib
Stein Atle	Haugerud	Norway	Dr. techn. Olav Olsen a.s.
Aurelio	Muttoni	Switzerland	École polytechnique fédérale de Lausanne (EPF Lausanne)
Fernando	Stucchi	Brazil	ABECE/EGT
Luis	Peset Gonzales	Spain	Dragados SA
Michel	Hamon	France	Doris Engineering
Scott	Haynes	Hong Kong	VSL
Paul	Notenboom	Netherlands	Arcadis
Christophe	Rozier	France	Bouygues Travaux Publics
Coen	Van der Vliet	Netherlands	Arcadis
Hugo	Corres Peiretti	Spain	FHECOR Ingenieros Consultores
Dag Nikolay	Jenssen	Norway	-

WP1.2.2 - Submerged floating tube bridges (SFTB)

Sometimes our infrastructures need to cross water. Immersed tunnels that sit on the seabed are widely used; more than 100 have been built.

Submerged floating tube bridges (SFTB) have never been built. Submerged floating tube bridges are floating bridges, submerged at a defined depth below the water surface. They may be supported between landfalls, either by tension legs or pontoons. They have a closed cross section, like the one of an ordinary tunnel, but they behave like a bridge.

The main scope of this working party is to provide the community with the information needed regarding the SFTB technology.

Convener
Arianna Minoretti

First name	Last name	Country	Affiliation
Gordon	Jackson	United Kingdom	Arup Energy
David	Fernández-Ordóñez	Switzerland	fib
Stein Atle	Haugerud	Norway	Dr. techn. Olav Olsen a.s.
Arianna	Minoretti	Norway	Statens vegvesen
Coen	Van der Vliet	Netherlands	Arcadis
Bjørn	Isaksen	Norway	Norwegian Road Administration
Hugo	Corres Peiretti	Spain	FHECOR Ingenieros Consultores
Tor Ole	Olsen	Norway	Olav Olsen a.s.
Dirk Jan	Peters	Netherlands	RHDHV
Heang-ki	Lee	Korea, Republic of	Kaist ERC center for SFT
Mathias Egeland	Eidem	Norway	Statens vegvesen (NPRA)
Marco	Novello	Italy	Sapeim
Noelia	Gonzalez Patiño	Spain	Ggravity-Dragados
Yuichiro	Kawabata	Japan	-

WP1.2.3 - Environmental benefits of marine concrete structures

The WP would work on the topics of influence of the marine concrete structures on the biological environment, climate challenges (CO2) for marine structures and resilience of marine structures respect to climate changes. An additional topic could be how marine concrete structures can help reducing the negative environmental aspects of nowadays activities, like congestions, polluting factories, renewable energies, food production and so on.

Convener
Arianna Minoretti

First name	Last name	Country	Affiliation
Arianna	Minoretti	Norway	Statens vegvesen
Christian John	Engelsen	Norway	SINTEF
Carl	Bois	France	Quiet Oceans
Tim	Fristed	Norway	Multiconsult
Evert	Mul	Norway	NINA
Liberato	Ferrara	Italy	Politecnico di Milano
Satoshi	Komatsu	Japan	Yokohama National University
Luca	Martinelli	Italy	Politecnico di Milano - Dep. of Civil and Environmental Engineering
Marco	Novello	Italy	Sapeim
Tor Ole	Olsen	Norway	Olav Olsen a.s.
Cheng	Shanshan	United Kingdom	University of Plymouth
Aad	van der Horst	Netherlands	-

WP1.2.4 - Submerged/floating bridges in seismic areas

The WP would work on floating structures as solutions for seismic areas.

Convener
Luca Martinelli

First name	Last name	Country	Affiliation
Luca	Martinelli	Italy	Politecnico di Milano - Dep. of Civil and Environmental Engineering
David	Fernández-Ordóñez	Switzerland	fib
Federico	Perotti	Italy	Politecnico di Milano
Dora	Foti	Italy	Politecnico di Bari
Raffaele	Landolfo	Italy	Università degli Studi di Napoli "Federico II"
Federico	Mazzolani	Italy	Università degli Studi di Napoli "Federico II"
Beatrice	Faggiano	Italy	Università degli Studi di Napoli "Federico II"
Yiqiang	Xiang	China	Zhejiang University
Yonggang	Shen	China	Zhejiang University
Margaux	Geuzaine	Belgium	NatHaz Modeling Laboratory

WP1.2.5 - Inspections monitoring and maintenance for constructions

The WP will focus on how to best solve issues on inspections and continuous monitoring to answer to the maintenance problems, toward a more durable life for marine structures.

Convener
Marco Novello

First name	Last name	Country	Affiliation
Giovanni	Massari	Italy	SAIPEM
David	Fernández-Ordóñez	Switzerland	fib
Marco	Novello	Italy	Sapeim
Simon	Fjendbo	Denmark	DTI - Danish Technological Institute
Matteo	Gastaldi	Italy	Politecnico of Milano
Samindi	Samarakoon	Norway	University of Stavanger
Carola	Corazza	Italy	HBK
Claudia	Gennaro	Italy	SISGEO
Thibaut	Lando	France	Antea Group
Hadeel	Maiah	United Arab Emirates	Gulf Survey
Régis	Blin	Switzerland	SMARTEC SA

WP1.2.6 - Solutions for floating structures

The WP would work on several topics, like cracks and self-healing (also involving COM 4) and optimisation of the weight of the structures (use of lightweight concrete, alternative materials for reinforcement..).

Convener
Patrick Bamonte

First name	Last name	Country	Affiliation
David	Fernández-Ordóñez	Switzerland	fib
Patrick	Bamonte	Italy	Politecnico di Milano

First name	Last name	Country	Affiliation
Tor Ole	Olsen	Norway	Olav Olsen a.s.
Harald	Rogne	Norway	Olav Olsen
David	Fernández-Ordóñez	Switzerland	fib
Stein Atle	Haugerud	Norway	Dr. techn. Olav Olsen a.s.
Arianna	Minoretti	Norway	Statens vegvesen
Coen	Van der Vliet	Netherlands	Arcadis
Satoshi	Komatsu	Japan	Yokohama National University
Jan	Suchorzewski	Sweden	RISE Research institutes of Sweden
Mathias Egeland	Eidem	Norway	Statens vegvesen (NPRA)
Liberato	Ferrara	Italy	Politecnico di Milano
Heang-ki	Lee	Korea, Republic of	Kaist ERC center for SFT
Gordon	Jackson	United Kingdom	Arup Energy
Alberto	Meda	Italy	University of Rome “Tor Vergata”
Noelia	Gonzalez Patiño	Spain	Ggravity-Dragados
Aad	van der Horst	Netherlands	-
Aurelio	Muttoni	Switzerland	École polytechnique fédérale de Lausanne (EPF Lausanne)
Federico	Perotti	Italy	Politecnico di Milano
Cheng	Shanshan	United Kingdom	University of Plymouth
Luca	Martinelli	Italy	Politecnico di Milano - Dep. of Civil and Environmental Engineering
Terje	Kanstad	Norway	The Norwegian Univ.of Science & Tech
Marco	Novello	Italy	Sapeim

TG1.3 - Buildings

The use of concrete in Building Structures is widespread throughout the world and is generally well documented in the various national codes and standards. There are however a number of areas where guidance to designers is unclear or where significant interpretation is required. The aim of this task group is to review the current design and construction approaches used and to identify where additional guidance is required. Where it is felt necessary, the group will undertake the appropriate literature searches, review the available current guidance and produce new design advice and recommendations in the form of fib bulletins.

The main goals of TG1.3 main goals are to:

identify how recent improvements in concrete knowledge and technology are, or could be, applied to building structures;
prepare state-of-the-art reports, guidelines and recommendations on the use of concrete in the design and construction of concrete buildings.

Convener
Andrew Truby

WP1.3.1 - Structural Design of Concrete Transfer Structures

Transfer structures are often used in building structures as a means of varying load paths through the structure to suit changes in the building grid. Transfer structures typically attract loadings from large areas of a structure and are therefore required to accommodate very large forces. The design of such structures is often outside the scope of normal code guidance and may require a degree of interpretation and engineering judgement. Transfer structures will normally be classified as “Key Elements” and therefore considerations of robustness and progressive collapse are key to their design.

The main goals of WP1.3.1 will be to provide a reference document which will describe the types and features of concrete transfer structures and provide information and guidance on their design and construction.

Convener
Andrew Truby

First name	Last name	Country	Affiliation
Andrew	Truby	United Kingdom	Truby Stevenson Ltd
Jean Marc	Jaeger	France	SETEC TPI
Stuart	Marsh	United Kingdom	Skidmore Owings & Merrill LLP
Fabrizio	Palmisano	Italy	PPV Consulting Studio Palmisano Perilli Associati,
Paulo	Silva Lobo	Portugal	University of Madeira-Funchal
Kaare	Dahl	Denmark	Rambøll
Phil	Mansell	United Kingdom	Robert Bird

WP1.3.2 - Planning Movement Joints in Concrete Buildings

For larger concrete buildings, movement joints are necessary to control the effects of drying shrinkage, temperature and creep. The positioning of movement joints is dependent on building shape, positioning of cores and shear walls and can be influenced by construction sequence and pour layout. The presence of joints is a fundamental factor in planning the stability system of buildings.

There is a trend in hospitals and other buildings requiring hygienic conditions towards wider spacing of movement joints.

The main goals of WP1.3.2 will be to create a reference document that will provide guidance on planning for movement and positioning of movement joints in concrete buildings, with particular emphasis on enclosed rather than open buildings.

Convener
Jeremy Wells

First name	Last name	Country	Affiliation
Jeremy	Wells	United Kingdom	WSP Parsons Brinckerhoff Ltd
Jenny	Burridge	United Kingdom	The Concrete Centre
Stuart	Marsh	United Kingdom	Skidmore Owings & Merrill LLP
Nadarajah	Surendran	United Kingdom	PRAETER Engineering Ltd
Richard	Reynolds	United Kingdom	Buro Happold
Andrew	Truby	United Kingdom	Truby Stevenson Ltd
Andrew	Fraser	United Kingdom	Ramboll UK
Christian	Tygoer	United Kingdom	AKT II
Phil	Mansell	United Kingdom	Robert Bird
Colin	Banks	United Kingdom	Laing O’Rourke
Keith	Jones	United Kingdom	Ramboll
Dave	Cotton	United Kingdom	Atkins

First name	Last name	Country	Affiliation
George	Keliris	United Kingdom	Buro Happold Ltd.
Steve	Mckechnie	United Kingdom	Arup
Jean Marc	Jaeger	France	SETEC TPI
Andrew	Fraser	United Kingdom	Ramboll UK
Pierre	Leflour	France	Setec tpi
Richard	Reynolds	United Kingdom	Buro Happold
Paulo	Silva Lobo	Portugal	University of Madeira-Funchal
Jenny	Burridge	United Kingdom	The Concrete Centre
Stefano	Cammelli	United Kingdom	BMT Fluid Mechanics Ltd.
Phil	Mansell	United Kingdom	Robert Bird
Colin	Banks	United Kingdom	Laing O’Rourke
Andrew	Truby	United Kingdom	Truby Stevenson Ltd
Nadarajah	Surendran	United Kingdom	PRAETER Engineering Ltd
Stuart	Marsh	United Kingdom	Skidmore Owings & Merrill LLP
Mario Alberto	Chiorino	Italy	Politecnico di Torino
John	Cairns	United Kingdom	Heriot-Watt University
Kaare	Dahl	Denmark	Rambøll
David	Fernández-Ordóñez	Switzerland	fib
Jeremy	Wells	United Kingdom	WSP Parsons Brinckerhoff Ltd
Nick	Zygouris	Greece	Lithos Consulting Engineers
Fabrizio	Palmisano	Italy	PPV Consulting Studio Palmisano Perilli Associati,

TG1.4 - Tunnels

Transportation, mining, water management, energy network development, combined with environmental concerns, have led to a significant increase in the construction of tunnels around the world. Along with other materials, structural concrete plays a primary role in the realisation of these structures, and many issues related to the use of concrete in tunnels ought to be accordingly addressed in order to promote the best use of structural concrete in this field of civil engineering.

The main goals of TG1.4 main goals are to:

identify how recent improvements in concrete knowledge and technology are, or could be, applied to tunnels, and how new developments in tunnel construction can rely upon concrete technologies;
prepare state-of-the-art reports, guidelines, recommendations on the use of concrete in tunnel design and construction.

Convener
Alberto Meda

First name	Last name	Country	Affiliation
Frank	Dehn	Germany	KIT Karlsruher Institut für Technologie
Konrad	Bergmeister	Austria	Univ. Bodenkultur
Carola K.	Edvardsen	Denmark	Cowi AS
Alberto	Meda	Italy	University of Rome “Tor Vergata”
Hiroshi	Dobashi	Japan	Shutoko Technology Center
David	Fernández-Ordóñez	Switzerland	fib
Peter	Jackson	France	Sistra
Albert	De la Fuente	Spain	Universitat Politècnica de Catalunya
Catherine	Larive	France	Tunnels Study Centre
Giuseppe	Tiberti	Italy	University of Brescia
ab	van den bos	Netherlands	NLyse

WP1.4.3 - Fiber Reinforced Sprayed Concrete in Tunnels and Underground spaces

Tunnel and underground spaces lining are more often made using Fiber-Reinforced Concrete (FRC) sprayed concrete. This solution, initially used for temporary structures, is nowadays adopted also for permanent structures. Codes and guidelines for Fiber Reinforced Concrete do not completely cover the sprayed concrete solution. Due to the structural relevance of these applications, it is important to fill in this gap with adequate information.

The main scope of the Working Party is to support the designer, construction companies, clients in adopting this technology. Information on the design process, considering aspect as the material characterization and the quality control will be introduced. The indications will refer to Model Code 2010 as a reference document.

Convener
Alberto Meda

First name	Last name	Country	Affiliation
Frank	Dehn	Germany	KIT Karlsruher Institut für Technologie
David	Fernández-Ordóñez	Switzerland	fib
Panagiotis	Spyridis	Germany	-
Albert	De la Fuente	Spain	Universitat Politècnica de Catalunya
Alberto	Meda	Italy	University of Rome “Tor Vergata”
Giovanni	Plizzari	Italy	University of Brescia
Catherine	Larive	France	Tunnels Study Centre
Alessandro	Fantilli	Italy	Politecnico di Torino
Colin	Eddie	United Kingdom	CECL
Alan	Bloodworth	United Kingdom	Warwick University
Giovanni	Blasini	Italy	Consultant
Sotiris	Psomas	United Kingdom	Morgan Sindall
Lindita	Kodra	France	Bouygues
Mike	King	United Kingdom	WSP
Nicolas	Bsaibes	France	Vinci Construction Grands Projects
Sylvie	Giuliani-Leonardi	France	Vinci Construction Grands Projets
Michele	Mangione	United Kingdom	ARUP
Anmol	Bedi	United Kingdom	Bedi Consulting
Ross	Dimmock	United Kingdom	Normet
Richard	Forrester	United Kingdom	BAM Nuttal
Sébastien	Bouteille	France	Développement durable
Giuseppe	Tiberti	Italy	University of Brescia
Jiang	Su	United Kingdom	Bedi Consulting
Marco	di Prisco	Italy	Politecnico di Milano
ab	van den bos	Netherlands	NLyse
Jeovan	Freitas	Norway	Private

WP1.4.4 - Assemblies and fastenings

Tunnels are provided with a variety of industry-specific construction products for the connection and assembly of various elements. These items play an important role as regards the construction phase, as well as the safety, quality, and durability in the operation phase of the tunnel structure.

Fastenings for catenary installations and heavy suspended equipment are specially treated in tunneling since they are associated with very long life-cycle requirements and load types (long term suspension loads and dynamic/cyclic loads), and because – as historically seen – the failure of such elements poses significant human safety and financial/operational threats.

Convener
Panagiotis Spyridis

First name	Last name	Country	Affiliation
Panagiotis	Spyridis	Germany	-
Alberto	Meda	Italy	University of Rome “Tor Vergata”
Giovanni	Muciaccia	Italy	Politecnico di Milano
Mike	King	United Kingdom	WSP
Philipp	Grosser	Liechtenstein	Hilti Corporation
Gael	Le Bloa	France	HILTI France
David	Fernández-Ordóñez	Switzerland	fib
Agemar	Manny	Germany	-
Boglárka	Bokor	Liechtenstein	Hilti Corporation
Donal	Coughlan	United Kingdom	Jacobs / Crossrail
Christophe	Delus	France	Optimas-Sofrasar
Ivica	Duzic	Germany	Halfen
Anthony	Harding	Australia	Jacobs / Brisbane Metro
Spyros	Konstantis	Greece	Independent Consultant
Graham	Langshaw	United Kingdom	Technical Tunneling Components
Francois	Renault	France	Vinci
Alejandro	Sanz	Spain	gGRAVITY Engineering
Angelos	Gakis	Austria	Dr Sauer & Partners

TG1.5 - Structural sustainability

Recently, sustainability has been discussed with regard to materials, recycling and so on, relating to the reduction of CO2 emissions. However, sustainability has another aspect, for example, the structure, design and construction, which can lead to reducing energy consumption and non-renewable resources over the course of the full life-time of a structure. Minimising energy consumption and non-renewable resources, will be discussed in the context of environmental, social and economic aspects in order to provide sustainable solutions for our society. These discussions will be key for developing sustainable structures. This philosophy is defined as “Structural Sustainability”.

The aim of this Task Group is to focus on minimising energy consumption and non-renewable resources during the life-time of structures from the structural point of view. Basically, the structures built using current specifications are durable. Therefore, structural sustainability should be defined as the difference from existing technologies to new ones in order to make structural sustainability clear. Examples of structural type, detailing, design, special construction techniques and so on for structural sustainability will be collected to publish a state-of-the-art report.

Convener
Akio Kasuga

First name	Last name	Country	Affiliation
Gordon	Clark	United Kingdom	Consultant
Milan	Kalny	Czech Republic	Pontex s.r.o. Prague
Akio	Kasuga	Japan	Sumitomo Mitsui Construction Co., Ltd
José	Arizón	Spain	Aguacanal
Kenichi	Kata	Japan	Sumitomo Mitsui Consctruction Co, Ltd.
João	Almeida	Portugal	Instituto Superior Técnico Lisboa
Ekkehard	Fehling	Germany	IBB Fehling + Jungmann GmbH
Michel	Moussard	France	Consultant
Alessandro	Palermo	New Zealand	The University of Canterbury
David	Fernández-Ordóñez	Switzerland	fib
Petr	Hajek	Czech Republic	Czech Technical University in Prague
Philippe	Vion	France	VINCI Construction Grands-Projets
Hugo	Corres Peiretti	Spain	FHECOR Ingenieros Consultores
Natividad	Garcia Troncoso	Ecuador	Escuela Superior Politecnica del Litoral
Khuyen	Hoang	Japan	-
Adriano	Reggia	Italy	-
Borja	Regúlez	Spain	-
Konrad	Bergmeister	Austria	Univ. Bodenkultur
Agnieszka	Bigaj-van Vliet	Netherlands	TNO - Buildings, Infrastructures and Maritime

TG1.6 - History of concrete structures

During the long history of CEB, FIP and now fib, the main objectives of their commissions, task groups and special activity groups were and are actual topics of research, application and dissemination.

Construction history is a rapidly growing research field in the community of architects and civil engineers. The last conference on construction history took place in Paris in July 2012 and consisted of 66 sessions. Only two of them focused on concrete and concrete construction. Furthermore, none of the key lectures was related to concrete.

The task group intends to set up a process which shall result in the publication of a series of bulletins covering the global history of structural concrete, from its first developments to the present situation.

At the beginning, it is very important to organise the extremely broad field of historic research. It is suggested to start with a narrower approach, mainly with the collection of historic material. A broader approach implies the integration of concrete history within the time, including political, social, climatic, economic and ecological circumstances. This will require more time as well as the addition of historically educated experts.

Convener
Manfred Curbach

Co-Convener
Michel Moussard

First name	Last name	Country	Affiliation
Gordon	Clark	United Kingdom	Consultant
David	Fernández-Ordóñez	Switzerland	fib
Edwin	Trout	United Kingdom	The Concrete Society
François	Cussigh	France	Vinci Construction
Per	Jahren	Norway	Consultant
Patricia	Garibaldi	Germany	Technische Univ. Dresden
Rita	Greco	Italy	Technical University of Bari - DICATECH
Jean Michel	Torrenti	France	Univ Gustave Eiffel
Manfred	Curbach	Germany	Technische Univ. Dresden
Michel	Moussard	France	Consultant
F. Javier	León	Spain	FHECOR - Ingenieros Consultores
Luc	Taerwe	Belgium	Ghent University
Paul	Acker	France	Consulting
Ruben Paul	Borg	Malta	University of Malta
Pepa	Cassinello	Spain	Universidad Politécnica de Madrid

TG1.7 - Construction of concrete structures

The areas of interest have been developed from the viewpoint that the construction process has two main components: perception related aspects and process aspects. The perception related aspects comprise materials, workmanship, formwork and scaffolding, curing of concrete, concrete surface, testing and monitoring, high performance concrete, special technologies, specifications and training/education. The process related aspects comprise the construction process of concrete structures, quality management and life cycle management.

The task group addresses state-of-the-art basic principles of the construction process of concrete structures at site. Furthermore, the task group reflects on anticipated developments, which could have a significant influence on construction. The objective is to develop awareness regarding aspects which have an impact on safety, serviceability, durability and environmental issues of concrete structures to be built on site, and to provide information as how to handle the basic principles. The output will be presented as internationally harmonised reports.

Convener
Aad van der Horst

Co-Convener
Christophe Portenseigne

First name	Last name	Country	Affiliation
Fabrice	Cayron	France	Bouygues Travaux Publics
Didier	Primault	France	Vinci Construction
José	Turmo Coderque	Spain	Universitat Politecnica de Catalunya
Günter	Rombach	Germany	Techn. Univ. of Hamburg-Harburg
Aad	van der Horst	Netherlands	-
Oliver	Fischer	Germany	Technical University Munich
David	Fernández-Ordóñez	Switzerland	fib
Gopal	Srinivasan	United Kingdom	Arup
Marcos	Sanchez	Ireland	ARUP
Héctor	Bernardo Gutiérrez	Spain	Pontem Engineering Services

TG1.8 - Concrete industrial floors

Concrete is often used for industrial floors that are designed to withstand static and dynamic loads as well as the degradation caused by operations and the environment.

Industrial floor must be properly designed for resisting point and distributed loads due to shelves and vehicles present on the floor. Seismic action transmitted by shelves must be considered in seismic areas.

Shrinkage phenomena play a major role since they provoke early age cracks that can be controlled by contraction joints that are likely to damage due to wheel crossing.

Another important issue is represented by the top finishing layer that had to be properly designed to resist abrasion.

Main scope of the Task Group is to briefly describe the most important issues in concrete technology for industrial floors, give relevant references to important literature, describe important design premises, give guidance to potential improvements and maintenance. Some attention will be also devoted to refurbishing of existing floors.

Convener
Giovanni A. Plizzari

First name	Last name	Country	Affiliation
Gianluigi	Pirovano	Italy	-
Valérie	Pollet	Belgium	BBRI-Rilem
Pedro	Serna Ros	Spain	Univ. Politecnica de Valencia-Icitech
Johan	Silfwerbrand	Sweden	KTH Royal Institute of Technology
Alberto	Meda	Italy	University of Rome “Tor Vergata”
Giovanni	Plizzari	Italy	University of Brescia
David	Fernández-Ordóñez	Switzerland	fib
Bryan	Barragan	France	OCV Chambery International
Klaus	Holschemacher	Germany	HTWK Leipzig
Amir	Bonakdar	United States	Euclid Chemical – ACI
Todd	Clarke	Australia	Barchip
Antonio	Conforti	Italy	University of Brescia
Carles Cots	Corominas	Spain	BASF
Albert	De la Fuente	Spain	Universitat Politècnica de Catalunya
Vinciane	Dieryck	Belgium	BBRI
Navneet	Narayan	India	Bekaert
Ralf	Winterberg	Malaysia	Managing Director
Raul Luis	Zerbino	Argentina	LEMIT-CIC

First name	Last name	Country	Affiliation
Josée	Bastien	Canada	University Laval
João	Almeida	Portugal	Instituto Superior Técnico Lisboa
Akio	Kasuga	Japan	Sumitomo Mitsui Construction Co., Ltd
Gordon	Clark	United Kingdom	Consultant
Giovanni	Plizzari	Italy	University of Brescia
Aad	van der Horst	Netherlands	-
Andrew	Truby	United Kingdom	Truby Stevenson Ltd
Tor Ole	Olsen	Norway	Olav Olsen a.s.
Alberto	Meda	Italy	University of Rome “Tor Vergata”
Jim	Forbes	Australia	Arcadis
Manfred	Curbach	Germany	Technische Univ. Dresden
David	Fernández-Ordóñez	Switzerland	fib
Michel	Moussard	France	Consultant
Shoji	Ikeda	Japan	Hybrid Research Inst. Inc.
Michel	Virlogeux	France	Virlogeux Consulting
Hugo	Corres Peiretti	Spain	FHECOR Ingenieros Consultores
Thierry	Delemont	Switzerland	T-ingenierie SA
Arianna	Minoretti	Norway	Statens vegvesen

YMG: Young Members Group

Written on 21 March 2017.

Motivation

The fib Presidium has approved the creation of an fib Young Members Group. All members of the Presidium have high expectations for the development of this group.

The fib thinks that it is crucial that young professionals are given the opportunity to fully participate in the activities of the organisation. They are welcome to participate in commissions and task groups and to become part of the decision bodies. However, young members do not normally participate in the development of documents and in the decisions of the fib.

The Young Members Group aims to build a framework that will allow young engineers to participate in the activities of the association and to bring their ideas to the working groups and the decision bodies.

Scope and objective

The main objectives of the fib Young Members Group include:

Improving the profession’s self-concept in the XXI century
Encouraging mentoring within the fib
Studying the work of other engineers to improve one's own work
Networking
Establishing connections with the Universities to encourage junior engineers to help engineering students
Organising workshops and meetings tailored to students' and junior engineers' needs
Promoting the idea that junior engineers can participate in meetings and conferences and be a source of knowledge for the students

The fib Young Members Group aims to establish connections with similar groups and associations in other countries.

Further links:

Commission Chair
TBD

Deputy Chair

Marcelo Melo

YMG Board Members
Ohno Motohiro (Japan) - Past chair	Andri Setiawan (Indonesia) - Secretary
Marta Del Zoppo (Italy)	Felipe García (Spain)
Natividad Garcia (Ecuador)	Rodolfo Jr Mendoza (Philippines)
Ahmad Khartabil (UAE)	Andrey Lapshinov (Russia)
Gaël Le Bloa (France)	Joanna Agnieszka Markowska (Norway)
Ze'ev Navon (Israel)	Benedict Olalusi (South Africa)
Chong Yong Ong (Malaysia)	João Pacheco (Portugal)
Samanta Robuschi (Sweden)	Ahmed Seyam (Palestine)
Vladyslav Shekhovtsov (Ukraine)	Sandor Solyom (Hungary)
Nadine Pressmair (formerly Stoiber) (Austria)	Nikola Tošić (Serbia)
Patrick Valeri (Switzerland)	Graham Webb (United Kingdom)

There are two working groups within the YMG that focuse on Webinars and Podcasts:

WEBINARS wORKING GROUP	PODCASTS wORKING GROUP
Marta Del Zoppo - Convener	Patrick Valeri - Convener
Ahmed Khartabil	Nadine Pressmair
Andrey Lapshinov	Nikola Tošić
Ze'ev Navon	Graham Webb
João Pacheco
Andri Setiawan
Vladyslav Shekhovtsov

The fib mentoring programme brings together experienced professionals keen to share their knowledge and network, and young professionals starting their professional career and who are in need of advice from knowledgeable engineers.
- Who is it for?
To take part as a mentee, individuals should be fib members and members of the fib Young Members Group. They should either be finishing their studies or starting out their career as an engineer.

To take part as a mentor, individuals should be fib members, above 40 years old, have 5 years of professional experience in structural concrete and have been a member of the fib for 5 years or more. fib Fellows are particularly encouraged to become mentors.
- How does it work?
Mentoring is a cooperative partnership in which seasoned professionals share their experience and knowledge with less experienced young professionals. Both parties stand to gain from this partnership.

The duration of mentoring is one year but may be renewed if both parties agree. The mentoring agreement is a starting point for mentees and mentors to establish their mutual goals and plan their meetings.
- How to apply?
If you wish to apply as a mentee, please contact the fib Secretariat.

First name	Last name	Country	Affiliation
David	Fernández-Ordóñez	Switzerland	fib
Nikola	Tošić	Spain	Universitat Politècnica de Catalunya
Patrick	Valeri Lorenzo	Switzerland	Dr. Lüchinger+Meyer Bauingenieure AG
Motohiro	Ohno	Japan	The University of Tokyo
Dmitry	Kuzevanov	Russian Federation	NIIZHB
Vladyslav	Shekhovtsov	Ukraine	Odesa State Academy of Civil Engineering and Architecture
Raffaele	Cantone	Switzerland	-
Graham	Webb	United Kingdom	WSP
Gael	Le Bloa	France	HILTI France
Anass	El Farissi	France	University of La Rochelle
Marco	Teichgraeber	Poland	-
Sándor	Sólyom	Hungary	Budapest Univ. of Techn. & Economics
Mladena	Luković	Netherlands	-
Elena	Ciampa	Italy	University of Sannio
Andrey	Lapshinov	Russian Federation	"Moscow State University of Civil Engineering mgsu.ru"
Alexandre	Mathern	Sweden	-
Jemma	Ehsman	Australia	Rio Tinto - Dampier Salt
Marta	Del Zoppo	Italy	University of Naples Federico II
Isabella Giorgia	Colombo	Italy	Politecnico di Milano
Maria Teresa	De Risi	Italy	University of Naples Federico II
Lorenzo	Radice	Italy	DSC ERBA Engineering
Marco	Rampini	Italy	Politecnico di Milano
Giulio	Zani	Italy	Politecnico di Milano
Vittoria	Ciotta	Italy	University of Naples Federico II
Diego	Gino	Italy	Politecnico di Torino
Dmitry	Laptev	Russian Federation	ARCHIMATIKA
Costantino	Menna	Italy	University of Naples Federico II
Paolo	Castaldo	Italy	Politecnico di Torino
Fuyuan	Gong	China	Zhejiang University
Michele W.T.	Mak	United Kingdom	University of Leeds
Đorđe	Čairović	Czech Republic	-
Peter	Paulik	Slovakia	Slovak University of Technology in Bratislava
Fangjie	Chen	Australia	-
Laura	Hernandez	Germany	-
Debadri	Som	Canada	Graduate Student/Research Assistant
Oladimeji	Olalusi	South Africa	University of Kwazulu-Natal
João Nuno	Pacheco	Portugal	CERIS/c5Lab Sustainable Construction Materials Association
Lampros	Koutas	Greece	University of Thessaly
saied	kashkash	Hungary	-
John	Kolawole	United Kingdom	Loughborough University
Asaad	Biqai	Lebanon	Beirut Arab University
Senthil Kumar	Kaliyavaradhan	India	CSIR-Structural Engineering Research Centre
Jakub	Kraľovanec	Slovakia	University of Žilina
Munir	Basmaji	United Arab Emirates	-
Ahmad	Khartabil	United Arab Emirates	Transgulf Readymix Concrete Co.
Alireza	Tabrizikahou	Poland	PhD candidate at Poznan University of Technology
Rui	Valente	Portugal	Universidade do Porto
Zeev	Navon	Israel	-
Samanta	Robuschi	Sweden	Chalmers University
Rodolfo Jr	Mendoza	Philippines	De La Salle University
Filip	Niketic	Switzerland	École polytechnique fédérale de Lausanne
Andrija	Radović	Serbia	Faculty of Technical Sciences, University of Priština in Kosovska Mitrovica
Jessica	Forsdyke	United Kingdom	-
Özgür	Yurdakul	Czech Republic	Univerzita Pardubice
Brandon	Byers	Switzerland	ETH Zurich
Samuel	Halim	Indonesia	-
Bessong	Tambe MIET	Cameroon	The Chartered Institute Of Building CIOB
Natividad	Garcia Troncoso	Ecuador	Escuela Superior Politecnica del Litoral
Mahshid	Abdoli	Iran, Islamic Republic of	-
Giovanni	Volpatti	Switzerland	-
Zengfeng	Zhao	China	Tongji University
Nandhu	Prasad	India	-
Irene	Josa	United Kingdom	University College London (UCL)
Milena	Janković	Montenegro	-
Jdidi	DAOUD	Tunisia	-
Ingrid	Irreno	Brazil	-
Pavel	Ostrovsky	Finland	Ramboll Finland
Junjie	Wang	China	-
Ana	Brunčič	Slovenia	Slovenian Association of Structural Engineers
Abhishek	Chaudhari	India	Research Scholar
Nadine	Pressmair (formerly Nadine Stoiber)	Austria	University of Natural Resources and Life Sciences
Mouna	BOUMAAZA	France	Vinci Construction
Elisabete	Teixeira	Portugal	-
Andrea	Monserrat López	Spain	Universitat Politècnica de Catalunya
Petar	Bajic	Spain	-
Jushan	Babar	Bangladesh	Chittagong University of Engineering & Technology (CUET), Chittagong, Bangladesh
Marcelo	Melo	Brazil	Casagrande Engenharia
Orhun	Kalyoncu	Turkey	Researcher
André	Abreu	Brazil	-
Manoj	N	India	VNIT
Xianlin	Wang	Switzerland	Ecole Polytechnique Fédérale de Lausanne (EPFL)
Kasperi	Pirttikoski	Finland	Ramboll Finland
Mehboob	Rasul	Japan	Technology Development Division
Jules	Smits	Belgium	KU Leuven - De Nayer Campus
Peter	Gappmaier	Austria	-
Janusz	Rogowski	Poland	Lodz University of Technology
Daniel	Trento	Italy	-
Giorgio	Mattarollo	Italy	Carinthia University of Applied Sciences
Konrad	Szczepański	Poland	-
Eryk	Goldmann	Poland	Silesian University of Technology
Sevin Yaren	Aytepe	Netherlands	TU Delft
Abdullah	Niğdelioğlu	Turkey	-
Mohamed Nafees	Mohamed Nushan	Pakistan	Washington Accord Affiliation, Registered
Swapnil	Ghodke	India	-
Joanna	Markowska	Norway	-
Mohammad Sulaiman	Dawood	United States	-
André	Furtado	Portugal	CERIS - Instituto Superior Técnico
Eduardo	Sanchez	Ecuador	Estudiante
Pietro	Mazzuca	Italy	University of Calabria
Shana	Van Hout	Belgium	-
Onur	Çevik	Turkey	-
Juan Mauricio	Lozano Valcarcel	Germany	Technical University of Munich
Qifan	Ren	Portugal	University of Lisbon
Ali	Salmani	Iran, Islamic Republic of	Faculty of Civil Engineering, Iran University of Science and Technology, Tehran, Iran
Fred	Ferreira da Conceição	Brazil	-
Rafaela	Eckhardt	Brazil	-
Szabolcs	Szinvai	Hungary	BME
Rekia	Zouini	Algeria	-
Ligia	Oliva Doniak	Brazil	-

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