柠檬酸和pH值对α-半水脱硫石膏晶体形貌的调控及影响

采用常压盐溶液法制备α-半水脱硫石膏,研究转晶剂柠檬酸在不同pH值条件下对α-半水脱硫石膏晶体形貌的影响。从产物晶体形貌、脱水速率、液相离子浓度等角度,研究了溶液pH值对柠檬酸调晶效果的影响规律。结果表明:柠檬酸调晶效果非常显著,在0.01%的低掺量下,α-半水脱硫石膏由棒状转变为长径比接近1∶1的短柱状晶体。pH值是影响其调晶效果最敏感的因素之一,在pH=3.5～4.8之间的酸性范围内,有利于结晶习性改良。

丁二酸对水热合成α-半水脱硫石膏微晶形貌及力学强度的影响

为提高脱硫石膏利用率和附加值,采用水热合成法在温度为95℃的15%(质量分数)氯化钠溶液中制备高强α-半水脱硫石膏材料,研究了丁二酸掺量对α-半水脱硫石膏转晶行为、物相组成、微晶形貌及力学强度的影响。结果表明,随着丁二酸掺量的增加,α-半水脱硫石膏的诱导成核与晶体生长时间均逐渐增大,转晶时间延长。同时,α-半水脱硫石膏的长径比随着丁二酸掺量的增加而降低,这有利于促进α-半水脱硫石膏水化,提高结构密实性,改善材料的力学性能。其中,掺入0.20%(质量分数)丁二酸时α-半水脱硫石膏的长径比降至1∶1左右,其2 h抗折强度和烘干抗压强度分别提高至5.54 MPa、38.47 MPa。

聚羧酸减水剂对α-半水脱硫石膏的水化进程及其硬化体微结构的影响

采用扫描电镜、压汞测孔仪等微观分析方法,结合宏观物理力学性能实验,测试了加入聚羧酸减水剂后α-半水脱硫石膏的水化温升、水化率、硬化体的强度、孔结构以及显微结构,并研究聚羧酸减水剂对α-半水脱硫石膏水化硬化性能的影响。结果表明,聚羧酸减水剂对石膏水化进程影响较小;在一定的掺量内,聚羧酸减水剂能大幅提高石膏硬化体强度,改善硬化体孔结构,降低石膏孔隙率,细化孔径,这是聚羧酸减水剂提高α-半水脱硫石膏硬化体强度的内在原因。

石灰石-石膏湿法烟气脱硫系统(WFGD)副产物产业化方案

用于生产α-石膏的传统的“液相法”生产技术有许多缺陷,如由于长时间的干燥导致产品质量低、干燥设备的费用高、在粉磨改性过程中浪费能源。本文研究的目的在于:使用连续式生产方法设法克服传统生产技术中的这些缺陷。首先,加热石膏浆液,并使之流动,同时脱除结晶水并形成半水石膏结晶。然后瞬间减压使浆液流进干燥塔,引起蒸汽爆炸,同时完成干燥和改性2个环节。

Promotion of conversion activity of flue gas desulfurization gypsum into α-hemihydrate gypsum by calcination-hydration treatment

The massive accumulation of flue gas desulfurization(FGD)gypsum produced in the wet limestone-gypsum flue gas desulfurization process not only encroaches on lands but also causes serious environmental pollution.The preparation ofα-hemihydrate gypsum(α-HH)is an important way to achieve high-value utilization of FGD gypsum.Although the glycerol-water solution approach can be used to produceα-HH from FGD gypsum under mild conditions,the transition is kinetically unfavorable in the mixed solution.Here,an easy pretreatment was used to activate FGD gypsum by calcination and hydration to readily complete the transition.The pretreatment deteriorated the crystallinity of FGD gypsum and caused it to form small irregular flaky crystals,which dramatically increased the specific surface area.Additionally,most of the organics adsorbed onto FGD gypsum surfaces were removed after pretreatment.The poor crystallinity,increased specific surface area,and elimination of organics adsorbed onto crystal surfaces effectively improved the conversion activity of FGD gypsum,thereby promoting dihydrate gypsum(DH)dissolution andα-HH nucleation.Overall,the phase transition of FGD gypsum toα-HH is facilitated.