KR200169162Y1 - For impeller vacuum self priming pump - Google Patents

Abstract

The present invention relates to an impeller of a vacuum ferromagnetic pump that pumps water or a high concentration and high viscosity liquid by vacuum suction, and prevents vibration and noise of the pump by reducing frictional resistance between the impeller blades and the sucked liquid and casing. Reduce the load on the pump to improve the service life and performance of the pump.

In the present invention, in the impeller 10 having a radially formed wing 11 and embedded in the inner and outer casings 2 and 3 of the vacuum ferromagnetic pump, the high speed rotating,

Impeller 10 is formed by forming a plurality of through holes 13 penetrating radially formed wings 11 and side end portions of the outer periphery so as to have a curved surface R, and partitions 12 formed so that one side is blocked. It is characterized in that configured to prevent the frictional resistance and the load at high speed.

Description

Impeller vacuum self priming pump

The present invention relates to an impeller of a vacuum ferromagnetic pump that pumps water or a high concentration and high viscosity liquid by vacuum suction, and prevents vibration and noise of the pump by reducing frictional resistance between the impeller blades and the sucked liquid and casing. Reduce the load on the pump to improve the service life and performance of the pump.

The vacuum ferromagnetic pump method, which sucks and pumps water or high concentration and high viscosity liquids by suction power generated by rotating the impeller at high speed, has excellent suction power and durability of the pump, and also has low vibration and noise, thereby expanding its use range.

The vacuum suction pump using the impeller can know the technical details in the patent No. 175650 registered and registered in advance, and the technical details of the impeller of the vacuum ferromagnetic pump can be found in the patent application 10-1999-0011884 can be found in detail.

The configuration of the prior-application conventional vacuum ferromagnetic pump is formed in the outer casing (3) and the inlet (4) and the outlet (5) is connected to the U-shaped feed groove (6) as shown in Figures 1 and 2 shown in the figure It can be seen that the impeller 10 having the blades of the impeller 10 is built in the inner casing 2 and coupled to the axial direction of the motor 1 so that the impeller 10 is rotated at a high speed by the rotation of the motor 1.

Therefore, the impeller embedded in the inner casing rotates at a high speed by the high speed rotation of the motor, so as to pump and suck water or high concentration and high viscosity liquid through the transfer groove of the outer casing.

Conventional vacuum ferromagnetic pumps and impellers are structured to block one side of the impeller contacting the inner surface of the inner casing with a partition to increase suction force, but this is a liquid between the inner surface of the inner casing and the partition of the impeller. When the impeller is rotated at a high speed in the state, the liquid does not escape and the pressure rises, thereby pushing the impeller to increase the friction force on the impeller and the outer casing, causing a problem of generating a load.

In addition, since the upper end of the impeller wing contacting the inner side of the outer casing and the conveying groove is angled, surface contact occurs with the inner side of the outer casing, and the frictional resistance is large, and the frictional resistance is also generated with the inhaled liquid. And the noise is seriously happening.

The present invention was devised to solve the above problems, and reduces the frictional resistance between the impeller blades and the suction liquid and the casing to prevent the vibration and noise of the pump, while reducing the load of the impeller to reduce the life and performance of the pump The purpose of the improvement is to devise.

1 is a perspective view of an installation state of a conventional vacuum ferromagnetic pump

Figure 2 is a cross-sectional view of the installation state of the conventional vacuum ferromagnetic pump

Figure 3 is a side view of the impeller showing an embodiment of the present invention

4 is a cross-sectional view of the impeller wing of the present invention

5 is a cross-sectional view showing an installation state of the present invention

[Description of Symbols for Main Parts of Drawing]

1.Motor 2.Inner Casing 3.Outer Casing

4.Inlet port 5.Outlet port 6.Transfer groove

10.Impeller 11.wing 12.partition

13.through

The present invention reduces the frictional resistance of the liquid sucked through the impeller 10, the outer casing (3) and the transfer groove (6) of the vacuum ferromagnetic pump to prevent vibration and noise and to suppress the flow of the impeller (10) By reducing the load to improve the service life and performance of the pump, the configuration shown in Figures 3 to 5 shown in the drawings.

Impeller 10 is configured such that a plurality of wings 11 are formed radially as in the conventional shape and one side contacting the inner surface of the inner casing 2 is blocked by the partition 12 but penetrated through the partition 12. The insertion groove 14 is formed to form a plurality of through holes 13 and the motor shaft is fitted into the center.

In addition, the impeller 10 is formed so that the inner surface of the outer casing (3) and the wing 11 and the outer end of the outer circumference in contact with the sucked liquid to the curved surface (R) and the inner surface of the outer casing (3) at high speed The linear contact is generated to reduce the frictional resistance while reducing the frictional resistance with the liquid sucked through the transfer groove 6.

Since the wing 11 and the outer end of the outer circumferential side of the outer edge of the outer surface of the outer casing (3) and the friction surface (R) is in contact with the inner surface to reduce the friction area significantly reduced frictional resistance than conventional surface contact In addition, the curved surface (R) wing 11 and the outer periphery is to lower the flow rate resistance of the sucked liquid.

Several through holes 13 formed in the partition 12 blocking one side of the impeller 10 flow freely between the inner surface of the inner casing 2 and the partition 12 of the impeller 10. And when the impeller 10 is rotated at high speed by the drive of the motor 1 by discharging the liquid impregnated between the gaps through the several through holes 13, the pressure does not rise to suppress the flow of the impeller 10 It will be possible.

Therefore, the present invention installs a plurality of through holes 13 in one partition 12 of the impeller 10 to suppress the flow of the impeller 10, while the wing 11 of the impeller 10 and the side end of the outer peripheral surface is curved By forming (R) so as to significantly reduce the frictional resistance between the outer casing (3) and the sucked liquid to prevent the load on the impeller (10) and improve the life and performance of the pump.

The present invention significantly reduces the frictional resistance of high-speed rotating impellers to prevent vibration and noise during operation, while reducing the load caused by the flow of the impellers, thereby preventing damage to bearings or O-rings connected to the pumps, thereby improving the service life of the pumps. And to improve performance.

Claims (1)

In the impeller 10 having a radially formed wing 11 and embedded in the inner and outer casings 2 and 3 of the vacuum ferromagnetic pump, the high speed rotating impeller 10 Impeller 10 is formed by forming a plurality of through holes 13 penetrating radially formed wings 11 and side end portions of the outer periphery so as to have a curved surface R, and partitions 12 formed so that one side is blocked. Impeller of the vacuum ferromagnetic pump characterized in that it is configured to prevent the friction resistance and load at high speed.