The plunger displacement requirements and construction parameters of a high pressure plunger pump depend on several factors including required flow, pressure requirements and specific application. Here is an overview of these considerations: Plunger displacement requirements: Plunger displacement is the volume of fluid displaced by the plunger per stroke. It determines the flow rate of the pump and is usually expressed in units such as liters per minute (LPM) or gallons per minute (GPM). The plunger displacement requirement is determined by the flow required by the application. To calculate plunger displacement, you need to consider the required flow, which is usually dictated by system requirements. The flow rate depends on factors such as the amount of fluid that needs to be pumped per unit of time and the operating conditions of the system. Structural parameters: The structural parameters of high pressure plunger pumps are designed to handle specific operating conditions and pressure requirements. These parameters include: Plunger Diameter: The plunger diameter determines the cross-sectional area of the plunger and affects the force applied during pumping. Larger plunger diameters are typically used for higher flow rates and higher pressure applications. Stroke Length: Stroke length is the distance the plunger moves with each stroke. It determines the volume of fluid displaced per stroke. The stroke length is selected according to the required flow and the structural capacity of the pump. Working Pressure: High pressure plunger pumps are designed to handle a specific pressure range. The structural parameters such as the materials used, the design of the cylinder and valves, and the sealing mechanism are all selected to withstand the required working pressure. Materials of Construction: Materials used in pump construction should be compatible with the fluid being pumped and the operating conditions. Common materials include stainless steel, brass, and high-strength alloys to withstand high pressure and resist corrosion or wear. 90R130-KT-5-BC-80-R-3-F1-H-03-GBA-38-38-24 90R130KT5BC80R3F1H03GBA383824 90-R-130-KT-5-BC-80-P-3-F1-H-04-GBA-38-38-24 90R130KT5BC80P3F1H04GBA383824 90R130-KT-5-BC-80-P-3-F1-H-04-GBA-38-38-24 90R130KT5BC80P3F1H04GBA383824 90-R-130-KT-5-BC-80-L-4-F1-F-00-GBA-35-35-24 90R130KT5BC80L4F1F00GBA353524 90R130-KT-5-BC-80-L-4-F1-F-00-GBA-35-35-24 90R130KT5BC80L4F1F00GBA353524 90-R-130-KT-1-NN-80-L-3-F1-H-00-GBA-32-32-28 90R130KT1NN80L3F1H00GBA323228 90R130-KT-1-NN-80-L-3-F1-H-00-GBA-32-32-28 90R130KT1NN80L3F1H00GBA323228 90-R-130-KT-1-DE-80-R-4-F1-H-00-GBA-38-32-30 90R130KT1DE80R4F1H00GBA383230 90R130-KT-1-DE-80-R-4-F1-H-00-GBA-38-32-30 90R130KT1DE80R4F1H00GBA383230 90-R-130-KT-1-CD-80-R-4-F1-H-00-GBA-38-32-30 90R130KT1CD80R4F1H00GBA383230 Sealing Mechanism: Piston pumps employ a sealing mechanism, such as packing or seals, to ensure a proper seal between the plunger and cylinder. Seal material selection and seal system design are important considerations in preventing leaks and maintaining efficiency. Drive Mechanism: High pressure plunger pumps can be driven by various mechanisms including electric motors, internal combustion engines or hydraulic motors. The drive mechanism should be selected based on power requirements, operating conditions and specific application needs. Cooling and Lubrication: Some high pressure piston pumps may contain cooling and lubrication systems to manage the heat generated during operation and ensure smooth operation. These systems may include heat exchangers, coolers or dedicated lubrication mechanisms. Number of plungers: High pressure plunger pumps can have one plunger or multiple plungers, arranged in a radial or axial configuration. The number of plungers affects the flow and pressure capabilities of the pump. Multiple plungers operating in parallel can provide higher flow rates and greater efficiency than a single plunger. Plunger Speed: The speed at which the plunger moves affects the flow and pressure produced by the pump. Plunger speed is generally determined by the drive mechanism and desired operating conditions. It is important to ensure that the construction parameters and materials of the pump are capable of withstanding the forces and stresses associated with the required plunger speed. Valve Design: High pressure plunger pumps contain valves that control the flow of fluid into and out of the pump chamber. The design of these valves, such as ball or plate valves, affects the efficiency, pressure capability and wear resistance of the pump. Proper valve design is critical to minimizing fluid leakage and optimizing pump performance. Power requirements: The power requirements of a high pressure plunger pump depend on factors such as pump flow, pressure and efficiency. The drive mechanism should be selected to provide sufficient power to meet the operational demands of the pump, taking into account factors such as energy efficiency and environmental considerations. Noise and Vibration: The structural design of the pump affects the noise and vibration levels during operation. Features such as solid construction, precise balance of moving parts, and vibration-damping mechanisms help reduce noise and vibration, providing smoother, quieter operation. 90R130-KT-1-CD-80-R-4-F1-H-00-GBA-38-32-30 90R130KT1CD80R4F1H00GBA383230 90-R-130-KT-1-CD-80-R-4-F1-F-03-GBA-26-26-20 90R130KT1CD80R4F1F03GBA262620 90R130-KT-1-CD-80-R-4-F1-F-03-GBA-26-26-20 90R130KT1CD80R4F1F03GBA262620 90-R-130-KT-1-CD-80-D-3-F1-L-00-GBA-38-38-24 90R130KT1CD80D3F1L00GBA383824 90R130-KT-1-CD-80-D-3-F1-L-00-GBA-38-38-24 90R130KT1CD80D3F1L00GBA383824 90-R-130-KT-1-BC-80-S-3-F1-H-00-GBA-38-38-24 90R130KT1BC80S3F1H00GBA383824 90R130-KT-1-BC-80-S-3-F1-H-00-GBA-38-38-24 90R130KT1BC80S3F1H00GBA383824 90-R-130-KT-1-BC-80-R-3-F1-H-03-GBA-42-42-24 90R130KT1BC80R3F1H03GBA424224 90R130-KT-1-BC-80-R-3-F1-H-03-GBA-42-42-24 90R130KT1BC80R3F1H03GBA424224 90-R-130-KT-1-BC-80-D-3-F1-L-00-GBA-32-32-24 90R130KT1BC80D3F1L00GBA323224 Maintenance and Serviceability: Consider the ease of maintenance and serviceability of the pump. Components such as seals, packings and valves shall be easy to inspect, replace or maintain. A well-designed pump will provide easy disassembly and reassembly of the unit, minimizing downtime and facilitating routine maintenance tasks. Compliance with standards: High pressure plunger pumps should comply with relevant industry standards and regulations to ensure their safety, performance and environmental compatibility. Examples of such standards include those developed by organizations such as ISO (International Organization for Standardization) or specific industry standards for applications such as oil and gas, mining or industrial processes. When selecting a high pressure piston pump, be sure to consult the manufacturer or supplier to understand the specific requirements of your application. They can provide guidance on proper plunger displacement, construction parameters and other considerations based on your system requirements and operating conditions.