|
| ब्रांड नाम: | SY Hydraulic |
| मॉडल संख्या: | SY-A4VSO |
| एमओक्यू: | 1pc |
| मूल्य: | USD 1000-2000 / pc |
| भुगतान की शर्तें: | T/T |
| आपूर्ति करने की क्षमता: | 1000 pcs per month |
A4VSO Rexroth Piston Pump SAE Ports 95CC Displacement for Energy Sector
Features:
Technical data:
| Size | 40 | 71 | 125 | 180 | 200 | 250 | 355 | 500 | |||
| Displacement | Vg max | mL/r | 40 | 71 | 125 | 180 | 200 | 250 | 355 | 500 | |
| Max. Speed | Vg= Vg max | nnom | r/min | 2600 | 2200 | 1800 | 1800 | 1800 | 1500 | 1500 | 1320 |
| Vg≤Vg max | nmax | r/min | 3200 | 2700 | 2200 | 2100 | 2100 | 1800 | 1700 | 1600 | |
| Flow | at nnom and Vg max | qv | L/min | 104 | 156 | 225 | 324 | 360 | 375 | 533 | 660 |
| n = 1500 r/min | L/min | 60 | 107 | 186 | 270 | 420 | 375 | 533 | 581 | ||
| Power Δp=350 bar |
n=nnom | P | kW | 61 | 91 | 131 | 189 | 245 | 219 | 311 | 385 |
| n = 1500 r/min | P | kW | 35 | 62 | 109 | 158 | 210 | 219 | 311 | 339 | |
| Torque Vg= Vg max |
Δp=350 bar | Mmax | Nm | 223 | 395 | 696 | 1002 | 1114 | 1391 | 1976 | 2783 |
| Δp=100 bar | M | Nm | 64 | 113 | 199 | 286 | 318 | 398 | 564 | 795 | |
| Inertia moment of the driveshaft | JTW | kgm2 | 0.0049 | 0.0121 | 0.03 | 0.055 | 0.055 | 0.0959 | 0.19 | 0.3325 | |
| Volume of case | V | L | 2 | 2.5 | 5 | 4 | 4 | 10 | 8 | 14 | |
| Weight | m | kg | 39 | 53 | 88 | 102 | 102 | 184 | 207 | 320 | |
| Permissibleload of the drive shaft | Max.axial force | ± Fax max | N | 600 | 800 | 1000 | 1400 | 1400 | 1800 | 2000 | 2000 |
| Max.radial force | Fq max | N | 1000 | 1200 | 1600 | 2000 | 2000 | 2000 | 2200 | 2500 | |
Specifications:
|
Warranty
|
1 Year
|
|
Model
|
SY-A4VSO
|
|
Place of Origin
|
China
|
|
Type
|
Hydraulic piston pump
|
|
Color
|
Available any color
|
|
Material
|
Cast iron
|
|
Application
|
Tunnel Boring Machinery
|
|
Feature
|
High Quality
|
|
Delivery Time
|
15 Days after Payment
|
|
MOQ
|
1 Piece
|
Applications:
Competitive Advantage:
1. With selectable load‑sensing and pressure‑compensated control modes, the A4VSO axial piston pump intelligently modulates its displacement to match consumer demand, preventing pressure spikes and hydraulic shock when load conditions change abruptly; this self‑regulating performance not only protects downstream valves and actuators from undue stress but also maintains smooth, uninterrupted operation, making the pump an ideal choice for sensitive applications in tunnel boring machines, precision forging presses, and material handling equipment that demand both safety and repeatability under fluctuating process loads.
2. Featuring an integrated electro‑hydraulic proportional control interface, the A4VSO hydraulic pump seamlessly communicates with PLC and SCADA automation platforms, enabling closed‑loop feedback of flow and pressure setpoints; this capability to fine‑tune hydraulic outputs reduces overshoot during startup and transition phases, improves process repeatability, and enhances safety in applications like aerospace test stands, automotive dynamometers, and wind turbine pitch systems, where precise motion control is paramount. The pump’s digital interface accelerates commissioning and simplifies system tuning, driving faster time‑to‑market for OEM equipment designers.
3. Optional integrated oil cooler assemblies available for the A4VSO axial piston pump significantly enhance heat dissipation, allowing continuous operation under high ambient temperatures or sustained heavy‑load conditions; by maintaining optimum oil viscosity, the pump prevents efficiency losses due to thermal thinning and reduces the risk of seal degradation, thereby extending service life and reliability in applications such as steel mill rolling lines, paper machine coaters, and offshore drilling rigs, where consistent thermal management directly impacts process stability and safety.
The Analysis For Rexroth A4VSO Piston Pump Common Breakdown:
1. Bearing fatigue and failure causing abnormal noise: The high‑rigidity ball thrust and radial bearings, when subjected to continuous shock loads, can wear due to insufficient lubrication or particulate contamination, leading to roller deformation and cage cracking. This manifests as metallic impact sounds during operation. If abnormal noise and bearing temperature rise are detected, immediate shutdown and bearing replacement are critical to prevent shaft bending or crack propagation that could irreversibly damage the pump housing. Implementing multi‑stage internal filtration and adhering to filter replacement schedules substantially reduces bearing failure risk in the hydraulic pump.
2. Stiction in control valves causing pressure instability: Integrated pressure control or load‑sensing valves may stick when contaminants enter the clearance between spool and sleeve, resulting in erratic output pressure. Systems exhibiting pressure surges and inconsistent actuator behavior often suffer from valve stiction. Regular valve body cleaning and timely replacement of high‑efficiency filters mitigate spool wear and binding. Additionally, monitoring real‑time oil cleanliness—maintaining particle counts below ISO 4406 16/14/11—helps prolong valve life and ensures smooth operation of the axial piston pump’s hydraulic control components.
3. Overtemperature triggering thermal protection shutdown: The integrated thermal protection device reduces displacement or shuts the pump down when oil temperature exceeds 120 ℃ to prevent internal component damage. Frequent thermal trips often indicate insufficient cooling system capacity or excessive load demands. Inspection of the integrated and external cooling circuits is necessary to ensure proper heat exchange. Verifying hydraulic fluid viscosity grade matches manufacturer recommendations and adjusting soft‑start parameters to limit inrush flow can prevent sudden temperature spikes and reduce repeated activation of the axial piston pump’s thermal safeguard.
