摘要 An overview of some popular rotary and reciprocating positive displacement (PD) pump types is given with the objective of presenting and comparing the respective sizing relationships and performance features. Reciprocating pumps discussed are the piston and plunger types. Rotary pumps addressed are gear (external and internal), vane, lobe, screw, and liquid ring pumps. To put the relative pump sizes in perspective, attention is fixed on the rotors or reciprocating elements of PD pumps, just as impellers indicate the sizes of rotodynamic pumps. The size of a PD pump is found from a dimensionless combination of displacement flow rate, rotative speed and diameter. The flow rate, head (or pressure rise) and power are related through the component efficiencies. The cavitation coefficient, often close to unity, connects the rotor tip speed or piston speed with the required NPSH, which can also be affected by the pressure rise of the pump due to leakage across the internal clearances. Operational effects due to cavitation, ingestion of gas or abrasives, and viscous and nonNewtonian fluids are discussed.
Abstract:An overview of some popular rotary and reciprocating positive displacement (PD) pump types is given with the objective of presenting and comparing the respective sizing relationships and performance features. Reciprocating pumps discussed are the piston and plunger types. Rotary pumps addressed are gear (external and internal), vane, lobe, screw, and liquid ring pumps. To put the relative pump sizes in perspective, attention is fixed on the rotors or reciprocating elements of PD pumps, just as impellers indicate the sizes of rotodynamic pumps. The size of a PD pump is found from a dimensionless combination of displacement flow rate, rotative speed and diameter. The flow rate, head (or pressure rise) and power are related through the component efficiencies. The cavitation coefficient, often close to unity, connects the rotor tip speed or piston speed with the required NPSH, which can also be affected by the pressure rise of the pump due to leakage across the internal clearances. Operational effects due to cavitation, ingestion of gas or abrasives, and viscous and nonNewtonian fluids are discussed.
通讯作者:
Wang Chaowei(1982—), male, senior R&D engineer, M.S.(Corresponding author, chaoweiwang@gmail.com), research fields:hydraulic design and analysis.
作者简介: Cooper Paul(1934—), male, consultant, Ph.D.(paul.cooper@verizon.net), research fields:research, education and consulting in fluid machinery, mainly pumps.
引用本文:
Cooper Paul, Wang Chaowei. Sizing and performance features of rotary and reciprocating positive displacement pumps[J]. 排灌机械工程学报, 2014, 32(12): 1013-1022.
Cooper Paul, Wang Chaowei. Sizing and performance features of rotary and reciprocating positive displacement pumps. Journal of Drainage and Irrigation Machinery Engin, 2014, 32(12): 1013-1022.
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