一、科研项目
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项目名称
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项目类型
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起始时间
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干式真空泵泵组技术开发
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企业横向
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2024-2025
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干式真空泵泵组设计及仿真软件开发
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企业横向
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2024-2026
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螺杆泵转子开发
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企业横向
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2023-2024
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新能源汽车空调压缩机设计开发
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企业横向
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2023-2025
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干式多级罗茨真空泵开发
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企业横向
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2023-2024
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氢气隔膜压缩机设计
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企业横向
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2023-2023
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专利:一种非对称椭圆型扭叶罗茨转子及压缩机、膨胀机等
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成果转化
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2022-2024
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燃料电池发电系统开发
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企业横向
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2022-2026
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高温蒸气热泵压缩机与卡诺电池开发
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企业横向
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2022-2026
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干式无油真空泵技术开发
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企业横向
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2022-2023
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专利:一种齿环结构气体压缩或膨胀装置
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成果转化
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2021-2022
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车用燃料电池空压机研发
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国家重点研发计划
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2019-2022
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离心式蒸汽热泵压缩机技术开发
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企业横向
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2022-2023
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高压加氢压缩机研究与开发
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企业横向
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2021-2024
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螺杆制冷压缩机小型化潜力及其关键技术研究
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重点实验室基金
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2021-2022
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加氢站高压隔膜压缩机研究与开发
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企业横向
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2020-2021
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低温动力循环系统分析模型及程序开发
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军工纵向
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2019-2021
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专利:双转子类压缩机的双电机驱动结构及其控制方法
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成果转化
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2019-2024
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专利:一种螺杆压缩机转子型线设计方法等
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成果转化
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2019-2020
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专利:螺杆式复合增压系统及其控制方法等
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成果转化
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2019-2020
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干式真空泵机组开发
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企业横向
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2019-2020
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双驱动无油螺杆空气压缩机开发
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企业横向
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2018-2019
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冰箱压缩机气流脉动与噪声研究
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科技支撑计划
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2013-2016
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二、论文
[1] S. Sun, X. Guo, H. Zhang, Y. Li, Z. He, C. Li, Design and sensitivity analysis of a multistage solid oxide fuel cell hybrid system with an inter-cooled-recuperated gas turbine and organic Rankine cycle, Energy, (2024) 129561-129561.
[2] D. Li, Z. He, K. Ma, C. Sun, Z. Xing, Rotor profile improvement by optimizing meshing curve for helical roots blowers in HFCV application, Proceedings of the Institution of Mechanical Engineers Part E-Journal of Process Mechanical Engineering, (2024).
[3] Q. Liu, A. Arabkoohsar, Y. Liu, Z. He, Techno-economic analysis of a liquid air energy storage system combined with calcium carbide production and waste heat recovery, Journal of Energy Storage, 60 (2023).
[4] L. Xing, J. Feng, Z. He, X. Peng, Analysis and development of a roots-type air compressor with fixed internal compression for fuel cell system, Proceedings of the Institution of Mechanical Engineers Part a-Journal of Power and Energy, 236 (2022) 51-60.
[5] J. Wang, Z. He, D. Li, W. Wu, Numerical Simulation of Vortex-Induced Vibration of TTR and SCR, Journal of Marine Science and Engineering, 10 (2022).
[6] D. Li, Z. He, W. Wu, Z. Xing, Study on the Quimby-tooth rotor profile for dry screw vacuum pumps, Proceedings of the Institution of Mechanical Engineers Part E-Journal of Process Mechanical Engineering, 236 (2022) 1947-1957.
[7] D. Li, Z. He, C. Wang, S. Sun, K. Ma, Z. Xing, Simulation of dry screw vacuum pumps based on chamber model and thermal resistance network, Applied Thermal Engineering, 211 (2022).
[8] D. Li, Z. He, S. Sun, Z. Xing, Dynamic characteristics modelling and analysis for dry screw vacuum pumps, Vacuum, 198 (2022).
[9] W. Hu, Z. He, D. Li, K. Ma, Z. Xing, Geometry of intersecting-axis conical twin-screw rotors, Mechanism and Machine Theory, 174 (2022).
[10] J. Wang, Q. Zuo, G. Liao, F. Luo, P. Zhao, W. Wu, Z. He, Y. Dai, Machine Learning-Based Fault Detection and Diagnosis of Organic Rankine Cycle System for Waste-Heat Recovery, Journal of Energy Engineering, 147 (2021).
[11] C. Wang, Z. Xing, S. Sun, W. Chen, Z. He, Theoretical research on the wear characteristics of rotors in a twin-screw compressor, Proceedings of the Institution of Mechanical Engineers Part E-Journal of Process Mechanical Engineering, (2021).
[12] C. Peng, W. Wu, Z. Zhang, J. Xie, Q. Feng, Z. He, Dynamic characteristics improvement of the single screw compressor with odd-grooves screw rotor, International Journal of Refrigeration, 132 (2021) 100-108.
[13] Q. Liu, Z. He, Y. Liu, Y. He, Thermodynamic and parametric analyses of a thermoelectric generator in a liquid air energy storage system, Energy Conversion and Management, 237 (2021).
[14] D. Li, Z. He, Q. Wang, X. Wang, W. Wu, Z. Xing, Thermodynamic analysis and optimization of a partial evaporating dual-pressure organic rankine cycle system for low-grade heat recovery, Applied Thermal Engineering, 185 (2021).
[15] D. Li, Z. He, C. Wang, Y. Guo, W. Wei, D. Lin, Z. Xing, Design methodology and performance analysis of conical rotors for dry screw vacuum pumps, Vacuum, 185 (2021).
[16] D. Li, Z. He, S. Sun, C. Wang, W. Chen, Z. Xing, Development and analysis of novel six-lobe helical rotors for hydrogen fuel cell vehicle roots blowers, International Journal of Hydrogen Energy, 46 (2021) 30479-30493.
[17] Z. He, D. Li, Y. Han, M. Zhou, Z. Xing, X. Wang, Noise control of a twin-screw refrigeration compressor, International Journal of Refrigeration, 124 (2021) 30-42.
[18] Q. Wang, W. Wu, D. Li, J. Wang, Z. He, Thermodynamic analysis and optimization of four organic flash cycle systems for waste heat recovery, Energy Conversion and Management, 221 (2020).
[19] C. Wang, Z. Xing, S. Sun, Z. He, Loss analysis of oil-free twin-screw expanders for recovering energy in fuel cell systems by means of p-theta diagrams, Energy, 201 (2020).
[20] C. Wang, Z. Xing, S. Sun, W. Chen, Z. He, Experimental study on the performance of oil-free twin-screw expanders for recovering energy in fuel cell systems, Applied Thermal Engineering, 165 (2020).
[21] Z. He, X. Yang, D. Li, W. Wu, Dynamic characteristics of a swing compressor for an air conditioning system at different discharge pressures, International Journal of Refrigeration-Revue Internationale Du Froid, 112 (2020) 125-135.
[22] Z. He, X. Qu, L. Ji, W. Wu, X. Wang, Analysis and Optimization of Truck Windshield Defroster, Applied Sciences-Basel, 10 (2020).
[23] Z. He, D. Li, L. Ji, X. Wang, T. Wang, Investigation on the Mass Flow Rate of a Refrigerator Compressor Based on the p-V Diagram, Applied Sciences-Basel, 10 (2020).
[24] Z. He, L. Ji, Z. Xing, Experimental Investigation on the DLC Film Coating Technology in Scroll Compressors of Automobile Air Conditioning, Energies, 13 (2020).
[25] Z. He, Y. Han, W. Chen, M. Zhou, Z. Xing, Noise control of a two-stage screw refrigeration compressor, Applied Acoustics, 167 (2020).
[26] 周明龙, 陈文卿, 何志龙, 邢子文, 螺杆制冷压缩机振动噪声控制技术研究, 制冷与空调, 19 (2019) 55-60.
[27] 周明龙, 陈文卿, 何志龙, 邢子文, 螺杆制冷压缩机气流脉动诱发气动噪声机理研究, 压缩机技术, (2019) 1-6.
[28] 杨侨明, 陈文卿, 周明龙, 何志龙, 邢子文, 压缩机用电动机振动噪声故障诊断, 压缩机技术, (2019) 17-20+26.
[29] 杨侨明, 陈文卿, 周明龙, 何志龙, 邢子文, 压缩机用电动机振动噪声研究现状, 制冷与空调, 19 (2019) 65-69+78.
[30] 何志龙, 杨显照, 姬蓝天, 李丹童, 摆动转子压缩机受力分析与理论计算, 流体机械, 47 (2019) 24-30.
[31] Q. Wang, W. Wu, Z. He, D. Ziviani, Analysis of the intake process and its influence on the performance of a two-phase reciprocating expander, Applied Thermal Engineering, 160 (2019).
[32] Q. Wang, W. Wu, Z. He, Thermodynamic analysis and optimization of a novel organic Rankine cycle based micro-scale cogeneration system using biomass fuel, Energy Conversion and Management, 198 (2019).
[33] C. Wang, Z. Xing, W. Chen, S. Sun, Z. He, Analysis of the leakage in a water-lubricated twin-screw air compressor, Applied Thermal Engineering, 155 (2019) 217-225.
[34] J. Lantian, H. Zhilong, H. Yaoxiang, C. Weiqing, X. Ziwen, Investigation on the performance improvement of the scroll compressor by DLC film, IOP Conference Series: Materials Science and Engineering, 604 (2019) 012078 (012010 pp.)-012078 (012010 pp.).
[35] 何志龙, 陈倩, 李丹童, 李博, 气阀对汽车空调涡旋压缩机工作过程的影响研究, 流体机械, 46 (2018) 79-83.
[36] C. Wang, Z. Xing, X. Pan, Z. He, Simulation of the characteristics of the water-lubricated journal bearing in twin-screw air compressor, Industrial Lubrication and Tribology, 70 (2018) 1476-1486.
[37] C. Wang, Z. Xing, W. Chen, Q. Yang, Z. He, Development of an oil free water-lubricated twin-screw air compressor, Applied Thermal Engineering, 143 (2018) 396-402.
[38] W. Tao, Y. Guo, Z. He, X. Peng, Investigation on the delayed closure of the suction valve in the refrigerator compressor by FSI modeling, International Journal of Refrigeration-Revue Internationale Du Froid, 91 (2018) 111-121.
[39] Z. He, T. Wang, X. Wang, X. Peng, Z. Xing, Experimental Investigation into the Effect of Oil Injection on the Performance of a Variable Speed Twin-Screw Compressor, Energies, 11 (2018).
[40] X. Wu, Z. Xing, Z. He, X. Wang, W. Chen, Effects of lubricating oil on the performance of a semi-hermetic twin screw refrigeration compressor, Applied Thermal Engineering, 112 (2017) 340-351.
[41] Y. Tian, Z. Xing, Z. He, H. Wu, Modeling and performance analysis of twin-screw steam expander under fluctuating operating conditions in steam pipeline pressure energy recovery applications, Energy, 141 (2017) 692-701.
[42] F. Hu, Z. Zhang, W. Chen, Z. He, X. Wang, Z. Xing, Experimental investigation on the performance of a twin-screw expander used in an ORC system, in: F. Alam, R. Jazar, H. Chowdhury (Eds.) 1st International Conference on Energy and Power, Icep20162017, pp. 210-215.
[43] Z. He, Z. Jian, T. Wang, D. Li, X. Peng, Iop, Investigation on the variation of pressure in the cylinder of the refrigerator compressor based on FSI model, 10th International Conference on Compressors and Their Systems2017.
[44] Z. He, Q. Chen, D. Li, J. Wang, P. Xia, T. Wang, Iop, Research on Noise Reduction of Reed Valves of a Hermetic Refrigerator Compressor, 10th International Conference on Compressors and Their Systems2017.
[45] 吕鹏, 曹建文, 陈文卿, 李星星, 何志龙, 喷油对变频螺杆压缩机性能影响的试验研究, 压缩机技术, (2016) 27-31.
[46] 郭俊, 李博, 汪少兵, 胡文超, 何志龙, 基于流固耦合的压缩机舌簧阀流量系数与有效作用面积系数的计算(英文), 中国北京, 2016, pp. 6.
[47] X. Wu, Z. Xing, Z. He, X. Wang, W. Chen, Performance evaluation of a capacity-regulated high temperature heat pump for waste heat recovery in dyeing industry, Applied Thermal Engineering, 93 (2016) 1193-1201.
[48] T. Wang, B. Li, Q. Peng, Z. He, X. Peng, Flow Field Simulation and Noise Control of a Twin-Screw Engine-Driven Supercharger, Mathematical Problems in Engineering, (2016).
[49] J. Shen, Z. Xing, K. Zhang, Z. He, X. Wang, Development of a water-injected twin-screw compressor for mechanical vapor compression desalination systems, Applied Thermal Engineering, 95 (2016) 125-135.
[50] J. Shen, Z. Xing, K. Zhang, Z. He, X. Wang, Development of a water-injected twin-screw compressor for mechanical vapor compression desalination systems, Applied Thermal Engineering, 95 (2016) 125-135.
[51] J. Guo, B. Li, S. Wang, W. Hu, Z. He, Ieee, Calculation of Flow Coefficient and Effective Action Area Coefficient of Compressor's Reed Valve based on Fluid-solid Coupling, 2016.
三、授权专利
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专利名称
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类别
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专利号
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相交轴传动的外啮合锥形双螺杆压缩机转子及压缩机
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发明专利
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ZL202110785734.5
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一种单头扭叶罗茨泵转子及罗茨泵
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发明专利
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ZL202110786684.2
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一种变螺距内啮合螺杆转子设计方法及双螺杆压缩机转子
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发明专利
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ZL202110206125.X
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|
多齿空间摆线式内啮合锥形双螺杆压缩机转子及压缩机
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发明专利
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ZL202110786679.1
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一种变螺距的空间内啮合锥形双螺杆压缩机转子及压缩机
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发明专利
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ZL202110786685.7
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|
相交轴传动的空间内啮合锥形双螺杆压缩机转子及压缩机
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发明专利
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ZL202110785786.2
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|
一种扭叶罗茨转子及其设计方法与压缩机、膨胀机
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发明专利
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ZL202011192721.9
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一种基于涡流管的跨临界二氧化碳发电系统
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发明专利
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ZL202010575032.X
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一种研究两相膨胀过程的等效膨胀测试系统和方法
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发明专利
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ZL202011433103.9
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一种低温水蒸馏系统及方法
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发明专利
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ZL201911203851.5
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一种水蒸馏系统及方法
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发明专利
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ZL201911046311.0
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基于有机朗肯循环和有机闪蒸循环的余热回收系统及方法
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发明专利
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ZL201911183874.4
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一种非对称椭圆型扭叶罗茨转子及压缩机、膨胀机
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发明专利
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ZL201911061041.0
|
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一种爪式泵转子及爪式泵
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发明专利
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ZL201911061818.3
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一种螺杆真空泵转子及螺杆真空泵
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发明专利
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ZL201911061811.1
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一种双螺杆转子及膨胀机、压缩机
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发明专利
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ZL201911061022.8
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一种双螺杆转子及压缩机、膨胀机
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发明专利
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ZL201911061033.6
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一种罗茨泵转子及罗茨泵
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发明专利
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ZL201911061820.0
|
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一种椭圆形滚动活塞及滚动活塞压缩机
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发明专利
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ZL201811512096.4
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熔融电石一次冷却粒化成型系统及余热回收方法
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发明专利
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ZL201811331256.5
|
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一种双头爪式泵转子及其型线
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发明专利
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ZL201810707679.6
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一种双电机驱动的双滚动活塞压缩机结构及其控制方法
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发明专利
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ZL201910328993.8
|
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一种双对置活塞压缩机结构
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发明专利
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ZL201811377451.1
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一种严格密封型双齿双螺杆真空泵
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发明专利
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ZL201711064608.0
|
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一种双螺杆真空泵转子型线
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发明专利
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ZL201711066235.0
|
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一种用于压缩机的板阀
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发明专利
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ZL201610332840.7
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|
一种齿环结构气体压缩或膨胀装置
|
发明专利
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ZL201710116607.X
|
|
一种空气压缩机流量测量装置及其标定系统和标定方法
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发明专利
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ZL201410270209.X
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