[1]龙武剑,周波,梁沛坚,等.颗粒堆积模型在混凝土中的应用[J].深圳大学学报理工版,2017,34(1):63-74.[doi:10.3724/SP.J.1249.2017.01063]
 Long Wujian,Zhou Bo,Liang Peijian,et al.Application of particle packing model in concrete[J].Journal of Shenzhen University Science and Engineering,2017,34(1):63-74.[doi:10.3724/SP.J.1249.2017.01063]
点击复制

颗粒堆积模型在混凝土中的应用()
分享到:

《深圳大学学报理工版》[ISSN:1000-2618/CN:44-1401/N]

卷:
第34卷
期数:
2017年第1期
页码:
63-74
栏目:
土木建筑工程
出版日期:
2017-01-09

文章信息/Info

Title:
Application of particle packing model in concrete
文章编号:
201701009
作者:
龙武剑周波梁沛坚孙柔嘉
深圳大学土木工程学院,广东省滨海土木工程耐久性重点实验室,广东深圳 518060
Author(s):
Long Wujian Zhou Bo Liang Peijian and Sun Roujia
Guangdong Provincial Key Laboratory of Durability for Marine Civil Engineering, College of Civil Engineering, Shenzhen University, Shenzhen 518060, Guangdong Province, P.R.China
关键词:
混凝土颗粒堆积模型堆积密实度颗粒体系松动效应附壁效应空隙率配合比
Keywords:
concrete particle packing model packing density particle system loosening effect wall effect void ratio mix proportions
分类号:
TU 528
DOI:
10.3724/SP.J.1249.2017.01063
文献标志码:
A
摘要:
评述颗粒堆积模型的基本理论、发展及其最新应用. 对比分析多种颗粒堆积模型间的差异,指出颗粒堆积模型的主要优点、局限性及其在复合颗粒体系材料领域中的应用范围. 分析表明,利用颗粒堆积模型优化计算混凝土的堆积密实度,可以降低复合颗粒体系间的空隙体积,使颗粒系统达到最紧密堆积状态,减少混凝土中胶凝材料的用量,实现低胶凝材料用量绿色混凝土优化设计.
Abstract:
The main advantages and limitations of particle packing models, as well as their applications in the field of composite particle systems are pointed out by comparing and analyzing the differences among various particle packing models. The analysis show that, in order to reduce the void volume and achieve the most compact accumulation state of the composite particle system, the particle packing model can be used to calculate the packing density, thus the volume of cementitious materials in the concrete can be reduced and the optimal design of low binder green concrete can be realized.

参考文献/References:

[1] Gao Tianming, Shen Lei, Shen Ming, et al. Analysis on differences of carbon dioxide emission from cement production and their major determinants[J]. Journal of Cleaner Production, 2015, 103(23): 160-170.
[2] Suhendro B. Toward green concrete for better sustainable environment[J]. Procedia Engineering, 2014, 95(95): 305-320.
[3] Yoshioka K, Obata D, Nanjo H, et al. New ecological concrete that reduces CO2 emissions below zero level new method for CO2 capture and storage[J]. Energy Procedia, 2013, 37: 6018-6025.
[4] HiguchiI T, Morioka M, Yoshioka I, et al. Development of a new ecological concrete with CO2 emissions below zero[J]. Construction and Building Materials, 2014, 67: 338-343.
[5] Yu R, Spesz P, Brouwers H J H. Development of an eco-friendly ultra-high performance concrete (UHPC) with efficient cement and mineral admixtures uses[J]. Cement and Concrete Composites, 2015, 55(1): 383-394.
[6] Westman A E R, Hugill H R. The packing of particles[J]. Journal of the American Ceramic Society ,1930, 13(10): 767-779.
[7] Andreason A H M. Uber die beziehung zwischen kornabstufung und zwischenraum in produckten aus losen kornern[J]. Kolloid Z, 1930, 50(3): 217-228.
[8] Dinger D R, Funk J E. Particle packing: review of packing theories[C]// Proceeding of Fine Particle Society 13th Annual Meeting. Chicago, USA: American Ceramic Society, 1982.
[9] Furnas C C. Grading aggregates I-mathematical relations for beds of broken solids of maximum density[J]. Industrial and Engineering Chemistry, 1931, 23(9): 1052-1028.
[10] Toufar W, Born E K M. Berechnung der packungsdichte von korngemischen[J]. Aufbereitungs-Technik, 1977, 18(11): 603-608.
[11] Am R B, Goff P L. Effet de paroi dans les empilements désordonnés desphères et application à la porosité de mélanges binaries[J]. Powder Technology, 1968,1(5): 281-290.
[12] Goltermann P, Johansen V, Palbol L. Packing of aggregates: an alternative tool to determine the optimal aggregate mix[J]. American Concrete Institute Materials Journal, 1997, 94(5):435-443.
[13] Chan K W, Kwan A K H. Evaluation of particle packing models by comparing with published test results[J]. Particuology, 2014, 16(5): 108-115.
[14] Stovall T, Bull M. Linear packing density model of grain mixtures[J]. Powder Technology, 1986, 48(1): 1-12.
[15] 王海兵,刘咏,黄伯云, 等. 粉末颗粒线性堆积密实度模型的改进[J].粉末冶金技术, 2001, 19(4):208-211.
Wang Haibing, Liu Yong, Huang Boyun, et al. Improvement of linear packing density model of powder particles[J]. Powder Metallurgy Technology, 2001, 19(4):208-211.(in Chinese)
[16] Dewar J D. Computer modelling of concrete mixtures[M]. London: Routledge, 1998.
[17] Larrard F. Concrete mixture proportioning: a scientific approach[M]. London: Routledge, 1999.
[18] Kwan A K H. A 3-parameter particle packing model incorporating the wedging effect [J]. Powder Technology, 2013, 237(3): 172-179.
[19] Wong V, Kwan A K H. A 3-parameter model for packing density prediction of ternary mixes of spherical particles[J]. Powder Technology, 2014, 238(1): 357-367.
[20] Kwan A K H, Wong V, Fung W W S. A 3-parameter packing density model for angular rock aggregate particles[J]. Powder Technology, 2015, 239(2): 154-162.
[21] Knop Y, Peled A. Packing density modeling of blended cement with limestone having different particle size[J]. Construction and Building Materials, 2016, 102: 44-50.
[22] Wen Yuanyun, Liu Malin, Liu Bing, et al. Comparative study on the characterization method of particle mixing index using DEM method[J]. Procedia Engineering, 2015, 102: 1630-1642.
[23] Fan Haojie, Mei Dengfei, Tian Fengguo, et al. DEM simulation of different particle ejection mechanisms in a fluidized bed with and without cohesive interparticle forces[J]. Powder Technology, 2016, 288: 228-240.
[24] Cleary P W. A multiscale method for including fine particle effects in DEM models of grinding mills[J]. Minerals Engineering, 2015, 84: 88-99.
[25] 时金广.基于堆积模型的胶凝材料颗粒系统的离散单元法分析仿真研究[D]. 深圳:深圳大学,2016.
Shi Jinguang. The research of discrete element method simulation for particle packing-based cementitious materials[D]. Shenzhen: Shenzhen University, 2016.(in Chinese)
[26] Johansen V, Andersen P J. Particle packing and concrete properties[J]. Materials Science of Concrete , 1989, 2: 111-146.
[27] Jones M R, Zheng L, Newlands M D. Comparison of particle packing models for proportioning concrete constituents for minimum voids ratio[J]. Materials and Structures, 2002, 35(5): 301-309.
[28] Standish N, Borger D E. The porosity of particulate mixtures[J]. Powder Technology, 1979, 22(1): 121-125.
[29] Fennis S A A M. Design of ecological concrete by particle packing optimization[D]. Netherlands: Delft University of Technology, 2011.
[30] Kwan A K H, Wong H H C. Packing density of cementitious materials: packing and flow of OPC+PFA+CSF[J]. Materials and Structures, 2008, 41: 773-784.
[31] Gallias J L, Kara-Ali R, Bigas J P. The effect of fine mineral admixtures on water requirement of cement pastes[J]. Cement Concrete Composites, 2000, 30(10): 1543-1549.
[32] Peng Yanzhou, Hu Shuguang, Ding Qingjun. Dense packing properties of mineral admixtures in cementitious material[J]. Particuology, 2009, 7(5): 399-402.
[33] Knop Y, Peled A. Setting behavior of blended cement with limestone: influence of particle size and content[J].Materials and Structures, 2016, 49(1): 439-452.
[34] Felekogˇlu B. Effects of PSD and surface morphology of micro-aggregates on admixture requirement and mechanical performance of micro-concrete[J]. Cement Concrete Composites, 2007, 29(6): 481-489.
[35] Knop Y, Peled A, Cohen R. Influence of limestone particle size distributions and contents on blended cement properties[J]. Construction and Building Materials, 2014, 71: 26-34.
[36] 牛全林,冯乃谦,杨静.矿渣超细粉作用机理的探讨[J].建筑材料学报, 2002, 5(1):84-89.
Niu Quanlin, Feng Naiqian, Yang Jing. Discussion on the action mechanism of superfine slag powder[J]. Journal of Building Materials, 2002, 5(1):84-89.(in Chinese)
[37] Fayed M E, Otten L. Handbook of powder science and technology [M]. New York: Chapman and William Hall, 1997.
[38] 陈延信,吴锋,胡亚茹. 提高粉体堆积密实度的理论与实验研究[J]. 煤炭转化, 2012(1): 40-43.
Chen Yanxin, Wu Feng, Hu Yaru. Theoretical and experimental study on increasing the bulk density of powder[J]. Coal Conversion, 2012(1): 40-43.(in Chinese)
[39] 龙广成,谢友均,王新友.矿物掺合料对新拌水泥浆体密实性能的影响[J].建筑材料学报, 2002, 5(1): 21-25.
Long Guangcheng, Xie Youjun, Wang Xinyou. Effect of mineral admixtures on the compaction property of fresh cement paste[J]. Journal of Building Materials, 2002, 5(1):21-25.(in Chinese)
[40] Binici H, Aksogan O, Cagatay I H, et al. The effect of particle size distribution on the properties of blended cements incorporating GGBFS and natural pozzolan (NP) [J]. Powder Technology, 2007, 177(3): 140-147.
[41] Givi A N, Rashid S A, Aziz F N A, et al. Assessment of the effects of rice husk ash particle size on strength, water permeability and workability of binary blended concrete[J]. Construction and Building Materials, 2008, 24(11): 2145-2150.
[42] Kwan A K H, Chen J J. Adding fly ash microsphere to improve packing density, flowability and strength of cement paste[J]. Powder Technology, 2013, 234:19-25.
[43] Kwan A K H, Li Y. Effects of fly ash microsphere on rheology, adhesiveness and strength of mortar[J]. Construction and Building Materials, 2013, 42: 137-45.
[44] Ghoddousi P, Javid A A S, Sobhani J. Effects of particle packing density on the stability and rheology of self-consolidating concrete containing mineral admixtures[J]. Construction and Materials, 2014, 53: 102-109.
[45] Nassim S, Mahfoud B. Composition of self compacting concrete (SCC) using the compressible packing model, the chinese method and the european standard[J]. Construction and Building Materials, 2013, 43: 382-328.
[46] 龚建清. 超高性能混凝土的级配效应研究[D]. 长沙:湖南大学, 2008.
Gong Jianqing. Study on the gradation effect of ultra high performance concrete[D]. Changsha: Hunan University, 2008.(in Chinese)
[47] 曹荣奎. 基于CPM模型和比强度法的超高性能混凝土配合比设计研究[D]. 长沙:湖南大学, 2008.
Cao Rongkui. Study on mix proportion design of ultra-high performance concrete based on CPM model and specific strength[D]. Changsha: Hunan University, 2008.(in Chinese)
[48] 聂晶. 基于可压缩堆积模型的水泥基复合材料性能研究[D]. 长沙:湖南大学, 2008.
Nie Jing. Study on performance of cement-based composite materials based on compressible packing model[D]. Changsha: Hunan University, 2008.(in Chinese)
[49] 李丙明. 低碱度钢渣配制复合胶凝材料研究[D]. 西安: 西安建筑科技大学, 2009.
Li Bingming. The study on preparing composite cementitious materials with low-alkalinity steel slag[D]. Xi’an: Xi’an University of Architecture and Technology, 2009.(in Chinese)
[50] 丑凯. 超高性能混凝土堆积密实度和火山灰效应量化研究[D]. 长沙:湖南大学, 2010.
Chou Kai. Quantitative analysis on packing density and pozzolanic effect of ultra-high performance concrete[D]. Changsha: Hunan University, 2010.(in Chinese)
[51] 何振伟. 持续应力下密封早龄期混凝土力学性能依时发展规律研究[D]. 北京:北京交通大学, 2013.
He Zhenwei. Development of mechanical properties of sealed concrete in early age under sustained stress action[D]. Beijing: Beijing Jiaotong University, 2013.(in Chinese)
[52] 陈瑾祥. 基于可压缩堆积模型的绿色混凝土材料性能研究[D]. 深圳: 深圳大学, 2015.
Chen Jinxiang. Compressible packing model based of green concrete[D]. Shenzhen: Shenzhen University, 2015.(in Chinese)

相似文献/References:

[1]张武满,巴恒静,高小建,等.重复载荷作用下矿渣混凝土的渗透性[J].深圳大学学报理工版,2007,24(4):352.
 ZHANG Wu-man,BA Heng-jing,GAO Xiao-jian,et al.Permeability of slag concrete under repeated loading[J].Journal of Shenzhen University Science and Engineering,2007,24(1):352.
[2]龙广成,邢锋,余志武,等.氯离子在混凝土中的沉积特性研究[J].深圳大学学报理工版,2008,25(2):117.
 LONG Guang-cheng,XING Feng,YU Zhi-wu,et al.Characteristics of chloride ion sedimentation in concrete[J].Journal of Shenzhen University Science and Engineering,2008,25(1):117.
[3]刘伟,邢锋,谢友均.矿物掺合料对混凝土毛细吸水性的影响[J].深圳大学学报理工版,2008,25(3):303.
 LIU Wei,XING Feng,and XIE You-jun.Influence of mineral admixture on the water sorptivity of concrete[J].Journal of Shenzhen University Science and Engineering,2008,25(1):303.
[4]杨文武,钱觉时,范英儒.混凝土早期收缩性能试验研究[J].深圳大学学报理工版,2009,26(1):81.
 YANG Wen-wu,QIAN Jue-shi,and FAN Ying-ru.Experimental research on early age shrinkage of concrete by eddy current method[J].Journal of Shenzhen University Science and Engineering,2009,26(1):81.
[5]李伟文,邢锋,严志亮,等.硫酸盐腐蚀环境下CFRP-混凝土界面性能研究[J].深圳大学学报理工版,2009,26(1):86.
 LI Wei-wen,XING Feng,YAN Zhi-liang,et al.Investigation on the mechanical behavior of adhesive bonded CFRP-concrete joints under the sulfate solution[J].Journal of Shenzhen University Science and Engineering,2009,26(1):86.
[6]戎志丹,孙伟,陈惠苏,等.超高性能水泥基材料的力学行为及机理分析[J].深圳大学学报理工版,2010,27(1):88.
 RONG Zhi-dan,SUN Wei,CHEN Hui-su,et al.Mechanical behaviors and microstructure mechanism analysis of ultra high performance cementitious composites[J].Journal of Shenzhen University Science and Engineering,2010,27(1):88.
[7]刘军,邢锋,董必钦,等.盐雾环境下氯离子在混凝土中的扩散[J].深圳大学学报理工版,2010,27(2):192.
 LIU Jun,XING Feng,DONG Bi-qin,et al.Diffusion of chloride ions into concrete in salt spray environment[J].Journal of Shenzhen University Science and Engineering,2010,27(1):192.
[8]张峰,蔡建军,李树忱,等.混凝土冻融损伤厚度的超声波检测[J].深圳大学学报理工版,2012,29(No.3(189-282)):207.[doi:10.3724/SP.J.1249.2012.03207]
 ZHANG Feng,CAI Jian-jun,LI Shu-chen,et al.Ultrasonic detection of freeze-thaw damage thickness of concrete[J].Journal of Shenzhen University Science and Engineering,2012,29(1):207.[doi:10.3724/SP.J.1249.2012.03207]
[9]刘鹏,余志武,王卫仑,等.自然环境湿度作用谱和混凝土内湿度响应谱[J].深圳大学学报理工版,2013,30(No.4(331-440)):356.[doi:10.3724/SP.J.1249.2013.04356]
 Liu Peng,Yu Zhiwu,Wang Weilun,et al.The action spectrum of air humidity in natural environment and the response spectrum of humidity of concrete[J].Journal of Shenzhen University Science and Engineering,2013,30(1):356.[doi:10.3724/SP.J.1249.2013.04356]
[10]邢锋,倪卓,汤皎宁,等.自修复混凝土系统的研究进展[J].深圳大学学报理工版,2013,30(No.5(441-550)):486.[doi:10.3724/SP.J.1249.2013.05486]
 Xing Feng,Ni Zhuo,Tang Jiaoning,et al.State-of-the-art for self-healing concrete[J].Journal of Shenzhen University Science and Engineering,2013,30(1):486.[doi:10.3724/SP.J.1249.2013.05486]

备注/Memo

备注/Memo:
Received:2016-08-29;Accepted:2016-11-20
Foundation:National Natural Science Foundation of China (51278306,51578341); Shenzhen Science and Technology Project (JCYJ20140418095735540)
Corresponding author:Associate professor Long Wujian. E-mail: longwj@szu.edu.cn
Citation:Long Wujian, Zhou Bo, Liang Peijian, et al. Application of particle packing model in concrete[J]. Journal of Shenzhen University Science and Engineering, 2017, 34(1): 63-74.(in Chinese)
基金项目:国家自然科学基金资助项目(51278306,51578341);深圳市科技计划资助项目(JCYJ20140418095735540)
作者简介:龙武剑(1977—),男,深圳大学副教授、博士. 研究方向:高性能混凝土材料设计及性能. E-mail: Longwj@szu.edu.cn
引文:龙武剑,周波,梁沛坚,等. 颗粒堆积模型在混凝土中的应用[J]. 深圳大学学报理工版,2017,34(1):63-74.
更新日期/Last Update: 2016-12-30