脱硫石膏-粉煤灰砖的力学性能研究
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摘要
以某电厂提供的脱硫石膏和粉煤灰为主要原料,采用压制成型制备胶结砖材,研究了粉煤灰掺量、水固比、养护制度对其力学性能的影响。结果表明:随着粉煤灰掺量的增加,脱硫石膏-粉煤灰砖的强度逐渐降低;蒸压养护比自然养护砖强度高。基于以上特点,在蒸压制度下,粉煤灰掺量为40%,水固比为0.31,脱硫石膏-粉煤灰砖在龄期为14 d时,抗压强度为8.19 MPa。
The desulfurized gypsum and fly ash from a power plant were used as the main raw materials, and the bonding bricks were made by pressing and molding. The effects of fly ash content, water solid ratio and curing regime on the mechanical properties of desulphurization gypsumfly ash brick were studied. The results show that the strength of desulphurized gypsum fly ash brick decreases gradually with the increase of fly ash content; the strength of autoclaved curing bricks is higher than that of natural curing. When the amount of fly ash is 40%, the ratio of water to solid is 0.31, the compressive strength of the desulphurized gypsum-fly ash brick is 8.19 MPa at the age of 14 d under the autoclave system based on the above characteristics.
The desulfurized gypsum and fly ash from a power plant were used as the main raw materials, and the bonding bricks were made by pressing and molding. The effects of fly ash content, water solid ratio and curing regime on the mechanical properties of desulphurization gypsumfly ash brick were studied. The results show that the strength of desulphurized gypsum fly ash brick decreases gradually with the increase of fly ash content; the strength of autoclaved curing bricks is higher than that of natural curing. When the amount of fly ash is 40%, the ratio of water to solid is 0.31, the compressive strength of the desulphurized gypsum-fly ash brick is 8.19 MPa at the age of 14 d under the autoclave system based on the above characteristics.
引文
[1]施惠生,夏明,郭晓潞.粉煤灰基地聚合物反应机理及各组分作用的研究进展[J].硅酸盐学报,2013(7):972-980.
[2]汪潇,王宇斌,杨留栓,等.高性能大掺量粉煤灰混凝土研究[J].硅酸盐通报,2013,32(3):523-532.
[3]徐子芳,解一涵,许明璐,等.超细粉煤灰烧结性能机理研究[J].非金属矿,2018,41(2):7-10.
[4]马昆林,龙广成,谢友均,等.水泥-粉煤灰-石灰石粉浆体塑性黏度的影响因素[J].硅酸盐学报,2013(11):1481-1486.
[5]童伟刚,姚雪荣,莫伟标.烟气脱硫方法分析及脱硫石膏的应用途径[J].新型建筑材料, 2006(8):55-57.
[6]邓琨.固体废弃物综合利用技术的现状分析—对粉煤灰、煤矸石、尾矿、脱硫石膏和秸秆综合利用技术专业化的探析[J].中国资源综合利用,2011,29(1):33-42.
[7] SIAGI Z, MBARAWA M. Dissolution rate of South African calciumbased materials at constant pH[J]. Journal of Hazardous Materials, 2009,163:678-682.
[8]HESSEC,GOETZ-NEUNHOEFFERF,NEUBAUERJ. Anew approach in quantitative in-situ XRD of cement pastes:Correlation of heat flow curves with early hydration reactions[J]. Cement&Concrete Research, 2011, 41(1):123-128.
[9] ZDRAVKOV B, PELOVSKI Y. Thermal behavior of gypsum based composites[J]. Journal of Thermal Analysis&Calorimetry, 2007, 88(1):99-102.
[10] GUO X L, SHI H S, DICK W A. Utilization of thermally treated Flue Gas Desulfurization(FGD)gypsum and class-C Fly Ash(CFA)to prepare CFA-based geopolymer[J]. Journal of Wuhan University of Technology-Mater, 2013, 28(1):132-138.
[11]曹钊,曹永丹,李现龙,等.高炉矿渣-粉煤灰-脱硫石膏-水泥制备硅酸钙板的协同水化机理[J].硅酸盐通报,2015,34(1):298-302.
[12] CAO Z, CAO Y D, ZHANG J S, et al. Preparation and characterization of high-strength calcium silicate boards from coal-fired industrial solid wastes[J]. Metallurgy and Materials, 2015, 22(8):892-899.
[13]赵素宁,曲烈,高士奇.脱硫石膏-粉煤灰复合胶凝材料的力学性能研究[J].粉煤灰,2013(2):1-3.
[14]周富涛,石宗利.石膏基复合胶凝材料养护制度的探讨[J].新型建筑材料,2007(4):70-73.
[15] MONTGOMERY D G, HUGHES D C, WILLIAMS R I T. Fly ash in concrete-a microstructure study[J]. Cement&Concrete Research, 1981,11(4):591-603.
[2]汪潇,王宇斌,杨留栓,等.高性能大掺量粉煤灰混凝土研究[J].硅酸盐通报,2013,32(3):523-532.
[3]徐子芳,解一涵,许明璐,等.超细粉煤灰烧结性能机理研究[J].非金属矿,2018,41(2):7-10.
[4]马昆林,龙广成,谢友均,等.水泥-粉煤灰-石灰石粉浆体塑性黏度的影响因素[J].硅酸盐学报,2013(11):1481-1486.
[5]童伟刚,姚雪荣,莫伟标.烟气脱硫方法分析及脱硫石膏的应用途径[J].新型建筑材料, 2006(8):55-57.
[6]邓琨.固体废弃物综合利用技术的现状分析—对粉煤灰、煤矸石、尾矿、脱硫石膏和秸秆综合利用技术专业化的探析[J].中国资源综合利用,2011,29(1):33-42.
[7] SIAGI Z, MBARAWA M. Dissolution rate of South African calciumbased materials at constant pH[J]. Journal of Hazardous Materials, 2009,163:678-682.
[8]HESSEC,GOETZ-NEUNHOEFFERF,NEUBAUERJ. Anew approach in quantitative in-situ XRD of cement pastes:Correlation of heat flow curves with early hydration reactions[J]. Cement&Concrete Research, 2011, 41(1):123-128.
[9] ZDRAVKOV B, PELOVSKI Y. Thermal behavior of gypsum based composites[J]. Journal of Thermal Analysis&Calorimetry, 2007, 88(1):99-102.
[10] GUO X L, SHI H S, DICK W A. Utilization of thermally treated Flue Gas Desulfurization(FGD)gypsum and class-C Fly Ash(CFA)to prepare CFA-based geopolymer[J]. Journal of Wuhan University of Technology-Mater, 2013, 28(1):132-138.
[11]曹钊,曹永丹,李现龙,等.高炉矿渣-粉煤灰-脱硫石膏-水泥制备硅酸钙板的协同水化机理[J].硅酸盐通报,2015,34(1):298-302.
[12] CAO Z, CAO Y D, ZHANG J S, et al. Preparation and characterization of high-strength calcium silicate boards from coal-fired industrial solid wastes[J]. Metallurgy and Materials, 2015, 22(8):892-899.
[13]赵素宁,曲烈,高士奇.脱硫石膏-粉煤灰复合胶凝材料的力学性能研究[J].粉煤灰,2013(2):1-3.
[14]周富涛,石宗利.石膏基复合胶凝材料养护制度的探讨[J].新型建筑材料,2007(4):70-73.
[15] MONTGOMERY D G, HUGHES D C, WILLIAMS R I T. Fly ash in concrete-a microstructure study[J]. Cement&Concrete Research, 1981,11(4):591-603.
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