What is the working principle of wear-resisting slurry pump?Slurry pump is a kind of centrifugal pump with high efficiency and relatively strong performance developed in recent years due to the large surface of material transport particles.Through the following points can let you understand the working principle of slurry pump.
First of all, the relationship between centrifugal pump and slurry pump, centrifugal concept from the pump principle, there are many kinds of pumps, according to different angles can be divided into dozens of categories.Centrifugal pump is divided from the working principle of the pump, is through the centrifugal force to achieve the process of pressurizing the conveying medium.In addition, there are common types including screw principle, plunger principle and so on can be divided into different from the centrifugal principle of the pump.
Say next slurry pump, slurry pump is divided from the transport medium.As the name implies, slurry pump is the transport of solid particles containing residues and water mixture, but from the principle of slurry pump belongs to a centrifugal pump, the main components of slurry pump is the impeller and the housing, the impeller device in the housing is located on the shaft, and connected with the prime mover to form a whole.
The main working parts are the impeller and the housing. The impeller device in the housing is located on the shaft and connected with the prime mover to form a whole.When the prime mover machine drives the impeller to rotate, the blade in the impeller forces the fluid to rotate, that is, the blade does work on the fluid along its motion direction, thus forcing the pressure potential energy and kinetic energy of the fluid to increase.At the same time, the fluid under the action of inertial force, from the center to the impeller edge flow, and at a high speed out of the impeller, into the pressure chamber, and then through the diffusion pipe discharge, this process is called the pressure water process.At the same time, due to the flow of fluid to the edge of the impeller center, a low-pressure area is formed in the center of the impeller. When it has enough vacuum, under the action of the pressure at the suction end (generally atmospheric pressure), the fluid enters the impeller through the suction chamber. This process is called water absorption process.Because impeller rotates continuously, fluid also is discharged continuously, suction continuously, form successive job.
When the prime mover machine drives the impeller to rotate, the blade in the impeller forces the fluid to rotate, that is, the blade does work on the fluid along its motion direction, thus forcing the pressure potential energy and kinetic energy of the fluid to increase.
At the same time, the fluid under the action of inertial force, from the center to the impeller edge flow, and at a high speed out of the impeller, into the pressure chamber, and then through the diffusion pipe discharge, this process is called the pressure water process.
At the same time, due to the flow of fluid to the edge of the impeller center, a low-pressure area is formed in the center of the impeller. When it has enough vacuum, under the action of the pressure at the suction end (generally atmospheric pressure), the fluid enters the impeller through the suction chamber. This process is called water absorption process.Because impeller rotates continuously, fluid also is discharged continuously, suction continuously, form successive job.
Finally, the working process of centrifugal pump (including slurry pump) is actually a process of energy transfer and conversion.It transfers the motor's high-speed rotating mechanical energy through the blades of the pump and converts it into the pressure energy and kinetic energy of the pumped fluid.
The working process of centrifugal pump (including slurry pump) is actually a process of energy transfer and conversion.It transfers the motor's high-speed rotating mechanical energy through the blades of the pump and converts it into the pressure energy and kinetic energy of the pumped fluid.