The PSVD2-26E is a variable displacement axial piston pump that operates on the swashplate principle.
It is designed to work with a hydraulic system, utilizing pressurized fluid to generate mechanical power. With a displacement of 26 cc/rev, this pump is capable of delivering high flow rates and efficient operation.
One of the notable features of the PSVD2-26E is its compact and robust design. It is built to withstand harsh working conditions and heavy loads, ensuring reliable performance even in demanding environments. The pump is constructed with high-quality materials, including durable cast iron and steel components, which contribute to its long lifespan and resistance to wear and tear.
The PSVD2-26E main pump is equipped with advanced control mechanisms, allowing for precise adjustment of flow and pressure. It offers a variable displacement range that enables operators to optimize the pump's output according to specific tasks and requirements. This flexibility enhances efficiency, reduces energy consumption, and minimizes the strain on the overall hydraulic system.
The pump features a built-in pressure compensator, which automatically adjusts the flow rate to maintain a consistent pressure level. This feature ensures smooth operation and protects the pump from excessive pressure, preventing potential damage or system failure. Additionally, the PSVD2-26E incorporates a hydraulic servo system, which enables precise control of the swashplate angle for fine-tuning the pump's performance.
Another advantage of the PSVD2-26E is its compatibility with various excavator models.
It is designed to be easily integrated into different hydraulic systems, making it a versatile choice for equipment manufacturers and operators. This interchangeability simplifies the replacement process and reduces downtime in case of pump failure or maintenance requirements.
Furthermore, the PSVD2-26E pump is engineered for efficient operation. It boasts high volumetric efficiency, which means it can deliver a large amount of fluid per revolution, maximizing productivity and reducing cycle times. This efficiency is further enhanced by the pump's low internal leakage, minimizing energy loss and contributing to overall system performance.
