KR102378637B1 - Drain pump - Google Patents

Abstract

[assignment]
To provide a drain pump capable of suppressing mixing of air bubbles into waste water flowing out from a discharge port and achieving quietness during operation.
[Solution]
A pump body having a motor, a housing having an upper end open and an inlet port provided at the lower end, and a discharge port provided on the side, a rotary blade connected to the motor, and a cover attached to the upper end of the housing while having a through hole in the center The pump chamber is defined by the housing and the cover, and the discharge port is a drainage pump having a discharge port inlet opening to the pump chamber, and the inner diameter above the discharge port inlet of the pump chamber is, The inner diameter of the discharge port inlet portion or the inner diameter of the discharge port inlet portion and the lower portion of the pump chamber are smaller than the inner diameter.

Description

Drain Pump{DRAIN PUMP}

The present invention relates to a drain pump that sucks in water from a suction port by means of a rotary blade and discharges it from a discharge port, and more particularly, to a drain pump suitable for achieving quietness during operation.

BACKGROUND ART Conventionally, in an air conditioner of a type embedded in an indoor ceiling, a drain pan for receiving drain water condensed on the surface of an indoor heat exchanger of the air conditioner is equipped. In order to drain the drain water in this drain pan to the outdoors, a drain pump (drain pump) is used (refer patent document 1).

Fig. 8 is an example of a conventional drainage pump described in Patent Document 1. A conventional drain pump 1 has a motor 10 and a pump body 30 attached to the motor 10 via a bracket 20 . The pump body 30 is made of plastic and has a housing 40 having an upper opening, a cover 32 fitting with an upper opening of the housing 40, and a rotary blade 50 connected to the motor 10 . ) is provided.

The housing 40 is a pipe-shaped suction pipe 42 having a suction port 43 at the lower portion, and a pump chamber 44 formed in an internal space defined (divided) by the housing and the cover 32; and a discharge pipe 45 having a discharge port 46 on the side thereof. Reference numeral 46a denotes an inlet (discharge port inlet) of the discharge port 46 opened to the pump chamber 44 .

The cover 32 is integrally formed with the bracket 20 and is connected to the housing 40 with the seal member 34 sandwiched therebetween.

In the pump chamber 44 , the rotary blade 50 rotated by the motor 10 is accommodated. The rotary blade 50 includes a shaft portion 52, a plurality of (for example, four) large-diameter flat blades 60 extending in the radial direction from the outer periphery of the shaft portion 52, and an intermediate blade disposed therebetween ( 60a), an annular member 62 provided along the tapered lower side of each of the large-diameter blades 60 and the intermediate blades 60a and having an opening 63 in the center, and each large-diameter through the inside of the opening 63 It has a plurality of flat plate-shaped small-diameter blades 54 connected to the lower end edge of the blade 60 (eg, the same number as the large-diameter blade 60 ). The rotary blade 50 is disposed in the pump chamber 44 such that the small-diameter blade 54 is inserted into the suction pipe 42 .

The shaft portion 52 extends through a through hole 36 formed in the center of the cover 32 and protrudes to the motor 10 side, and the motor 10 is disposed in a hole 53 provided along the central axis of the shaft portion 52 . ) of the drive shaft 12 is inserted and fixed. A water-receiving disk 14 is attached to the upper surface of the shaft 52 , and when the drain water is ejected from the through-hole 36 of the cover 32 , it is turned into a motor. (10) Prevents scattering to the side.

Japanese Patent Laid-Open No. 2013-64396

Fig. 9 is a longitudinal sectional view showing the outline of the inside of the pump body 30 of the conventional drain pump 1 shown in Fig. 8 .

As shown in FIG. 9 , since centrifugal force (arrow C in FIG. 9 ) is applied to the water sucked from the suction port 43 by the rotary blade 50 , in the radial direction of the rotary blade 50 , as shown in FIG. A layer of air is formed on the inside and a layer of water on the outside, and a layer of bubbles in which air and water mix with each other called a gas-liquid interface is formed at the boundary.

When the bubble generated on the gas-liquid interface exceeds the upper end of the rotary blade 50, it is pushed out in the circumferential direction by centrifugal force. There is a problem in that these bubbles are mixed in the waste water discharged from the discharge port 46 and generate noise when they flow out.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a drain pump capable of suppressing mixing of air bubbles into waste water flowing out from a discharge port and achieving quietness during operation.

In order to solve the above problems, the drain pump according to the present invention includes a motor, a housing having an upper end opening and a suction port provided at the lower end and a discharge port provided on the side, a rotary blade connected to the motor, and a through hole in the central portion It is made by a pump body having a cover mounted on the upper end of the housing and having a pump chamber defined by the housing and the cover, and the discharge port is a drainage pump having a discharge port inlet opening to the pump chamber, An inner diameter of the pump chamber above the outlet inlet is smaller than an inner diameter of a portion of the outlet inlet of the pump chamber, or an inner diameter of a portion of the outlet inlet of the pump chamber and a lower inner diameter thereof.

In this drain pump, the cover has an annular side wall portion that fits into the opening of the housing, and the lower end of the annular side wall portion extends to the same height as the upper end of the outlet port, The inner surface of the annular side wall portion may be formed to protrude from the outlet inlet to the inside of the cover.

In addition, the housing may further include an annular protrusion that extends to the same height as the lower end of the outlet inlet and has an inner surface protruding from the outlet inlet to the inside of the pump chamber.

According to the drainage pump of the present invention, since the inner diameter of the pump chamber is smaller than the discharge port inlet and the lower side than the discharge port inlet, the centrifugal force generated by the rotation of the rotor acts on the inner wall of the pump chamber. , in the conventional drainage pump, the upper and lower sides of the discharge inlet were uniform, but in the drain pump of the present invention, the upper side of the discharge port inlet is smaller than the discharge port inlet (and lower than that).

In addition, the water that exceeds the upper end of the rotary blade and reaches the upper outer periphery of the pump chamber (the portion corresponding to the upper part of the discharge port in the pump chamber) contains many bubbles that cause noise when it flows out. Since the centrifugal force acting above the discharge port inlet is smaller than that of the discharge port inlet (and below it), most of the water flowing from the pump chamber into the discharge port inlet faces the discharge port inlet where the centrifugal force is strong (part of the discharge port inlet of the pump chamber, or the portion of the discharge port inlet and the portion below it), the amount of water containing a lot of bubbles reaching the upper outer periphery of the pump chamber and flowing into the discharge port inlet is reduced. As a result, mixing of air bubbles into the water flowing into the outlet from the pump chamber, that is, the waste water flowing out from the outlet is suppressed, and quietness during operation can be achieved.

1A is a view showing the outline of the pump body of the drain pump according to the first embodiment of the present invention, and is a longitudinal cross-sectional view taken along a plane passing through a center line of a discharge port;
Fig. 1B is a view showing an outline of a pump body of a drain pump according to a first embodiment of the present invention, and is a perspective view with a rotary blade removed from Fig. 1A;
2 is a perspective view showing an outline of an example of a rotary blade applied to the drain pump according to the first embodiment of the present invention;
Fig. 3 is a perspective view showing an outline of a modified example (first modified example) of a rotary blade used in the drain pump according to the first embodiment of the present invention;
Fig. 4 is a perspective view showing the outline of another modified example (second modification) of the rotary blade used for the drain pump according to the first embodiment of the present invention;
5 is a perspective view showing the outline of another modified example (third modified example) of the rotary blade used in the drain pump according to the first embodiment of the present invention.
6A is a view showing the outline of the pump body of the drain pump according to the second embodiment of the present invention, and is a longitudinal cross-sectional view taken along a plane passing through the center line of the discharge port;
Fig. 6B is a view showing the outline of the pump body of the drain pump according to the second embodiment of the present invention, and is a perspective view with the rotary blade removed from Fig. 6A;
7 is a graph showing a result of comparing the noise during operation of the drain pump shown in the first embodiment of the present invention and the conventional drain pump.
8 is an example of a conventional drain pump used in an air conditioner.
Fig. 9 is a longitudinal sectional view showing the outline of the inside of the pump body of the conventional drain pump shown in Fig. 8;

<First embodiment>

1 is a diagram showing an outline of a pump body of a drain pump according to a first embodiment of the present invention. Here, FIG. 1A is a longitudinal cross-sectional view of the pump body 130 cut to a plane passing through the center line of the discharge port 146 to be described later, and FIG. 1B is the pump body 130 with the rotary blade 150 removed. ) is a perspective view viewed from below obliquely after cutting through the center line.

As shown in FIG. 1 , the pump body 130 of the drain pump according to the first embodiment includes a housing 140 having an upper opening, a cover 132 fitted with the upper opening of the housing 140, The rotor blade 150 is provided in the pump chamber 144 defined by the housing 140 and the cover 132 . Here, each of the above-mentioned components constituting the pump body 130 may be made of, for example, plastic.

The housing 140 includes a pump chamber 144 formed therein, a pipe-shaped suction pipe 142 having a suction port 143 communicating with the pump chamber 144 from below, and a pump chamber 144 provided on the side of the pump chamber ( 144) and a pipe-shaped discharge pipe 145 having a discharge port 146 communicating with the outside. Reference numeral 146a denotes a discharge port inlet through which the discharge port 146 opens to the pump chamber 144 .

The cover 132 has an annular side wall portion 133 fitted to the upper opening of the housing 140 , and is connected to the housing 140 with the seal member 134 sandwiched therebetween.

The lower end 133a of the annular side wall portion 133 extends to the same height as the upper end of the outlet inlet 146a, and the inner surface 133b of the annular side wall portion 133 is the outlet inlet 146a. It is formed in a shape protruding from the top toward the inner center of the cover 132 .

That is, in FIG. 1 , the distance from the rotation axis O of the rotary blade 150 to the outlet inlet 146a is R ₁ , and the distance to the inner surface 133b of the annular side wall part 133 is R ₂ On the lower surface, the annular side wall portion 133 has a shape such that R ₁ >R ₂ . In addition, the protrusion amount (difference between R ₁ and R ₂ ) of the inner surface of the annular side wall portion 133 may be set, for example, to about 2 mm.

Fig. 2 is a perspective view showing an outline of an example of a rotary blade applied to the drain pump according to the first embodiment.

As shown in FIG. 1A , in the pump chamber 144 of the housing 140 , the rotary blade 150 rotated by a motor (not shown) is accommodated.

The rotary blade 150 is connected to the lower edge of the shaft portion 152 and the four plate-shaped large-diameter blades 160 extending in the radial direction from the outer periphery of the shaft portion 152, and the lower edge of each large-diameter blade 160, together with a suction pipe It has four flat plate-shaped small diameter blades 154 inserted into 142 .

The shaft portion 152 protrudes through a through hole 136 formed in the center of the cover 132 , and the drive shaft of the motor is inserted and fixed in the hole 153 provided along the central axis of the shaft portion 152 . .

The lower edge of the large-diameter wing 160 is formed in a tapered shape, and the lower edge is connected by a disk-shaped annular member 162 having an opening 163 . This annular member 162 has an inverted truncated truncated side shape, and the upper surface of its outer periphery has a planar shape protruding outward from the outer peripheral ends of the large-diameter wing 160 and the auxiliary wing 168. An annular flat portion 164 is formed.

In addition, four auxiliary blades 168 are provided between the adjacent large-diameter blades 160, and the lift of the pump can be secured by the auxiliary blades 168 and the large-diameter blades 160.

This rotary blade 150 is connected to the motor 10 as shown in FIG. 8, for example, and, thereby, a drain pump is comprised.

Next, the operation of the first embodiment of the present invention will be described with reference to Fig. 1A.

First, when a motor (not shown) is rotated, the rotary blade 150 rotates, water is sucked into the pump chamber 144 from the suction port 143 , and the sucked water is discharged from the discharge port 146 .

Since the water sucked in from the suction port 143 is given a centrifugal force by the rotary blade 150, an air layer is formed on the inner side and a water layer on the outside in the radial direction of the rotary blade 150, and the boundary is called a gas-liquid interface. A layer of bubbles is formed where the air and water mix with each other.

When the bubble generated on the gas-liquid interface exceeds the upper end of the rotary blade 150, it is pushed out in the outer circumferential direction by centrifugal force.

Here, in the first embodiment, since the annular side wall portion 133 is formed on the cover 132 , the inner diameter of the pump chamber 144 is on the upper side (the portion indicated by the reference numeral 133b) than the discharge port inlet 146a. This discharge port inlet 146a is smaller than that of and below it. As a result, the centrifugal force generated by the rotation of the rotary blade 150 acts on the inner wall of the pump chamber 144 is uniform above and below the outlet in the conventional drain pump. In the drain pump of the present invention, the outlet The force acting above the inlet 146a (symbol P1 in Fig. 1A) is smaller than the force acting at the discharge port inlet and below it (symbol P2 in Fig. 1A).

As described above, the water reaching the upper outer periphery of the pump chamber 144 beyond the upper end of the rotary blade 150 (the portion corresponding to the upper portion of the discharge port inlet 146a in the pump chamber 144) has a cause of noise when it flows out. Although many bubbles are included, in this first embodiment, as described above, the centrifugal force acting above the discharge port inlet 146a of the pump chamber 144 becomes smaller than the discharge port inlet 146a and the portion below it. , most of the water flowing into the discharge port inlet 146a from the pump chamber 144 is a portion facing the discharge port inlet 146a, where the action of centrifugal force is strong (the portion of the discharge port inlet 146a of the pump chamber 144) and a portion below it The amount of water containing a large amount of foam that becomes water in the pump chamber 144 and reaches the upper outer periphery (portion indicated by an arrow of reference numeral P1) of the pump chamber 144 flows into the discharge port inlet 146a is reduced. As a result, mixing of air bubbles into the water flowing into the discharge port inlet 146a from the pump chamber 144, that is, the waste water flowing out from the discharge port 146, is suppressed, and quietness during operation can be achieved.

Fig. 3 is a perspective view showing an outline of a modified example (first modified example) of a rotary blade used for a drain pump according to the first embodiment of the present invention. The rotor blade 250 is disposed in a pump chamber 144 defined by a housing 140 and a cover 132 as shown in FIGS. 1A and 1B .

As shown in FIG. 3 , in the rotary blade 250 , an end portion 272 is formed at an upper end edge among the edges of the large-diameter blade 260 , and an end portion 282 is formed at the outer edge portion, respectively.

Also in this rotary blade 250, the lower end edge of the large-diameter blade 260 is formed in a tapered shape, and this lower end edge is connected by a disc-shaped annular member 262 having an opening 263 .

In addition, auxiliary blades 268 are provided between the adjacent large-diameter blades 260, and also in the auxiliary blades 268, an end 274 is formed at its upper end edge, and an end 284 is formed at its outer edge.

The annular member 262 has an inverted truncated lateral shape, and the upper surface of the outer periphery protrudes outward from the outer peripheral ends of the end 282 of the large-diameter blade 260 and the end 284 of the auxiliary blade 268 . It is made into the annular flat part 264 of one planar shape.

The ends 272 and 274 are formed over the entire length of the upper end edges of the large-diameter blade 260 and the auxiliary blade 268, respectively. Such end portions 272 and 274 have a function of guiding the water sucked in from the suction port upward and upwards.

In addition, the ends 282 and 284 are formed over the entire length of the outer edge edge of the large-diameter blade 260 and the auxiliary blade 268, respectively. Such end portions 282 and 284 have a function of guiding the water sucked in from the suction port outward in the radial direction of the rotary blade 250 .

With such a configuration, in the drainage pump using the rotary blade 250 of the first modified example, the ends 272 and 282 of the large-diameter blade 260 and the ends 274 and 284 of the auxiliary blade 268 have a synergistic action. By this, since the position of the gas-liquid interface of the discharged water becomes a position further away from the rotational shaft of the rotary blade 250, it is possible to improve the suction capacity of the rotary blade and reduce vibration and noise.

In addition, by the annular flat surface 264 , the water flow rising along the bottom surface of the annular member 262 flows over the outer edge edge of the large diameter blade 260 and the auxiliary blade 268 , and It does not interfere and achieves the effect that generation|occurrence|production of a bubble is further suppressed.

Fig. 4 is a perspective view showing the outline of another modified example (second modification) of the rotary blade used for the drain pump according to the first embodiment of the present invention. The rotor blade 350 is disposed in the pump chamber 144 defined by the housing 140 and the cover 132 as shown in FIGS. 1A and 1B .

As shown in FIG. 4 , in the rotary blade 350 , an end 372 is formed at an upper end of the edges of the large-diameter blade 360 .

Also in this rotary blade 350, the lower end edge of the large-diameter blade 360 is formed in a tapered shape, and this lower end edge is connected by a disk-shaped annular member 362 having an opening 363 .

In addition, auxiliary blades 368 are provided between the adjacent large-diameter blades 360, and also in the auxiliary blades 368, an end portion 374 is formed at the upper end edge thereof.

In this rotary blade 350 , the outer edge of the large diameter blade 360 and the auxiliary blade 368 are connected by a cylindrical wall member 364 . In Fig. 4, the height of the cylindrical wall member 364 is configured to match the heights of the large-diameter blades 360 and the auxiliary blades 368, although higher or lower than the heights of the large-diameter blades 360 and the auxiliary blades 368. good night. Further, an end portion 366 is formed on the inner wall surface of the cylindrical wall member 364 .

With such a configuration, in this drainage pump, in addition to the guiding function of the water flow by the end 372 of the large-diameter blade 360 and the end 374 of the auxiliary blade 368, the water flow is directed to the cylindrical wall member 364. By adding the function of flowing smoothly upward and outward, the rotary blade can improve the suction ability and reduce vibration and noise.

In addition, by the cylindrical wall member 364, the water flow rising from the bottom surface of the annular member 362 along the outer side of the cylindrical wall member 364 is the large-diameter blade 360 and the auxiliary blade 368. The rotation does not interfere with the water flow flowing along the inner side of the cylindrical wall member 364, thereby achieving the effect that the generation of air bubbles is further suppressed.

Fig. 5 is a perspective view showing the outline of another modified example (third modified example) of the rotary blade used for the drain pump according to the first embodiment of the present invention. The rotor blade 450 is disposed in the pump chamber 144 defined by the housing 140 and the cover 132 as shown in FIGS. 1A and 1B .

As shown in FIG. 5 , in the rotary blade 450 , an end 472 is formed at an upper end of the edges of the large-diameter blade 460 , and an end 482 is formed at an outer edge thereof.

Also in this rotary blade 450 , the lower end edge of the large-diameter blade 460 is formed in a tapered shape, and this lower end edge is connected by a disk-shaped annular member 462 having an opening 463 .

In addition, auxiliary blades 468 are provided between the adjacent large-diameter blades 460, and also in auxiliary blades 468, an end portion 474 is formed at its upper end edge and an end portion 484 is formed at its outer edge portion, respectively.

The annular member 462 has the shape of a side surface of an inverted truncated cone, and the upper surface of the outer periphery protrudes outward from the outer peripheral end of the end 482 of the large-diameter blade 460 and the end 484 of the auxiliary blade 468 . It is made of a flat annular flat portion 464 of one planar shape.

In this rotary blade 450, two inclined surfaces 472a and 472b are formed at the end 472 located at the upper end edge of the large-diameter blade 460, for example. These inclined surfaces 472a and 472b are shifted in the rotational direction by the angle of incidence of the water flow hitting the side surface of the large-diameter blade 460 rotated around the rotational axis of the rotary blade 450 and the step difference of the end 472 It is formed so as to have an inclination angle that coincides with the incident angle of the water flow contacting the inclined surfaces 472a and 472b at one location, with respect to the side surface of the large-diameter blade 460 .

In addition, the end 474 is formed over the entire length of the upper edge of the auxiliary blade 468, respectively.

By having such a shape, the water flow splashed up by the large-diameter blade 460 is directed in the tangential direction of the circle centered on the rotation axis of the rotary blade 450, and the water flow in front and back of the end portion 472 becomes uniform. For this reason, generation|occurrence|production of a turbulence can be reduced and the mixing of air bubbles to a water flow can be suppressed.

Further, the ends 482 and 484 are formed over the entire length of the outer edge edges of the large-diameter blade 460 and the auxiliary blade 468, respectively. These end portions 482 and 484 have a function of guiding the water sucked in from the suction port outward in the radial direction of the rotary blade 450 .

With such a configuration, in this drainage pump, the position of the gas-liquid interface of the water discharged by the synergistic action of the ends 472 and 482 of the large-diameter blade 460 and the ends 474 and 484 of the auxiliary blade 468 becomes a position further away from the axis of rotation of the rotary blade (450). In addition, by the inclined surfaces 472a and 472b formed on the upper end of the large-diameter blade 460 , it suppresses the occurrence of turbulence in the water flow formed in the rotary blade 450 . For this reason, while a rotary blade improves suction capability, a vibration and a noise can be reduced.

In addition, by the annular flat surface 464 , the water flow rising along the bottom surface of the annular member 462 does not interfere with the water flow flowing over the outer edge edge of the large-diameter blade 460 and the auxiliary blade 468 . This achieves the effect that the generation of bubbles is further suppressed.

<Second embodiment>

Fig. 6 is a diagram showing the outline of the pump body of the drain pump according to the second embodiment of the present invention. Here, FIG. 6A is a longitudinal cross-sectional view of the pump body 530 cut through a plane passing through the center line of the discharge port 546 to be described later, and FIG. 6B is the pump body 530 with the rotary blade 550 removed. ), it is a perspective view viewed from below, cut with a plane passing through the center line. The rotary blade 550 shown in FIG. 6A is equivalent to the rotary blade 250 shown in FIG. 3, for example, is connected to the motor 10 as shown in FIG. 8, and is rotatable.

As shown in FIG. 6 , the pump body 530 of the drain pump according to the second embodiment includes a housing 540 having an upper opening, a cover 532 fitted with the upper opening of the housing 540 ; A rotary blade 550 disposed in a pump chamber 544 defined by a housing 540 and a cover 532 is provided. Here, each of the above-mentioned components constituting the pump body 530 may be made of, for example, plastic.

The housing 540 has a pump chamber 544 formed therein, a pipe-shaped suction pipe 542 having a suction port 543 communicating with the pump chamber 544 from below, and a pump chamber 544 provided on the side of the pump chamber 544 . ) and a discharge pipe 545 having a discharge port 546 communicating with the outside. Reference numeral 546a denotes a discharge port inlet through which the discharge port 546 opens to the pump chamber 544 .

In the second embodiment, the housing 540 has an upper end surface 548a at the same height as the lower end of the outlet inlet 546a, and the inner surface protruding from the outlet inlet 546a toward the inner center of the housing 540 . An annular projection 548 having a 548b is provided on the inner surface side thereof.

Meanwhile, the cover 532 has an annular side wall portion 533 fitted to the upper opening of the housing 540 , and is connected to the housing 540 with the seal member 534 sandwiched therebetween.

The lower end 533a of the annular side wall portion 533 extends to the same height as the upper end of the discharge port inlet 546a, and the inner surface 533b of the annular side wall portion 533 is the outlet inlet 546a. It is formed in a shape protruding from the inner center of the cover 532 .

Next, the operation of the second embodiment of the present invention will be described with reference to Fig. 6A.

First, when a motor (not shown) is rotated, the rotary blade 550 rotates, water is sucked into the pump chamber 544 from the suction port 543 , and the sucked water is discharged from the discharge port 546 .

Since the centrifugal force is applied to the water sucked from the suction port 543 by the rotary blade 550, an air layer is formed on the inner side and a water layer on the outside in the radial direction of the rotary blade 550, and the boundary is called a gas-liquid interface. A layer of bubbles is formed where the air and water mix with each other.

When the bubbles generated on the gas-liquid interface cross the upper end of the rotary blade 550, they are pushed out in the circumferential direction by centrifugal force.

Here, in the second embodiment, since an annular side wall portion 533 is formed on the cover 532 and an annular protrusion 548 is formed on the housing 540, the inner diameter of the pump chamber 544 is , the upper side (the portion indicated by reference numeral 533b) and the lower side (the portion indicated by the reference number 548b) of the discharge port inlet 546a are smaller than those of the discharge port inlet 546a. As a result, the centrifugal force generated by the rotation of the rotary blade 550 acts on the inner wall portion of the pump chamber 544, the force acting on the upper and lower portions of the discharge port inlet 546a rather than the portion of the pump chamber 544. gets smaller

Therefore, in the second embodiment as well as in the first embodiment, most of the water flowing into the discharge port inlet 546a from the pump chamber 544 is the portion opposite to the discharge port inlet 546a where the action of centrifugal force is strong (the part of the pump chamber 544) The amount of water flowing into the discharge port inlet 546a which becomes water from the discharge port inlet 546a) and which has reached the upper outer periphery of the pump chamber 544 is reduced. As a result, mixing of air bubbles into the water flowing into the discharge port inlet 546a from the pump chamber 544, ie, the waste water flowing out from the discharge port 546, is suppressed, and quietness during operation can be achieved.

In addition, by providing the annular protrusion 548 on the lower inner surface of the housing 540 , compared to the conventional drainage pump, the annular protrusion 548 formed on the outer peripheral end of the rotary blade 550 and the inner surface of the housing 540 . ) and the distance is closer, and the pump chamber 544 of the pump body 530 is divided into an upper pump chamber and a lower pump chamber in appearance with the rotary blade 550 as a boundary.

Thereby, the water discharged from the discharge port 546 is discharged from the above-described upper pump chamber and is stable without interfering with the water flow in the upper pump chamber.

In addition, in this second embodiment, it is also possible to use a rotary blade as shown in Figs. 2, 4 or 5.

7 is a graph showing a result of comparing noise during operation between the drain pump according to the first embodiment of the present invention shown in FIGS. 1 and 2 and the conventional drain pump shown in FIGS. 8 and 9 . In the graph shown in Fig. 7, the horizontal axis represents the frequency, and the vertical axis represents the sound pressure level of noise. In addition, the broken line in a graph shows the result by the conventional drain pump, and the solid line shows that of the drain pump by this invention.

As shown in Fig. 7, the conventional drain pump and the drain pump according to the first embodiment of the present invention exhibit the same generation tendency in sound pressure level with respect to frequency.

However, in the frequency band of about 1000 to 3000 Hz, which is easy to feel as noise from a hearing point of view, the sound pressure level of the drain pump according to the first embodiment of the present invention tends to be lower than that of the conventional drain pump. , confirmed by experiments.

By the way, the present invention is not limited to each of the above-described examples, and various modifications can be made.

For example, in the above embodiment, the case in which the annular side wall portion is integrally formed with the cover in the cover of the drain pump is exemplified. However, the annular side wall portion may be configured as a separate body and disposed in the pump chamber.

In particular, when compared with the cover of the conventional drain pump shown in Fig. 9, only the annular portion from which the cover of the drain pump of the present invention protrudes is formed as a separate ring member, and the separate ring is arranged in the pump chamber, The effect of the present invention can be obtained only by adding the ring member to the conventional drain pump.

Further, in the second embodiment, the housing 540 has been described with an annular protrusion 548 formed, but the present invention is not limited thereto, and the protrusion 548 is separate from the housing 540, A separate projection 548 may be attached to the inside of the pump chamber 544 .

In addition, various things other than the thing mentioned above are applicable to the rotor blade applied to this invention. For example, a plurality of auxiliary blades may be arranged between the large-diameter blades, or the auxiliary blades themselves may be omitted, and the number of large-diameter blades, auxiliary blades and small-diameter blades is not limited to the above four pieces. It goes without saying that it does not matter even if the rotor blades have other configurations.

In addition, various modifications can be made to each of the above-described embodiments without departing from the gist of the present invention.

130, 530: pump body
132, 532: cover
140, 540: housing
142, 542: suction pipe
146, 546: outlet
146a, 546a: outlet entrance
150, 250, 350, 450, 550: rotary blade
152, 252, 352, 452, 552: shaft
154: small diameter wings
160, 260, 360, 460: large diameter wings
162, 262, 362, 462: annular member
168, 268, 368, 468: auxiliary wing

Claims (5)

A pump body having a motor, a housing having an upper end open and an inlet port provided at the lower end, and a discharge port provided on the side, a rotary blade connected to the motor, and a cover attached to the upper end of the housing while having a through hole in the center A drain pump comprising a pump chamber defined by the housing and the cover, and the discharge port having a discharge port inlet opening to the pump chamber,
The pump chamber has an annular inner wall portion having a ceiling portion having the through hole and perpendicular to the axis line of the rotor blade, and the discharge port inlet coaxial with the axis line of the rotor blade,
The annular inner wall portion constitutes a multi-stage cylindrical inner wall having a different inner diameter coaxially with respect to the axis with the upper end of the outlet inlet as a boundary, and a first inner diameter in a first area above the upper end of the outlet inlet and a cylindrical inner wall portion having a second inner diameter greater than the first inner diameter in at least a second area from the upper end of the outlet inlet to the lower end of the outlet in a region lower than the upper end of the outlet inlet, In the pump chamber, the area having the first inner diameter does not overlap the second area. The method of claim 1,
The cover has an annular side wall portion that fits into the opening of the housing, a lower end of the annular side wall portion is positioned at the same height as an upper end of the outlet inlet, and an inner surface of the annular side wall portion extends from the outlet inlet to the cover is formed in a shape protruding inward of the , and the first region is constituted by the annular side wall portion. 3. The method of claim 1 or 2,
The housing further has an annular protrusion, and the annular protrusion has an upper end positioned at the same height as a lower end of the outlet inlet, and an inner surface of the annular protrusion protrudes from the outlet inlet to the inside of the pump chamber. drain pump. 3. The method of claim 1 or 2,
The rotary blade includes a shaft portion connected to the output shaft of the motor, a plurality of large-diameter blades extending in a radial direction from the shaft portion, and a plurality of small-diameter blades connected to a lower edge of the large-diameter blade. 5. The method of claim 4,
A drain pump, characterized in that an auxiliary blade is also provided between the adjacent large-diameter blades.

Images