Your search keyword '"Ng, Yan Hao"' showing total 2 results

1. Thermal decomposition and fire response of non-halogenated polymer-based thermal coatings for concrete structures.

Author

Ng, Yan Hao, Suri, Anil, Dasari, Aravind, and Tan, Kang Hai

Subjects

*CONCRETE coatings, *COMBUSTION, *HEAT transfer, *FIRE resistant polymers, *FIRE resistant materials

Abstract

This work highlights the thermal decomposition and fire-protective behaviour of two polymer-based coatings for concrete. The coatings are entirely free of halogenated compounds. Although the combustion behaviour of the coatings is different from classical intumescence, their action is based on a condensed-phase mechanism, which creates a steep temperature gradient between the coating surface and the coating-concrete interface. When subjected to the ISO 834 heating curve, one of the coatings could prevent the temperature of the interface from rising above 345 °C even after 3 h (corresponding furnace temperature is 1114 °C). Heat transfer simulation corroborates the observed fire-protective behaviour and shows that it may have potential for use on structural members. Analysis of the concentration of several gases produced by the burning of the coatings shows that they do not pose an immediate danger to life and health. [ABSTRACT FROM AUTHOR]

Published

2017

2. Thermal properties of carbon nanofibers enhanced lightweight cementitious composite under high temperature.

Author

Wang, Su, Ng, Yan Hao, Tan, Kang Hai, and Dasari, Aravind

Subjects

*CARBON nanofibers, *THERMAL properties, *THERMAL diffusivity, *HIGH temperatures, *THERMAL conductivity, *CEMENT composites, *CARBON foams

Abstract

• Carbon nanofibers enhanced lightweight cementitious composite (CNF-LCC). • Thermal properties of CNF-LCC under high temperature. • Effect of foam bubbles and carbon nanofibers on the thermal properties. • Characterisation of the dehydration reaction of CNF-LCC under high temperature. • Heat transfer tests and numerical analysis to verify measured. Foam concrete is conventionally used in non-structural applications (e.g. thermal and acoustic insulation) due to its lightweight nature and poor mechanical properties. However, interest in adopting foam concrete as structural components has increased phenomenally in recent years due to its lightweight and sustainable feature. A new type of foam concrete termed as carbon nanofibers enhanced lightweight cementitious composite (CNF-LCC) was developed by blending micro-foam bubbles with carbon nanofibers enhanced ultra-high performance concrete; it has superior mechanical properties, long-term properties and bond performance with steel bar compared with conventional foam concrete. In this paper, thermal properties of CNF-LCC during heating were investigated and compared with normal weight concrete (NWC) and lightweight aggregate concrete (LWAC). From room temperature to 800 ℃, the thermal diffusivity of CNF-LCC was lower than NWC and similar to LWAC while the specific heat and thermal conductivity of CNF-LCC was lower than both NWC and LWAC. CNF-LCC showed better structural efficiency than NWC and LWAC in combination of mechanical and thermal insulation properties. The measured thermal insulation properties under high temperature were verified by conducting one-dimensional heat transfer tests and numerical analysis on CNF-LCC blocks. Furthermore, the thermal strain of CNF-LCC during heating is lower and more stable than NWC and LWAC. Dehydration reaction at isothermal elevated temperature was characterised for the analysis of experimental results. Foam bubbles could reduce both thermal insulation and strain properties while a low dosage of CNFs had minimum effect on the thermal insulation properties but could improve the mechanical properties and decrease the thermal shrinkage. CNF-LCC showed potential for fire resistant as a structural lightweight concrete due to the excellent thermal insulation and lower thermal strain properties. [ABSTRACT FROM AUTHOR]

Published

2021