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材料导报  2018, Vol. 32 Issue (19): 3387-3393    https://doi.org/10.11896/j.issn.1005-023X.2018.19.013
  无机非金属及其复合材料 |
珊瑚骨料混凝土力学性能及耐久性能研究
苏丽1,牛荻涛1,2,罗大明1,2
1 西安建筑科技大学土木工程学院,西安 710055;
2 西安建筑科技大学省部共建 西部绿色建筑国家重点实验室,西安 710055
Research of Coral Aggregate Concrete on Mechanical Property and Durability
SU Li1, NIU Ditao1,2, LUO Daming1,2
1 School of Civil Engineering, Xi’an University of Architecture and Technology, Xi’an 710055;
2 State Key Laboratory of Green Building in Western China, Xi’an University of Architecture and Technology, Xi’an 710055
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摘要 随着南海岛礁的开发和建设,混凝土骨料的来源成为急需解决的问题之一。南海诸岛的地质结构大多为珊瑚岛礁,尝试采用珊瑚骨料代替普通骨料配制岛礁用混凝土,为此问题的解决提供了可能的途径。本文基于国内外已有的珊瑚骨料混凝土研究成果,综述了珊瑚骨料的基本特性、珊瑚骨料混凝土的力学和耐久性能以及矿物掺合料和纤维对珊瑚骨料混凝土的增强性能。文末简要讨论了今后珊瑚骨料混凝土的研究方向。
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苏丽
牛荻涛
罗大明
关键词:  珊瑚骨料混凝土  力学性能  耐久性能  增强性能    
Abstract: The development and construction of the South China Sea reefs exaggerate the gravity of local shortage of concrete aggregate sources. Most of the South China Sea islands have the geological structure of coral reefs, and the use of coral aggregate to replace ordinary aggregates for concrete preparation opens a plausible approach to the above mentioned problem. Based on the current worldwide research of coral aggregate concrete, this article reviews the basic characteristics of coral aggregate and mechanical properties and durability of coral aggregate concrete. It also describes the performances of coral aggregate concretes with mineral admixture or fiber reinforcements. The paper ends with a concise discussion upon the existing problems and the future research directions.
Key words:  coral aggregate concrete    mechanical property    durability    reinforced performance
               出版日期:  2018-10-10      发布日期:  2018-10-18
ZTFLH:  TU528  
基金资助: 国家自然科学基金重大项目(51590914);陕西省教育厅重点实验室科研计划项目(16JS056);陕西省自然科学基础研究计划项目(2017JQ5103)
作者简介:  苏丽:女,1990年生,博士研究生,主要从事混凝土结构耐久性方面的研究 E-mail:13629207839@163.com ;牛荻涛:通信作者,男,1963年生,教授,博士研究生导师,主要从事混凝土结构耐久性方面的研究 E-mail:niuditao@163.com
引用本文:    
苏丽, 牛荻涛, 罗大明. 珊瑚骨料混凝土力学性能及耐久性能研究[J]. 材料导报, 2018, 32(19): 3387-3393.
SU Li, NIU Ditao, LUO Daming. Research of Coral Aggregate Concrete on Mechanical Property and Durability. Materials Reports, 2018, 32(19): 3387-3393.
链接本文:  
http://www.mater-rep.com/CN/10.11896/j.issn.1005-023X.2018.19.013  或          http://www.mater-rep.com/CN/Y2018/V32/I19/3387
1 Chen Z L, Chen T Y, Qu X M. Feasibility study of the application for coral sand concrete[J].Ocean Engineering,1991(3):67(in Chinese).
陈兆林,陈天月,曲勋明.珊瑚礁砂混凝土的应用可行性研究[J].海洋工程,1991(3):67.
2 UFC 3-440-05N:Unified Facilities Criteria (UFC) Tropical Engineering[S].Hyattsville, MD 20781-1102: US Army Corps of Engineers,2004.
3 Howdyshell P A. The use of coral as an aggregate for portland cement concrete structures[R].USA: Army Construction Engineering Research Laboratory,1974.
4 Rick A E. Coral concrete at Bikini Atoll[J].Concrete International,1991,13(1):19.
5 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.
6 Wang Y G. The feasibility of coral concrete application in the port industry[J].Port and Waterway Engineering,1988(9):46(in Chinese).
王以贵.珊瑚混凝土在港工中应用的可行性[J].水运工程,1988(9):46.
7 Chen Z L, Sun G F, Tang X N, et al. Study on applications of concretes from coral reef sand mixed with seawater for patching-up in reef engineering[J].Coast Engineering,2008,27(4):60(in Chinese).
陈兆林,孙国峰,唐筱宁,等.岛礁工程海水拌养珊瑚礁、砂混凝土修补与应用研究[J].海岸工程,2008,27(4):60.
8 Sun Z X. Engineering properties of coral sands in Nansha islands[J].Tropic Oceanology,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 Wang F. Experimental and research on bearing capacity of coral-concrete filled steel tube column[D].Harbin: Harbin Institute of Technology,2013(in Chinese).
王芳.钢管珊瑚混凝土柱承载力试验和理论研究[D].哈尔滨:哈尔滨工业大学,2013.
10 Wang L, Zhao Y L, Lyu 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.
11 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.
12 Li L. Research on basic characteristics of coral concrete[D].Nanning: Guangxi University,2012(in Chinese).
李林.珊瑚混凝土的基本特性研究[D].南宁:广西大学,2012.
13 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(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(5):11.
14 Kolver K, Jensen O M. Internal curing of concrete-state-of-the-art report of RILEM Technical Committee 196-ICC[R].Bagneux: RILEM Publications SARL,2007.
15 Lo T Y, Cui H Z. Effect of porous lightweight aggregate on strength of concrete[J].Materials Letters,2004,58(6):916.
16 Bentz D P. Influence of internal curing using lightweight aggregates on interfacial transition zone percolation and chloride ingress in mortars[J].Cement & Concrete Composites,2009,31(5):285.
17 Ole Mejlhede Jensen, Per Freiesleben Hansen. Water-entrained cement-based materials: Ⅰ. Principles and theoretical background[J].Cement and Concrete Research,2001,31(4):647.
18 Ole Mejlhede Jensen, Per Freiesleben Hansen. Water-entrained cement-based materials: Ⅱ. Experimental observations[J].Cement and Concrete Research,2002,32(6):973.
19 Raoufi K, Schlitter J, Bentz D, et al. Parametric assessment of stress development and cracking in internally cured restrained mortars experiencing autogenous deformations and thermal loading[J].Advances in Civil Engineering,2011,2011(1687-8086):1.
20 Zheng X H, Zhang B S. Effect of pre-wetting degree on microstructure and strength of shale ceramsite concret[J].Materials Enginee-ring,2005(10):3(in Chinese).
郑秀华,张宝生.预湿程度对页岩陶粒混凝土显微结构及强度的影响[J].材料工程,2005(10):3.
21 Shao Y J. Strength index and statistical parameter of lightweight aggregate concrete[J].Industrial Construction,2007(37):82(in Chinese).
邵永健.轻骨料混凝土材料的强度指标及其统计参数[J].工业建筑,2007(37):82.
22 Chen F X, Zhang G Z, Ding S, et al. Experimental research on the properties of coral concrete[J].China Concrete 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.
23 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.海水拌养珊瑚混凝土抗压龄期强度试验研究[J].混凝土,2011(2):43.
24 Li Z X, Wei Z B, Shen J L. Application of relevance vector machine to prediction of compressive strength of coral concrete[J].Concrete,2016(7):1(in Chinese).
李仲欣,韦灼彬,沈锦林.相关向量机在珊瑚混凝土抗压强度预测中的应用[J].混凝土,2016(7):1.
25 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.
26 Mi R J, Yu H F, Ma H Y, et al. Study on the mechanical property of coral concrete[J].Ocean Engineering,2016,34(4):47(in Chinese).
糜人杰,余红发,麻海燕,等.全珊瑚骨料海水混凝土力学性能试验研究[J].海洋工程,2016,34(4):47.
27 Da B, Yu H F, Ma H Y, et al. Experimental research on whole stress-strain curves of coral aggregate seawater concrete under unia-xial compression[J].Journal of Building Structures,2017,38(1):144(in Chinese).
达波,余红发,麻海燕,等.全珊瑚海水混凝土单轴受压应力-应变全曲线试验研究[J].建筑结构学报,2017,38(1):144.
28 Wang Q, Li P, Tian Y, 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):996.
29 Lu B, Liang Y B. Experimental research on coral sea sand concrete Ⅰ[J].Marine Science Bulletin,1993(5):69(in Chinese).
卢博,梁元博.海水珊瑚砂混凝土的实验研究Ⅰ[J].海洋通报,1993(5):69.
30 Pan B Z, Wei Z B. Experimental study on effects to coral sand concrete compressive strength of raw marerials[J].Engineering Mecha-nics,2015,32(S1):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(S1):221.
31 Sun X, Wei Z B, Gao Y. Experimental study on the mixture ratio of coral aggregate concrete mixed with seawater[J].Sichuan Architecture,2016,36(1):204(in Chinese).
孙潇,韦灼彬,高屹.海水拌养珊瑚骨料混凝土配合比试验研究[J].四川建筑,2016,36(1):204.
32 Li L, Zhao Y L, Lyu H B, et al. Coral aggregate pre-wet on the mechanical properties of concrete[J].Concrete,2011(1):85(in Chinese).
李林,赵艳林,吕海波,等.珊瑚骨料预湿对混凝土力学性能的影响[J].混凝土,2011(1):85.
33 Arumugam R A, Ramamurthy K. Study of compressive strength characteristics of coral aggregate concrete[J].Magazine of Concrete Research,1996,48(176):141.
34 Wang L, Fan L. The strength characteristics and failure pattern analysis of coral detritus concrete[J].China Concrete and Cement Products,2015(1):1(in Chinese).
王磊,范蕾.珊瑚碎屑混凝土的强度特性及破坏形态分析[J].混凝土与水泥制品,2015(1):1.
35 Wanchai Yodsudjai, Nobuaki Otsuki, Takahiro Nishida, et al. Study on strength and durability of concrete using low quality coarse aggregate from circum-pacific region[C]∥27th Conference on Our World in Concrete & Structures. Singapore,2002:617.
36 Wattanachai P, Otsuki N, Saito T, et al. A study on chloride ion diffusivity of porous aggregate concretes and improvement method[J].Journal of Japan Society of Civil Engineers Ser E1,2009,65(1):30.
37 Kakooei S, Akil H M, Dolati A, et al. The corrosion investigation of rebar embedded in the fibers reinforced concrete[J].Construction & Building Materials,2012,35(10):564.
38 Kakooei S, Akil H M, Jamshidi M, et al. The effects of polypropy-lene fibers on the properties of reinforced concrete structures[J].Construction & Building Materials,2012,27(1):73.
39 Yu Q, Jiang Z C. Analysis on durability of a Xisha island sea-coral reef sand concrete[J].Construction Technology,2013(42):258(in Chinese).
余强,姜振春.浅析西沙某岛海水-珊瑚礁砂混凝土的耐久性问题[J].施工技术,2013(42):258.
40 Da B, Yu H, Ma H, et al. Chloride diffusion study of coral concrete in a marine environment[J].Construction & Building Materials,2016,123:47.
41 Dou X M, Yu H F, Ma H Y, et al. Surface chloride concentration profiles of coral concrete exposed to marine environment[J].Bulletin of the Chinese Ceramic Society,2016,35(9):2695(in Chinese).
窦雪梅,余红发,麻海燕,等.海洋环境下珊瑚混凝土的表面氯离子浓度规律[J].硅酸盐通报,2016,35(9):2695.
42 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.南海海域珊瑚混凝土结构的耐久性影响因素[J].硅酸盐学报,2016,44(2):253.
43 Wang F, Zha X X. Experimental and theoretical study on coral concrete filled steel tube[J].Journal of Building Structures,2013,34(s1):288(in Chinese).
王芳,查晓雄.钢管珊瑚混凝土试验和理论研究[J].建筑结构学报,2013,34(s1):288.
44 Chen Z L, Tang X N, Sun G F, et al. Research on durability and application of seawater concrete[J].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.
45 Chen Y Z, Ma Z Q, Sun T, et al. Effect of mineral admixtures on coral sand concrete[J].The World of Building Materials,2016,37(2):11(in Chinese).
陈友治,马章强,孙涛,等.矿物掺合料对珊瑚砂混凝土性能的影响[J].建材世界,2016,37(2):11.
46 Sun B L. Mechanical property test of silica fume reinforced coral concrete[J].Low Temperature Architecture Technology,2014,36(8):12(in Chinese).
孙宝来.硅灰增强珊瑚混凝土力学性能试验研究[J].低温建筑技术,2014,36(8):12.
47 Liu C P, Deng X L, Fang Y S, et al. Effect of silica fume on sisal fiber reinforced coral concrete[J].Low Temperature Architecture Technology,2016,38(3):1(in Chinese).
刘存鹏,邓雪莲,方滢顺,等.硅灰对剑麻纤维珊瑚混凝土的影响[J].低温建筑技术,2016,38(3):1.
48 Cheng S, Shui Z, Sun T, et al. Effects of fly ash, blast furnace slag and metakaolin on mechanical properties and durability of coral sand concrete[J].Applied Clay Science,2017,141:111.
49 Wang L, Liu C P, Xiong Z J. Study test on mechanical property of sisal fiber reinforced coral concrete[J].Journal of Henan Polytechnic University (Natural Science),2014,33(6):826(in Chinese).
王磊,刘存鹏,熊祖菁.剑麻纤维增强珊瑚混凝土力学性能试验研究[J].河南理工大学学报:自然科学版,2014,33(6):826.
50 Wang L, Xiong Z J, Liu C P, et al. Mechanical property tests of co-ral 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混凝土的力学性能研究[J].混凝土,2014(7):96.
51 Wang L, Wang G X, Deng X L. Research on the mechanical properties of different content carbon fiber coral concrete[J].China Rural Water and Hydropower,2014(9):148(in Chinese).
王磊,王国旭,邓雪莲.不同掺量碳纤维珊瑚混凝土力学性能试验研究[J].中国农村水利水电,2014(9):148.
52 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.
53 Liu C P, Liu C X, Deng X L, et al. Microstructure test of sisal fiber reinforced coral concrete[J].Low Temperature Architecture Technology,2016,38(4):7(in Chinese).
刘存鹏,刘存翔,邓雪莲,等.剑麻纤维珊瑚混凝土微观结构研究[J].低温建筑技术,2016,38(4):7.
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