Descrizione del progetto
Consolidare le conoscenze relative ad alternative sostenibili innovative al cemento e al calcestruzzo tradizionali
Il cemento è un importante agente legante e adesivo per il calcestruzzo, che a sua volta è di fondamentale importanza per il settore edile. Si prevede che il valore del mercato globale del cemento raggiungerà quasi i 682 miliardi di dollari americani entro il 2025, per cui i nuovi leganti a base di geopolimeri, un’opzione alternativa al cemento Portland standard del settore, sono destinati ad aumentare la propria quota di mercato. Ciononostante, le proprietà termiche e meccaniche dettagliate del calcestruzzo geopolimerico in presenza di temperature elevate non sono ben caratterizzate. Il progetto TemGPC, finanziato dall’UE, le esaminerà utilizzando metodi sperimentali e la modellizzazione computazionale. Il gruppo responsabile del progetto intende approfondire le conoscenze relative agli effetti della temperatura e dello stress sui calcestruzzi innovativi per ottenere un maggiore controllo sulle proprietà e sulle prestazioni potenziate dei componenti.
Obiettivo
Concrete is a non-uniform, multi-phase porous material. With the increase in temperature, the chemical configuration of the material changes, and the mortar and coarse aggregate, owing to their different thermal expansions, will produce different thermal stresses, thereby reducing their bonding strength. The thermal and mechanical behaviours of geopolymer concrete that uses geopolymer to replace traditional Portland cement, are different from those of Portland cement concrete in many ways. In order to enable the widespread and safe use of geopolymer concrete in construction industry where fire safety is extremely important, this project will carry out a systematic study on the thermal and mechanical behaviours of geopolymer concrete at elevated temperatures. The study includes the effect of temperature on the thermal and mechanical properties of geopolymer concrete and the combined effect of the initial stress and temperature on the constitutive relation of geopolymer concrete at various different temperatures. The research methodology includes the use of advanced experimental testing techniques and multi-physics and multi-phases computer modelling, and the development of theoretical models based on the results obtained from both the experimental and numerical studies. The research will create new knowledge and improve our understanding on the temperature effect on concrete behaviour and performance. The work will help maintain EU excellence in concrete research. The outcome of the project can also lead to the development of new types of concrete with targeted performance. This project covers a wide range of disciplines including materials, chemistry, physics, engineering, and computer science. Through the project the individual fellowship will significantly improve his interdisciplinary knowledge and innovative research skills as well as his career development.
Campo scientifico
Parole chiave
Programma(i)
Argomento(i)
Meccanismo di finanziamento
MSCA-IF - Marie Skłodowska-Curie Individual Fellowships (IF)Coordinatore
PL4 8AA Plymouth
Regno Unito