[an error occurred while processing this directive] [an error occurred while processing this directive] [an error occurred while processing this directive]
[an error occurred while processing this directive]

黄金科学技术 >

2021 , Vol. 29 >Issue 2: 275 - 286

DOI: https://doi.org/10.11872/j.issn.1005-2518.2021.02.125

采选技术与矿山管理

基于CiteSpace可视化分析下2013~2020年冻融岩石力学热点研究探析

  • 邓红卫 , 1, 2 ,
  • 田广林 1, 2
展开
  • 1. 中南大学资源与安全工程学院,湖南 长沙 410083
  • 2. 中南大学高海拔寒区采矿工程技术研究中心,湖南 长沙 410083

邓红卫(1969-),男,湖南岳阳人,教授,从事金属矿山开采、矿山安全、水资源利用与灾害防治研究工作。

收稿日期: 2020-07-13

  修回日期: 2020-09-14

  网络出版日期: 2021-05-28

基金资助

国家自然科学基金项目“寒区散体冻胀裂解孕育排土场灾变机理及干预机制研究”(51874352)

中南大学研究生科研创新项目“混凝土温度极限条件下微观本构特征试验研究”(2019zzts985)

收起

Analysis on Hot Topics of Rock Mechanics Research in the Freeze-Thaw Environment from 2013 to 2020 Based on Visual Analysis of CiteSpace

  • Hongwei DENG , 1, 2 ,
  • Guanglin TIAN 1, 2
Expand
  • 1. School of Resources and Safety Engineering,Central South University,Changsha 410083,Hunan,China
  • 2. High-altitude Cold Area Mining Engineering Technology Research Center of Central South University,Changsha 410083,Hunan,China

Received date: 2020-07-13

  Revised date: 2020-09-14

  Online published: 2021-05-28

Fold

本文亮点

2013年以来,随着寒冷地区资源开发利用与工程建设规模不断扩大,国内外冻融岩石力学研究发展迅速。论文以2013~2020年Web of Science和CNKI数据库收录的冻融岩石力学领域相关论文为数据源,使用文献可视化软件CiteSpace构建了国内外冻融岩石力学研究的关键词共现网络、热点知识演进时区视图和发文高产机构知识图谱,并进行了图谱可视化分析。结合统计结果与知识图谱研究发现:①国内外冻岩力学研究处于快速发展阶段,参与国家和创新性研究成果逐年增加,研究状态火热;②论文在核心期刊与研究机构中的分布集中度较高,企业、科研院所课题研究参与度较低,难以发挥“产学研”综合优势;③热点研究可概括为冻融岩石多尺度力学损伤特性、裂隙岩体冻融损伤机制、岩石本构模型及数值模拟研究;④岩石多场耦合作用、成熟研究成果的工程转化运用将是后续研究的重点关注方向。

本文引用格式

邓红卫 , 田广林 . 基于CiteSpace可视化分析下2013~2020年冻融岩石力学热点研究探析[J]. 黄金科学技术, 2021 , 29(2) : 275 -286 . DOI: 10.11872/j.issn.1005-2518.2021.02.125

Highlights

Since 2013,with the implementation of the “Belt and Road” Initiative,the development and utilization of resources and the scale of engineering construction in cold regions along the way have been expanding.Research on the mechanical properties of frozen rocks in cold regions at home and abroad has developed rapidly,and many valuable academic results have been obtained.However,there is no paper that summarizes the hot topics and development trends of domestic and foreign research in recent years.In order to understand the research hotspots and development trends of rock mechanics under the freezing and thawing environment from 2013 to 2020,and to provide reference and innovation space for follow-up scholars in related research,bibliometric research was conducted in this paper.By selecting the search term of TS=(freeze-thaw OR freeze-thawing OR freezing and thawing OR freezing-thawing OR frozen-thawed) and TS=(rock OR rock mass) and SU=(freeze-thaw or freeze-thaw cycle) and SU=(rock or rock mass),the subject search was performed on the academic papers in the relevant direction included in the Web of Science foreign language database and the domestic CNKI database.CiteSpace cluster analysis selects the appropriate clustering threshold and pruning method(Pathfinder),and a visually intuitive domestic freeze-thaw rock mechanics research organization cooperation network, keyword co-occurrence network, and hot research evolution time zone view knowledge map was constructed through the visual analysis of the built-in software system of Institution,Keyword,and Timezone View functions.Through comprehensive statistical analysis results of papers and the clustering structure of the knowledge map,it is found that the research on freeze-thaw rock mechanics at home and abroad is in a rapid development stage.The participating countries and research results are increasing year by year,and the research status is hot.The distribution of core journals is relatively high.As a representative journal of the research direction of rock mechanics in China,14.8% of academic papers are included in Rock and Mechanics Engineering,Rock and Soil Mechanics,and Geotechnical Engineering,indicating that a series of innovations have emerged in domestic frozen rock research achievements.The distribution of core research institutions is obvious.The University of Chinese Academy of Sciences,Central South University,and Xi’an University of Science and Technology play a key role in the cooperative network structure of publishing institutions.However,the participation of enterprises and scientific research institutes in project research is relatively low,and it is difficult to give full play to “production,study and research” comprehensive advantages,a single research model will not be conducive to the development of domestic frozen rock mechanics.The research hotspots can be summarized as research on multi-scale mechanical damage characteristics of freeze-thaw rocks,research on fractured rock mass freeze-thaw damage mechanisms,rock freeze-thaw damage constitutive models and numerical simulation research.The multi-field coupling study of rock under freezing and thawing conditions and the engineering transformation of mature research results will be the focus of subsequent related research.

[an error occurred while processing this directive]

《关于“十四五”大宗固体废弃物综合利用的指导意见》

为深入贯彻落实党的十九届五中全会精神,进一步提升大宗固体废弃物(以下简称“大宗固废”)综合利用水平,全面提高资源利用效率,推动生态文明建设,促进高质量发展,近日,国家发展改革委联合科技部、工业和信息化部、财政部、自然资源部、生态环境部、住房和城乡建设部、农业农村部、市场监管总局、国管局印发《关于“十四五”大宗固体废弃物综合利用的指导意见》(以下简称《指导意见》)。

《指导意见》强调,以习近平新时代中国特色社会主义思想为指导,深入贯彻党的十九大和十九届二中、三中、四中、五中全会精神,坚定不移贯彻新发展理念,以全面提高资源利用效率为目标,以推动资源综合利用产业绿色发展为核心,加强系统治理,创新利用模式,实施专项行动,促进大宗固废实现绿色、高效、高质、高值、规模化利用,提高大宗固废综合利用水平。要坚持政府引导与市场主导相结合、规模利用与高值利用相结合、消纳存量与控制增量相结合、突出重点与系统治理相结合、技术创新与模式创新相结合等基本原则推进大宗固废综合利用。

《指导意见》明确,到2025年,煤矸石、粉煤灰、尾矿(共伴生矿)、冶炼渣、工业副产石膏、建筑垃圾、农作物秸秆等大宗固废的综合利用能力显著提升,利用规模不断扩大,新增大宗固废综合利用率达到60%,存量大宗固废有序减少。同时,提出综合利用产业体系不断完善、技术创新体系逐步建立、综合利用制度基本完善、协同发展模式不断创新和示范引领作用显著增强等5个方面目标。

《指导意见》提出,要提高大宗固废资源利用效率,拓宽煤矸石、粉煤灰、尾矿(共伴生矿)、冶炼渣、工业副产石膏、建筑垃圾、农作物秸秆等大宗固废利用途径,扩大综合利用规模。推进大宗固废综合利用绿色发展,推进产废行业绿色转型,推动利废行业绿色生产,强化大宗固废规范处置。推动大宗固废综合利用创新发展,创新大宗固废综合利用模式、综合利用关键技术、协同利用机制和管理方式。实施骨干企业示范引领、综合利用基地建设、资源综合利用产品推广、大宗固废系统治理能力提升等资源高效利用行动。

《指导意见》要求,各级发展改革委和各有关部门要切实履行职责,建立协调机制,统筹推进大宗固废综合利用工作。健全法律法规,积极推动资源综合利用立法,强化执法监管。继续落实税收优惠政策,鼓励绿色信贷,支持相关企业发放绿色债券,鼓励地方支持资源综合利用产业发展,不断探索依靠市场机制推动大宗固废综合利用的路径和模式。加强宣传推广,充分发挥各类媒体作用,宣传大宗固废综合利用典型案例,推广典型经验,营造全社会积极参与的良好氛围。

脚注

http://www.goldsci.ac.cn/article/2021/1005-2518/1005-2518-2021-29-2-275.shtml

参考文献

原文顺序 | 文献年度倒序 | 文中引用次数倒序
Abdolghanizadeh K Hosseini M Saghafiyazdi M2019. Effect of freezing temperature and number of freeze-thaw cycles on mode I and mode II fracture toughness of sandstone[J]. Theoretical and Applied Fracture Mechanics10(4):967.

Chen Chaomei2009.Citespace Ⅱ:Detecting and visualizing emerging trends and transient patterns in scientific literature[J].Chen Yue,Hou Jianhua,Liang Yongxia,Transl.Journal of Information,28(3):401-421.

Chen Rensheng Kang Ersi Wu Lizong al et2005.Cold regions in China[J].Journal of Glaciology and Geocryology27(4):469-475.

Chen Song Qiao Chunsheng Ye Qing al et2019. Compositedamage model of jointed rock mass under freezing and thawing load[J]. Journal of Harbin Institute of Technology51(2):100-108.

Chen Youliang Dai Mingxing Liu Mingliang al et2013.Experimental investigation on freezing damage characteristics of granite with initial damage[J].Chinese Quarterly of Mechanics34(1):74-80.

Chen Yue Chen Chaomei Liu Zeyuan al et2015.The methodology function of CiteSpace mapping knowledge domains[J].Studies in Science of Science33(2):242-253.

Deng Hongwei Tian Weigang Zhou Keping al et2013.Progress in freezing-thawing rock mechanics during the period of 2001 to 2012[J]. Science & Technology Review31(24):74-79.

Du Debin Ma Yahua2015.One Belt and One Road:The grand geo-strategy of China’s rise[J].Geographical Research34(6):1005-1014.

Fogue-Djombou Y I Corn S Clerc L2019. Freeze-thaw resistance of limestone roofing tiles assessed through impulse vibration monitoring and finite element modeling in relation to their microstructure[J]. Construction & Building Materials, 205:656-667.

Gambino G F Harrison J P2017.Rock engineering design in frozen and thawing rock:Current approaches and future directions[J]. Procedia Engineering,191:656-665.

Ghobadi M H Torabi-Kaveh M2014.Assessing the potential for deterioration of limestones forming Taq-e Bostan monuments under freeze-thaw weathering and karst development[J].Environmental Earth Sciences72(12):5035-5047.

Huang Shibing Liu Quansheng Cheng Aiping al et2018.Preliminary experimental study of frost heaving pressure in crack and frost heaving propagation in rock mass under low temperature[J].Rock and Soil Mechanics39(1):78-84.

Jia Hailiang Liu Qingbing Xiang Wei al et2013. Damage evolution model of saturated sandstone under freeze-thaw cycles[J].Chinese Journal of Rock Mechanics and Engineering32(Supp.2):3049-3055.

Jiang H B2018.The relationship between mechanical properties and gradual deterioration of microstructures of rock mass subject to freeze-thaw cycles[J].Earth Sciences Research Journal22(1):53-57.

Li J L Kaunda R B Zhou K P al et2018.Experimental investigations on the effects of ambient freeze-thaw cycling on dynamic properties and rock pore structure deterioration of sandstone[J].Cold Regions Science and Technology,154:133-141.

Kock T D Boone M A Schryver T D al et2015.A pore-scale study of fracture dynamics in rock using X-ray Micro-CT under ambient freeze-thaw cycling[J].Environmental Science & Technology49(5):2867-2874.

Li Changhong Xiao Yonggang Wang Yu al et2019.Review and prospects for understanding deformation and failure of rock slopes in cold regions with high altitude[J].Chinese Journal of Engineering41(11):1374-1386.

Li Jie Chen Chaomei2016.CiteSpace:Scientific Text Mining and Visualization[M].Beijing:Capital University of Economics and Business Press:89-90,150.

Li Jielin Zhou Keping Ke Bo2015.Association analysis of pore development characteristics and uniaxial compressive strength property of granite under freezing-thawing cycles[J].Journal of China Coal Society40(8):1783-1789.

Li Jielin Zhou Keping Zhang Yamin al et2014.Experiment study on physical characteristics in weathered granite under freezing-thawing cycles[J].Journal of Central South University(Science and Technology)45(3):798-802.

Li Xinping Lu Yani Wang Yangjun al et2013.Research on damage model of single jointed rock masses under coupling action of freeze-thaw and loading[J].Chinese Journal of Rock Mechanics and Engineering32(11):2307-2315.

Liu Quansheng Huang Shibin Kang Yongshui al et2015a. Advance and review on freezing-thawing damage of fractured rock[J].Chinese Journal of Rock Mechanics and Engineering34(3):452-471.

Liu Quansheng Huang Shibing Kang Yongshui al et2015b.Numerical and theoretical studies on frost heaving pressure in a single fracture of frozen rock mass under low temperature[J].Chinese Journal of Geotechnical Engineering37(9):1572-1580.

Lu Yani Li Xinping Wu Xinghong2014.Fracture coalescence mechanism of single flaw rock specimen due to freeze-thaw under triaxial compression[J].Rock and Soil Mechanics35(6):1579-1584.

Maji V Murton J B2019. Micro-computed tomography imaging and probabilistic modelling of rock fracture by freeze-thaw[J]. Earth Surface Processes and Landforms45(3):666-680.

Martins L Vasconcelos G Lourenco P B al et2016.Influence of the freeze-thaw cycles on the physical and mechanical properties of granites[J].Journal of Materials in Civil Engineering28(5):04015201.

Meng Xiangzhen Zhang Huimei Kang Xiaoge2019.Damage constitutive model of porous rock under freeze-thaw[J].Journal of Xi’an University of Science and Technology39(4):688-692.

Murton J B Kuras O Krautblatter M al et2016.Monitoring rock freezing and thawing by novel geoelectrical and acoustic techniques[J].Journal of Geophysical Research:Earth Surface121(12):2309-2332.

Rusin Z Świercz P Owsiak Z2015.Effect of microstructure on frost durability of rock in the context of diagnostic needs[J]. Procedia Engineering,108:177-184.

Sarici D E Ozdemir E2018. Determining point load strength loss from porosity, Schmidt hardness, and weight of some sedimentary rocks under freeze-thaw conditions[J]. Environmental Earth Sciences77(3):62.1-62.9.

Shen Yanjun Yang Gengshe Rong Tenglong al et2016.Proposed scheme for freeze-thaw cycle tests on rock[J].Chinese Journal of Geotechnical Engineering38(10):1775-1782.

Wang P Xu J Fang X al et2017.Ultrasonic time-frequency method to evaluate the deterioration properties of rock suffered from freeze-thaw weathering[J].Cold Regions Science and Technology,143:13-22.

Wang Zhen Zhu Zhende Chen Huiguan al et2011. A thermo-hydro-mechanical coupled constitutive model for rocks under freeze-thaw cycles[J]. Rock and Soil Mechanics40(7):2608-2616.

Wen Lei Li Xibing Tang Haiyan al et2017.Study of physico-mechanical characteristics of rock under different frozen-thawed circle tempura range and its engineering application[J].Engineering Mechanics34(5):247-256.

Yan Xidong Liu Hongyan Xing Chuangfeng al et2015.Constitutive model research on freezing-thawing damage of rock based on deformation and propagation of microcracks[J].Rock and Soil Mechanics36(12):3489-3499.

Yang Gengshe Shen Yanjun Jia Hailiang al et2018.Research progress and tendency in characteristics of multi-scale damage mechanics of rock under freezing-thawing[J].Chinese Journal of Rock Mechanics and Engineering37(3):545-563.

Ye Longsheng Wan Guangcai2017.Research on the evaluation of infrastructure construction in 18 provinces and cites along “The Belt and Road” [J].Journal of Jiangnan University(Humanities & Social Sciences)16(4):82-89.

Yin Yucheng Chen Youliang Meng Xiangrui2019. Comparison of mechanical properties and fracture toughness changes of sandstone and granite under freeze-thaw cycle and chemical corrosion[J].Journal of Water Resources and Water Engineering30(4):217-224.

Yuan Chao Zhang Huimei Meng Xiangzhen al et2019.Influence of internal friction angle on damage constitutive model of freeze-thaw rock[J].Coal Geology & Exploration47(4):138-143.

Zhang Huimei Meng Xiangzhen Peng Chuan al et2018.Freeze-thaw damage model and parameters of rock deformation in whole process[J].Journal of Xi’an University of Science and Technology38(2):260-265.

Zhang Huimei Meng Xiangzhen Peng Chuan al et2019.Rock damage constitutive model based on residual intensity characteristics under freeze-thaw and load[J].Journal of China Coal Society44(11):3404-3411.

Zhang Huimei Xia Haojun Yang Gengshe al et2018.Experimental research of influences of freeze-thaw cycles and confining pressure onphysical-mechanical characteristics of rocks[J].Journal of China Coal Society43(2):441-448.

Zhang Huimei Yang Gengshe2013a.Damage constitutive model of loaded rock under freeze-thaw condition[J].Journal of Wuhan University of Technology35(7):79-82.

Zhang Huimei Yang Gengshe2013b.Mechanical property experiment and damage analysis of red sandstone under freeze-thaw environment[J].Mechanics in Engineering35(3):57-61.

Zhang Huimei Yang Gengshe2013c.Experimental study of damage deterioration and mechanical properties for freezing-thawing rock[J].Journal of China Coal Society38(10):1756-1762.

Zhang Huimei Zhang Mengjun Xie Xiangmiao al et2015.The experimental study on the physical and mechanical properties of red sandstone under the action of freeze-thaw cycle[J].Journal of Taiyuan University of Technology46(1):69-74.

Zhou Keping Zhang Yamin Li Jielin al et2013.Degradation mechanism and evolutionary pattern of granites with coarse and grains in freezing-thawing condition[J].Journal of Uni-versity of Science and Technology Beijing35(10):1249-1255.

陈超美,2009.CiteSpace Ⅱ:科学文献中新趋势与新动态的识别与可视化[J].陈悦,侯剑华,梁永霞,译.情报学报, 28(3):401-421.

陈仁升,康尔泗,吴立宗,等,2005.中国寒区分布探讨[J].冰川冻土27(4):469-475.

陈松,乔春生,叶青,等,2019.冻融荷载下节理岩体的复合损伤模型[J].哈尔滨工业大学学报51(2):100-108.

陈有亮,代明星,刘明亮,等,2013.含初始损伤岩石的冻融损伤试验研究[J].力学季刊34(1):74-80.

陈悦,陈超美,刘则渊,等,2015.CiteSpace知识图谱的方法论功能[J].科学学研究33(2):242-253.

邓红卫,田维刚,周科平, 等,2013.2001-2012年岩石冻融力学研究进展[J].科技导报31(24):74-79.

杜德斌,马亚华,2015.“一带一路”:中华民族复兴的地缘大战略[J].地理研究34(6):1005-1014.

黄诗冰,刘泉声,程爱平,等,2018.低温岩体裂隙冻胀力与冻胀扩展试验初探[J].岩石力学与工程学报39(1):78-84.

贾海梁,刘清秉,项伟,等,2013.冻融循环作用下饱和砂岩损伤扩展模型研究[J].岩石力学与工程学报32(增2):3049-3055.

李长洪,肖永刚,王宇,等,2019.高海拔寒区岩质边坡变形破坏机制研究现状及趋势[J].工程科学学报41(11):1374-1386.

李杰,陈超美,2016.CiteSpace:科技文本挖掘及可视化[M].北京:首都经济贸易大学出版社:89-90,150.

李杰林,周科平,柯波,2015.冻融后花岗岩孔隙发育特征与单轴抗压强度的关联分析[J].煤炭学报40(8):1783-1789.

李杰林,周科平,张亚民,等,2014.冻融循环条件下风化花岗岩物理特性的实验研究[J].中南大学学报(自然科学版)45(3):798-802.

李新平,路亚妮,王仰君,2013.冻融荷载耦合作用下单裂隙岩体损伤模型研究[J].岩石力学与工程学报32(11):2307-2315.

刘泉声,黄诗冰,康永水,等,2015a.低温冻结岩体单裂隙冻胀力与数值计算研究[J].岩土工程学报37(9):1572-1580.

刘泉声,黄诗冰,康永水,等,2015b.裂隙岩体冻融损伤研究进展与思考[J].岩石力学与工程学报34(3):452-471.

路亚妮,李新平,吴兴宏,2014.三轴压缩条件下冻融单裂隙岩样裂缝贯通机制[J].岩土力学35(6):1579-1584.

孟祥振,张慧梅,康晓革,2019.含孔隙冻融岩石的损伤本构模型[J].西安科技大学学报39(4):688-692.

申艳军,杨更社,荣腾龙,等,2016.岩石冻融循环试验建议性方案探讨[J].岩土工程学报38(10):1775-1782.

王震,朱珍德,陈会官,等,2019.冻融作用下岩石力—热—水耦合本构模型研究[J].岩土力学40(7):2608-2616.

闻磊,李夕兵,唐海燕,等,2017.变温度区间冻融作用下岩石物理力学性质研究及工程应用[J].工程力学34(5):247-256.

阎锡东,刘红岩,刑闯峰,等,2015.基于微裂隙变形与扩展的岩石冻融损伤本构模型研究[J].岩土力学36(12):3489-3499.

杨更社,申艳军,贾海梁,等,2018.冻融环境下岩体损伤力学特性多尺度研究及进展[J].岩石力学与工程学报37(3):545-563.

叶龙生,万光彩,2017.“一带一路”沿途18省市基础建设评价研究[J].江南大学学报(人文社会科学版)16(4):82-89.

印宇澄,陈有亮,孟祥瑞,2019.砂岩与花岗岩在冻融循环和化学腐蚀下力学性能及断裂韧度变化的对比[J].水资源与水工程学报30(4):217-224.

袁超,张慧梅,孟祥振,等,2019.内摩擦角对冻融岩石损伤本构模型的影响探讨[J].煤田地质与勘探47(4):138-143.

张慧梅,孟祥振,彭川,等,2018a.岩石变形全过程冻融损伤模型及其参数[J].西安科技大学学报38(2):260-265.

张慧梅,孟祥振,彭川,等,2019.冻融—荷载作用下基于残余强度特征的岩石损伤模型[J].煤炭学报44(11):3404-3411.

张慧梅,夏浩峻,杨更社,等,2018b.冻融循环和围压对岩石物理力学性质影响的试验研究[J].煤炭学报43(2):441-448.

张慧梅,杨更社,2013a.冻融循环条件下受荷岩石的损伤本构模型[J].武汉理工大学学报35(7):79-82.

张慧梅,杨更社,2013b.冻融环境下红砂岩力学特性试验及损伤分析[J].力学与实践: 35(3):57-61.

张慧梅,杨更社,2013c.冻融岩石损伤劣化及力学特性试验研究[J].煤炭学报38(10):1756-1762.

张慧梅,张蒙军,谢祥妙,等,2015.冻融循环条件下红砂岩物理力学特性试验研究[J].太原理工大学学报46(1):69-74.

周科平,张亚民,李杰林,等,2013.粗、细粒径花岗岩冻融损伤机理及其演化规律[J].北京科技大学学报35(10):1249-1255.

Options
文章导航

/

[an error occurred while processing this directive]