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
收稿日期: 2020-10-16
网络出版日期: 2021-04-23
基金资助
国家自然科学基金(52062009);广西建筑新能源与节能重点实验室开发基金(桂科能)(19-J-22-3)
Effects of succinic acid on crystallite morphology and mechanical strength of α-hemihydrate desulfurized gypsum synthesized by hydrothermal method
Received date: 2020-10-16
Online published: 2021-04-23
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。
胡成 , 向玮衡 , 陈平 , 明阳 . 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[J]. 无机盐工业, 2021 , 53(4) : 76 -80 . DOI: 10.11962/1006-4990.2020-0319
In order to improve untilization rate and additional value of desulfurized gypsum,high strength α-hemihydrate desulfurization gypsum material was prepared by hydrothermal synthesis method in 15%(mass fraction) NaCl solution at 95 ℃. The effects of succinic acid content on crystal transformation behavior,phase composition,crystallite morphology and mechanical strength of the α-hemihydrate desulfurized gypsum were studied.The results showed that the induction nucleation and crystal growth times of the α-hemihydrate desulfurized gypsum increased gradually with the increase of mixing amount of succinic acid and the crystal transformation time was prolonged.At the same time,the length-diameter ratio of the α-hemihydrate desulfurized gypsum decreased with increase of succinic acid,which was benefit to promote hydration of α-hemihydrate desulfurized gypsum and improve compactness to enhance mechanical properties of the materials.Among,the length-diameter ratio of α-hemihydrate desulfurized gypsum reduced to 1∶1 with succinic acid of 0.20%(mass fraction) which enhanced the 2 h flexural strength and drying compressive strength of the materials to 5.54 MPa and 38.47 MPa,respectively.
| [1] | 李忠 . 促进我国资源综合利用对策研究[J]. 宏观经济管理, 2011(3):39-41. |
| [2] | Brad B . FGD gypsum issues[J]. Power Engineering, 2007,111:112-116. |
| [3] | Zdravkov B, Pelovski Y . Thermal behavior of gypsum based composites[J]. Journal of Thermal Analysis & Calorimetry, 2007,88(1):99-102. |
| [4] | Wu X Q, Tong S T, Guan B H , et al. Transformation of flue-gas-desulfurization gypsum to α-hemihydrated gypsum in salt solution at atmospHeric pressure[J]. Chinese Journal of Chemical Engineering, 2011,19(2):349-355. |
| [5] | 林敏, 万体智, 彭家惠 , 等. 盐溶液水热法制备α-半水脱硫石膏工艺条件研究[J]. 新型建筑材料, 2009,36(6):1-3. |
| [6] | Schoch P, Cunningham A . Production of gypsum plaster by wet methods[J]. Transactions of American Institute of Chemical Engineer, 1941,37:1-18. |
| [7] | Eipeltauer E . Preparation of crude gipseous rock and its conversioninto its various hemihydrate plaster forms[J]. Zem-Kalk-Gips, 1958,11:264-304. |
| [8] | 岳文海, 王志 . α-半水石膏晶形转化剂作用机理的探讨[J]. 武汉工业大学学报, 1996,18(2):1-4. |
| [9] | Mao X, Song X, Lu G , et al. Control of crystal morphology and size of calcium sulfate whiskers in aqueous HCl solutions by additives:experimental and molecular dynamics simulation studies[J]. Industrial & Engineering Chemistry Research, 2015,54(17):4781-4787. |
| [10] | 胥桂萍, 童仕唐 . 从FGD残渣中制备α型半水石膏过程晶形的控制[J]. 吉林化工学院学报, 2002(2):3-7. |
| [11] | Li F, Liu J, Yang G , et al. Effect of pH and succinic acid on the morphology of α-calcium sulfate hemihydrate synthesized by a salt solution method[J]. Journal of Crystal Growth, 2013,374:31-36. |
| [12] | 胡宏兴, 蒋善行, 任永珍 . 湿式石灰石-石膏法烟气脱硫技术应用[J]. 中国新技术新产品, 2010(16):16. |
| [13] | 毛经纬 . 脱硫石膏溶液结晶法制备α-半水石膏的稳定性及结垢研究[D]. 杭州:浙江大学, 2013. |
| [14] | 张秀英, 迟铭巧, 闫秀莹 . 有机转晶剂对常压盐溶液法制备的α-半水石膏晶体形态的影响[J]. 金属矿山, 2016(10):181-184. |
| [15] | 刘红霞, 彭家惠, 瞿金东 . 常压盐溶液法制备α-半水石膏转晶剂的研究[J]. 新型建筑材料, 2010,37(4):5-8. |
| [16] | Skrdla P J . Kinetics and thermodynamics of efficient chiral symmetry breaking in nearly racemic mixtures of conglomerate crystals[J]. Crystal Growth&Design, 2011,11(5):1957-1965. |
| [17] | Tang M, Shen X, Huang H . Influence of α-calcium sulfate hemihydrate particle characteristics on the performance of calcium sulfate-based medical materials[J]. Materials Science and Engineering:C, 2010,30(8):1107-1111. |
/
| 〈 |
|
〉 |
