热处理时间对磷石膏基复合胶凝材料劈裂抗拉性能的影响

硅酸盐通报 ›› 2022, Vol. 41 ›› Issue (2): 545-552.

热处理时间对磷石膏基复合胶凝材料劈裂抗拉性能的影响

安红芳¹, 付汝松¹, 陆跃贤¹, 孔德文¹, 罗双², 王琳¹, 吕方涛¹

1.贵州大学土木工程学院,贵阳 550025;
2.湖南大学土木工程学院,长沙 410082

收稿日期:2021-11-01 修回日期:2021-12-19 出版日期:2022-02-15 发布日期:2022-03-01
通讯作者: 孔德文,博士,教授。E-mail:kongdewen0608@126.com
作者简介:安红芳(1996—),女,硕士研究生。主要从事土木工程材料的研究。E-mail:3222423473@qq.com
基金资助:
国家自然科学基金(51968009,52168027);贵州省科技计划项目(黔科合[2018]2816,[2020]1Y244)

Effect of Heat Treatment Time on Splitting Tensile Properties of Phosphogypsum-Based Composite Cementitious Material

AN Hongfang¹, FU Rusong¹, LU Yuexian¹, KONG Dewen¹, LUO Shuang², WANG Lin¹, LYU Fangtao¹

1. School of Civil Engineering, Guizhou University, Guiyang 550025, China;
2. School of Civil Engineering, Hunan University, Changsha 410082, China

Received:2021-11-01 Revised:2021-12-19 Online:2022-02-15 Published:2022-03-01

摘要/Abstract

摘要： 通过恒温烘箱对磷石膏(PG)进行热处理,复掺灰钙粉、普通硅酸盐水泥、缓凝剂及减水剂制备磷石膏基复合胶凝材料(PGCM),研究热处理时间对PGCM的劈裂抗拉强度、轴心抗压强度与劈裂抗拉强度折减系数、破坏形态、劈裂抗拉应力-应变曲线的影响规律。结果表明:PGCM的劈裂抗拉强度随热处理时间的延长先增加后减小,当热处理时间为90 min时,PGCM的劈裂抗拉强度最大达到1.68 MPa;轴心抗压强度与劈裂抗拉强度折减系数随热处理时间的延长几乎都减小,PGCM的劈裂抗拉强度为轴心抗压强度的4.2%~9.2%;PGCM的破坏形态主要有中心开裂破坏、局部破坏和次要裂缝破坏;PGCM的劈裂抗拉应力-应变曲线先逐渐上升后呈直线下降。结合试验数据,得到PGCM的轴心抗压强度与劈裂抗拉强度的换算关系以及劈裂抗拉应力-应变上升段曲线方程,拟合结果与试验数据较吻合。

关键词: 热处理时间, 磷石膏, 复合胶凝材料, 劈裂抗拉强度, 破坏形态, 应力-应变曲线, 资源利用

Abstract: The phosphogypsum (PG) was heat-treated in an oven with a constant temperature, and the phosphogypsum-based composite cementitious material (PGCM) was prepared by adding lime calcium powder, normal Portland cement, retarder and water reducing agent. The effects of heat treatment time on the splitting tensile strength of PGCM, the reduction coefficient of axial compressive strength and splitting tensile strength, the failure morphology, and the splitting tensile stress-strain curves were studied. The results show that the splitting tensile strength increases first and then decreases with the extension of heat treatment time. When the heat treatment time is 90 min, the splitting tensile strength reaches the maximum 1.68 MPa. The reduction coefficients of axial compressive strength and splitting tensile strength almost reduce with the extension of heat treatment time. The splitting tensile strength is 4.2% to 9.2% of axial compressive strength. The failure morphology of PGCM mainly including central cracking failure, local failure and minor crack failure. The splitting tensile stress-strain curves of PGCM gradually rise first and then decrease linearly. Combined with the test data, the conversion relationship between the axial compressive strength and splitting tensile strength of PGCM, and the equation of splitting tensile stress-strain rising section curves are obtained. The fitting results are in good agreement with test data.

Key words: heat treatment time, phosphogypsum, composite cementitious material, splitting tensile strength, failure morphology, stress-strain curve, resource utilization

中图分类号:

TQ177

安红芳, 付汝松, 陆跃贤, 孔德文, 罗双, 王琳, 吕方涛. 热处理时间对磷石膏基复合胶凝材料劈裂抗拉性能的影响[J]. 硅酸盐通报, 2022, 41(2): 545-552.

AN Hongfang, FU Rusong, LU Yuexian, KONG Dewen, LUO Shuang, WANG Lin, LYU Fangtao. Effect of Heat Treatment Time on Splitting Tensile Properties of Phosphogypsum-Based Composite Cementitious Material[J]. BULLETIN OF THE CHINESE CERAMIC SOCIETY, 2022, 41(2): 545-552.

参考文献

[1] AL-HWAITI M S. Assessment of the radiological impacts of treated phosphogypsum used as the main constituent of building materials in Jordan[J]. Environmental Earth Sciences, 2015, 74(4): 3159-3169.
[2] RASHAD A M. Phosphogypsum as a construction material[J]. Journal of Cleaner Production, 2017, 166: 732-743.
[3] CAMPOS M P, COSTA L J P, NISTI M B, et al. Phosphogypsum recycling in the building materials industry: assessment of the radon exhalation rate[J]. Journal of Environmental Radioactivity, 2017, 172: 232-236.
[4] 彭家惠.尽快解决磷石膏资源化的共性难题[N].中国建材报,2020-12-22(1).
PENG J H. Solve the common problems of phosphogypsum resource utilization as soon as possible[N]. China Building Materials News, 2020-12-22(1) (in Chinese).
[5] 孙天琦,秦绪江,闵惜茗,等.磷石膏在建材行业的应用研究进展[J].广州化工,2021,49(10):20-22+66.
SUN T Q, QIN X J, MIN X M, et al. Research progress on application of phosphogypsum in building materials industry[J]. Guangzhou Chemical Industry, 2021, 49(10): 20-22+66 (in Chinese).
[6] CHEN X M, GAO J M, ZHAO Y S. Investigation on the hydration of hemihydrate phosphogypsum after post treatment[J]. Construction and Building Materials, 2019, 229: 116864.
[7] SINGH M. Effect of phosphatic and fluoride impurities of phosphogypsum on the properties of selenite plaster[J]. Cement and Concrete Research, 2003, 33(9): 1363-1369.
[8] MEI F D, HOU J J, LIU Z D. Research on activity characteristics on composite cementitious materials based on phosphogypsum[J]. Procedia Engineering, 2012, 43: 9-15.
[9] 李凤玲,钱觉时,倪小琴,等.快烧对磷石膏脱水相组成及胶凝性能的影响[J].硅酸盐学报,2015,43(5):579-584.
LI F L, QIAN J S, NI X Q, et al. Effect of fast-firing on dehydrated phase composition and cementitious property of phosphogypsum[J]. Journal of the Chinese Ceramic Society, 2015, 43(5): 579-584 (in Chinese).
[10] 林洲,邓铃夕,李凤玲,等.快烧对磷石膏可溶磷杂质及其脱水产物的影响[J].非金属矿,2013,36(5):1-3.
LIN Z, DENG L X, LI F L, et al. Transformation of soluble phosphate impurities and dehydration product in phosphogypsum after fast firing[J]. Non-Metallic Mines, 2013, 36(5): 1-3 (in Chinese).
[11] 马懿星,高渝棕,叶楠,等.高掺量磷石膏基复合胶凝材料耐水性能研究[J].武汉理工大学学报,2012,34(3):29-33.
MA Y X, GAO Y Z, YE N, et al. Water resistance of composite binders based on phosphogypsum[J]. Journal of Wuhan University of Technology, 2012, 34(3): 29-33 (in Chinese).
[12] 高渝棕.煅烧预处理对磷石膏基复合胶凝材料的影响[D].武汉:华中科技大学,2012.
GAO Y Z. Effect of calcination pretreatment process on phosphogypsum-based composite binder[D]. Wuhan: Huazhong University of Science and Technology, 2012 (in Chinese).
[13] 徐悦,李建锡,阚黎黎.磷石膏煅烧制备复合胶凝材料的研究[J].硅酸盐通报,2014,33(4):953-958.
XU Y, LI J X, KAN L L. Study on composite cementitious material prepared by calcinating phosphogypsum[J]. Bulletin of the Chinese Ceramic Society, 2014, 33(4): 953-958 (in Chinese).
[14] 罗双,付汝宾,孔德文,等.掺合料对磷石膏基复合胶凝材料耐水性及强度的影响综述[J].无机盐工业,2020,52(11):6-11.
LUO S, FU R B, KONG D W, et al. Summary on effects of admixtures on water resistance and strength of phosphogypsum-based composite cementitious materials[J]. Inorganic Chemicals Industry, 2020, 52(11): 6-11 (in Chinese).
[15] 郑绍聪,余强,宁平,等.无水石膏AⅢ对β半水石膏性能的影响及作用机理[J].土木建筑与环境工程,2015,37(4):118-124.
ZHENG S C, YU Q, NING P, et al. Effects and mechanism of anhydrite AⅢ on the performance of β-hemihydrate gypsum[J]. Journal of Civil, Architectural & Environmental Engineering, 2015, 37(4): 118-124 (in Chinese).
[16] 邓华锋,张吟钗,李建林,等.含水率对层状砂岩劈裂抗拉强度影响研究[J].岩石力学与工程学报,2017,36(11):2778-2787.
DENG H F, ZHANG Y C, LI J L, et al. Effect of moisture content on splitting tensile strength of layered sandstone [J]. Chinese Journal of Rock Mechanics and Engineering, 2017, 36(11): 2778-2787 (in Chinese).
[17] 高丹盈.钢纤维混凝土拉伸应力应变关系的试验研究[J].水力发电,1991,17(11):54-58+66.
GAO D Y. Experimental study on the relationship between tensile stress and strain of steel fiber concrete[J]. Water Power, 1991, 17(11): 54-58+66 (in Chinese).
[18] 徐礼华,梅国栋,黄乐,等.钢-聚丙烯混杂纤维混凝土轴心受拉应力-应变关系研究[J].土木工程学报,2014,47(7):35-45.
XU L H, MEI G D, HUANG L, et al. Study on uniaxial tensile stress-strain relationship of steel-polypropylene hybrid fiber reinforced concrete[J]. China Civil Engineering Journal, 2014, 47(7): 35-45 (in Chinese).
[19] 马钢,都思哲,高宇璇,等.再生保温混凝土受拉应力应变全曲线的研究[J].新型建筑材料,2018,45(7):28-32+59.
MA G, DU S Z, GAO Y X, et al. Experimental research on stress-strain full curve of recycled aggregate thermal insulation concrete in tension[J]. New Building Materials, 2018, 45(7): 28-32+59 (in Chinese).