Potential of spent fluid cracking catalyst (FCC) waste for low-carbon cement production. Effect of treatments to enhance reactivity

Z. Lei, S. Pavia
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Abstract

Spent fluid cracking catalyst (FCC) waste is produced to convert petroleum crude oil into gasoline, and its main component is a reactive zeolite known as faujasite. This paper studies low-energy treatments to enhance reactivity. When untreated, the spent FCC has outstanding activity, and a fast set which delivered significant strength (6–10 MPa) and a high mechanical index (MI=14). Calcination (up to 800 °C) is not enough to amorphize the faujasite and increase reactivity. However, NaOH-fusion is highly efficient. Even at low temperature (450 °C), NaOH-fusion breaks down the zeolite structure, dissolving Si4+ that forms cementing hydrates with high Ca/Si and Si/Al ratios which delivered high strengths. NaOH-fusion at 450 °C totally amorphized the zeolite resulting in high strength (9–13 MPa) and outstanding MI>22; superior to pozzolans, and closer to cementitious materials. Fusion at 600 °C reorganises some of the amorphous phase into a silicate whose hydrates provided the greatest strengths (over 16 MPa) and an outstanding MI of 24.

Na2CO3-fusion at 600 °C did not alter the spent FCC but provided CO32− which formed calcite cements. These initially densified the matrix providing strength but lowered long-term strength and workability.

Acid-etching partially dissolved spent FCC particles which improved early activity but caused a loss of soluble Si4+ and Al3+ that reduced the ultimate strength. Due to the low organic matter in the spent FCC, oxidation did not increase reactivity.

The spent FCC is highly pozzolanic, it can safely reduce the embodied carbon of cements: concentrations of heavy metals are either traces or insignificant. Therefore, they can easily immobilise in a stable matrix.

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废流体裂化催化剂(FCC)废物用于低碳水泥生产的潜力。提高反应性的处理效果
废流体裂化催化剂(FCC)废物用于将石油原油转化为汽油,其主要成分是一种被称为八面沸石的活性沸石。本文研究了低能量处理以提高反应性。未经处理时,废FCC具有出色的活性和快速凝固,可提供显著的强度(6–10 MPa)和高机械指数(MI=14)。煅烧(高达800°C)不足以使八方沸石非晶化并增加反应性。然而,NaOH融合是非常有效的。即使在低温(450°C)下,NaOH熔融也会破坏沸石结构,溶解Si4+,形成具有高Ca/Si和Si/Al比的胶结水合物,从而提供高强度。450°C下的NaOH熔融使沸石完全非晶化,产生高强度(9–13 MPa)和优异的MI>;22;优于火山灰,更接近胶结材料。600°C下的熔融将一些非晶相重组为硅酸盐,其水合物提供了最大的强度(超过16 MPa)和24.Na2CO3的突出MI。600°C的熔融没有改变废FCC,但提供了形成方解石胶结物的CO32-。这些最初使基质致密,提供了强度,但降低了长期强度和可加工性。酸蚀刻部分溶解了废FCC颗粒,这提高了早期活性,但导致可溶性Si4+和Al3+的损失,从而降低了极限强度。由于废催化裂化中的低有机物,氧化并没有增加反应性。废催化裂化是高度火山灰的,它可以安全地减少水泥中的含碳:重金属浓度要么是微量的,要么是微不足道的。因此,它们可以很容易地固定在稳定的基质中。
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