微纳技术在泡沫混凝土中的应用进展*

doi:10.11896/j.issn.1005-023X.2017.03.014

《材料导报》期刊社

2017, Vol. 31

Issue (3): 80-85 https://doi.org/10.11896/j.issn.1005-023X.2017.03.014

材料综述

微纳技术在泡沫混凝土中的应用进展^*

刘晓英, 肖玉, 彭家惠

重庆大学材料科学与工程学院,重庆400045;

Progress of Micro/Nanotechnology Applied in Foamed Concrete

LIU Xiaoying, XIAO Yu, PENG Jiahui

College of Materials Science and Engineering, Chongqing University, Chongqing 400045;

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摘要微纳技术可从多方面提升泡沫混凝土的性能,使二者性能达到完美结合。从泡沫混凝土气孔结构、泡沫混凝土强度、发泡催化剂以及泡沫混凝土电磁屏蔽效应4个方面综述了近年来微纳技术在泡沫混凝土中的应用,分析并展望了泡沫混凝土的前沿技术。

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关键词: 微纳技术泡沫混凝土表征技术纳米纤维电磁屏蔽

Abstract: Application of micro/nanotechnology in foam concrete can enhance the performance of foam concrete in diverse aspects, aiming at a synergetic combination of their intrinsic properties. This review addressed the applications of micro/nanotechnology in foam concrete in recent years and analyzed the cutting-edge technology of foam concrete from four main aspects, involving advanced characterization nanotechnology for pore structures, nanofibers-strengthened foam concrete, carbon nanotube (CNTs)-modified cement-base materials, nanocatalysts for preparing novel foaming agent and the electromagnetic shield effect of nanomaterials-embedded foam concrete.

Key words: micro/nanotechnology foam concrete characterization techniques nano-fibers electromagnetic shielding

出版日期: 2017-02-10 发布日期: 2018-05-02

ZTFLH:

TU528.2

基金资助: *重庆市科研创新项目(YB16014)

作者简介: 刘晓英:女,1985年生,博士研究生,研究方向为建筑功能材料 E-mail:liuxiaoying0202@foxmail.com 彭家惠:通讯作者,男,1962年生,博士,教授,研究方向为建筑功能材料 E-mail:pengjh@cqu.edu.cn

引用本文:

刘晓英, 肖玉, 彭家惠. 微纳技术在泡沫混凝土中的应用进展^*[J]. 《材料导报》期刊社, 2017, 31(3): 80-85.
LIU Xiaoying, XIAO Yu, PENG Jiahui. Progress of Micro/Nanotechnology Applied in Foamed Concrete. Materials Reports, 2017, 31(3): 80-85.

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http://www.mater-rep.com/CN/10.11896/j.issn.1005-023X.2017.03.014 或 http://www.mater-rep.com/CN/Y2017/V31/I3/80

1 Cheng Zhiyin. The preparation , property and development prospect of foam concrete[J]. Fly Ash,2015,4(3):43(in Chinese).
程志寅.泡沫混凝土的制备、性能与发展前景[J].粉煤灰,2015,4(3):43.
2 Amran Y H Mugahed,Farzadnia Nima,Abang Ali A A. Properties and applications of foamed concrete: A review[J]. Construction Building Mater,2015,101:990.
3 庞超明,王少华. 泡沫混凝土孔结构的表征及其对性能的影响[J/OL]. 建筑材料学报, http://www.cnki.net＼kcms/detail/31.1764.TU.20160302.1440020 html.
4 Wang Lijuan,Chen Yuan,Du Gaoxiang. Influence mechanism of microstructure of foam concrete on macroscopic propersities[J]. China Powder Sci Technol,2015,21(5):63(in Chinese).
王丽娟,陈缘,杜高翔.泡沫混凝土微观结构对宏观性能的影响机理[J].中国粉体技术,2015,21(5):63.
5 Zhang Xin,Ye Jianfeng,Zhou Haibing,et al. Research on preparation of ultra-light and hydroghobic foam concrete by chemical foaming[J]. New Building Mater,2013,40(3):49(in Chinese).
张欣,叶剑锋,周海兵,等.化学发泡制备超轻憎水泡沫混凝土研究[J].新型建筑材料,2013,40(3):49.
6 Hang Meiyan,Kong Fanlong,Zhang Peiyu. Research on influence facter of foam concrete in chemical method[J]. China Concr Cem Products,2015(2):62(in Chinese).
杭美艳,孔凡龙,张培育.化学法制备泡沫混凝土影响因素试验研究[J].混凝土与水泥制品,2015(2):62.
7 Chen Zhichun,Li Yingquan,Hu Shikai,et al. Reasearch on factors influencing the material properties of chemical foamed concrete[J]. J Xuzhou Institute of Technology: Nat Sci Ed,2014(2):63(in Chinese).
陈志纯,李应权,扈士凯,等.化学发泡泡沫混凝土材料性能的影响因素[J].徐州工程学院学报:自然科学版,2014(2):63.
8 Nambiar E K Kunhanandan,Ramamurthy K. Air-void characterisa-tion of foam concrete[J]. Cem Concr Res,2007,37(2):221.
9 Kearsley E P,Wainwright P J. Porosity and permeability of foamed concrete[J]. Cem Concr Res,2001,31(5):805.
10 Kearsley E P,Wainwright P J. The effect of porosity on the strength of foamed concrete[J]. Cem Concr Res,2002,32(2):233.
11 Nambiar E K Kunhanandan,Ramamurthy K. Sorption characteristics of foam concrete[J]. Cem Concr Res,2007,37(9):1341.
12 Sugama T,Brothers L E,de Putte T R Van. Air-foamed calcium aluminate phosphate cement for geothermal wells[J]. Cem Concr Compos,2005,27(7-8):758.
13 Tanaçan Leyla,Ersoy Halit YaŞa,Arpacgˇo U＇luümit. Effect of high temperature and cooling conditions on aerated concrete properties[J]. Construction Building Mater,2009,23(3):1240.
14 Qiu Junfu,Sun Guifang,Wang Yongkui,et al. Study on toughing mechanism of foam concrete with nano-fiber[J]. New Building Mater,2015,42(12):37(in Chinese).
邱军付,孙桂芳,王永魁,等.纳米纤维增韧泡沫混凝土的机理研究[J].新型建筑材料,2015,42(12):37.
15 Wang Qing,Wu Taojun,Qiu Linge,et al. Effect on hollow glass microshpere on performance of foam concrete[J]. Concrete,2014(2):71(in Chinese).
王晴,吴陶俊,邱琳格,等.空心玻璃微珠对泡沫混凝土性能的影响[J].混凝土,2014(2):71.
16 Wang Jinyan. Research on regenerated broken brick concrete hollow blocks with polystyrene particles[J]. Heilongjiang Sci Technol Information,2016(6):258(in Chinese).
王金燕.添加聚苯颗粒的再生碎砖混凝土空心砌块的试验研究[J].黑龙江科技信息,2016(6):258.
17 Long Zhiqin,Wang Zhigang. Research on performance of carbon fiber reinforced concrete[J]. Light Ind Sci Technol,2016(4):21(in Chinese).
龙志勤,王志刚.碳纤维掺量增强泡沫混凝土性能试验研究[J].轻工科技,2016(4):21.
18 Yang Kang,Wang Delin,Yu Chengcheng,et al. Foam concrete mised with rice husk ash and its development analysis[J]. Sichuan Building Mater,2014(3):25(in Chinese).
杨康,王德玲,喻成成,等.掺入稻壳灰的泡沫混凝土及其发展分析[J].四川建材,2014(3):25.
19 Wu Xiaoyan,Liu Hongfei,Zhang Cheng. Study on improving the compressive strength of foamed concrete with rice stem[J]. China Concr Cem Products,2014(9):56(in Chinese).
吴晓艳,刘红飞,张程,等.稻杆纤维对改善泡沫混凝土抗压强度的研究[J].混凝土与水泥制品,2014(9):56.
20 Corinaldesi Valeria,Nardinocchi Alessandro. Influence of type of fibers on the properties of high performance cement-based composites[J]. Construction Building Mater,2016,107:321.
21 Cui Hongzhi,Yang Jianming,Lin Jiongzeng. Reasearch progress on carbon nanotubes dispersion techniques and CNTs-reinforced cement-based materials[J]. Mater Rev: Rev,2016,30(2):91(in Chinese).
崔宏志,杨嘉明,林炅增.碳纳米管分散技术及碳纳米管-水泥基复合材料研究进展[J].材料导报:综述篇,2016,30(2):91.
22 Huiskes D M A,Keulen A,Yu Q L,et al. Design and performance evaluation of ultra-lightweight geopolymer concrete[J]. Mater Design,2016,89:516.
23 Güneyisi Erhan,Gesoglu Mehmet,Azez Oday Ali,et al. Effect of nano silica on the workability of self-compacting concretes having untreated and surface treated lightweight aggregates[J]. Construction Building Mater,2016,115:371.
24 Gomez-Zamorano L Y,Vega-Cordero E,Struble L. Composite geopolymers of metakaolin and geothermal nanosilica waste[J]. Construction Building Mater,2016,115:269.
25 Lei Tuanjie,Li Haoran,Geng Fei,et al. Preparation and study on new tpe concrete foaming agent[J]. New Building Mater,2013,40(12):93(in Chinese).
雷团结,李浩然,耿飞,等.新型泡沫混凝土发泡剂的制备与性能研究[J].新型建筑材料,2013,40(12):93.
26 Hu Gao,Jia Xingwen. Research on application of the catalyst in hydrogen peroxide foaming lightweight foam concrete[J]. Building Block Block Construction,2015(5):41(in Chinese).
胡皞,贾兴文.催化剂在双氧水发泡超轻泡沫混凝土中的应用研究[J].建筑砌块与砌块建筑,2015(5):41.
27 Du Lianxiang,Folliard Kevin J. Mechanisms of air entrainment in concrete[J]. Cem Concr Res,2005,35(8):1463.
28 Jones M R,McCarthy A. Heat of hydration in foamed concrete: Effect of mix constituents and plastic density[J]. Cem Concr Res,2006,36(6):1032.
29 Sauceau Martial,Fages Jacques,Common Audrey,et al. New challenges in polymer foaming: A review of extrusion processes assisted by supercritical carbon dioxide[J]. Prog Polym Sci,2011,36(6):749.
30 Greco A,Maffezzoli A,Manni O. Development of polymeric foams from recycled polyethylene and recycled gypsum[J]. Polym Degradation Stability,2005,90(2):256.
31 Pedersen K,Jensen A,Skjothrasmussen M,et al. A review of the interference of carbon containing fly ash with air entrainment in concrete[J]. Prog Energy Combustion Sci,2008,34(2):135.
32 Leung Siu N,Wong Anson,Wang Lilac Cuiling,et al. Mechanism of extensional stress-induced cell formation in polymeric foaming processes with the presence of nucleating agents[J]. J Supercritical Fluids,2012,63:187.
33 Cambronero L E G,Ruiz-Roman J M,Corpas F A,et al. Manufactu-ring of Al-Mg-Si alloy foam using calcium carbonate as foaming agent[J]. J Mater Processing Technol,2009,209(4):1803.
34 Faure S,Volland S,Crouzet Q,et al. Synthesis of new fluorinated foaming particles[J]. Colloids Surfaces A: Physicochem Eng Aspects,2011,382(1-3):139.
35 Golpazir Iman,Ghalandarzadeh Abbas,Jafari Mohammad Kazem,et al. Dynamic properties of polyurethane foam-sand mixtures using cyclic triaxial tests[J]. Construction Building Mater,2016,118:104.
36 Ducman V,Korat L. Characterization of geopolymer fly-ash based foams obtained with the addition of Al powder or H₂O₂ as foaming agents[J]. Mater Characterization,2016,113:207.
37 Naden Benjamin J. Competitive adsorption of surfactant foaming agents to nanoclays added to cement foams for enhanced strength[J]. Mater Structures,2015,49(5):1667.
38 Li Bo,Zhang Yanqing,Zhang Xiong. Study on electromagnetic shielding foam concrete[J]. Mater Rev: Res,2014,28(6):119(in Chinese).
李博,张晏清,张雄.电磁屏蔽泡沫混凝土的性能研究[J].材料导报:研究篇,2014,28(6):119.
39 Zhang Shuai,Luo Jianlin,Li Qiuyi,et al. Physics-mechanical and damping performance of carbon nanotubes modified foamed cocrete[J]. Concrete,2015(4):78(in Chinese).
张帅,罗健林,李秋义,等.碳纳米管改性泡沫混凝土物理力学与阻尼性能[J].混凝土,2015(4):78.
40 Jia Xingwen,Zhang Yajie,Qian Jueshi,et al. Microwave abosorbing property of the graphite foam concrete[J]. J Funct Mater,2012,43(17):2397(in Chinese).
贾兴文,张亚杰,钱觉时,等.石墨泡沫混凝土的吸波性能研究[J].功能材料,2012,43(17):2397.
41 Zhu Wangfa,Zhang Yehong,Su Ying. Study progress and enginee-ring application of foamed concrete in china[J]. Mater Rev,2013,27(S1):317(in Chinese).
竺万发,张业红,苏英,等.我国泡沫混凝土的研究进展及工程应用[J].材料导报,2013,27(专辑21):317.

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