KR200396769Y1 - The Impeller Of Exhaust Water Pump - Google Patents

Abstract

 The present invention relates to an impeller structure of a drain pump, in particular, in the structure of the impeller for supplying water from the drain pump, a cylindrical wall member formed so as to wrap in a ring shape on the outer circumferential surface of the large diameter wing, the cylindrical wall member and large diameter It is very useful to efficiently increase the amount of water by reducing the resistance of the water to be supplied, since it forms a wall incision and an annular incision by cutting each part of the annular member formed to surround the bottom part of the wing in a disk shape. It is about effective design.

Description

Impeller Structure of Drain Pump {The Impeller Of Exhaust Water Pump}

The present invention relates to a drainage pump, in particular, in the structure of the impeller for supplying water from the drainage pump, the cylindrical wall member is formed to wrap in a ring shape on the outer circumferential surface of the large diameter wing, and the bottom portion of the cylindrical wall member and the large diameter wing A part of the annular member formed to surround the disk in the shape of a disc to cut the wall and the annular incision to form a water pump, when the pumping, to reduce the resistance of the water supplied to the impeller structure of the drain pump to increase the amount of water efficiently will be.

In general, the indoor unit of the air conditioner, during the cooling operation, moisture in the air condenses into water droplets in the heat exchanger and falls into the drain pan under the heat exchanger. The drain pump is configured to discharge water from the drain pan.

The general form of the various types of drainage pumps has been provided with a housing having a suction port on the bottom surface and a drain port on the side surface, and an impeller rotating by a motor fixed to the opening of the housing by a cover. The rotating shaft of the motor is connected to the shaft of the impeller past the lid. The cover is provided with a through hole for communicating the inner space of the housing with the atmosphere. When the impeller is turned by the power of the motor, the water in the drain pan rises from the bottom of the impeller and is pumped by centrifugal force and then discharged to the outside through the outlet.

1 is a perspective view showing an impeller structure of a conventional drain pump, FIG. 2 is a plan view of an impeller structure of a conventional drain pump, and FIG. 3 is a state diagram of an impeller structure of a conventional drain pump.

In general, the conventional drainage pump 1 is composed of a pump body 30 connected to the lower end of the motor by a motor 10 and a bracket 20. The bracket 20 is integrally formed with a lid 32 which is an upper member of the pump housing, and the lid 32 is connected to the housing 40 by a sealing member 34.

The housing 40 is made of a plastic resin, and is formed of a suction port 42, a pump chamber 44, and a drain port 46.

The pump housing 40 accommodates a rotating shaft 52 and an impeller 50 composed of a plurality of flat and radially narrow blades 54 at the center of the rotating shaft.

As a specific embodiment, the impeller 50 has four small diameter wings.

The rotary shaft 52 passes through the through hole 36 in the center of the cover 32 toward the motor 10 and supports the drive shaft 12 of the motor connected to the central pupil in the rotary shaft 52. Doing. The water source disk 14 is attached to the upper end of the rotating shaft 52, and is to prevent the water sprayed from the through hole 36 of the cover 32 to splash on the motor.

The small-winged blade 54 provided in the impeller 50 is inserted into a pipe-shaped inlet at the lower end of the housing 40. The end of the suction port is tapered toward the open end, the inner diameter is smaller, the tip of the small blade is inclined, the shape is the same as the end of the suction port. The pump chamber 44 provided in the pump housing 40 and along its contour accommodates the large-diameter wing 60 of the impeller 50.

The impeller 50 is provided with a large-diameter blade 60 extending radially from the outer circumferential portion of the rotary shaft 52 and having a flat plate shape. From the lower end of the flat-shaped large-diameter blade 60, A small-diameter wing 54 is connected toward the suction port side, which is connected to an annular member 62 having the same shape as the lower portion of the round plate, the width of which decreases toward the lower side of the central axis. In this embodiment, the large-diameter wings 60 and the small-diameter wings 54 form a single member made of resin, and are flat, and the number thereof may be changed depending on the case. Auxiliary wing 68 is provided between the large-diameter wings 60, and helps to increase the synergistic action of the drain pump.

The small-sized vane 54 has an arc portion 57 facing in the rotational direction so that the noise generated when the drain of the suction port 42 swings is reduced, and the drain is rotated by the small-sized vane 54, so that the pump chamber You can see the effect ascending smoothly at (44).

The upper end of the cylindrical wall member 64 forms an arc portion 70 that is bent inward.

By having the shape as described above, the cylindrical wall member 64 is a bubble generated in the liquid surrounding the large diameter wing (60) flows smoothly to the drain port 46, the bubble of the bubble that touches the lower surface of the cover (32). Shock is alleviated. As a result, noise due to bubbles is reduced. Moreover, even if a large amount of water returns to the pump chamber 44 in the outer cover of the drain hole 46 and impacts the cylindrical wall member 64 so that the drainage pump is stopped, the large amount of water remains in the cylindrical wall member 64. Because of the slow dispersion due to the buffering action, the noise caused by the water coming back is also reduced.

In particular, the circular arc portion 70 having a radius of curvature corresponding to the thickness of the cylindrical wall member 64, the drainage flowing radially by the rotation of the large-diameter wing 60 and the auxiliary blade 68 is the cylindrical wall It makes it easy to cross the top of the member 64. That is, the flow of bubbles in the liquid smoothly goes to the drain 46, where again the noise is reduced.

The lower end of the cylindrical wall member 64, the lower diameter wing 60, the lower end of the auxiliary wing 68 is connected to each other by the annular member 62.

A function of the annular member 62 is to divide the drainage surface rising in a large amount from the suction port 42 to the upper and lower portions, and as a result, the amount of water that reaches the large-diameter wing 60 is reduced and bubble generation is reduced. .

The annular opening 63 is formed between the inner circumferential edge and the central portion of the impeller 50. The lower ends of the large-diameter wing 60 and the auxiliary wing 68 are inclined in the direction of the small-diameter wing 54, and the annular member 62 also has a dish shape along the inclined surface of the wing.

However, as described above, in the conventional impeller 50, the cylindrical wall member 64 and the annular member 62, when the drainage pump is stopped, the water returned from the drain port 46 to the suction port 42, the cylindrical wall It is buffered by the member 64 and the annular member 62, and serves to smoothly fall in the direction of the suction port 42. However, in the pump driving of the impeller 50, water sucked from the suction port 42 is rather drained. Since it is disturbed by hitting the annular member 62 and the cylindrical wall member 64 when moving to 46, the amount of pumping amount is reduced, and the pumping efficiency is significantly lowered.

The present invention has been made in view of this point, in the structure of the impeller for supplying water from the drainage pump, a cylindrical wall member formed to wrap in a ring shape on the outer circumferential surface of the large diameter wing, and the bottom surface of the cylindrical wall member and large diameter wing It is intended to efficiently increase the amount of pumping by reducing the resistance of the water supplied during the pumping, because each part of the annular member formed to surround the disc in the shape of a disc is cut to form a wall cutout and an annular cutout.

This object includes a rotary shaft connected to the drive shaft of the motor; A plurality of large diameter wings radially formed on the rotation shaft; A small diameter wing having a flat shape connected to the lower end of the large diameter wing; A cylindrical wall member connecting the outer circumference of the large-diameter blade; A drainage pump consisting of an annular member radially directed toward an inner central axis radially along a lower end of the large diameter wing from the cylindrical wall member, wherein a portion of the cylindrical wall member is opened to open the drain hole at the large diameter wing through the small diameter wing. It is achieved by providing an impeller structure of a drainage pump that forms a number of wall cuts through which water to be pumped is passed.

In addition, it is preferable to increase the pumping efficiency by forming an annular cutout which is connected to the wall cutout and cut in the annular member in the same manner.

In addition, it is preferable that the wall cutout portion and the annular cutout portion are in contact with the large-diameter wings to form the number of large-diameter wings.

The wall cutout portion and the annular cutout portion are preferably formed by cutting the wall cutout portion so as to have an interval α of 1/8 to 1/2 with respect to the gap β between the two large-diameter wings.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of the present invention.

First, Figure 4 is a perspective view of the impeller structure of the drain pump according to an embodiment of the present invention, Figure 5 is a side view of the impeller structure of the drain pump according to an embodiment of the present invention, Figure 6 is a drain pump according to an embodiment of the present invention 7 is a plan view of the impeller structure, Figure 7 is a state of use of the impeller for the drain pump according to an embodiment of the present invention, Figure 8 is a pumping performance comparison table of the drain pump according to the present invention.

The configuration of the impeller of the drain pump of the present invention, the rotary shaft 102 is connected to the drive shaft 12 of the motor 10; A plurality of large-diameter wings 104 formed radially on the rotation shaft 102; A small-diameter wing 112 having a flat plate shape connected to the lower end of the large-diameter wing 104; A cylindrical wall member 106 connecting the outer circumference of the large-diameter wing 104; In the drain pump (1) consisting of an annular member (108) radially directed from the cylindrical wall member (106) toward the inner central axis radially along the lower end of the large blade (104), a portion of the cylindrical wall member (106) The incision to form a plurality of wall incision 118 through which the water pumped from the large diameter wing 104 to the drain hole 46 through the small diameter wing 112 through the inlet 42.

In addition, the annular cutout 120, which is connected to the wall cutout 118 and is similarly cut in the annular member 108, is formed to increase pumping efficiency.

In addition, the wall cutout 118 and the annular cutout 120 is preferably in contact with the large-diameter blade 104 to form the number of large-diameter wings 104, but can be added or subtracted as necessary. . In the drawings to illustrate that four are formed.

The wall cutout 118 and the annular cutout 120 are cut to have an interval α of 1/8 to 1/2 with respect to the gap β between the two large-diameter wings 104. It is preferable to form. Especially. Most preferably, the annular incision 120 has a spacing α of 1/4 with respect to the spacing β between the two large-diameter wings 104. Hereinafter, description will be made based on the interval α of 1/4.

The wall cutout 118 and the annular cutout 120 are formed to be narrower gradually from the cylindrical wall member 106 toward the center thereof, and are perpendicular to the tangent to the outer circumferential surface of the cylindrical wall member 106. It is preferably formed by cutting off.

And in the impeller 100 of the present invention, it is configured to delete the auxiliary wing 68 that was conventionally provided.

Hereinafter, look at the action and effect of the present invention in detail by the accompanying drawings.

First, referring to the state of use of the impeller structure of the drain pump according to the present invention, as shown in Figure 7, the impeller 100 having a wall cutout 118 and the annular cutout 120 according to the present invention ) To be manufactured and installed inside the housing 40, and the rotary shaft 102 is coupled to the drive shaft 102 of the motor 10 by shaft coupling.

As such, the motor 10 is driven while the impeller 100 is installed to rotate the small-wing blade 112 from the suction port 42 of the housing 40 to suck water and ascend to the upper portion.

The small-winged wing 112 has an arc portion 116 facing in the rotational direction, and the inclined surface portion 114 is inclined about 45 ° with respect to the outer peripheral surface.

In addition, when the drainage of the suction port 42 oscillates due to the arc portion 57 and the inclined surface portion 114, the noise generated is reduced, and the drainage is smoothly performed by the rotation of the small-wing blade 112. To ascend to.

In addition, the drainage raised by the small-diameter wing 112 is transported through the annular incision 120 cut between the annular opening 110 and the large-diameter wing 104 formed inside the annular member 108 to have a large diameter. While hit by the rotation of the blade 104, the drain is discharged to the outside through the drain hole 46 of the housing 40 through the wall cutout 118 partially cut in the cylindrical wall member 106.

Since the annular member 108 divides the drain surface rising in a large amount from the suction port 42 into upper and lower portions, the annular member 108 serves to reduce the amount of water hit by the large diameter wing 104 to reduce bubble generation.

The cylindrical wall member 106 allows bubbles generated in the large-diameter wing 104 to be smoothly discharged to the drain port 46, and alleviates the impact of the bubbles on the lower surface of the cover 32.

On the other hand, when the driving of the drain pump 10 is stopped, a large amount of water discharged to the drain port 46 is returned and bumped against the cylindrical wall member 106, so that the noise is greatly reduced.

In addition, even if a part of the water returned from the drain hole 46 is introduced through the wall cutout 118, the housing 40 passes through the annular cutout 120 while hitting the wall surface of the large diameter wing 104 and the wall surface of the rotary shaft 102. Since the lowering to the suction port 42, the noise does not increase much.

In addition, the wall cutout 118 and the annular cutout 120 are cut to have a gap α of 1/4 with respect to the gap β between the two large-diameter blades 104 and the large-diameter blade ( Since approximately four are formed in accordance with the number of 104, the area occupied by the cylindrical wall member 108 and the annular member 108 is only one quarter, so the supply efficiency is high when water is supplied, but the water is returned. At this time, the noise generated is characterized by a configuration such that it is not loud.

On the other hand, Figure 8 is a pumping performance comparison table of the drainage pump according to the present invention, pumping using the impeller 100 to form a wall cutout 118 and the annular cutout 120 of the present invention with respect to the conventional design When operating at 187V, 220V, 230V, 240V voltages at 60Hz and 50Hz, respectively, it compares the power consumption (W), current consumption (mA) and pumping quantity (cc). Results are shown.

As such, according to the results of quantifying the data, when the impeller 110 according to the present invention is applied, the power consumption (W) and the current consumption (mA) increase slightly within the range of 0.5%, compared to the prior art. It can be seen that the increase rate (%) of the pumping amount increases to about 10% on average, and particularly, in the case of the drain pump 10 having a frequency of 50 Hz, the pumping performance is remarkably increased.

On the contrary, the noise generated due to the incision of the wall cutout 118 and the annular cutout 120 is about 40 dB, which proves that there is no major problem in use.

Therefore, as described above, when using the impeller structure of the drain pump according to the present invention, in the structure of the impeller for supplying water from the drain pump, the cylindrical wall member is formed to wrap in a ring shape on the outer peripheral surface of the large diameter wing, Since a predetermined portion of the annular member formed to surround the bottom portion of the cylindrical wall member and the large diameter blade in a disc shape is formed, respectively, a wall incision and an annular incision are formed, thereby reducing the resistance of the water to be supplied and pumping the water efficiently. It is a very useful and effective design to increase.

1 is a perspective view showing an impeller structure of a conventional drainage pump,

2 is a plan view of an impeller structure of a conventional drainage pump,

3 is a state diagram used in the impeller structure of the conventional drain pump,

Figure 4 is a perspective view of the impeller structure of the drain pump according to an embodiment of the present invention,

5 is a side view of the impeller structure of the drain pump according to the embodiment of the present invention,

6 is a plan view of the impeller structure of the drain pump according to the embodiment of the present invention,

7 is a state diagram used of the impeller for the drain pump according to an embodiment of the present invention,

8 is a comparison table of pumping performance of the drain pump according to the present invention.

* Description of the symbols for the main parts of the drawings *

100 impeller 102 rotation axis

104: large diameter wing 106: cylindrical wall member

108: annular member 110: annular opening

112: small diameter wing 114: inclined surface portion

116: arc part 118: wall incision

120: annular incision

Claims (4)

A rotating shaft connected to the drive shaft of the motor; A plurality of large diameter wings radially formed on the rotation shaft; A small diameter wing having a flat shape connected to the lower end of the large diameter wing; A cylindrical wall member connecting the outer circumference of the large-diameter blade; In the drain pump consisting of an annular member radially toward the inner central axis along the lower end of the large diameter wing from the cylindrical wall member, Impeller structure of the drain pump, characterized in that for opening a predetermined portion of the cylindrical wall member to form a plurality of wall incision through which the water pumped from the large diameter wing to the drain through the small diameter wing from the suction port. The impeller structure of a drain pump according to claim 1, wherein an annular cutout which is connected to the wall cutout so as to be connected to the annular member is formed to increase the pumping efficiency. The impeller structure of claim 2, wherein the wall cutout portion and the annular cutout portion are formed in contact with the large-diameter wings to form the number of the large-diameter blades. The wall cutout portion and the annular cutout portion are formed by cutting in such a manner as to have an interval α of 1/8 to 1/2 with respect to the gap β between the two large-diameter wings. The impeller structure of the drain pump.