The axial flow path characteristics of an axial piston pump refer to the design and behavior of fluid flow in the axial flow path of the pump. These passages play a vital role in generating the required hydraulic oil pressure and flow in the pump. Following are some key characteristics of axial flow passages in axial piston pumps: 1. Axial: As the name suggests, the fluid flow in an axial piston pump mainly occurs in the axial direction. The pump consists of a cylinder with multiple axial passages or holes. These channels are aligned parallel to the axis of rotation of the pump. 2. Piston movement: There is a reciprocating plunger in each axial flow channel. These plungers are driven by a swash plate mechanism or other device that converts rotary motion into linear motion. The movement of the piston creates the necessary pressure differential to drive fluid flow. 3. Suction and Discharge: Axial flow channels have a suction and discharge that allow fluid to enter and exit the pump. These ports are strategically positioned along the length of the channel to facilitate fluid flow. 4. Valves or ports: Depending on the specific design of the axial piston pump, there may be valves or ports within the axial flow channels to control the direction and timing of fluid flow. These valves or ports ensure proper synchronization of the plungers and control the flow of fluid during the different phases of pump operation. 90-R-250-HF-2-CD-80-T-4-C8-J-03-NNN-32-32-24 90R250HF2CD80T4C8J03NNN323224 90R250-HF-2-CD-80-T-4-F1-K-03-NNN-38-38-28 90R250HF2CD80T4F1K03NNN383828 90-R-250-HF-2-CD-80-T-4-F1-K-03-NNN-38-38-28 90R250HF2CD80T4F1K03NNN383828 90R250-HF-2-EG-80-T-3-C8-K-00-NNN-32-32-24 90R250HF2EG80T3C8K00NNN323224 90-R-250-HF-2-EG-80-T-3-C8-K-00-NNN-32-32-24 90R250HF2EG80T3C8K00NNN323224 90R250-HF-2-EG-80-T-4-C8-K-03-NNN-32-32-24 90R250HF2EG80T4C8K03NNN323224 90-R-250-HF-2-EG-80-T-4-C8-K-03-NNN-32-32-24 90R250HF2EG80T4C8K03NNN323224 90-R-250-HF-5-AB-80-S-3-C8-K-03-NNN-42-42-24 90R250HF5AB80S3C8K03NNN424224 90R250-HF-5-AB-80-S-4-C8-J-03-NNN-42-42-24 90R250HF5AB80S4C8J03NNN424224 90-R-250-HF-5-AB-80-S-4-C8-J-03-NNN-42-42-24 90R250HF5AB80S4C8J03NNN424224 90R250-HF-5-AB-80-S-4-C8-K-03-NNN-42-42-24 90R250HF5AB80S4C8K03NNN424224 90-R-250-HF-5-AB-80-S-4-C8-K-03-NNN-42-42-24 90R250HF5AB80S4C8K03NNN424224 90R250-HF-5-AB-80-T-3-C8-J-03-NNN-42-42-24 90R250HF5AB80T3C8J03NNN424224 90-R-250-HF-5-AB-80-T-3-C8-J-03-NNN-42-42-24 90R250HF5AB80T3C8J03NNN424224 90R250-HF-5-AB-80-T-4-C8-K-03-NNN-42-42-24 90R250HF5AB80T4C8K03NNN424224 90-R-250-HF-5-AB-80-T-4-C8-K-03-NNN-42-42-24 90R250HF5AB80T4C8K03NNN424224 90R250-HF-5-AB-80-T-4-F1-K-03-NNN-35-17-24 90R250HF5AB80T4F1K03NNN351724 90-R-250-HF-5-AB-80-T-4-F1-K-03-NNN-35-17-24 90R250HF5AB80T4F1K03NNN351724 90R250-HF-5-BB-80-S-3-C8-J-03-NNN-38-20-24 90R250HF5BB80S3C8J03NNN382024 90-R-250-HF-5-BB-80-S-3-C8-J-03-NNN-38-20-24 90R250HF5BB80S3C8J03NNN382024 5. Sealing element: In order to maintain the required pressure difference and prevent leakage, the axial flow channel is equipped with a sealing element. These seals ensure fluid flow in the desired direction and minimize internal leakage. 6. Flow adjustment: The axial flow channel of the axial piston pump is used to adjust the flow of hydraulic oil. The pump can have variable displacement capability, allowing flow to be adjusted according to the needs of the system. This is accomplished by adjusting the angle of the swash plate or other mechanism that controls the length of the plunger stroke. 7. Efficiency considerations: The design of the axial flow channel takes efficiency considerations into consideration. Channels are optimized to minimize pressure loss, turbulence and internal leakage, increasing the overall efficiency of the pump. 8. Pressure balance: The design of the axial flow channel can ensure proper pressure balance in the pump. This helps distribute the load evenly across the plunger and reduces excessive stress on components. 9. Cooling and lubrication: the axial flow channel also plays the role of cooling and lubrication of the pump. Hydraulic oil flows through these channels to help dissipate heat generated during operation and provide lubrication to moving parts. 90R250-HF-5-BB-80-T-3-C8-K-03-NNN-35-35-24 90R250HF5BB80T3C8K03NNN353524 90-R-250-HF-5-BB-80-T-3-C8-K-03-NNN-35-35-24 90R250HF5BB80T3C8K03NNN353524 90R250-HF-5-BB-80-T-4-C8-K-03-NNN-35-35-28 90R250HF5BB80T4C8K03NNN353528 90-R-250-HF-5-BB-80-T-4-C8-K-03-NNN-35-35-28 90R250HF5BB80T4C8K03NNN353528 90R250-HF-5-BC-80-S-3-C8-K-03-NNN-42-42-24 90R250HF5BC80S3C8K03NNN424224 90-R-250-HF-5-BC-80-S-3-C8-K-03-NNN-42-42-24 90R250HF5BC80S3C8K03NNN424224 90R250-HF-5-BC-80-S-4-C8-J-03-NNN-26-26-24 90R250HF5BC80S4C8J03NNN262624 90-R-250-HF-5-BC-80-S-4-C8-J-03-NNN-26-26-24 90R250HF5BC80S4C8J03NNN262624 90R250-HF-5-BC-80-S-4-F1-J-03-NNN-17-17-24 90R250HF5BC80S4F1J03NNN171724 90-R-250-HF-5-BC-80-S-4-F1-J-03-NNN-17-17-24 90R250HF5BC80S4F1J03NNN171724 90R250-HF-5-BC-80-S-4-F1-J-03-NNN-42-42-24 90R250HF5BC80S4F1J03NNN424224 90-R-250-HF-5-BC-80-S-4-F1-J-03-NNN-42-42-24 90R250HF5BC80S4F1J03NNN424224 90R250-HF-5-BC-80-T-3-F1-J-03-NNN-23-23-24 90R250HF5BC80T3F1J03NNN232324 90-R-250-HF-5-BC-80-T-3-F1-J-03-NNN-23-23-24 90R250HF5BC80T3F1J03NNN232324 90R250-HF-5-BC-80-T-4-F1-J-03-NNN-29-29-24 90R250HF5BC80T4F1J03NNN292924 90-R-250-HF-5-BC-80-T-4-F1-J-03-NNN-29-29-24 90R250HF5BC80T4F1J03NNN292924 90R250-HF-5-CD-80-S-4-C8-K-03-NNN-42-42-24 90R250HF5CD80S4C8K03NNN424224 90-R-250-HF-5-CD-80-S-4-C8-K-03-NNN-42-42-24 90R250HF5CD80S4C8K03NNN424224 90R250-HF-5-CD-80-T-3-C8-K-03-NNN-40-40-28 90R250HF5CD80T3C8K03NNN404028 90-R-250-HF-5-CD-80-T-3-C8-K-03-NNN-40-40-28 90R250HF5CD80T3C8K03NNN404028 10. Material considerations: The choice of axial flow channel material is very important to ensure compatibility with the hydraulic fluid used and to withstand the pressures and forces exerted within the pump. Common materials include high-strength alloys, hardened steels, and surface coatings to enhance wear resistance. 11. Cylinder block layout: The axial flow channel is usually arranged radially around the central axis or cylinder of the pump. The cylinder block contains a number of axial flow passages, each of which houses a plunger assembly. 12. Plunger arrangement: The plungers in the axial flow channel are evenly distributed around the cylinder body. The number of plungers can vary according to pump design and application requirements. Common configurations include pumps with three, five, seven or nine plungers. 13. Cross-sectional shape: The cross-sectional shape of the axial flow channel is usually rectangular or oval. This shape helps to optimize the flow path and minimize pressure loss. 14. Swash plate angle: In many axial piston pumps, the swash plate mechanism is used to convert the rotational motion of the pump shaft into the reciprocating motion of the plunger. The angle of the swash plate can be adjusted to change the plunger stroke length and control the displacement and flow of the pump. 15. Pressure compensation: Axial piston pumps usually employ a pressure compensation mechanism to maintain a constant flow regardless of system pressure. These mechanisms help ensure that the pump provides a constant flow even when operating under varying load conditions. 90R250-HF-5-CD-80-T-3-C8-K-03-NNN-42-42-28 90R250HF5CD80T3C8K03NNN424228 90-R-250-HF-5-CD-80-T-3-C8-K-03-NNN-42-42-28 90R250HF5CD80T3C8K03NNN424228 90R250-HF-5-CD-80-T-3-F1-K-03-NNN-35-35-24 90R250HF5CD80T3F1K03NNN353524 90-R-250-HF-5-CD-80-T-3-F1-K-03-NNN-35-35-24 90R250HF5CD80T3F1K03NNN353524 90R250-HF-5-CD-80-T-4-C8-J-03-NNN-35-35-24 90R250HF5CD80T4C8J03NNN353524 90-R-250-HF-5-CD-80-T-4-C8-J-03-NNN-35-35-24 90R250HF5CD80T4C8J03NNN353524 90R250-HF-5-CD-80-T-4-C8-K-03-NNN-35-35-28 90R250HF5CD80T4C8K03NNN353528 90-R-250-HF-5-CD-80-T-4-C8-K-03-NNN-35-35-28 90R250HF5CD80T4C8K03NNN353528 90R250-HF-5-CD-80-T-4-C8-K-03-NNN-38-38-24 90R250HF5CD80T4C8K03NNN383824 90-R-250-HF-5-CD-80-T-4-C8-K-03-NNN-38-38-24 90R250HF5CD80T4C8K03NNN383824 90R250-HF-5-CD-80-T-4-F1-J-03-NNN-29-29-24 90R250HF5CD80T4F1J03NNN292924 90-R-250-HF-5-CD-80-T-4-F1-J-03-NNN-29-29-24 90R250HF5CD80T4F1J03NNN292924 90R250-HF-5-CD-80-T-4-F1-K-03-NNN-26-26-24 90R250HF5CD80T4F1K03NNN262624 90-R-250-HF-5-CD-80-T-4-F1-K-03-NNN-26-26-24 90R250HF5CD80T4F1K03NNN262624 90R250-HF-5-DE-80-T-3-C8-J-03-NNN-35-35-28 90R250HF5DE80T3C8J03NNN353528 90-R-250-HF-5-DE-80-T-3-C8-J-03-NNN-35-35-28 90R250HF5DE80T3C8J03NNN353528 90R250-HF-5-DE-80-T-3-C8-J-04-NNN-35-35-24 90R250HF5DE80T3C8J04NNN353524 90-R-250-HF-5-DE-80-T-3-C8-J-04-NNN-35-35-24 90R250HF5DE80T3C8J04NNN353524 90R250-HF-5-DE-80-T-3-C8-K-06-NNN-35-35-24 90R250HF5DE80T3C8K06NNN353524 90-R-250-HF-5-DE-80-T-3-C8-K-06-NNN-35-35-24 90R250HF5DE80T3C8K06NNN353524 16. Filtration: In order to maintain the performance and service life of the pump, proper filtration of hydraulic oil is very important. Filter elements are usually integrated into the air inlet or a separate filter unit to prevent contaminants from entering the axial flow channels and causing damage to pump components. 17. Wear Considerations: Axial flow channels and associated components are subject to wear due to reciprocating motion and high pressure. To reduce wear, proper surface treatment, coatings and high wear resistant materials are used to prolong the life of the pump. 18. Material Compatibility: Selection of axial flow channel material is critical to ensure compatibility with hydraulic oil and prevent corrosion or degradation. Materials such as steel alloys, cast iron or special coatings are often used to provide the necessary strength and corrosion resistance. 19. Leakage Control: Proper sealing and leakage control are critical to maintaining the efficiency of an axial piston pump. Sealing elements such as O-rings or piston rings are employed to minimize internal leakage and maintain the required differential pressure within the axial flow passage. 20. Manufacturing Precision: The manufacturing precision of axial flow passages and related components is critical to ensure proper alignment, smooth operation and optimum performance of the pump. Precision machining techniques are used to achieve tight tolerances and minimize backlash. Together, these characteristics contribute to the efficient and reliable operation of axial piston pumps by controlling hydraulic fluid flow, pressure and displacement. Manufacturers carefully design and optimize axial flow passages to achieve desired performance characteristics and meet the specific requirements of various hydraulic systems.