Theresa Siegmund, Christian Gollmer, Niklas Horstmann, Martin Kaltschmitt
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The mitigation effects on CO emissions have previously been reported mostly in a subordinate role and explanations are given in the form of hypotheses. In this study, seven additives (i.e., kaolin, kaolinite, meta-kaolinite, aluminum hydroxide, muscovite, muscovite coated with titanium dioxide and kalsilite, each at 0.3 wt%<sub>a.r.</sub>) were investigated during wood pellet combustion in a small-scale furnace (7.8 kW). 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引用次数: 0
摘要
事实证明,固体生物燃料添加剂是减少总颗粒物质(TPM)和一氧化碳(CO)排放,以及减少与灰有关的问题(如结垢和结渣)的有效方法。在使用添加剂进行燃烧的过程中,固体生物燃料中释放的钾(K)会被结合成温度稳定的化合物,从而防止形成无机(即钾基)TPM。同时,通过减少气相中的钾,还可抑制由于钾对现有自由基池的干扰而导致的气相氧化(如 CO 氧化)。特别是高岭土,一种基于铝硅酸盐的添加剂已被证明不仅能有效减少 TPM,还能有效减少 CO 排放。以前的报告中,对 CO 排放的缓解作用大多处于从属地位,并以假设的形式进行了解释。在本研究中,我们在小型熔炉(7.8 千瓦)中对木质颗粒燃烧过程中的七种添加剂(即高岭土、高岭石、偏高岭石、氢氧化铝、麝香石、涂有二氧化钛的麝香石和kalsilite,每种添加剂的含量均为 0.3 wt%)进行了调查。在 CO 和 TPM 排放方面,高岭土被证明是最有效的(即 CO -52%,TPM -49%),其次是麝香石、高岭石、TiO 涂层麝香石、氢氧化铝和元高岭石。
Carbon monoxide (CO) and particulate matter (PM) emissions during the combustion of wood pellets in a small-scale combustion unit – Influence of aluminum-(silicate-)based fuel additivation
The additivation of solid biofuels has proven to be an effective method for reducing total particulate matter (TPM) and carbon monoxide (CO) emissions, as well as for reducing ash-related problems related to, e.g., fouling and slagging. During the combustion with additives, potassium (K) released from the solid biofuels is bound into temperature-stable compounds, thus preventing the formation of inorganic (i.e., K-based) TPM. Simultaneously by reducing K in the gas phase, the inhibition of gas-phase oxidation (e.g., CO oxidation) due to interference of K within the existing radical pool is hindered. Particularly kaolin, an aluminum-silicate-based additive has proven effective in reducing not only TPM but also CO emissions. The mitigation effects on CO emissions have previously been reported mostly in a subordinate role and explanations are given in the form of hypotheses. In this study, seven additives (i.e., kaolin, kaolinite, meta-kaolinite, aluminum hydroxide, muscovite, muscovite coated with titanium dioxide and kalsilite, each at 0.3 wt%a.r.) were investigated during wood pellet combustion in a small-scale furnace (7.8 kW). For both CO and TPM emissions, kaolin proved to be most effective (i.e., −52% CO, −49% TPM), followed by muscovite, kaolinite, TiO2 coated muscovite, aluminum hydroxide, and meta-kaolinite.
期刊介绍:
Fuel Processing Technology (FPT) deals with the scientific and technological aspects of converting fossil and renewable resources to clean fuels, value-added chemicals, fuel-related advanced carbon materials and by-products. In addition to the traditional non-nuclear fossil fuels, biomass and wastes, papers on the integration of renewables such as solar and wind energy and energy storage into the fuel processing processes, as well as papers on the production and conversion of non-carbon-containing fuels such as hydrogen and ammonia, are also welcome. While chemical conversion is emphasized, papers on advanced physical conversion processes are also considered for publication in FPT. Papers on the fundamental aspects of fuel structure and properties will also be considered.