Elevated Temperatures Impact on the Mechanical Behavior of Reactive Powder Concrete Containing Hybrid Fibers

Journal of Pure & Applied Sciences Pub Date : 2022-10-03 DOI:10.51984/jopas.v21i4.2112

Z. M. A. Abdul Rasoul, مشتاق صادق راضي, Laith Mohammed Ridha Mahmmod, A. Alsaad

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Abstract

Reactive Powder Concrete (RPC) is a combined material that will allow the concrete industry to enhance material consumption, produce economic benefits, be more durable, and be more environmentally friendly. Due to the highly dense microstructure of RPC, it performs poorly at high temperatures due to the formation of high pore pressure, which causes material breakdown. This paper demonstrates the outcomes of an investigational study of the behavior of six RPC mixes incorporating hybrid steel and plastic waste (polypropylene) fibers after being subjected to high temperatures of up to 500 ºC. Residual compressive strength, residual splitting strength, and density were performed for all the RPC mixes. The results demonstrate that the drop in the compressive strength of RPC is greater than the reduction in their corresponding splitting strength. Furthermore, within a temperature range of about 500 ºC, this mechanical strength showed a noticeable decrease. The decrement of splitting strength ranged between about 8% to 33% . Steel and polypropylene fibers also improve the residual strength of RPC samples. On the basis of these results, a mix containing mixed fibers (25 % steel and 75 % polypropylene) is recommended as appropriate for extreme temperature applications.

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高温对含混杂纤维活性粉末混凝土力学性能的影响

活性粉末混凝土(RPC)是一种复合材料，它将使混凝土工业提高材料消耗，产生经济效益，更耐用，更环保。由于RPC的高密度微观结构，在高温下由于形成高孔隙压力而性能较差，导致材料击穿。本文展示了六种混合混合钢和塑料废料(聚丙烯)纤维在经受高达500ºC的高温后的行为的调查研究的结果。对所有RPC混合料进行了残余抗压强度、残余劈裂强度和密度测试。结果表明:RPC抗压强度的下降幅度大于其相应的劈裂强度的下降幅度;此外，在500℃左右的温度范围内，这种机械强度表现出明显的下降。劈裂强度的衰减幅度在8% ~ 33%之间。钢纤维和聚丙烯纤维也能提高RPC试样的残余强度。根据这些结果，建议使用含有混合纤维(25%钢和75%聚丙烯)的混合物，以适合极端温度应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Pure & Applied Sciences

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