KR101836455B1 - a impeller for pump - Google Patents

Abstract

The present invention relates to an impeller installed in a pump and inhaling and discharging a fluid. The impeller for a pump according to one embodiment of the present invention comprises: a lower flange portion having a penetrated inlet formed at the center thereof; an upper flange portion spaced apart from an upper portion of the lower flange portion; a vane positioned between the lower flange portion and the upper flange portion and sucking the fluid into the inlet in accordance with rotation to generate suction force and discharge force, thereby discharging the fluid into the lower flange portion and the circumference between the lower flange portion; and a plurality of fluid engaging grooves formed in a suction space through which the fluid is sucked from the inlet to a gap between the lower flange portion and the upper flange portion to increase frictional force of the fluid to complement a decrease in suction force due to gravity. Therefore, discharge force of the pump can be improved.

Description

A pump impeller and pump having the same

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an impeller provided in a pump for providing a suction force and a ground output for sucking and discharging a fluid, and a pump having the same.

Generally, a pump is a device for sucking and discharging a fluid, and various types of pumps are used depending on the purpose of use, capacity, and the like.

As an example of the pump, the wastewater pump installed in the wastewater tank and sucking and discharging the wastewater is disadvantageous in that when impurities contained in the wastewater are sucked together, impurities are caught by the impeller and the impeller and the driving motor are damaged.

In order to solve this problem, a cutter rotating together with the impeller was installed in the suction port, and the foreign substance sucked into the suction port was cut by a cutter and sucked in, thereby preventing breakage by foreign matter.

However, even if the foreign matter is cut by the cutter, the effect of preventing the foreign matter from getting caught in the vane or blocking the suction port and preventing the foreign matter from entering is small. Thus, in the past, the self-cleaning function of the Korean Patent Publication No. 10-1537714 Quot; channel type pump "has been disclosed.

Conventionally, a channel type pump having a self-cleaning function was provided with an impeller having a single vane, so that the foreign matter sucked in was not caught by the vane but could be sucked and discharged as it was without being clogged by centrifugal force.

However, a conventional channel-type pump having a self-cleaning function can discharge foreign substances together, but there is a problem that the toe output is reduced because there is only one vane.

SUMMARY OF THE INVENTION The present invention has been devised to solve the problems as described above, and it is an object of the present invention to solve the above problems, And to provide an impeller for a pump.

According to an aspect of the present invention, there is provided an impeller for a pump, comprising: a lower flange portion having a suction port formed at a center thereof; an upper flange portion spaced apart from an upper portion of the lower flange portion; A vane that is positioned between the flange portions and sucks fluid into the suction port in accordance with the rotation to generate a suction force and a ground output to be discharged between the lower flange portion and the lower flange portion; And a plurality of fluid hooking grooves formed in the suction space through which the fluid is sucked through the upper flange portion to increase the frictional force of the fluid to compensate for a decrease in suction force due to gravity.

And an extension vane portion extending from the inner vane portion and the outer vane portion so as to protrude further outward than the peripheries of the lower flange portion and the upper flange portion.

And a cutter blade 150 installed on a surface of the outer vane where the fluid moves to cut a foreign substance contained in the fluid moving along the outer vane portion.

Wherein the upper flange portion facing the suction port is formed with a shaft coupling groove into which a drive shaft of a drive motor is coupled, and an outer surface exposed in a state of being fitted in the shaft coupling groove is formed with a curved surface having a curved surface, .

According to the present invention, not only is it possible to suck a fluid without sucking foreign matter from the suction port, but also to increase the frictional force of the fluid sucked from the lower part to the upper part by forming a fluid catching groove in the inner circumference of the suction space inhaling the fluid. Thereby reducing the loss of fluid due to gravity and improving the toe output.

In addition, a shaft cap is provided in the shaft engagement groove facing the suction port to prevent the occurrence of turbulent flow, so that the toe output can be improved.

In addition, a cutter blade is provided in the outer vane portion, so that the foreign matter can be cut by the cutter blade to easily suck and discharge the fluid including foreign matter.

Further, by extending the length of the vane by the extended vanes, the toe output can be improved.

1 is a perspective view showing a pump impeller according to an embodiment of the present invention.
2 is a plan sectional view showing a pump impeller according to an embodiment of the present invention.
3 is a cross-sectional view taken along line AA of FIG.
FIG. 4 is a plan view of a pump impeller according to an embodiment of the present invention, schematically illustrating a state in which the impeller is installed in a suction casing.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 to 3, the impeller 100 for a pump according to an embodiment of the present invention may include a lower flange 110 and an upper flange 120.

The upper flange portion 120 and the lower flange portion 110 may be formed in a disc shape, and may be disposed on the same axis and spaced upward and downward.

A suction port 111 through which the fluid is sucked may be formed at the center of the lower flange 110 and a pump impeller 100 may be provided at the center of the upper flange portion 120 facing the suction port 111, The shaft coupling groove 121 may be formed in which the driving shaft 210 of the driving motor is inserted through and inserted into the fixing nut.

The intake port 111 is formed in the lower flange portion 110 and the upper flange portion 120 so as to discharge fluid between the upper flange portion 120 and the lower flange portion 120 through the center of the lower flange portion 110. [ The suction port 111 may be formed so as to extend in a direction orthogonal to the suction port 111 while maintaining the diameter of the suction port 111 between the suction port 111 and the suction port 111, 140).

At this time, the suction space 140 may be formed so as to be flexibly bent in a helical shape so that the fluid can be smoothly discharged from the suction port in a direction orthogonal to the lower flange portion 110 and the upper flange portion 120.

As shown in FIGS. 1 to 3, the impeller 100 for a pump having improved suction power according to an embodiment of the present invention may include a vane 130.

The vane 130 can be positioned between the lower flange portion 110 and the upper flange portion 120. When the vane 130 is viewed in a plan view, the diameter of the vane 130 gradually increases from the inlet 111 toward the circumferential direction The fluid can be sucked into the suction port 111 by the centrifugal force when the driving motor rotates to discharge the fluid between the lower flange portion 110 and the upper flange portion 120. [

One or more vanes 130 may be formed between the lower flange portion 110 and the upper flange portion 120. The vane 130 may include a lower flange portion 110, The flange portion 120 may be formed to have a gradually thinner thickness.

The vane 130, the lower flange portion 110, and the upper flange portion 120 can be integrally molded by casting.

3, the impeller 100 for a pump according to the embodiment of the present invention may include a fluid engagement groove 145.

This fluid catching groove 145 can increase the frictional force of the fluid sucked into the suction port 111 and improve the toe output of the fluid.

The fluid catching groove 145 provides frictional force to the fluid discharged from the suction port 111 between the lower flange portion 110 and the upper flange portion 120 so that the fluid is guided to the lower portion It is possible to increase the discharge amount of the fluid.

In other words, the centrifugal impeller 100, by its nature, lifts up the fluid to the upper part by the suction port 111 formed at the lower part, and therefore gravity acts on the fluid drawn upward from the suction port 111, The discharge amount of the fluid can be increased by reducing the action of gravity in such a manner that the fluid drawn up to the upper portion spans the fluid catch groove 145.

The fluid catching grooves 145 may be formed in the suction space 140 in which the fluid is sucked and a plurality of fluid engaging grooves 145 may be formed in the suction space 140 in a pattern.

The fluid catching grooves 145 are formed not only in a concave shape but also in the shape of a droplet as the shape becomes narrower as the depth is lowered toward a portion discharged from the portion where the fluid is sucked, A tail portion having a reduced width and a lowered depth may be formed so as to face the direction in which the fluid is sucked and discharged.

Here, when the fluid catching groove 145 is formed such that the tail is directed toward the direction in which the fluid is sucked, such as the shape of the water drop, the fluid is caught in the relatively wide lower end portion of the water drop shape, The fluid flowing in the fluid catching groove 145 can be easily released and sucked in a direction in which it is naturally sucked.

1 and 2, the impeller 100 for a pump according to the embodiment of the present invention may include an extended wing 160.

The end of the vane 130 positioned between the upper flange portion 120 and the lower flange portion 110 extends beyond the periphery of the upper flange portion 120 and the lower flange portion 110, So that the suction force and the toe output can be improved.

The impeller 100 is rotatably installed in the suction casing 220. Since the output of the impeller 100 is improved as the tip of the impeller 100 and the inner portion of the suction casing 220 are closer to each other, And the end of the vane 130 is positioned as close as possible to the inner circumference of the suction casing 220, so that the toe output can be improved.

The extension wing 160 may be detachably installed on the vane 130 so that the extension wing 160 can be selectively installed according to the distance between the suction casing 220. The extension wing 160 may be installed on the vane 130, The extension wings 160 having various weights may be selected and installed.

The extension wing portion 160 is formed with a fitting groove 135 in one of the extended vane 160 and the vane 130 so as to be detachably coupled to the end of the vane 130, A fitting protrusion 165 to be fitted in the fitting groove 135 is formed in the fitting groove 135 so that the fitting protrusion 165 can be fitted in the fitting groove 135 in a detachable manner.

1 to 3, the impeller 100 for a pump having improved suction force according to an embodiment of the present invention may include a cutter blade 150.

The foreign matter contained in the fluid sucked by the suction port 111 is sucked into the gap between the upper flange portion 120 and the lower flange portion 110 and is guided to the periphery of the vane 130, It is possible to cut out the foreign matter in the form of scratching the foreign matter contained in the fluid.

The cutter blade 150 may be formed along the outer surface of the vane 130 to which the fluid to be discharged is guided. The cutter blade 150 may be formed in a shape of a triangular groove or a triangular band around the outer periphery of the vane 130 And may be configured to be welded thereto.

A plurality of cutter blades 150 may be vertically spaced apart from each other at the vane 130.

3, the impeller 100 for a pump according to an embodiment of the present invention may include a shaft cap 170.

The shaft cap 170 may seal the shaft coupling groove 121 to minimize the turbulence generated when the fluid sucked into the shaft coupling groove 121 formed at the center of the upper flange portion 120 is collided.

The outer surface of the shaft cap 170 exposed to the suction space 140 in the state of being coupled to the shaft coupling groove 121 may be formed into a curved surface having continuity with the inner surface of the suction space 140, The fluid catching grooves can also be formed.

The operation and effects of the above-described respective structures will be described.

The impeller 100 for a pump according to the embodiment of the present invention is provided with a vane 130 between the lower flange portion 110 having the inlet port 111 and the upper flange portion 120 located at the upper portion of the lower flange portion 110, The suction port 111 is formed in a spiral shape and has a suction space formed in a curved shape in the direction of 90 in the suction port 111 so that the sucked fluid can be discharged between the upper flange portion 120 and the lower flange portion 110. [ (140) is formed.

A cutter blade 150 is formed around the vane 140 along the outer circumferential surface of the vane in order to cut foreign matter contained in the fluid.

A fluid catching groove 145 is formed in the suction space 140 to minimize the action of gravity of the fluid to be sucked. The fluid catching groove 145 is narrowed in the form of a water droplet, And a plurality of these are arranged toward the direction in which they are discharged.

The vane 130 is fitted to the end of the vane 130 so as to have a length close to the inner circumference of the suction casing 220 to which the extension vane 160 is to be installed and the extension vane 160 is inserted into the vane 130 The overall weight balance is adjusted so that the impeller 100 can rotate stably without being eccentric.

The drive shaft 210 of the drive motor is inserted through the shaft coupling groove 121 in a state where the extended wing 160 is installed and the impeller 100 is coupled to the drive shaft 210 by tightening the fixing nut.

When the pump impeller 100 is rotated by the driving motor in this state, the pump impeller 100 rotates while sucking the fluid through the inlet port 111 by the centrifugal force of the vane 130, 120 and the lower flange portion 110. [0064]

4, when the impeller 100 rotates, the fluid is sucked through the suction port 111 formed at the center of the lower flange portion 110 by the vane 130, The air is sucked into the gap between the lower flange 110 and the upper flange 120 by the vane 130 passing through the space 140 and the outer circumferential surface of the lower flange 110 and the upper flange 120 .

The fluid sucked into the suction port 111 is attracted to the upper portion of the suction port 111 by the suction force and is sucked by the fluid engaging groove 145 formed in the inner circumference of the suction space 140, The suction force of the fluid can be increased by minimizing the gravity action of the fluid being sucked.

When the fluid is sucked in the suction port 111, the end of the drive shaft 210 is surrounded by the shaft cap 170 to minimize the occurrence of turbulent flow by the shaft coupling groove 121 and the drive shaft 210, The suction force can be improved.

The vane 130 is positioned close to the inner circumference of the suction casing 220 by the extended vanes 160 installed at the end of the vane 130 when the impeller 100 rotates, The output can be increased.

The foreign matter contained in the fluid moving by the vane 130 is cut through the cutter blade 150 to prevent a relatively large foreign matter from being trapped between the suction casing 220 and the impeller 100 .

The pump having the pump impeller 100 according to the embodiment of the present invention may include the pump impeller 100 according to the embodiment described above and may include a drive motor and a discharge casing 220.

The drive motor can receive the electricity and rotate the drive shaft 210 by the electromagnetic force. The discharge casing 220 can be installed to rotate the impeller 100 for the pump. The discharge casing 220 has a fluid And a fluid discharge port through which the sucked fluid is discharged may be formed on a side surface of the discharge casing 220. [

Further, the driving motor may be positioned above the discharge casing 220, and the driving motor may be enclosed by the motor casing to prevent the inflow of the fluid into the inside.

When the drive shaft 210 is rotated by the drive motor, the pump impeller 100 coupled to the drive shaft 210 rotates to generate a suction force, Sucks the fluid into the fluid inlet of the fluid outlet 220, and discharges the sucked fluid to the fluid outlet.

Therefore, in the impeller 100 for a pump according to the embodiment of the present invention and the pump including the impeller 100, a fluid engagement groove 145 is formed in a suction space 140 in which a fluid is sucked, By increasing the frictional force of the fluid, and by reducing the gravitational force acting on the fluid, it is possible to increase the suction amount of the fluid.

Further, since there is no part where the foreign substance is caught by the vane 130, the fluid can be sucked and discharged in a state including foreign matter.

An extension wing 160 is provided at the end of the vane 130 to minimize the suction amount between the suction casing 220 and the impeller 100 to improve the suction force of the pump by increasing the compressive force of the fluid. have.

In addition, a cutter blade 150 is provided on the outer surface of the vane 130 to cut foreign matter contained in the fluid sucked in accordance with the rotation of the impeller 100, and to discharge the foreign matter.

A shaft cap 170 continuous with the inner surface of the suction space 140 is provided in the shaft coupling groove 121 in which the drive shaft 210 located at the portion facing the suction port 111 is coupled, By minimizing the turbulence, the toe output can be improved.

While the present invention has been particularly shown and described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And all changes and modifications to the scope of the invention.

100: Impeller 110: Lower flange portion
111: inlet port 120: upper flange portion
121: Axial coupling groove 130: Vane
135: fitting groove 140: suction space
145: Fluid gripping groove 150: Cutter blade
160: extension wing 165:
170: Shaft cap
210: drive shaft 220: suction casing

Claims (5)

A lower flange portion having a suction port formed at the center thereof,
An upper flange portion spaced apart from an upper portion of the lower flange portion,
A vane that is positioned between the lower flange portion and the upper flange portion and sucks fluid into the suction port in accordance with the rotation to generate a suction force and a ground output to be discharged between the lower flange portion and the lower flange portion,
And a plurality of fluid catching grooves formed in the suction space through which the fluid is sucked from the suction port to between the lower flange portion and the upper flange portion to increase frictional force of the fluid to compensate for a decrease in suction force due to gravity Impeller for pumps. The method according to claim 1,
And an extension wing portion extending an end of the vane so as to project further outward than a periphery of the lower flange portion and the upper flange portion. The method according to claim 1,
And a cutter blade formed on an outer surface of the vane and cutting a foreign substance contained in the fluid moving along the outer surface of the vane. The method according to claim 1,
Wherein the upper flange portion facing the suction port is formed with a shaft coupling groove into which a drive shaft of a drive motor is coupled, and an outer surface exposed in a state of being fitted in the shaft coupling groove is formed with a curved surface having a curved surface, And the impeller for a pump. The impeller for a pump according to claim 1,
A suction casing enclosing the impeller and having a suction port through which the fluid is sucked by the impeller and a discharge port through which the sucked fluid is discharged,
And a driving motor for rotating the impeller.

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