basic working principle of centrifugal pump|centrifugal pump size chart

The most common centrifugal pump control methods are • Stop-Start/Float Level control Operation • Control Valve Operation . This is generally the lowest cost and most popular method of controlling the flow rate of a .

Centrifugal pumps are vital equipment in various industries for the transportation of fluids. They operate on the principle of converting rotational kinetic energy into hydrodynamic energy to move liquids. These pumps are classified into different types based on various factors such as the number of impellers or stages, impeller design, case-split orientation, volute type, bearing support, shaft orientation, and other miscellaneous features. Understanding the basic working principle of centrifugal pumps is essential for efficient operation and maintenance.

The Centrifugal pumpis working based on the centrifugal force and the name follows the same. Fluid enters into the pumps, gets the energy from the centrifugal force of the impeller, and raised its velocity and pressure. Due to this pressure, the liquid is transferred from one place to another. See more

Number of Impellers or Stages

The number of impellers or stages in a centrifugal pump determines its capacity to increase the pressure of the fluid being pumped. Single-stage pumps have only one impeller, while multi-stage pumps have multiple impellers arranged in series to achieve higher pressure levels. The selection of the number of impellers or stages depends on the specific requirements of the application.

Impeller Design

The design of the impeller plays a crucial role in the performance of a centrifugal pump. Different impeller designs, such as open, semi-open, and closed, impact the pump's efficiency, flow rate, and head generation. The selection of the appropriate impeller design is based on factors like the type of fluid, operating conditions, and desired performance characteristics.

Case-Split Orientation

The orientation of the case-split in a centrifugal pump refers to how the pump casing is divided to access the internal components. Horizontal split-case pumps have a casing that is split horizontally, while vertical split-case pumps have a vertical split. The choice of case-split orientation depends on installation space, maintenance requirements, and operational preferences.

Type of Volute

The volute is a critical component of a centrifugal pump that converts the kinetic energy of the fluid into pressure. Different types of volutes, such as single volute, double volute, and concentric volute, affect the pump's efficiency and performance. The selection of the appropriate volute type is based on factors like flow characteristics and system requirements.

Bearing Support

Bearing support is essential for the smooth operation of a centrifugal pump. The type of bearing support, such as ball bearings, sleeve bearings, or magnetic bearings, influences the pump's reliability, maintenance needs, and lifespan. Proper bearing support ensures minimal friction, noise, and vibration during pump operation.

Shaft Orientation

The orientation of the shaft in a centrifugal pump can be horizontal or vertical, depending on the application requirements. Horizontal shaft pumps are commonly used in industrial settings, while vertical shaft pumps are preferred for specific applications like sump pumping. The shaft orientation affects the pump's footprint, installation flexibility, and maintenance accessibility.

Miscellaneous Features

The main parts of the Centrifugal Pump are: 1. Impeller 2. Casing 3. Backplate 4. Suction & Discharge Nozzles 5. Suction pipe 6. A foot valve 7. Strainer 8. Suction nozzle or suction

Centrifugal pumps perform better in the center of the curve known as BEP (best efficiency point). At lower or higher pressure levels, the centrifugal pump efficiency reduces. It is therefore suggested to operate centrifugal pumps within a window of 80 . See more

basic working principle of centrifugal pump|centrifugal pump size chart