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《材料导报》期刊社  2018, Vol. 32 Issue (9): 1528-1533    https://doi.org/10.11896/j.issn.1005-023X.2018.09.018
  材料综述 |
珊瑚骨料混凝土性能及微结构的研究进展
王爱国1,吕邦成1,刘开伟1,马 雪2,徐海燕1,谭京梅1
1 安徽建筑大学安徽省先进建筑材料重点实验室,合肥 230022;
2 西南科技大学材料科学与工程学院,绵阳 621010
A Review of Properties and Microstructure of Coral Aggregate Concrete
WANG Aiguo1, LYU Bangcheng1, LIU Kaiwei1, MA Xue2, XU Haiyan1, TAN Jingmei1
1 Anhui Key Laboratory of Advanced Building Materials, Anhui Jianzhu University, Hefei 230022;
2 College of MaterialsScience and Engineering, Southwest University of Science and Technology, Mianyang 621010
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摘要 海洋工程混凝土是发展海洋经济的重要基础支撑,远洋岛礁工程“就地取材”,即采用珊瑚等物料进行建设,是海洋土木工程研究的必然追求。珊瑚骨料与普通砂石骨料、轻集料在组成、结构及性能等方面存在明显差异。本文阐述了珊瑚骨料特性对混凝土工作性能、力学性能、体积稳定性能、耐久性能及微结构的影响,指出了珊瑚骨料混凝土存在强度不足、脆性大和抗蚀差等问题,并针对适合海洋环境的高强度、高韧性和高耐久的珊瑚骨料混凝土的研究开发进行了展望。
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王爱国
吕邦成
刘开伟
马 雪
徐海燕
谭京梅
关键词:  珊瑚骨料  混凝土  工作性能  力学性能  体积稳定性  耐久性  微结构    
Abstract: The rapid development of marine economy rely remarkably on the production of marine engineering concrete, for which the utilization of nearby readily accessible raw materials is of great necessity in ocean reef construction. Coral aggregates exhibit composition, structure and properties quite dissimilar to ordinary aggregates or light aggregates. This article provides a clear description over the effects of coral aggregate characteristics on workability, mechanical properties, volume stability, durabi-lity and microstructures of concrete. It presents the thorny problems for coral aggregate concrete, such as insufficient strength, large brittleness and poor corrosion resistance, and moreover, outlines the future prospect of creating high-strength, high-toughness and high-durabi-lity coral aggregate concrete which is adaptable to marine environment.
Key words:  coral aggregate    concrete    workability    mechanical property    volume stability    durability    microstructure
               出版日期:  2018-05-10      发布日期:  2018-07-06
ZTFLH:  TU528  
基金资助: 国家自然科学基金(51778003;11405140);安徽省高等教育人才项目(皖教高[2014]11号文);高校优秀中青年骨干人才国内外访学研修项目(gxfxZD2016134);国家级大学生创新创业训练计划项目(201710878028)
通讯作者:  刘开伟:通信作者,男,1985年生,博士,讲师,主要从事高性能混凝土研究 E-mail:liukaiwei1985@gmail.com   
作者简介:  王爱国:男,1978年生,博士,副教授,主要从事高性能混凝土研究 E-mail:wag3134@126.com
引用本文:    
王爱国,吕邦成,刘开伟,马 雪,徐海燕,谭京梅. 珊瑚骨料混凝土性能及微结构的研究进展[J]. 《材料导报》期刊社, 2018, 32(9): 1528-1533.
WANG Aiguo, LYU Bangcheng, LIU Kaiwei, MA Xue, XU Haiyan, TAN Jingmei. A Review of Properties and Microstructure of Coral Aggregate Concrete. Materials Reports, 2018, 32(9): 1528-1533.
链接本文:  
http://www.mater-rep.com/CN/10.11896/j.issn.1005-023X.2018.09.018  或          http://www.mater-rep.com/CN/Y2018/V32/I9/1528
1 Wang L, Zhao Y L, Lv H B. Prospect on the properties and application situation of coral aggregate concrete[J].Concrete,2012(2):99(in Chinese).
王磊,赵艳林,吕海波.珊瑚骨料混凝土的基础性能及研究应用前景[J].混凝土,2012(2):99.
2 Howdyshell P A. The use of coral as an aggregate for Portland cement concrete structures[R].USA: Army Construction Engineering Research Laboratory,1974.
3 Chen Z L, Tang X N, Sun G F, et al. Research on durability and application of seawater concrete[J].The Ocean Engineering,2008,26(4):102(in Chinese).
陈兆林,唐筱宁,孙国峰,等.海水拌养混凝土耐久性试验与应用[J].海洋工程,2008,26(4):102.
4 Hu Q, Yang T, Wang Z Z, et al. Analysis of life cycle cost of FRP marine coral concretestructure and common reinforced concrete structure[J].Construction Economy,2016,37(1):61(in Chinese).
胡乔,阳涛,王壮志,等.FRP海水珊瑚骨料混凝土与普通钢筋混凝土结构的全寿命周期成本比较[J].建筑经济,2016,37(1):61.
5 Li L. Research on the basic characteristics of coral concrete[D].Nanning: Guangxi University,2012(in Chinese).
李林.珊瑚骨料混凝土的基本特性研究[D].南宁:广西大学,2012.
6 Wei Z B, Li Z X, Shen J L. Research on the influencing factors of performance of coral concrete and its early mechanical property[J].Industrial Construction,2017,47(3):130(in Chinese).
韦灼彬,李钟欣,沈锦林.珊瑚骨料混凝土性能影响因素及早期力学性质研究[J].工业建筑,2017,47(3):130.
7 Li W F, Guan J, Ma S H, et al. Application of sea sand and coral reefs in the production of concrete mixed with seawater[J].Concrete,2016(5):148(in Chinese).
李伟峰,管娟,马素花,等.海砂、珊瑚礁在海拌海养混凝土生产中的应用[J].混凝土,2016(5):148.
8 Sun Z X. Engineering properties of coral sands in Nansha islands[J].Journal of Tropical Oceanography,2000,19(2):1(in Chinese).
孙宗勋.南沙群岛珊瑚砂工程性质研究[J].热带海洋,2000,19(2):1.
9 Pan B Z, Wei Z B. Experimental study on effects to coral sand concrete compressive strength of raw materials[J].Engineering Mecha-nics,2015,32(1):221(in Chinese).
潘柏州,韦灼彬.原材料对珊瑚砂混凝土抗压强度影响的试验研究[J].工程力学,2015,32(1):221.
10 Xu C M, Hu J B, Zhao J Y. Research on preparation technology of the coral sand in accropode concrete[J].The World of Building Materials,2016,37(6):14(in Chinese).
许成明,胡家兵,赵缙宇.珊瑚礁砂配制扭王字块混凝土技术研究[J].建材世界,2016,37(6):14.
11 Yuan Y F.Mix design and property of coral aggregate concrete[D].Nanjing: Nanjing University of Aeronautics and Astronautics,2015(in Chinese).
袁银峰.全珊瑚海水混凝土的配合比设计和基本性能[D].南京:南京航空航天大学,2015.
12 Zi M, Liu K Y, Liu S. et al. Study on the basic properties of coral sand used as fine aggregate[J].The World of Building Materials,2015,36(5):11(in Chinese).
紫民,刘旷怡,刘松,等.珊瑚礁砂细骨料基本性能研究[J].建材世界,2015,36(5):11.
13 Ding S, Zhang G Z, Chen F X, et al. Coral sand concrete preparation technology research[J].The World of Building Materials,2016,37(2):15(in Chinese).
丁沙,张国志,陈飞翔,等.珊瑚砂混凝土配制技术研究[J].建材世界,2016,37(2):15.
14 Han C. Experimental research on the fundamental mechanical beha-vior of seawater coral concrete[D].Nanning:Guangxi University,2011(in Chinese).
韩超.海水拌养珊瑚骨料混凝土基本力学性能试验研究[D].南宁:广西大学,2011.
15 Mrema A L, Bungara S H. Achieving high strength high perfor-mance concrete from coral-limestone aggregates using ordinary Portland cement, fly ash and superplasticizer[C]//6th International Conference on Structural Engineering, Mechanics and Computation. Boca Raton, Florida: CRC Press/Balkema,2016:1380.
16 Peng Z Q, Peng S, Li D, et al. Experimental research on mechanical performance of inorganic polymer coral sand concrete[J].Journal of Wuhan University of Technology,2016,38(11):92(in Chinese).
彭自强,彭胜,李达,等.无机聚合物珊瑚礁砂混凝土基本力学性能试验研究[J].武汉理工大学学报,2016,38(11):92.
17 Arumugam R A, Ranamurthy K. Study of compressive strength characteristics of coral aggregate concrete[J].Magazine of Concrete Research,1996,48(9):141.
18 Zhao Y L, Han C, Zhang S Z, et al. Experimental study on the compression age strength of seawater coral concrete[J].Concrete,2011(2):43(in Chinese).
赵艳林,韩超,张栓柱,等.海水拌养珊瑚骨料混凝土抗压龄期强度试验研究[J].混凝土,2011(2):43.
19 Da Bo, Yu Hongfa, Ma Haiyan, et al. Experimental investigation of whole stress-strain curves of coral concrete[J].Construction and Building Materials,2016,122:81.
20 Mi R J, Yu H F, Ma H Y, et al. Experimental research on the mechanical properties of full coral seawater concrete[J].Marine Engineering,2016,34(4):47(in Chinese).
糜人杰,余红发,麻海盐,等.全珊瑚海水混凝土力学性能试验研究[J].海洋工程,2016,34(4):47.
21 Gao Y, Wei Z B, Sun X. Experimental research on basic mechanical properties of coral aggregate concrete[J].Journal of Naval University of Engineering,2017,29(1):64(in Chinese).
高屹,韦灼彬,孙潇.珊瑚骨料混凝土基本力学性能试验研究[J].海军工程大学学报,2017,29(1):64.
22 Zhou J. Experimental study on preparation technology and physical mechanical properties of coral concrete[D].Nanjing:Hohai University,2015(in Chinese).
周杰.珊瑚骨料混凝土制备技术与物理力学性能试验研究[D].南京:河海大学,2015.
23 Wang L, Zhao Y L. The comparison of Coral concrete and other light weight aggregate concrete on mechanics performance[J].Advanced Materials Research,2012,446:3369.
24 Wang L, Yi J, Deng X L, et al. Study on mechanical property and damage morphology analysis of coral aggregate concrete with fiber[J].Journal of Henan Polytechnic University (Natural science),2016,35(5):713(in Chinese).
王磊,易金,邓雪莲,等.纤维增强珊瑚骨料混凝土的力学性能研究及破坏形态分析[J].河南理工大学学报(自然科学版),2016,35(5):713.
25 Wang L, Xiong Z Q, Liu C P, et al. Mechanical property tests of coral concrete with polypropylene fiber[J].Concrete,2014(7):96(in Chinese).
王磊,熊祖菁,刘存鹏,等.掺入聚丙烯纤维珊瑚骨料混凝土的力学性能研究[J].混凝土,2014(7):96.
26 Chen F X, Zhang G Z, Ding S, et al. Experimental research on the properties of coral sand concrete[J].Construction and Cement Pro-ducts,2016(7):16(in Chinese).
陈飞翔,张国志,丁沙,等.珊瑚砂混凝土性能试验研究[J].混凝土与水泥制品,2016(7):16.
27 Cheng S K, Shui Z H, Sun T, et al. Effect of fly ash,blast furnace slag and metakaolin on mechanical properties and durability of coral concrete[J].Applied Clay Science,2017,141:111.
28 Zhang Z H, Sang Z Q, Zhang L Y, et al. Experimental research on durability of concrete made by seawater and sea-sand[J].Advanced Materials Research,2013,641-642:385.
29 Cheng S K, Shui Z H, Yu R, et al. Multiple influences of internal curing and supplementary cementitious materials on the shrinkage and microstructure development of reefs aggregate concrete[J].Construction and Building Materials,2017,155:522.
30 Liu J M, Ou Z W, Mo J C, et al. Effectiveness of saturated coral aggregate and shrinkage reducing admixture on the autogenous shrin-kage of ultrahigh performance concrete[J].Advances in Materials Science and Engineering,2017,DOI:10.1155/2017/2703264.
31 Liang Y B, Lu B, Huang S J. On the tropical environment and the concrete for marine engineering[J].Ocean Technology,1995,14(2):58(in Chinese).
梁元博,卢博,黄韶健.热带海洋环境与海工混凝土[J].海洋技术,1995,14(2):58.
32 Saeid K, Hazizan M A, Abolghasem D, et al. The corrosion investigation of rebar embedded in the fibers reinforced concrete[J].Construction and Building Materials,2012,35:564.
33 Yu H F, Da B, Ma H Y, et al. Durability of concrete structures in tropical atoll environment[J].Ocean Engineering,2017,135:1.
34 Da B, Yu H F, Ma H Y, et al. Factors influencing durability of coral concrete structure in the South China Sea[J].Journal of the Chinese Ceramic Society,2016,44(2):253(in Chinese).
达波,余红发,麻海燕,等.南海海域珊瑚骨料混凝土结构的耐久性影响因素[J].硅酸盐学报,2016,44(2):253.
35 沈晓冬,李宗津.海洋工程水泥与混凝土材料[M].北京:化学工业出版社,2016.
36 Arnon B, Shin-ichi I, Konstantin K. Prevention of autogenous shrinkage in high-strength concrete by internal curing using wet lightweight aggregates[J].Cement and Concrete Research,2001,31:1587.
37 Da B, Yu H F, Ma H Y, et al. Chloride diffusion study of coral concrete in a marine environment[J].Construction and Building Mate-rials,2016,123:47.
38 Dou X M, Yu H F, Ma H Y. Experiment on chloride diffusion coefficient of coral concrete exposed to marine environment[J].The Ocean Engineering,2017,35(1):129(in Chinese).
窦雪梅,余红发,麻海燕,等.珊瑚骨料混凝土在海洋环境中氯离子扩散实验[J].海洋工程,2017,35(1):129.
39 Manu S, Menashi C, Jan O. Differentiating seawater and groundwater sulfate attack in Portland cement mortars[J].Cement and Concrete Research,2006,36:2132.
40 Tang J W, Cheng H, Zhang Q B, et al. Development of properties and microstructure of concrete with coral reef sand under sulphate attack and drying-wetting cycles[J].Construction and Building Materials,2018,165:647.
41 McNeil K, Kang T H K. Recycled Concrete Aggregates: A Review[J].International Journal of Concrete Structures and Materials,2013,7(1):61.
42 Liu J M, Ou Z W, Peng W, et al. Literature Review of Coral Concrete[J].Arabian Journal for Science and Engineering,2017,4:1.
43 Wang Q K, Li P, Tian Y P, et al. Mechanical properties and microstructure of Portland cement concrete prepared with coral reef sand[J].Journal of Wuhan University of Technology-Materials Science Edition,2016,31(5):906.
44 Yu H B, Sun Z X, Tang C. Physical and mechanical properties of coral sand in the Nansha islands[J].Marine Science Bulletin,2006,8(2):31.
45 Zhang S Z. Fatigue properties and microscopic mechanism of coral concrete[D].Nanning: Guangxi University,2012(in Chinese).
张栓柱.珊瑚骨料混凝土的疲劳特性及微观机理研究[D].南宁:广西大学,2012.
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