不同成灰温度下准东煤灰沉积特性实验研究

为探究准东煤灰沉积规律和积灰特性,在可视化飞灰沉积试验台上,对不同成灰温度下的五彩湾准东煤灰进行实验研究,并且利用SEM-EDS、XRD、粒度分布仪等对积灰样品进行测试.结果表明:不同成灰温度下的准东煤灰特性差异较大,650℃灰和500℃灰中钙的存在形式主要是CaCO_3、CaSO_4,而800℃灰主要为CaO;在800℃已经无法检测到NaCl的存在,并且发现五彩湾准东煤存在一定的自脱硫特性;在积灰特性上,颗粒直径较大的800℃灰的积灰高度最高,表明该实验条件下,物理因素为控制因素;650℃灰和500℃灰边界出现"凹凸不平"的现象,推测是在炉内灰颗粒形成孔隙,受热变软塌陷,即"边界粗糙化"现象,而800℃灰边界光滑.

成灰温度对准东煤灰理化特性影响的实验研究

将3种新疆准东煤和4种对比煤种在不同温度下制灰,研究了成灰温度对灰理化特性的影响,并分析了准东煤的积灰结渣特性。研究表明:灰分量、灰成分、灰熔融性、灰挥发特性均与成灰温度密切相关,成灰温度过高会导致碱金属挥发,过低则灰中含有可燃成分。过高或过低的成灰温度均不能准确反映准东煤灰的理化特性,655℃成灰温度比较适合准东煤.提出了采用ST与碱金属含量相结合的结渣判定方法,提高了准东煤结渣判别的准确性.

成灰温度对污泥灰矿物质演变及热力学特性的影响研究

采用STA、SEM、XRD等谱学表征技术对不同成灰温度下的污泥灰样进行理化特性分析。研究表明,低温灰样仍含有呈黑棕色的残余未燃尽物,矿物质成分以方解石、石英以及焦磷酸盐为主,随着成灰温度升高,灰样中的未燃尽物燃烧分解而逐渐变为铁红色,并形成较多晶枝结构,直至熔融,同时矿物质成分变化显著,主要以中长石类、硬石膏、赤铁矿以及磷酸正盐为主。同步热分析实验表明,随着受热温度升高,不同成灰温度下的灰样均出现了吸附水、结晶水析出,污泥灰残余有机物燃烧分解,白云石、方解石和白云母分解,以及随后的硬石膏分解等失重阶段,而且成灰温度越低,终止失重质量越大。由于低温灰样保留了较多的污泥原有特征,因此吸热量大于高温灰样。

生物质掺混比例对混煤灰分的影响分析

为研究生物质掺配比例对混煤灰分的影响,分别选取梧桐木、麦秆和烟煤按照不同掺配比例制备试样样品,通过试验确定梧桐木和麦秆混煤成灰温度和成灰时间。通过分析不同掺配比例生物质混煤灰分,得出梧桐木灰中CaO、MgO的含量明显高于烟煤,而Fe_(2)O_(3)的含量略高于烟煤,SiO_(2)、A1_(2)O_(3)的含量低于烟煤,几乎不含有Na_(2)O;麦秆灰中MgO的含量明显高于烟煤,CaO、SiO_(2)含量略高于烟煤,Fe_(2)O_(3)的含量与烟煤接近,基本不含有Al_(2)O_(3)。

Effects of synthesis temperature and raw materials composition on preparation of β-Sialon based composites from fly ash

β-Sialon based composites were successfully prepared from fly ash and carbon black under nitrogen atmosphere by carbothermal reduction-nitridation process. Effects of heating temperature and raw materials composition on synthesis process were investigated, and the formation process of the composites was also discussed. The phase composition and microstructure of the composites were characterized by X-ray diffraction and scanning electronic microscopy. The results show that increasing heating temperature or mass ratio of carbon black to fly ash can promote the formation of β-Sialon. The β-Sialon based composites can be synthesized at 1723 K for 6 h while heating the sample with mass ratio of carbon black to fly ash of 0.56. The as-received β-Sialon in the composites exists as granular with an average particle size of 2-3 μm. The preparation process of β-Sialon based composites includes the formation of O′-Sialon, X-Sialon and β-Sialon as well as the conversion processes of O′-Sialon and X-Sialon to β-Sialon.