矿用大功率柱塞泵研究现状及绿色化发展趋势与展望

doi:10.3901/JME.2023.10.333

机械工程学报 ›› 2023, Vol. 59 ›› Issue (10): 333-345.doi: 10.3901/JME.2023.10.333

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矿用大功率柱塞泵研究现状及绿色化发展趋势与展望

刘银水^1,2,3, 董婕^2,3, 韦文术⁴, 赵申诞^1,3, 李然⁴, 刘昊⁴, 叶健⁴, 吴德发¹

1. 华中科技大学机械科学与工程学院武汉 430074;
2. 兰州理工大学能源与动力工程学院兰州 730050;
3. 华中科技大学无锡研究院无锡 214174;
4. 北京天玛智控科技股份有限公司北京 100013

收稿日期:2022-05-26 修回日期:2022-09-20 出版日期:2023-05-20 发布日期:2023-07-19
通讯作者: 吴德发(通信作者),男,1983年出生,博士,教授,博士研究生导师。主要研究方向为水液压传动技术基础技术及应用。E-mail:defawu@hust.edu.cn E-mail:defawu@hust.edu.cn
作者简介:刘银水,男,1973年出生,博士,教授,博士研究生导师。主要研究方向为水液压传动技术、深海装备技术和矿用环保型液压元件。E-mail:liuwater@hust.edu.cn
基金资助:
国家自然科学基金资助项目(52075192)。

Research Status and Green Development Trend and Prospect of Mine High-power Plunger Pump

LIU Yinshui^1,2,3, DONG Jie^2,3, WEI Wenshu⁴, ZHAO Shendan^1,3, LI Ran⁴, LIUHao⁴, YE Jian⁴, WU Defa¹

1. School of Mechanical Science and Engineering, Huazhong University of Science and Technology, Wuhan 430074;
2. School of Energy and Power, Lanzhou University of Technology, Lanzhou 730050;
3. Wuxi Research Institute of Huazhong University of Science and Technology, Wuxi 214174;
4. Beijing Tianma Intelligent Control Technology Co., Ltd., Beijing 100013

Received:2022-05-26 Revised:2022-09-20 Online:2023-05-20 Published:2023-07-19

摘要/Abstract

摘要： 柱塞泵具有结构简单、耐冲击力强、易于实现高压等优势,是矿用液压支架的心脏。柱塞泵的水平不仅反映一个国家工业发展水平,而且我国高端矿用泵长期依赖进口,因此也是卡脖子技术之一。随着煤矿开采朝着高产高效和安全绿色化的方向发展,矿用柱塞泵面临两大发展趋势:以水为工作介质取代传动润滑液以实现绿色化;高压大流量高功率。介绍矿用柱塞泵的发展历程,在总结国内外矿用高压大功率水压柱塞泵产品现状的基础上,重点分析水压柱塞泵在矿用领域面临的核心技术难题和挑战,并提出应对措施,最后展望矿用高压大功率柱塞泵的绿色化发展趋势。

关键词: 矿用, 柱塞泵, 高压大功率, 水压化, 绿色化

Abstract: Plunger pumps have the advantages of simple structure, strong impact resistance, and easy to achieve high pressure, making them the core of mining hydraulic supports. The level of plunger pumps not only reflects a country's industrial development level, but also in China, high-end mining pumps have long relied on imports, making them one of the bottleneck technologies. With the development of coal mines towards high yield, efficiency, safety, and green, mining plunger pumps are facing two major development trends:using water as the working medium to replace transmission lubricants and achieve green development; High pressure, high flow rate, and high power. This article introduces the development history of mining plunger pumps, summarizes the current situation of high-pressure and high-power hydraulic plunger pumps in mines at home and abroad, analyzes the core technical problems and challenges faced by hydraulic plunger pumps in the mining field, and proposes countermeasures. Finally, the green development trend of high-pressure and high-power plunger pumps in mines is prospected.

Key words: mining, plunger pump, high pressure and high power, water hydraulic, green

中图分类号:

TG156

刘银水, 董婕, 韦文术, 赵申诞, 李然, 刘昊, 叶健, 吴德发. 矿用大功率柱塞泵研究现状及绿色化发展趋势与展望[J]. 机械工程学报, 2023, 59(10): 333-345.

LIU Yinshui, DONG Jie, WEI Wenshu, ZHAO Shendan, LI Ran, LIUHao, YE Jian, WU Defa. Research Status and Green Development Trend and Prospect of Mine High-power Plunger Pump[J]. Journal of Mechanical Engineering, 2023, 59(10): 333-345.

参考文献

[1] 谢克昌. 煤炭清洁高效开发利用将重构煤炭工业体系[N]. 中国煤炭报,2017-05-26(3). XIE Kechang. Clean and efficient development and utilization of coal will reconstruct the coal industry system[N]. China Coal News,2017-05-26(3).
[2] 康红普,王国法,王双明,等. 煤炭行业高质量发展研究[J]. 中国工程科学,2021,23(5):130-138. KANG Hongpu,WANG Guofa,WANG Shuangming,et al. Research on high-quality development of coal industry[J]. China Engineering Science,2021,23(5):130-138.
[3] 王国法. 工作面支护与液压支架技术理论体系[J]. 煤炭学报,2014,39(8):1593-1601. WANG Guofa. Technical theory system of working face support and hydraulic support[J]. Journal of China Coal Society,2014,39(8):1593-1601.
[4] 付翔,王然风,赵阳升,等. 基于交叠协同逻辑的液压支架运行自适应稳压供液控制方法[J]. 煤炭学报,2020,45(5):1891-1900. FU Xiang,WANG Ranfeng,ZHAO Yangsheng,et al. Self-adaptive control method of fluid feeding with steady pressure for hydraulic support based on overlapping synergetic logic[J]. Journal of China Coal Society,2020,45(5):1891-1900.
[5] WANG J H,HUANG Z H. The recent technological development of intelligent mining in China[J]. Engineering,2017,3(4):439-444.
[6] 李然. 矿用高压大流量乳化液泵站应用现状及发展趋势[J]. 煤炭科学技术,2015,43(7):93-96. LI Ran. Application status and development trend of mine high-pressure and large-flow emulsion pumping station[J]. Coal Science and Technology, 2015,43(7):93-96.
[7] CHURCH J,LUNDRN J G,DRAZ D,et al. Identification and characterization of bilgewater emulsions[J]. Science of the Total Environment,2019,691(C):981-995.
[8] ZHU J A,GUO P H. Developing history of water hydraulic technology and its application in coal mine production[J]. Applied Mechanics & Materials,2011,42:236-241.
[9] 何存兴. 液压元件[M]. 北京:机械工业出版社,1982. HE Cunxing. Hydraulic components[M]. Beijing:Machinery Industry Press, 1982.
[10] Cahaba Media Group,Inc. The history of pumps:Through the years[EB/OL].[2011-12-22]. https://www.pumpsandsystems.com.
[11] Hauhinco Maschinenfabrik,Inc. Triplex and quintuplex high pressure plunger pumps[EB/OL].[2021-12-12]. https://www.hauhinco.de.
[12] RMI Pressure System,Inc. S Series:Quinmax 5 plunger pumps[EB/OL].[2021-12-12]. http://www.rmipsl.com.
[13] KAMAT,Inc. 40 Years of high-pressure competence[EB/OL].[2021-12-12]. https://www.kamat.de.
[14] 刘建军,陈伟,赵光瑞. 国产大流量乳化液泵站技术革新及应用现状[J]. 煤矿机械,2020,41(8):135-138. LIU Jianjun,CHEN Wei,ZHAO Guangrui. Technological innovation and application status of domestic-made large-flow emulsion pump station[J]. Coal Mine Machinery,2020,41(8):135-138.
[15] 李然. 综采工作面智能供液技术及发展趋势[J]. 煤炭科学技术,2019,47(9):203-207. LI Ran. Intelligent fluid supply technology in fully-mechanized coal mining face and its development trend[J]. Coal Science and Technology,2019,47(9):203-207.
[16] Schaefer Pumps & Hydraulics,Inc. High-pressure pumps HDP[EB/OL].[2021-12-12]. https://www.schaefer-ph.de/en.
[17] 李然. 大采高工作面高压大流量乳化液泵的研制及应用[J]. 煤炭科学技术,2017,45(12):145-149. LI Ran. Research and development as well as application of high pressure and high flow emulsion pump to large mining height face[J]. Coal Science and Technology, 2017,45(12):145-149.
[18] 朱俊华,战长松. 往复泵设计[M]. 北京:机械工业出版社,1992. ZHU Junhua,ZHAN Changsong. Design of reciprocating pump[M]. Beijing:China Machine Press,1992.
[19] 聂松林,尹方龙. 水液压柱塞泵的研究进展及展望[J].液压与气动,2015(1):1-7. NIE Songlin,YIN Fanglong. Research progress and prospect of water hydraulic piston pump[J]. Hydraulics and Pneumatics,2015(1):1-7.
[20] 陈礼,符义红,陈红军,等. 五缸往复泵曲轴的柔体动力学分析[J]. 排灌机械工程学报,2020,38(8):770-774. CHEN Li,FU Yihong,CHEN Hongjun,et al. Flexible body dynamics of five-cylinder reciprocating pump crankshaft[J]. Journal of Drainage and Irrigation Machinery Engineering,2020,38(8):770-774.
[21] CHEN Y,ZHANG J H,XU B,et al. Multi-objective optimization of micron-scale surface textures for the cylinder/valve plate interface in axial piston pumps[J]. Tribology International,2019,138:316-329.
[22] 孙亚楠,高殿荣. 双介质双排量轴向柱塞泵配流窗处液体的泄漏和掺混特性[J]. 机械工程学报,2020,56(22):271-280. SUN Yanan,GAO Dianrong. Liquid leakage and mixing characteristics at distribution windows of dual-medium and dualdisplacement axial piston pumps[J]. Journal of Mechanical Engineering,2020,56(22):271-280.
[23] 张晋,龚学知,胡建军,等. 轴向柱塞泵配流分析用湍流模型探析[J]. 机械工程学报,2018,54(18):204-211. ZHANG Jin,GONG Xuezhi,HU Jianjun,et al. CFD Analysis of the turbulence model adopted in distribution process in axial piston pump[J]. Journal of Mechanical Engineering,2018,54(18):204-211.
[24] 李然,王伟,苏哲. 高压大流量乳化液泵滑动轴承热流体动力润滑仿真分析[J]. 煤炭学报,2014,39(增刊2):576-582. LI Ran,WANG Wei,SU Zhe. Numerical study on thermohydrodynamic performance of journal bearing in high-pressure and largeflow-rate emulsion pump[J]. Journal of China Coal Society,2014,39(Suppl.2):576-582.
[25] ZHAO X X,WANG J Z. Pump-back effect analysis and wear feature extraction for hydraulic cylinder piston seal based on multisensor monitoring[J]. IEEE Transactions on Industrial Electronics,2015,66(9):7270-7280.
[26] FTL. Reciprocating shaft seals for high-pressure per-formance[EB/OL].[2021-12-12]. https://ftl.technology/reciprocating-seals.
[27] 叶健. 乳化液泵站RMI与KAMAT比较分析[J]. 工矿自动化,2019, 45(3):41-44. YE Jian. Comparison and analysis of RMI and KAMAT in emulsion pumping station[J]. Industry and Mine Automation,2019,45(3):41-44.
[28] HUANG G,HE X,ZHU Y. Analysis on optimal clearance of piston friction pair and its influence factors for water hydraulic pump[J]. China Mechanical Engineering,2011,22(14):1668-1672.
[29] XU C W,NIE W,LIU Z Q,et al. Multi-factor numerical simulation study on spray dust suppression device in coal mining process[J]. Energy,2019,182(SEP.1):544-558.
[30] 刘银水. 水液压传动技术基础及工程应用[M]. 北京:机械工业出版社,2013. LIU Yinshui. Technical foundation and engineering application of water hydraulic transmission[M]. Beijing:China Machine Press,2013.
[31] 叶健. 大流量乳化液泵高压填料密封试验研究[J]. 中国煤炭,2020,46(4):87-90. YE Jian. Experimental research on high-pressure packing seal of large flow emulsion pump[J]. China Coal,2020,46(4):87-90.
[32] NIKAS G K. Eighty years of research on hydraulic reciprocating seals:Review of tribological studies and related topics since the 1930s[J]. Proceedings of the Institution of Mechanical Engineers,Part J:Journal of Engineering Tribology,2010,224(1):1-23.
[33] 李永康,王军,廉自生. 混合润滑条件下斯特封高速摩擦与密封特性[J]. 中国机械工程,2021,32(5):533-539. LI Yongkang,WANG Jun,LIAN Zisheng. Mixed lubrication friction and sealing performance analysis of the step seal under high velocity[J]. China Mechanical Engineering,2021,32(5):533-539.
[34] 焦素娟,周华,杨华勇,等. 填充聚醚醚酮复合材料在水润滑下的摩擦学特性研究[J]. 摩擦学学报,2003(5):385-389. JIAO Sujuan,ZHOU Hua,YANG Huayong,et al. Tribological behavior of filled polyetheretherketonecom- posites in sliding against stainless steel underwater lubrication[J]. Journal of Tribology,2003(5):385-389.
[35] 湛从昌,邓江洪,陈奎生. 低摩擦高频响变间隙密封液压缸研究[J]. 机械工程学报,2015,51(24):161-167. ZHAN Congchang, DENG Jianghong, CHEN Kuisheng. Research on low-friction and high-response hydraulic cylinder with variable clearance[J]. Journal of Mechanical Engineering,2015,51(24):161-167.
[36] Danfoss,Inc. Pumps for tap water[EB/OL].[2021-12-12]. https://store.danfoss.com.
[37] MIYAKAWA S. Aqua drive system:A technology using tap water and its applications[C]//The 8th JFPS International Symposium on Fluid Power,October 25-28,2011,OKINAWA,Japan,2011:26-37.
[38] KOGA T,FUJITA T. The hydrostatic noncontact seal including fluid inertia effect[J]. ASLE Transactions,1986,29(1):35-42.
[39] KAZAMA T,SASAKI H,NARITA Y. Simultaneous temperature measurements of bearing and seal parts of a swash plate type axial piston pump-effects of piston clearance and fluid property[J]. Journal of Mechanical Science and Technology,2010,24(1):203-206.
[40] SCHNEIDER J,MIRANZO P,OSENDI M I. Tribological performance of aligned silicon nitride ceramics under isooctane-lubricated oscillating sliding conditions[J]. Journal of the American Ceramic Society,2016,99(1):241-248.
[41] BALARINI R,STREY N F,SINATORA A,et al. The influence of initial roughness and circular axial run-out on friction and wear behavior of Si₃N₄-Al₂O₃ sliding in water[J]. Tribology International,2016,101:226-233.
[42] MENEZES P L,KISHORE,KAILAS S V,et al. Influence of surface texture and toughness of softer and harder counter materials on friction during sliding[J]. Journal of Materials Engineering and Performance,2014,24(1):393-403.
[43] WU D F,LIU Y S,YANG S D,et al. Friction and wear characteristics of WC-10Co-4Cr/Si₃N₄ tribopair lubricated under silt-laden water[J]. Wear,2012,294-295:370-379.
[44] LI R,WEI W S,LI S B,et al. Fracture toughness testing and prediction for ceramic materials using in large-flow-rate emulsion pumps[J]. International Journal of Mechanical Engineering and Applications,2019,7(2):46-53.
[45] WANG G R,ZHONG L,HE X,et al. Dynamic behavior of reciprocating plunger pump discharge valve based on fluid structure interaction and experimental analysis[J]. PLOS ONE,2015 10(10):e0140396.
[46] HUANG G Q,YU J,HE Y. Analysis on dynamic performance of FlatValve in water hydraulic piston pump[J]. Advanced Materials Research,2011,287-290:2764-2767.
[47] LIU Y S,WU D F,LONG L,et al. Research on the port valve of a water hydraulic axial pump[J]. Proceedings of the Institution of Mechanical Engineers,Part E:Journal of Process Mechanical Engineering,2009,223(3):155-166.
[48] 廉自生,严璐,廖瑶瑶,等. 一种乳化液泵高速配流阀:中国,CN201810303949.7[P]. 2018-08-31. LIAN Zisheng,YAN Lu,LIAO Yaoyao,et al. High- speed distribution valve of emulsion pump:China,CN201810303949.7[P]. 2018-08-31.
[49] 李然,张启龙,刘昊,等. 煤矿用纯水介质高压大流量柱塞泵关键技术研究[J]. 液压气动与密封,2020,40(5):17-21. LI Ran,ZHANG Qilong,LIU Hao,et al. Research on the key technology of high pressure and large flow plunger pump with pure water in coal mine[J]. Hydraulics Pneumatics & Seals,2020,40(5):17-21.
[50] ESPITIA L A,VARELA L,PINEDO C E,et al. Cavitation erosion resistance of low temperature plasma nitrided martensitic stainless steel[J]. Wear,2013,301(1-2):449-456.
[51] LIU S H,CHEN D R. Relationship between the geometric features of carbon steel cavitation erosion debris and the cavitation erosion stages[J]. Chinese Science Bulletin,2010(7):670-676.
[52] LOU M,ALPAS A T. High temperature wear mechanisms in thermally oxidized titanium alloys for engine valve applications[J]. Wear,2019,426-427:443-453.
[53] Hydrowatt,Inc. High-Pressure radial piston pumps[EB/OL].[2021-12-12]. https://www.hydrowatt.com.
[54] 严璐,廉自生,李永康. 高速径向柱塞泵配流阀的动态特性与结构优化研究[J]. 机电工程,2020,37(8):906-910. YAN Lu,LIAN Zisheng,LI Yongkang. Dynamic characteristics and structure optimization of distribution valve for high-speed radial piston pump[J]. Journal of Mechanical & Electrical Engineering,2020,37(8):906-910.
[55] 刘银水,吴德发,李东林,等. 海水液压技术在深海装备中的应用[J]. 机械工程学报,2014,50(2):28-35. LIU Yinshui,WU Defa,LI Donglin,et al. Applications of seawater hydraulics in deep-sea equipment[J]. Journal of Mechanical Engineering,2014,50(2):28-35.
[56] 李东,王海军,牟东,等. 液压支架纯水介质的技术研究[J]. 煤矿机械,2019,40(7):31-34. LI Dong,WANG Haijun,MOU Dong,et al. Research on technology of pure water medium for hydraulic support[J]. Coal Mine Machinery,2019,40(7):31-34.
[57] 国家能源投资集团有限责任公司. 神东第三套纯水制备装置在锦界煤矿投用[EB/OL].[2021-08-05]. https://www.ceic.com. CHN ENERGY Investment Group Co., LTD. The third set of pure water preparation equipment of Shendong was put into use in Jinjie Coal Mine[EB/OL].[2021-08-05]. https://www.ceic.com.
[58] JUNAIDI R,HASAN A,YERIZAM M,et al. The performance of reverse osmosis(RO) membrane in producing pure water[J]. Journal of Physics Conference Series,2020,1500(1):012057.
[59] QASIM M,BADRELZAMAN M,DARWISH N N,et al. Reverse osmosis desalination:A state-of-the-art review[J]. Desalination,2019,459:59-104.
[60] SAMIEIRAD S,MOUSAVI S M,SALJOUGHI E. Alignment of functionalized multiwalled carbon nanotubes in forward osmosis membrane support layer induced by electric and magnetic fields[J]. Powder Technology,2020,364(C):538-552.
[61] 刘向阳. 面向深海的水压换向阀关键技术研究[D]. 北京:北京工业大学,2018. LIU Xiangyang. Key technology research of water hydraulic directional valve applied in deep sea[D]. Beijing:Beijing University of Technology,2018.

矿用大功率柱塞泵研究现状及绿色化发展趋势与展望

Research Status and Green Development Trend and Prospect of Mine High-power Plunger Pump

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