改性高浓度硼酸溶液对蛇纹石屏蔽混凝土力学性能与中子屏蔽性能的影响

硅酸盐通报 ›› 2024, Vol. 43 ›› Issue (6): 2047-2055.

改性高浓度硼酸溶液对蛇纹石屏蔽混凝土力学性能与中子屏蔽性能的影响

甘学彧^1,2, 陈帅³, 耿海宁⁴, 李宗刚^1,2, 马浩森^1,2, 陈伟¹, 侯硕³, 李秋¹

1.武汉理工大学硅酸盐建筑材料国家重点实验室,武汉 430070;
2.武汉理工大学材料科学与工程学院,武汉 430070;
3.中广核研究院有限责任公司,深圳 518000;
4.湖北城市建设职业技术学院, 武汉 430205

收稿日期:2023-11-27 修订日期:2024-01-16 出版日期:2024-06-15 发布日期:2024-06-18
通信作者: 侯硕,高级工程师。E-mail:464256545@qq.com；李秋,博士,研究员。E-mail:Qiu-Li@whut.edu.cn
作者简介:甘学彧(2000—),男,硕士研究生。主要从事防辐射混凝土的研究。E-mail:a3617155@qq.com
基金资助:
国家自然科学基金面上项目(52072279)

Effect of Modified High Concentration Boric Acid Solution on Mechanical and Neutron Shielding Properties of Serpentine Shielded Concrete

GAN Xueyu^1,2, CHEN Shuai³, GENG Haining⁴, LI Zonggang^1,2, MA Haosen^1,2, CHEN Wei¹, HOU Suo³, LI Qiu¹

1. State Key Laboratory of Silicate Materials for Architectures, Wuhan University of Technology, Wuhan 430070, China;
2. School of Materials Science and Engineering, Wuhan University of Technology, Wuhan 430070, China;
3. China Nuclear Power Technology Research Institute Co., Ltd., Shenzhen 518000, China;
4. Hubei Urban Construction Vocational and Technological College, Wuhan 430205, China

Received:2023-11-27 Revised:2024-01-16 Online:2024-06-15 Published:2024-06-18

摘要/Abstract

摘要： 蛇纹石屏蔽混凝土是一种长期应用于高温条件下仍能保持高结晶水含量的中子屏蔽材料,但其密实度低,缺乏有效吸收热中子的硼元素。作为硼元素的来源,硼酸是生产屏蔽混凝土的有效材料,但在以水泥为主的水化体系中,硼酸的掺入会抑制水泥水化过程,导致材料强度及耐久性劣化。本研究通过改性高浓度硼酸溶液,诱导水泥浆体中游离硼酸盐生成高硼含量与结晶水含量的戈硼钙石,增加体系中硼元素含量的同时解除硼酸对水泥水化的抑制作用,研究改性高浓度硼酸溶液对蛇纹石屏蔽混凝土工作性能、力学性能、高温残余抗压强度、微观结构与屏蔽性能的影响。结果表明:掺加改性高浓度硼酸溶液对蛇纹石屏蔽混凝土的凝结时间、常温力学性能、高温残余抗压强度均无不良影响。掺加改性高浓度硼酸溶液后,蛇纹石屏蔽混凝土在400 ℃高温残余抗压强度提高了43.5%,常温下半值层降低了31.7%,350 ℃保温至恒重后半值层降低了21.4%,对中子射线的屏蔽能力增强。

关键词: 蛇纹石屏蔽混凝土, 中子屏蔽性能, 高温残余抗压强度, 改性高浓度硼酸溶液, 戈硼钙石, 凝结时间

Abstract: Serpentine shielded concrete is a neutron shielding material that can maintain high crystal water content even under high temperature condition for a long time, but its compactness is low and it lacks boron element that can effectively absorb thermal neutrons. As a source of boron, boric acid is an effective material for producing shielded concrete. However, in cement-based hydration systems, the addition of boric acid can inhibit the cement hydration process, leading to deterioration of material strength and durability. This study induced the formation of high boron content and crystalline water content of boric acid in cement slurry by modifying high concentration boric acid solution. The boron content in the system was increased while the inhibitory effect of boric acid on cement hydration was relieved. The effect of modified high concentration boric acid solution on workability, mechanical properties, high-temperature residual compressive strength, microstructure and shielding performance of serpentinite shielded concrete was studied. The results show that the addition of modified high concentration boric acid solution has no adverse effects on the setting time, mechanical properties at room temperature, and high-temperature residual compressive strength of serpentine shielded concrete. After adding modified high concentration boric acid solution, the high-temperature residual compressive strength at 400 ℃ of serpentinite shielding concrete increases by 43.5%, the half value layer at room temperature decreases by 31.7%, and the half value layer decreases by 21.4% after insulation at 350 ℃ to constant weight, enhancing the shielding ability of neutron rays.

Key words: serpentine shielded concrete, neutron shielding property, high-temperature residue compressive strength, modified high concentration boric acid solution, gowerite, setting time

中图分类号:

TL75⁺2.3

甘学彧, 陈帅, 耿海宁, 李宗刚, 马浩森, 陈伟, 侯硕, 李秋. 改性高浓度硼酸溶液对蛇纹石屏蔽混凝土力学性能与中子屏蔽性能的影响[J]. 硅酸盐通报, 2024, 43(6): 2047-2055.

GAN Xueyu, CHEN Shuai, GENG Haining, LI Zonggang, MA Haosen, CHEN Wei, HOU Suo, LI Qiu. Effect of Modified High Concentration Boric Acid Solution on Mechanical and Neutron Shielding Properties of Serpentine Shielded Concrete[J]. BULLETIN OF THE CHINESE CERAMIC SOCIETY, 2024, 43(6): 2047-2055.

参考文献

[1] 王飞, 代伟, 毛英辉, 等. 防护工程电磁屏蔽混凝土电磁损耗及屏蔽性能研究[J]. 混凝土, 2022(12): 185-188.
WANG F, DAI W, MAO Y H, et al. Study on electromagnetic loss and shielding performance of concrete in protective engineering[J]. Concrete, 2022(12): 185-188 (in Chinese).
[2] 何林, 蔡永军, 李强. 中子和伽马射线综合屏蔽材料研究进展[J]. 材料导报, 2018, 32(7): 1107-1113.
HE L, CAI Y J, LI Q. Research progress in radiation shielding materials serving as the combined barrier against neutron and gamma-ray[J]. Materials Review, 2018, 32(7): 1107-1113 (in Chinese).
[3] 杨昭, 石建军, 许新春, 等. 蛇纹石混凝土研究应用进展[J]. 硅酸盐通报, 2023, 42(6): 1912-1920.
YANG Z, SHI J J, XU X C, et al. Research and application progress of serpentine concrete[J]. Bulletin of the Chinese Ceramic Society, 2023, 42(6): 1912-1920 (in Chinese).
[4] 朱奇健. 不同材料对中子射线的屏蔽效果研究[J]. 海峡科学, 2023(8): 35-39.
ZHU Q J. Study on the shielding effect of different materials on neutron rays [J]. Straits Science, 2023(8): 35-39 (in Chinese).
[5] MASOUD M A, RASHAD A M, SAKR K, et al. Possibility of using different types of egyptian serpentine as fine and coarse aggregates for concrete production[J]. Materials and Structures, 2020, 53(4): 87.
[6] ZAYED A M, MASOUD M A, SHAHIEN M G, et al. Physical, mechanical, and radiation attenuation properties of serpentine concrete containing boric acid[J]. Construction and Building Materials, 2021, 272: 121641.
[7] LI Q, MA H, TANG Y, et al. Combined effect of NaAlO₂ and NaOH on the early age hydration of Portland cement with a high concentration of borate solution[J]. Cement and Concrete Research, 2021, 144: 106430.
[8] 张强, 刘红彪. 饱水法测定混凝土孔隙率的试块尺寸优化研究[J]. 水道港口, 2017, 38(6): 604-609.
ZHANG Q, LIU H B. Study on the optimization of test specimen size for concrete pore porosity testing with water displacement method[J]. Journal of Waterway and Harbor, 2017, 38(6): 604-609 (in Chinese).
[9] 中船重工第七一九研究所. 电离辐射防护材料屏蔽性能检测方法: Q/719J131—2018[S]. 武汉: 中船重工第七一九研究院, 2018.
No.719 Research Institute of China Shipbuilding Industry Group. Test method for shielding properties of ionizing radiation protective materials: Q/719J131—2018[S]. Wuhan: No.719 Research Institute of China Shipbuilding Industry Group, 2018 (in Chinese).
[10] PENG G F, BIAN S H, GUO Z Q, et al. Effect of thermal shock due to rapid cooling on residual mechanical properties of fiber concrete exposed to high temperatures[J]. Construction and Building Materials, 2008, 22(5): 948-955.
[11] 顾连胜, 刘大为, 梁炯丰, 等. 高温后玄武岩纤维混凝土力学性能试验研究[J]. 混凝土, 2023(3): 74-76.
GU L S, LIU D W, LIANG J F, et al. Experimental study on mechanical properties of basalt fiber reinforced concrete after high temperature[J]. Concrete, 2023(3): 74-76 (in Chinese).
[12] 周建伟, 杨文, 程宝军, 等. 超细粉煤灰和偏高岭土对高强混凝土耐热性能的影响[J]. 硅酸盐通报, 2020, 39(6): 1784-1790.
ZHOU J W, YANG W, CHENG B J, et al. Effect of ultra-fine fly ash and metakaolin on heat resistance of high strength concrete[J]. Bulletin of the Chinese Ceramic Society, 2020, 39(6): 1784-1790 (in Chinese).
[13] ZAYED A M, MASOUD M A, RASHAD A M, et al. Influence of heavyweight aggregates on the physico-mechanical and radiation attenuation properties of serpentine-based concrete[J]. Construction and Building Materials, 2020, 260: 120473.

[1]	刘远, 刘孝通, 杨安旭, 张远永, 杨林. 氟硅渣改性硫酸铝基无碱液体速凝剂对水泥性能的影响[J]. 硅酸盐通报, 2024, 43(6): 2005-2011.
[2]	周明凯, 王潇, 高鹏, 王宇强. 湿基α-半水石膏制备高强石膏制品研究[J]. 硅酸盐通报, 2024, 43(6): 2186-2197.
[3]	蒋明屾, 李飞, 周理安, 宁佳蕊, 张政. 碳酸钠、氢氧化钠与水玻璃复合激发对地聚物胶凝材料性能的影响[J]. 硅酸盐通报, 2024, 43(3): 929-937.
[4]	邓永刚, 代婷婷, 孙晨, 杨元全. 沸石微粉对磷酸钾镁水泥水化性能的影响[J]. 硅酸盐通报, 2023, 42(9): 3083-3088.
[5]	胡阳, 刘亚炜, 吴颖辉, 鲁刘磊, 黄文昊, 牛伟锋, 李生生, 汪峻峰. 两种改性剂对注浆材料流变性能的影响[J]. 硅酸盐通报, 2023, 42(9): 3135-3142.
[6]	潘荣祥, 杨敏, 袁宏. 减水剂对赤泥-粉煤灰基地质聚合物性能的影响[J]. 硅酸盐通报, 2023, 42(9): 3212-3220.
[7]	黄荣贵, 陶忠, 吴磊, 沈金金, 徐伟杰. 聚乙烯醇纤维对磷建筑石膏基复合材料性能的影响[J]. 硅酸盐通报, 2023, 42(9): 3258-3266.
[8]	方学东, 魏江, 冯自立, 杜镇宇, 全轶钊, 全力新. 注浆材料在机场场道工程中的应用进展[J]. 硅酸盐通报, 2023, 42(8): 3017-3032.
[9]	翁友法, 李沫弦, 王超凡, 陈兵. 硫氧镁水泥改性半水磷石膏试验研究[J]. 硅酸盐通报, 2023, 42(6): 2115-2120.
[10]	万子恒, 金子豪, 苏英, 王丽玥, 王斌. 缓凝剂对磷石膏-硫铝酸盐水泥复合胶凝体系性能影响[J]. 硅酸盐通报, 2023, 42(6): 2131-2039.
[11]	张晓静, 王德志, 靳凯戎, 刘江, 关岩. 花岗岩石粉对水泥浆体力学性能的影响[J]. 硅酸盐通报, 2023, 42(5): 1704-1709.
[12]	杜新宇, 陈潇, 周明凯, 张浩宇, 杨寅, 王瑜德. 含硫酸盐类固废对硅酸盐水泥水化影响研究[J]. 硅酸盐通报, 2023, 42(5): 1710-1720.
[13]	杨孟君, 曹义冬, 林常, 徐树英, 潘莉莎. 低钙粉煤灰地聚物的流变性能、凝结时间和抗压强度[J]. 硅酸盐通报, 2023, 42(5): 1721-1730.
[14]	刘佳宁, 洪梅, 魏涛, 陈日, 宋博宇. CTAB改性地质聚合物对地下污染源的阻截作用[J]. 硅酸盐通报, 2023, 42(5): 1831-1840.
[15]	陈新明, 张浩文, 焦华喆, 杨柳华, 荣阳阳. HPMC及硼砂对新型防漏高强注浆料性能及微观结构的影响[J]. 硅酸盐通报, 2023, 42(3): 861-870.