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A platform for research: civil engineering, architecture and urbanism
Potassium based geopolymer for passive fire protection of concrete tunnels linings
Graphical abstract Display Omitted
Highlights A fire resistant potassium based geopolymer was developed. FeNi slag doped with pure alumina was used as raw material. The K-geopolymer possess adequate mechanical properties. Subjected to thermal loading the K-geopolymer was resistant to the RWS curve. The test proved that the K-geopolymer can put an effective heat flux barrier.
Abstract The design of a fire resistant coating for tunnel passive fire protection and its performance under thermal loading are presented. The material falls under the class of potassium based geopolymers (K-geopolymer) and was prepared by mixing ferronickel (FeNi) slag, doped with pure alumina, with a highly alkaline potassium hydroxide aqueous phase. The physical, mechanical and thermal properties of the K-geopolymer were determined and compared to those of some commercially available fire resistant materials. Its behavior upon exposure to fire was assessed by subjecting a concrete slab, coated with a 5cm thick K-geopolymer layer, to thermal loading under the RijksWaterStaat (RWS) temperature–time curve, which is considered as the most severe prescribed tunnel fire scenario. During the test, the geopolymer/concrete interface temperature remained under 280°C, which is 100°C lower than the RWS test requirement, proving the effectiveness of the material as a thermal barrier. In addition, the K-geopolymer retained its structural integrity after the test, without any significant macroscopic damage.
Potassium based geopolymer for passive fire protection of concrete tunnels linings
Graphical abstract Display Omitted
Highlights A fire resistant potassium based geopolymer was developed. FeNi slag doped with pure alumina was used as raw material. The K-geopolymer possess adequate mechanical properties. Subjected to thermal loading the K-geopolymer was resistant to the RWS curve. The test proved that the K-geopolymer can put an effective heat flux barrier.
Abstract The design of a fire resistant coating for tunnel passive fire protection and its performance under thermal loading are presented. The material falls under the class of potassium based geopolymers (K-geopolymer) and was prepared by mixing ferronickel (FeNi) slag, doped with pure alumina, with a highly alkaline potassium hydroxide aqueous phase. The physical, mechanical and thermal properties of the K-geopolymer were determined and compared to those of some commercially available fire resistant materials. Its behavior upon exposure to fire was assessed by subjecting a concrete slab, coated with a 5cm thick K-geopolymer layer, to thermal loading under the RijksWaterStaat (RWS) temperature–time curve, which is considered as the most severe prescribed tunnel fire scenario. During the test, the geopolymer/concrete interface temperature remained under 280°C, which is 100°C lower than the RWS test requirement, proving the effectiveness of the material as a thermal barrier. In addition, the K-geopolymer retained its structural integrity after the test, without any significant macroscopic damage.
Potassium based geopolymer for passive fire protection of concrete tunnels linings
Sakkas, K. (author) / Panias, D. (author) / Nomikos, P.P. (author) / Sofianos, A.I. (author)
Tunnelling and Underground Space Technology ; 43 ; 148-156
2014-05-12
9 pages
Article (Journal)
Electronic Resource
English
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