High-Speed Construction Machinery Piston Motor 150 cc/rev Reinforced Cast Iron Housing

High-Speed Construction Machinery Piston Motor 150 cc/rev Reinforced Cast Iron Housing

Features:

1. Regulation via pump flow and motor displacement synergy

2. Torque amplification through pressure differential and displacement

3. High-efficiency energy transfer in hydrostatic transmission

4. Modular control device selection (mechanical/hydraulic/electronic)

5. Cost-efficient design eliminating gear shift mechanisms

6. Infinitely adjustable displacement from Vg max to Vg min=0

7. Output speed proportional to flow rate and inversely proportional to displacement

8. Torque increases linearly with pressure differential and displacement

9. Compact bent-axis structure

10. High power-to-weight ratio design

Technical data:

Specifications:

Applications:

Competitive Advantage:

1. Featuring advanced internal dynamic balancing and precision static-dynamic calibration, the Rexroth A6VM piston motor dramatically reduces axial and radial imbalance forces, minimizing vibration and noise emission. This optimized design enhances operator comfort and extends the service life of bearings and seals by reducing mechanical stress. Ideal for noise‑sensitive applications such as indoor machinery and urban construction equipment, this hydraulic motor delivers smooth, quiet operation without compromising on performance. As a result, it contributes to healthier work environments and lower maintenance costs.

2. Compliant with international hydraulic interface standards such as ISO 4401 and DIN 24340, the Rexroth A6VM axial piston motor offers a wide selection of flanges and mounting plates. Its standardized design simplifies procurement for OEMs and ensures global parts interchangeability and on‑site spares support. By streamlining logistics and reducing lead times, this hydraulic motor accelerates equipment delivery and service cycles worldwide. Whether deployed in North America, Europe, or Asia, this piston motor’s compatibility with existing systems minimizes integration effort and maximizes uptime.

3.  Equipped with digital fluid monitoring sensors, the Rexroth A6VM piston motor collects real‑time data on pressure, temperature, vibration, and flow. Its integrated gateway supports near‑field wireless transmission to cloud platforms for big‑data analytics. Through predictive maintenance algorithms and remote parameter tuning, this axial piston motor enhances smart maintenance capabilities and minimizes unplanned downtime. Perfect for Industry 4.0 smart factories and remote monitoring installations, this hydraulic motor delivers actionable insights for operational optimization and lifecycle cost reduction.

The Analysis For Rexroth A6VM Piston Motor Common Breakdown:

1. In failure scenario number 22, design defects or manufacturing tolerances in internal oil passages may lead to localized cavitation, generating fine bubbles and associated noise. This fault causes torque pulsations, efficiency loss, and accelerated component fatigue. It is recommended to disassemble the motor to inspect passage geometries and machining precision, optimize the oil channel design if necessary, and thoroughly clean internal passages to prevent bubble entrapment. Additionally, consider integrating cavitation suppression devices, such as suction line throttling valves, into the hydraulic circuit to mitigate bubble formation and protect the motor.

2. In failure scenario number 23, cross-contamination within the valve block passages can cause the valve spool to stick or select incorrect channels, resulting in unstable motor operation modes. This fault manifests as the motor failing to switch displacement correctly, leading to inefficient performance or complete lock-up. It is recommended to perform ultrasonic cleaning of the valve block, inspect passage connectivity, and recondition the internal surfaces by precision honing or replating if necessary. Replace aged seals to restore tight tolerances and proper fluid separation within the valve block for accurate mode transitions and reliable motor control.

3. In failure scenario number 24, excessive axial forces within the motor can cause axial displacement and create gaps between the end cap and cylinder body, leading to leakage and performance degradation. Symptoms include increased return flow, reduced efficiency, and accelerated end cap wear. Recommended corrective actions involve inspecting the axial thrust balance rings and end cap locating pins, resizing balance rings or reinstalling alignment dowels as needed, and verifying that axial forces remain within the motor’s design parameters. Addressing these issues eliminates gaps and restores hydraulic balance for optimal motor performance.