Summary
SUPERCONCRETE is a synergetic cross-disciplinary international/intersectoral project addressing theoretical models for next-generation concretes, characterised by a significant sustainability enhancement for the construction industry.
Three advanced concrete classes (CCs) are selected which represent the projects’ key research lines:
- Low-Carbon Concrete (LCC), characterised by non-conventional constituents, often derived from recycling industrial waste or by-products;
- High-Class Concrete (HCC), encompassing materials with enhanced performance in strength, durability;
- Fibre-reinforced Cementitious Composites (FCC), with special features on fibre/textile reinforcement and matrix improvement.
Developing synergetic through-life multi-scale models for these novel materials is the key objective of the SUPERCONCRETE project. Particularly, three transversal modelling issues (MIs) are considered:
- Rheology and Early age, dealing with the various physical and coupled thermo-hygro-chemical phenomena taking place in the first hours after mixing;
- Hardened state and service life, approached by constitutive modelling intended at predicting the instantaneous and long-term behaviour, for both service and ultimate conditions;
- Extreme conditions, based on constitutive theories capable of simulating the response under fire and high temperature exposure.
Each CC and MI is covered by one participant and the interactions among them is based on a matrix-like organisational approach aiming at achieving a true synergistic collaboration among those with specific CC knowledge and the ones bringing in transversal competences on MIs. A further cross-cutting objective aims at defining a “Sustainability Index”, based on its constituents and processes requested for each CC.
SUPERCONCRETE’s final deliverables will be 1) a joint international course on sustainable concretes with 2) an underlying textbook and 3) a web-based platform for interacting with students and practitioners.
Three advanced concrete classes (CCs) are selected which represent the projects’ key research lines:
- Low-Carbon Concrete (LCC), characterised by non-conventional constituents, often derived from recycling industrial waste or by-products;
- High-Class Concrete (HCC), encompassing materials with enhanced performance in strength, durability;
- Fibre-reinforced Cementitious Composites (FCC), with special features on fibre/textile reinforcement and matrix improvement.
Developing synergetic through-life multi-scale models for these novel materials is the key objective of the SUPERCONCRETE project. Particularly, three transversal modelling issues (MIs) are considered:
- Rheology and Early age, dealing with the various physical and coupled thermo-hygro-chemical phenomena taking place in the first hours after mixing;
- Hardened state and service life, approached by constitutive modelling intended at predicting the instantaneous and long-term behaviour, for both service and ultimate conditions;
- Extreme conditions, based on constitutive theories capable of simulating the response under fire and high temperature exposure.
Each CC and MI is covered by one participant and the interactions among them is based on a matrix-like organisational approach aiming at achieving a true synergistic collaboration among those with specific CC knowledge and the ones bringing in transversal competences on MIs. A further cross-cutting objective aims at defining a “Sustainability Index”, based on its constituents and processes requested for each CC.
SUPERCONCRETE’s final deliverables will be 1) a joint international course on sustainable concretes with 2) an underlying textbook and 3) a web-based platform for interacting with students and practitioners.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/645704 |
| Start date: | 01-07-2015 |
| End date: | 30-06-2019 |
| Total budget - Public funding: | 504 000,00 Euro - 468 000,00 Euro |
Cordis data
Original description
SUPERCONCRETE is a synergetic cross-disciplinary international/intersectoral project addressing theoretical models for next-generation concretes, characterised by a significant sustainability enhancement for the construction industry.Three advanced concrete classes (CCs) are selected which represent the projects’ key research lines:
- Low-Carbon Concrete (LCC), characterised by non-conventional constituents, often derived from recycling industrial waste or by-products;
- High-Class Concrete (HCC), encompassing materials with enhanced performance in strength, durability;
- Fibre-reinforced Cementitious Composites (FCC), with special features on fibre/textile reinforcement and matrix improvement.
Developing synergetic through-life multi-scale models for these novel materials is the key objective of the SUPERCONCRETE project. Particularly, three transversal modelling issues (MIs) are considered:
- Rheology and Early age, dealing with the various physical and coupled thermo-hygro-chemical phenomena taking place in the first hours after mixing;
- Hardened state and service life, approached by constitutive modelling intended at predicting the instantaneous and long-term behaviour, for both service and ultimate conditions;
- Extreme conditions, based on constitutive theories capable of simulating the response under fire and high temperature exposure.
Each CC and MI is covered by one participant and the interactions among them is based on a matrix-like organisational approach aiming at achieving a true synergistic collaboration among those with specific CC knowledge and the ones bringing in transversal competences on MIs. A further cross-cutting objective aims at defining a “Sustainability Index”, based on its constituents and processes requested for each CC.
SUPERCONCRETE’s final deliverables will be 1) a joint international course on sustainable concretes with 2) an underlying textbook and 3) a web-based platform for interacting with students and practitioners.
Status
CLOSEDCall topic
MSCA-RISE-2014Update Date
28-04-2024
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Organisations
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| UNIVERSITA DEGLI STUDI DI SALERNO (Coördinator)
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| FUNDACION TECNALIA RESEARCH & INNOVATION
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| GESELLSCHAFT FUER MATERIALFORSCHUNG UND PRUEFUNGSANSTALT FUER DAS BAUWESEN LEIPZIG MBH
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| TECHNISCHE UNIVERSITAT DARMSTADT
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| TECHNISCHE UNIVERSITEIT DELFT
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| UNIVERSIDAD DE BUENOS AIRES
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| UNIVERSIDADE DO MINHO
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| UNIVERSIDADE FEDERAL DO RIO DE JANEIRO
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| UNIVERSITY OF MICHIGAN THE REGENTS OF THE UNIVERSITY OF MICHIGAN
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| WILHELM ROSER SOHNE GMBH CO. KG