KR20120036747A - Drain pump - Google Patents

Abstract

PURPOSE: A drain pump is provided to prevent an electric leakage or a rust of a motor shaft caused by a drain attached to the motor shaft because the motor shaft is not exposed between an impeller and a split member. CONSTITUTION: A drain pump(1) comprises a pump part(3) and a motor part(2). The pump part comprises a pump chamber(33) and an impeller(34). The motor part comprises a motor shaft(22). The motor shaft is connected to the impeller in a coaxial. The pump part is arranged in the lower part of the motor part. The impeller comprises an impeller body and shaft part. A motor shaft compression concave part is formed in the shaft part.

Description

Drain Pump {DRAIN PUMP}

The present invention relates to a drain pump for discharging drain (drainage) that accumulates in the drain pan. More specifically, the present invention relates to a drain pump having a water cutting member for preventing the drain overflowing from the through hole formed in the pump chamber housing partitioning the pump chamber from being attached to the motor as the driving source.

In the indoor unit of an air conditioner, the drain pan which generate | occur | produces in the indoor unit by the evaporator at the time of cooling or dehumidification is received by the drain pan, and the drain accumulated in the drain pan is sucked up by the drain pump and discharged | emitted to the outdoors. The drain pump has a pump section including a pump chamber and a vane disposed in the pump chamber, and a motor section including a motor shaft connected coaxially to the vane, and is used in a state where the pump section is located below the motor section.

The drain pump agitates the drain in the pump chamber by rotating the vane in the pump chamber, and sucks the drain of the drain pan into the pump chamber from the suction port formed at the lower end of the pump chamber by the centrifugal force generated thereby, and thus the side of the upper part of the pump chamber. It discharges from the discharge port formed in the. A drain pipe is connected to the discharge port, and the drain is discharged to the outside from the discharge port via the drain pipe. In the pump chamber housing partitioning the pump chamber of the drain pump, a through hole for introducing air into the pump chamber is formed when the drain is stirred by the vane. An impeller is connected to the motor shaft via this through hole, and is driven by a motor.

In the drain pump, when the motor is stopped to stop the rotation of the van, the drain may sometimes flow backward from the drain pipe side toward the pump chamber. Here, if the drain flows backward, the drain overflows from the pump chamber through the through hole and may be attached to the motor disposed above the pump chamber. If the motor gets wet, a short circuit or malfunction of the motor may occur, so that the motor shaft is equipped with a cut-off plate to face the through-hole so that the drain discharged from the through-hole is not scattered to the motor side by the cut-off plate. have. Such a drain pump is described in patent document 1. As shown in FIG.

In Patent Literature 1, in consideration of the possibility that an electric leakage may occur even when a drain is attached to the motor shaft, the sealing member is attached to the outer circumferential side of the motor shaft exposed between the vane and the water receiving plate.

Japanese Laid-Open Patent Publication No. 2009-36167

In patent document 1, in order not to attach a drain to a motor, the sealing member is needed in addition to a cut-off board, and the component score is increasing. Moreover, in patent document 1, since the sealing member is arrange | positioned between the vane with which the motor shaft is connected, and the cutting board attached to the motor shaft, unless the motor shaft and vane are mounted with good precision in an axial direction, There exists a problem that the dimension between an impeller and a cutting board changes, and the sealing property by a sealing member falls.

In view of such a problem, an object of the present invention is to provide a drain pump that can reliably avoid the attachment of a drain overflowing through a through hole formed in a pump chamber housing partitioning a pump chamber to a motor shaft with only a water cutting member. It is in doing it.

In order to solve the above problems, the present invention,

As a drain pump which has a pump part provided with a pump chamber and a vane, and the motor part provided with the motor shaft connected coaxially to the said vane, The said pump part is used in the state located under the said motor part (drain pan side). ,

The vane passes through a through hole formed in a vane main body disposed in the pump chamber and a pump chamber housing extending coaxially from the vane main body and partitioning the pump chamber. Has a shaft portion projecting outward of the pump chamber,

The shaft portion is provided with a motor shaft press-in recess which extends downward on the coaxial axis from an upper end surface (motor section side end face) of the shaft portion,

The water shaft member of the shape which spreads outward from the outer peripheral surface of the said shaft edge part is attached to the said shaft edge part, It is characterized by the above-mentioned.

According to the present invention, the cutting member is not attached to the motor shaft, but is attached to the shaft end of the van. As a result, since the motor shaft is not exposed between the water-receiving member and the vane, it is possible to prevent a short circuit or rust of the motor shaft, which occurs due to the attachment of the drain to the motor shaft. In addition, in order to prevent the drain from adhering to the motor shaft, it is not necessary to form a seal member covering the outer circumferential side of the motor shaft, so that the number of parts can be reduced.

In the present invention, the cutting member is preferably fixed to the shaft end. In this case, for example, when the cutting member is fixed to the shaft end by press-fitting, the assembly work is facilitated because it can be fixed with sufficient strength.

In this case, it is preferable that the said cutting member is press-fitted to the said shaft end part, and the said cutting member is equipped with the shaft part press-fitting cylinder part in which the shaft end part was press-fitted. In this case, since the press-fitting zone with respect to the shaft end can be secured long, the rotational force and vibration of the pump, external shock, loosening and positional shift due to secular variation are less likely to occur. Is secured to a stable shaft end.

In this case, it is preferable that the said cutting member is provided with the collar part which spreads outward from the outer peripheral surface of the said shaft part press-fitting cylinder part, and it is preferable that the outer peripheral edge of the said collar part is located in the radial direction outer side rather than the said through-hole. By doing in this way, the effect which prevents the drain which overflowed upwards from the through-hole from scattering upwards rather than a water cutting member is high.

In this case, the pump chamber housing has a circular bottom plate having the through hole, an inner circumferential wall extending upward from an outer circumferential edge of the bottom plate, and a radial direction from an upper edge of the inner circumferential wall. An outer circumferential wall extending outwardly and an outer circumferential wall extending upwardly from an outer circumferential edge of the circular circumferential portion, the lower end of the outer circumferential wall having a long hole extending in the circumferential direction at equal angle intervals; (長 孔) is formed, and it is preferable that the said collar part is formed above the lower end of the said long hole. In this way, since the surface of the drain is discharged from the hole before reaching the collar portion, the drain does not reach the motor shaft over the collar portion. For this reason, rust of a motor shaft can be prevented.

In this case, the cutting member protrudes inward from the inner circumferential surface of the shaft press-fitting cylinder portion, and when the shaft end is press-fitted to the shaft press-fitting cylinder portion, the cutting member abuts against the positioning portion of the shaft member. It is preferable to have a stopper for determining By doing in this way, a water-repellent member can be attached in the state positioned at the shaft edge part of an impeller. In addition, by bringing the stopper into contact with the positioning portion of the shaft portion, the posture of the cutting member attached to the shaft end portion can be set to a predetermined predetermined position.

In this case, it is preferable that the said positioning part of the said shaft part is the upper end surface of the said shaft part. In this way, the shaft portion can be shortened.

In this case, the stopper has a shaft hole through which the motor shaft is inserted, and a gap is formed between the motor shaft and the stopper to prevent the capillary force from acting. desirable. In this way, even when the drain overflowed from the through hole is attached to the water-receiving member, it is possible to avoid that the drain is held between the motor shaft and the water-reducing member by capillary action.

In the present invention, the gap is preferably formed above the lower end of the long hole. In this way, since the surface of the drain is discharged from the long hole before reaching the gap, rust of the motor shaft can be prevented.

In the present invention, the motor shaft press-fit concave portion has a large diameter portion that is larger in diameter than the motor shaft from a distal end face side of the shaft portion, and a small diameter portion that is smaller in diameter than the large diameter portion and has been press-fitted in the motor shaft. It is preferable to have provided. By doing so, the motor shaft can be press-fitted into the motor-shaft press-in recessed part even if the tip part of the motor-shaft press-in recessed part is compressed inward by press-fitting and fixing the cutting member to the shaft end. Therefore, the operation of connecting the vanes, the water-receiving member, and the motor shaft becomes easy.

In this invention, it is preferable that the positioning part is formed in the outer peripheral side of the said shaft edge part, and the said cutting member is being fixed to the said positioning part. By doing in this way, the position of a cutting board and a vane can be assembled correctly.

In this case, it is preferable that the shaft end extends upwardly from the cutting member. In this way, the drain does not reach the motor shaft.

In this invention, it is preferable that the said positioning part is a circular-shaped step part, the said cutting member is a circular-shaped plate of fixed thickness, and the inner peripheral part of the said circular-shaped plate is fixed to the said circular-shaped step part. Do. In this case, since the cutting member is plate-shaped, its manufacturing cost can be suppressed.

In the present invention, the positioning portion is an annular groove extending in the circumferential direction of the shaft end, the cutting member is a circular plate of a constant thickness, the inner peripheral portion of the circular plate is in the annular groove It is preferable that it is fixed by being fitted. In this case, since the cutting member is plate-shaped, its manufacturing cost can be suppressed. In addition, the water-repellent member attached to the shaft end can prevent the position shift due to rotational force and vibration of the pump, shock from the outside, and aging change.

According to the present invention, the cutting member is not attached to the motor shaft, but is attached to the shaft end of the van. As a result, since the motor shaft is not exposed between the water-receiving member and the vane, it is possible to prevent a short circuit or rust of the motor shaft, which occurs due to the attachment of the drain to the motor shaft. In addition, in order to prevent the drain from adhering to the motor shaft, it is not necessary to form a seal member covering the outer circumferential side of the motor shaft, so that the number of parts can be reduced.

1 is an overview perspective view of a drain pump to which the present invention is applied.
2 is a longitudinal sectional view of a drain pump to which the present invention is applied.
3 is a sectional view of the pump portion and a partially enlarged view around the shaft portion of the vane.
4 is a perspective view, a plan view, and a sectional view of a vane.
5 is a perspective view and a cross-sectional view of the cutting member.
6 is an explanatory diagram for explaining the operation of the drain pump.
7 is a partially enlarged view of the periphery of the pump portion of the drain pump of the modification.
8 is a longitudinal sectional view of a pump portion of the drain pump of Embodiment 2. FIG.
9 is a partially enlarged view of the periphery of the pump portion of the drain pump of the modification of the second embodiment.

EMBODIMENT OF THE INVENTION Below, with reference to drawings, the drain pump to which this invention is applied is demonstrated.

(Example 1)

(Overall configuration)

1 is an overview perspective view of a drain pump. 2 is a longitudinal cross-sectional view of the drain pump. As shown in FIG. 1, the drain pump 1 is arrange | positioned above the drain pan 100 which accommodates the drain D which arises in the indoor unit by the evaporator at the time of cooling or dehumidification in the indoor unit of an air conditioner. It is.

The drain pump 1 has the motor part 2 and the pump part 3 used as a drive source. In the state using the drain pump 1, as shown in FIG. 1, the pump part 3 is located under the motor part 2, ie, the drain pan 100 side. From the upper part of the motor part 2, the three mounting arms 21 for fixing the drain pump 1 to an indoor unit protrude upwards. The motor shaft 22 protrudes downward from the lower end surface of the motor part 2.

The pump section 3 includes a suction pipe 30 extending downward and a discharge pipe 31 extending laterally. The lower end opening 30a of the suction pipe 30 is located inside the drain pan 100, and the drain pipe 101 is connected to the discharge pipe 31.

As shown in FIG. 2, the pump chamber 33 is partitioned inside the pump part 3 by the pump chamber housing 32, and the vane 34 is arrange | positioned in this pump chamber 33. As shown in FIG. The pump chamber housing 32 has a lower pump chamber housing 35 and an upper pump chamber housing 36, and the vanes 34 have through holes 331 formed in the bottom plate 361 of the upper pump chamber housing 36. It is connected to the motor shaft 22 through it. The vane 34 is equipped with a water-reducing member 37 for preventing the drain D overflowing upward from the pump chamber 33 via the through hole 331.

When the vane 34 rotates by driving the motor unit 2, the drain D accumulated in the drain pan 100 is sucked up from the lower end opening 30a of the suction pipe 30 into the pump chamber 33 to discharge the discharge pipe. It is discharged from 31. The drain D discharged from the discharge pipe 31 is discharged to the outside via the drain pipe 101.

(Motor part)

As shown in FIG. 2, the motor unit 2 includes a resin lower motor part case 23 and an upper motor part case 24. The lower motor part case 23 is upward from the annular bottom plate 231, the cylindrical portion 232 extending upward from the inner peripheral edge portion of the bottom plate 231, and the outer peripheral edge portion of the bottom plate 231. And a cylindrical flange 234 extending radially outward from a lower end portion of the peripheral wall 233. On the bottom plate 231, an annular circuit board 25 is placed with a slight gap. The cylinder part 232 is equipped with the circular-shaped step part 232a in the outer peripheral surface part in the middle of the axial direction L, The stator 26 is being fixed to this circular-shaped step part 232a. The stator 26 is provided with the stator core provided with the some salient pole which protrudes in the radial direction, and the drive coil wound around each salient pole.

On the inner circumferential side of the cylinder portion 232, two annular sintered bearings 27 are mounted at positions away from the axial direction L. These sintered bearings 27 are supported in a state in which the motor shaft 22 can rotate freely. The lower portion of the motor shaft 22 protrudes downward from the lower motor portion case 23, and the upper end portion of the motor shaft 22 protrudes upward from the cylinder portion 232. The cup-shaped yoke 28 is attached to the upper end of the motor shaft 22 with the opening facing downward, and the S pole and the N pole alternate in the circumferential direction to the inner circumferential surface of the yoke 28 facing inward. A ring-shaped permanent magnet 29 is magnetized.

The upper motor part case 24 extends radially outward from the circular ceiling plate 241, the outer circumferential wall 242 extending downward from the outer circumferential edge portion of the ceiling plate 241, and the outer circumferential wall 242. A ring-shaped flange 243 is provided. The upper motor part case 24 is covered by the lower motor part case 23 from above, and the inner peripheral surface part of the outer peripheral wall 242 abuts against the outer peripheral surface of the circumferential wall 233 of the lower motor part case 23, The lower end surfaces of the outer circumferential wall 242 and the flange 243 abut against the upper end surface of the flange 234 of the lower motor part case 23, and are fixed to the lower motor part case 23. Three mounting arms 21 protrude upward from the top plate 241.

(Pump part)

3 (a) is a sectional view of the pump section 3, and FIG. 3 (b) is a partially enlarged view of the periphery of the shaft of the vane 34. The pump chamber housing 32 which divides the pump chamber 33 in the pump part 3 is provided with the lower pump chamber housing 35 and the upper pump chamber housing 36. The lower pump chamber housing 35 has a large diameter portion 353 having a ring-shaped bottom plate 351 and an outer circumferential wall 352 extending upward from an outer circumferential edge of the bottom plate 351, and a bottom plate 351. Suction tube 30 extending downward from the inner circumferential edge thereof, discharge tube 31 extending laterally from the opening edge of circular opening 352a formed in the wall surface portion of outer circumferential wall 352, and outer circumferential wall 352. And a flange 354 formed so as to protrude upward after extending radially from an upper edge of the edge.

The upper pump chamber housing 36 includes a ring-shaped bottom plate 361 having a through hole 331 in the center portion, an inner circumferential wall 362 extending upward from an outer circumferential edge of the bottom plate 361, A circular plate portion 363 extending radially outward from the upper edge of the inner circumferential wall 362 and an outer circumferential wall 364 extending upward from the outer circumferential edge of the circular plate portion 363 are provided. . In the lower end portion of the outer circumferential wall 364, a plurality of long holes 365 extending in the circumferential direction at equal angle intervals are formed (see FIG. 1).

In the upper pump chamber housing 36, the lower portion of the inner circumferential wall 362 is inserted into the flange 354 of the lower pump chamber housing 35 via the O-ring 38, whereby the pump chamber 33 is It is partitioned. That is, the bottom plate 361 of the upper pump chamber housing 36 defines the ceiling of the pump chamber 33, and the space inside the lower pump chamber housing 35 is the pump chamber 33. The pump chamber 33 is provided with the large diameter pump chamber part 333 located inside the large diameter part 353 of the lower pump chamber housing 35, and the small diameter pump chamber part 334 located inside the suction pipe 30. As shown in FIG. .

Here, above the pump chamber 33, the small diameter recessed part 366 is partitioned from the pump chamber 33 side by the upper surface of the bottom plate 361 of the upper pump chamber housing 36 and the inner circumferential wall 362. The large-diameter concave portion 367 is partitioned off by the annular plate portion 363 and the outer circumferential wall 364.

(Wing car)

The vanes 34 will be described with reference to FIGS. 3 and 4. 4A is a perspective view of the vane 34 from above, FIG. 4B is a perspective view of the vane 34 from below, and FIG. 4C is a plan view of the vane 34. 4D is a longitudinal cross-sectional view of the vane 34. The impeller 34 is an integrally molded article made of resin, and as shown in FIG. 3, extends upward from the impeller main body 341 and the impeller main body 341 arranged in the pump chamber 33 and upwards. The shaft end 342a is provided with the shaft part 342 which penetrates the through-hole 331 of the upper pump chamber housing 36. As shown in FIG. The vane body 341 extends coaxially downward from the large diameter vane 343 and the large diameter vane 343 which is disposed in the large diameter pump chamber portion 333, and is disposed in the small diameter pump chamber portion 334. A small diameter vane 344 is provided.

As shown in FIG. 4, the large-diameter vanes 343 have an annular shape having a constant height arranged to surround the outer periphery of the eight wing plates 343a extending from the center toward the outside and the wing plates 343a. The plate 343b is provided. Each vane 343a extends along the axial direction L, and is inclined in the opposite direction to the rotational direction (arrow) in the radial direction (refer FIG. 4 (c)). In the four wing plates 343a arranged at intervals of one of the eight wing plates 343a, the notch 343c which is recessed upward toward the inner side is formed in the lower end part of the inner peripheral side. The small-diameter vanes 344 are provided with four blade plates 344a extending radially from the center toward the outside.

The shaft portion 342 extends upward from the center of the large diameter vane 343. The shaft portion 342 is formed with a recess 345 (motor shaft press-fit recessed portion) along the axial direction L (center axis line) from the upper end surface 342b of the shaft portion 342. As shown in FIG.4 (d), the recessed part 345 is formed until it reaches the upper end part of the vane main body 341. As shown in FIG.

Here, the upper end surface 342b of the shaft part 342 becomes a positioning part for determining the position of the cutting member 37 when attaching the cutting member 37. The concave portion 345 of the shaft portion 342 is inserted into the motor shaft 22, and as shown in FIG. 4 (d), the motor shaft 22 is formed from the upper end surface 342b side of the shaft portion 342. ) Is provided with a large diameter portion 345a which is larger in diameter and a smaller diameter portion 345b which is smaller in diameter than the large diameter portion 345a and in which the inserted motor shaft 22 is pressed. Here, in the state in which the water cutting member 37 is attached to the shaft portion 342, as shown in FIG. 3B, the large diameter portion 345a is located inside the water cutting member 37. In this example, the depth dimension of the large-diameter portion 345a coincides with the length dimension of the axial direction L of the attachment range of the water cutting member 37 in the shaft portion 342.

(Cutting member)

The cutting member will be described with reference to FIGS. 3 and 5. Fig. 5A is a perspective view of the cutting member 37 from above, Fig. 5B is a perspective view of the cutting member 37 from below, and Fig. 5C is a sectional view of the cutting member 37. Figs. . The cutting member 37 is made of resin, and a material close to the shaft portion 342 of the vane 34 and the coefficient of linear expansion or the same material as the vane 34 is used. The cutting member 37 includes a cylinder 371 (axial press fitting cylinder), an annular collar portion 372 which projects radially outward from the upper edge of the cylinder 371, and an upper end of the cylinder 371. The circular-shaped stopper 373 which protrudes radially inward from the edge is provided. The inner peripheral part of the lower end of the cylinder part 371 is cut out, and it is set as the tapered surface 371a.

As shown in FIG. 3 (a), the water-reducing member 37 is located above the bottom plate 361 of the upper pump chamber housing 36 at the shaft portion 342 of the vane 34 inside the cylinder portion 371. In the state where the exposed shaft end 342a is press-fitted, it is fixed to this shaft part 342. When the cutting member 37 is fixed to the shaft end 342a of the shaft portion 342, as shown in FIG. 3B, the lower end surface 373a of the ring-shaped stopper 373 is positioned at the shaft portion 342. The top face 342b, which is the determining portion, abuts, whereby the cutting member 37 is in a posture in which the collar portion 372 is widened in the direction orthogonal to the axial direction L. As shown in FIG. Moreover, the lower end surface 371b of the cylinder part 371 becomes the state which opposes the through-hole 331, and the outer peripheral edge 372a of the collar part 372 is the bottom of the upper pump chamber housing 36 of the pump chamber 33. Moreover, as shown in FIG. It is located in the radially outer side rather than the through-hole 331 of the board 361. In addition, after the water-reducing member 37 is attached to the shaft portion 342, the motor shaft 22 is inserted into the through hole 373b (shaft hole), which is in the center of the annular stopper 373, and the shaft portion 342 When the motor shaft 22 is press-fitted into the recessed part 345 of (), the vane 34 and the motor shaft 22 are connected. In the state in which the vane 34 and the motor shaft 22 are connected, the clearance A between the inner peripheral surface 373c of the circular-shaped stopper 373 and the outer peripheral surface of the motor shaft 22 so that a capillary force does not act. ) Is formed (see FIG. 3 (b)).

(Assembling method of the drain pump)

Here, the assembling method of the drain pump 1 is demonstrated. When assembling the drain pump 1, first, the shaft portion 342 of the vane 34 is passed through the through hole 331 of the bottom plate 361 of the upper pump chamber housing 36.

Next, the water-reducing member 37 is attached to the shaft end 342a which is exposed above the bottom plate 361 of the upper pump chamber housing 36 in the shaft part 342. That is, the shaft end 342a of the vane 34 is press-fitted inside the cylindrical portion 371 of the cutting member 37, so that the upper end surface 342b and the circular stopper 373, which are the positioning portions of the shaft portion 342, are pressed. Bottom surface 373a is brought into abutment. Thereby, the cutting member 37 is a vane 34 in a predetermined posture in which the collar portion 372 is widened in the direction orthogonal to the axial direction L while the position is determined at the upper end of the shaft portion 342. Is mounted on. Moreover, the water cutting member 37 is fixed to the vane 34 reliably by press fitting. Here, in this example, since the positioning part is made into the upper end surface 342b of the shaft part 342, and the cut-off member 37 is fixed to the upper end part of the exposed part of the shaft part 342, the through-hole ( The drain D overflowing upward from the 331 can be restrained from colliding strongly with the water-receiving member 37. Therefore, scattering of the drain D can be suppressed. That is, since the clearance gap between the collar portion 372 and the through hole 331 in the up and down direction becomes large, the force of the drain D overflowing upward from the through hole 331 until the collar portion 372 reaches the collar portion 372 is weak. Become.

Moreover, in order to improve the sealing property of the clearance gap between the cutting member 37 and the shaft end part 342a, you may apply a sealing compound or an adhesive agent to the interface vicinity of a press part, for example, a taper surface 371a and the clearance gap A. In addition, the cutting member 37 and the shaft end portion 342a may be welded.

Thereafter, the motor shaft 22 of the motor portion 2 is press-fitted into the recessed portion 345 formed in the shaft portion 342 to be fixed.

Here, by pressing the cutting member 37 into the shaft end 342a of the shaft portion 342, even when the shaft end 342a of the recess 345 is compressed inward, the recessed portion 345 Since the shaft end part 342a is made into the large diameter part 345a which is larger diameter than the motor shaft 22, it is easy to insert the motor shaft 22 with respect to the recessed part 345, and the motor shaft 22 Can be press-fit into the small-diameter portion 345b of the recess 345.

Then, the lower pump chamber housing 35 is mounted on the upper pump chamber housing 36 from below, and the vanes 34 are disposed in the pump chamber 33 partitioned by the lower pump chamber housing 35 and the upper pump chamber housing 36. An impeller body 341 is accommodated.

(Operation of the drain pump)

6 is an explanatory diagram for explaining the operation of the drain pump. In addition, the arrow in a figure shows the flow of the drain D. FIG.

If the drain D of the drain pan 100 accumulates above the lower end opening 30a of the suction pipe 30 disposed inside the drain pan 100, the motor portion 2 of the drain pump 1 is Driven. As a result, when the vanes 34 rotate, air is introduced into the pump chamber 33 via the through hole 331, and the drain D is stirred in the pump chamber 33, and the drain ( D) Sucked up into this pump chamber 33. That is, the drain D is sucked up from the drain pan 100 to the large diameter pump chamber part 333 via the small diameter pump chamber part 334 (D1). And it discharges from the discharge tube 31 through the circular opening 352a of the large diameter pump chamber part 333 (D2). The drain D discharged from the discharge pipe 31 is discharged to the outside via the drain pipe 101.

Here, when the motor part 2 stops and rotation of the vane 34 stops, the drain D will flow back from the drain pipe 101 side (D3). At this time, most of the backflow drain D is returned to the drain pan 100 via the suction pipe 30 (D4), but a part thereof overflows above the pump chamber 33 via the through hole 331. There is a case to come. For example, when the drain pipe 101 connected to the discharge pipe 31 is long, and the discharge port of the drain pipe 101 is arrange | positioned above the drain pump 1, or a part of the drain pipe 101 Is disposed above the drain pump 1, the drain D in the drain pipe 101 may strongly flow back toward the pump chamber 33, and in this case, the drain D that flows back A part overflows upward from the through hole 331 (D5).

In such a case, the drain D overflowing upward from the through hole 331 hits the water-reducing member 37 and is returned downward, and the small-diameter recess 366 partitioned above the pump chamber 33. Is stuck on. The drain accumulated in the small diameter concave portion 366 is returned from the through hole 331 to the drain pan 100 via the pump chamber 33. Moreover, the drain D which is about to overflow from the small diameter recessed part 366 is discharged | emitted toward the drain pan 100 below from the long hole 365 (D6). Therefore, the drain D overflowing upward from the through hole 331 can be prevented from adhering to the motor unit 2. Therefore, a short circuit caused by wet of the motor part 2 and the malfunction of the motor part 2 can be avoided. In addition, since the collar portion 372 and the gap A are formed above the lower end of the long hole 365 and the small diameter concave portion 366, the water surface of the drain D accumulated in the small diameter concave portion 366. Silver is discharged from the long hole 365 toward the drain pan 100 below before reaching the collar portion 372 and the gap A. As shown in FIG. Therefore, the drain D does not come in contact with the motor shaft 22, and rust of the motor shaft 22 can be prevented.

(Action effect)

According to this example, the water cutting member 37 is not attached to the motor shaft 22 but is attached to the shaft portion 342 of the vane 34. As a result, since the motor shaft 22 is not exposed between the cutting member 37 and the vane 34, the electric leakage and the motor shaft 22 which arise due to attaching the drain to the motor shaft 22 are not exposed. You can prevent this rusty. Moreover, in order to prevent the drain D from adhering to the motor shaft 22, it is not necessary to form the sealing member which covers the outer peripheral side of the motor shaft 22, and a component point can be reduced.

In addition, since the outer peripheral edge of the collar portion 372 of the cutting member 37 is located on the outer side in the radial direction than the through hole 331, the drain D overflows upward from the through hole 331 and the cutting member The effect of preventing scattering upward is higher than (37).

In addition, according to this example, the water cutting member 37 protrudes inward from the inner circumferential surface 371c of the cylindrical portion 371, and the positioning of the shaft portion 342 is performed when the shaft end 342a is pressed into the cylindrical portion 371. A circular-shaped stopper 373 which is in contact with the female upper end surface 342b and determines the position of the water-reducing member 37 is provided. Therefore, the cutting member 37 can be mounted in a state of being positioned at the shaft end 342a of the vane 34. In addition, by bringing the annular stopper 373 into contact with the upper end surface 342b of the shaft portion 342, the posture of the cut-off member 37 attached to the shaft end 342a can be set to a predetermined predetermined posture. .

In addition, in this example, the water cutting member 37 is provided with the cylindrical cylinder part 371, and the shaft part 342 is press-fitted inside the cylinder part 371. As shown in FIG. As a result, since the press-fitting stage with respect to the axial part 342 can be ensured for long, the rotational force and vibration of the pump part 3, the external shock, loosening and position shift by secular variation hardly arise, The fixation of the cutting member 37 to the shaft end 342a becomes stable.

In addition, since a gap A is formed between the inner circumferential surface 373c of the annular stopper 373 of the cutting member 37 and the outer circumferential surface of the motor shaft 22 to prevent the capillary force from acting, a through hole is formed. Even when the drain D overflowed from the 331 is attached to the cutting member 37, the drain D can be avoided between the motor shaft 22 and the cutting member 37 by capillary action. have.

In addition, since the shaft portion 342 of the vane 34 is formed long so as to extend upwardly through the through hole 331, the motor shaft 22 press-fitted into the shaft portion 342 can be configured to be short. Therefore, the material cost of the motor shaft 22 can be reduced.

In addition, since the water harvesting member 37 is formed of a material close to the shaft portion 342 of the vane 34 and the coefficient of linear expansion or the same material as the vane 34, the environment in which the drain pump 1 is operating is performed. Even when the temperature is changed, the change in the pressing force of the shaft portion 342 of the vane 34 that is pressed into the cylindrical portion 371 of the water cutting member 37 is suppressed. Thus, the cutting member 37 is firmly fixed to the shaft end 342a regardless of the temperature change.

(Variation)

7 is a partially enlarged view of the periphery of the shaft portion 342 of the vane 34 of the drain pump of the variation of the first embodiment. In the drain pump 1, the water-receiving member 37 is fixed using the upper end surface 342b of the shaft portion 342 of the vane 34 as the positioning portion. In the drain pump 1 'of the modification, the vane 34 has a ring-shaped stepped section 342c on the outer circumferential side of the shaft end 342a of the shaft section 342, and uses the ring-shaped stepped section 342c as a positioning unit to cut off the member 37. Is fixing. In addition, since the drain pump 1 'of a modification has the same structure as the said drain pump 1, the same code | symbol is attached | subjected to the corresponding structure, and the description is abbreviate | omitted.

As shown in FIG. 7, the shaft portion 342 has, at its upper end, an outer diameter dimension smaller than the outer dimension of the shaft portion, and a circular protrusion 342d extending coaxially with the shaft portion 342. The annular stepped portion 342c is an annular end surface 342e which extends in the direction orthogonal to the axial direction L from the outer circumferential surface 342e of the annular projection 342d and the lower end of the annular projection 342d ( 342f). The inner diameter of the annular protrusion 342d has the same inner diameter as the large diameter portion 345a of the recess 345 of the shaft portion 342, and the inner circumferential surface of the annular protrusion 342d and the large diameter portion ( The inner peripheral surface of 345a is continuous.

The through hole 373b at the center of the annular stopper 373 is formed in the cutting member 37 so as to have an inner diameter dimension corresponding to the outer diameter dimension of the annular protrusion 342d.

When attaching the water cutting member 37 to the shaft end 342a, the shaft end 342a of the vane 34 is press-fitted into the cylindrical portion 371 of the water cutting member 37, and the circle of the shaft portion 342 is pressed. The annular stepped portion 342c and the circular stopper 373 abut. That is, the inner circumferential surface 373c of the circular stopper 373 abuts on the outer circumferential surface 342e of the circular protrusion 342d, and a circle is formed on the circular sectional face 342f of the circular step 342c. The lower surface 373a of the annular stopper 373 abuts. Thereby, the cutting member 37 is predetermined in which the collar portion 372 is widened in the direction orthogonal to the axial direction L in a state where the position of the cutting member 37 is determined in the annular stepped portion 342c of the shaft portion 342. It is attached to the vane 34 in a posture. Moreover, the water cutting member 37 is fixed to the vane 34 reliably by press fitting. Also in the drain pump 1 'of a modification, the effect similar to the said drain pump 1 can be acquired. Further, between the annular end face 342f of the annular stepped portion 342c and the lower end surface 373a of the annular stopper 373, and the outer peripheral surface 342e and the annular ring of the annular protrusion 342d. Capillary force acts between the inner circumferential surface 373c of the shaped stopper 373 so that the drain D is between the outer circumferential surface 342e of the annular protrusion 342d and the inner circumferential surface 373c of the circular stopper 373. Even if it intrudes, since the shaft end 342a (circular protrusion 342d) extends above the upper surface of the cutting member 37, the drain D does not reach the motor shaft 22. .

(Example 2)

Next, with reference to FIG. 8, the drain pump of Example 2 which mounts the water-receiving member different from the said example is demonstrated. 8 is a longitudinal sectional view of the pump section of the drain pump of this example. Since the drain pump 1A of this example is equipped with the same motor part 2 as the said drain pump 1, the illustration is abbreviate | omitted. In addition, since the pump part 3 of the drain pump 1A of this example has the same structure as the pump part 3 of the said drain pump 1, it attaches | subjects the same code | symbol to a corresponding structure, and demonstrates the description. Omit.

In this example, the water cutting member 40 is made of a circular plate of a constant thickness. The vane 34 is a circle extending in the circumferential direction on the outer circumferential surface of the shaft end 342a that is exposed above the bottom plate 361 of the upper pump chamber housing 36 of the pump chamber 33 at the shaft portion 342. An annular groove 342g is provided.

The cutting member 40 is fixed to the shaft end 342a by the inner circumferential portion 41 being fitted into the annular groove 342g. That is, the ring-shaped groove 342g is a positioning member for determining the position of the cutting member 40 when the cutting member 40 is fixed to the shaft end 342a, and the cutting member 40 ) Is fixed to the shaft end 342a. When the cutting member 40 is fixed to the shaft portion 342, the cutting member 40 is press-fitted into the shaft end portion 342a while elastically deforming the cutting member 40, and the inner circumferential portion 41 is inserted into the annular groove 342g. Put it in.

In this way, since the cutting member 40 is plate-shaped, the manufacturing cost can be suppressed. In addition, since the cutting member 40 is fitted into the annular groove 342g and fixed to the shaft end 342a, the cutting member 40 is positioned at the shaft end 342a of the vane 34. In addition to being able to mount in a state, the posture of the cutting member 37 attached to the shaft end 342a can be set in a predetermined predetermined position. In addition, since the cutting member 40 is fitted into the annular groove 342g and is fixed, the cutting member 40 is loosened due to the rotational force and vibration of the pump portion 3, the impact from the outside, and the secular variation. It does not occur, and the fixation to the shaft end 342a of the cutting member 37 becomes stable and stable. In addition, since the shaft end portion 342a extends upward from the upper surface of the water cutting member 40, the drain D does not reach the motor shaft 22.

In addition, in order to improve the sealing property of the clearance gap between the cutting member 40 and the shaft end part 342a, you may apply a sealing compound or an adhesive agent to cyclic groove 342g. In addition, the cutting member 37 and the shaft end portion 342a may be welded.

(Variation)

9 is a partially enlarged view of the periphery of the shaft portion 342 of the vane 34 of the drain pump of the modification of the second embodiment. In the above-mentioned drain pump 1A, the water-receiving member 40 is fixed using the annular groove 342g formed in the outer peripheral surface 342e of the shaft end 342a as a positioning part and a fixing part. In 1A ', the impeller 34 has a circular stepped part 342c on the outer circumferential side of the shaft end 342a of the shaft part 342, and positions this circular stepped part 342c. The water cutting member 37 is fixed as the crystal part. In addition, since the drain pump 1A 'of a modification has the same structure as the said drain pump 1', 1A, the same code | symbol is attached | subjected to the corresponding structure and the description is abbreviate | omitted.

As shown in FIG. 9, the shaft part 342 is provided in the upper end part with the annular protrusion part 342d whose outer diameter dimension is smaller than the outer dimension of the shaft part, and coaxially extends with the said shaft part 342. As shown in FIG. The annular stepped portion 342c is an annular cross-section that extends in the direction orthogonal to the axial direction L from the outer circumferential surface 342e of the annular protrusion 342d and the lower end of the annular protrusion 342d. It is formed by 342f. The inner diameter of the annular protrusion 342d has the same inner diameter as the large diameter portion 345a of the recess 345 of the shaft portion 342, and the inner circumferential surface of the annular protrusion 342d and the large diameter portion ( The inner peripheral surface of 345a is continuous.

The cutting member 40 is a circular plate, and a circular stepped portion 342c is inserted into the central opening 42, and is fixed to the shaft end 342a by an adhesive or welding. In the state where the water-reducing member 40 is attached to the shaft end part 342a, the lower end surface 41a of the inner peripheral part 41 of the water-reducing member 40 is matched with the ring-shaped cross section of the ring-shaped step part 342c. I'm reaching. Thereby, the cutting member 40 is in the state where the position in the axial direction L was determined by the circular stepped part 342c of the axial part 342, and the collar part 372 is orthogonal to the axial direction L. It is attached to the vane 34 in a predetermined posture widening in the direction to be made. Moreover, you may comprise so that the inner peripheral surface 41b of the water cutting member 40 may contact the outer peripheral surface 342e of the annular protrusion 342d. In addition, since the shaft end portion 342a extends upward from the upper surface of the water cutting member 40, the drain D does not reach the motor shaft 22.

(Other Embodiments)

In the above example, the water-reducing member 37 was made of resin, but may be made of metal such as stainless steel.

1, 1 ', 1A, 1A': Drain Pump
2: motor part
3: pump part
21: mounting arm
22: motor shaft
23: lower motor case
24: upper motor case
25: circuit board
26: stator
27: Sintered Bearing
28: York
29: permanent magnet
30: suction tube
30a: bottom opening
31: discharge tube
32: pump chamber housing
33: pump room
34: wing car
35: lower pump chamber housing
36: upper pump chamber housing
37: cutting member
38: O ring
40: cutting member
41a: bottom surface
41: inner part
42: center opening
100: drain pan
101: drain pipe
231: bottom plate
232: tube
232a: ring-shaped stepped portion
233: circumferential wall
234 flange
241 ceiling panel
242: outer wall
243: flange
331: through hole
333: large diameter pump chamber
334: small diameter pump chamber
341: Wing body
342: shaft portion
342a: shaft end
342b: top surface
342c: ring-shaped stepped portion
342d: ring-shaped protrusion
342e: outer circumference
342f: Circular shape cross section
342 g: circular groove
343 large diameter wing car
343a: wing plate
343b: circular plate
343c: cutout
344: small diameter van
344a: wing plate
345: recessed part (recessed part for motor shaft press-in)
345a: large diameter part
345b: small diameter portion
351: bottom plate
352: outer wall
352a: circular opening
353: large diameter part
354: flange
361: bottom plate
362: inner circumferential wall
363: circular plate shape
364: outer circumferential wall
365: Longevity
366: small diameter concave
367: large diameter concave
371: tube part (tube part for shaft press-in)
371a: tapered surface
371b: bottom surface
371c: inner circumference
372: collar part
372a: outer edge
373: circular shape stopper
373a: bottom surface
373b: through hole
373c: inner circumference
D: Drain
L: axis direction

Claims (16)

As a drain pump which has a pump part provided with a pump chamber and a vane, and a motor part provided with the motor shaft connected coaxially to the said vane, The said pump part is used in the state located under the said motor part,
The vane passes through a through hole formed in a vane main body disposed in the pump chamber and a pump chamber housing extending coaxially from the vane main body and partitioning the pump chamber. Has a shaft portion projecting outward of the pump chamber,
The shaft portion is provided with a motor shaft press-in recess which extends downward on the coaxial shaft from an upper end surface of the shaft portion.
A drain pump having a shape that extends outward from an outer circumferential surface of the shaft end is attached to the shaft end. The method of claim 1,
The said water-receiving member is being fixed to the said shaft end, The drain pump characterized by the above-mentioned. The method of claim 2,
The said cutting member is press-fitted to the said shaft end part, The said cutting member is equipped with the shaft part press-fitting cylinder part in which the shaft end part was press-fitted, The drain pump characterized by the above-mentioned. The method of claim 3, wherein
The said water-receiving member is equipped with the collar part which spreads outward from the outer peripheral surface of the said shaft part press-fitting cylinder part, and the outer peripheral edge of the said collar part is located in the radial direction outer side rather than the said through-hole, The drain pump characterized by the above-mentioned. The method of claim 4, wherein
The pump chamber housing includes a ring-shaped bottom plate including the through hole, an inner circumferential wall extending upward from an outer circumferential edge of the bottom plate, and a circle extending radially outward from an upper edge of the inner circumferential wall. An annular plate portion and an outer circumferential wall extending upwardly from an outer circumferential edge of the annular plate portion, and a long hole extending in the circumferential direction at an equiangular interval at a lower end portion of the outer circumferential wall. Formed,
The collar portion, the drain pump is formed above the lower end of the long hole. The method of claim 5, wherein
The cutting member protrudes inward from the inner circumferential surface of the shaft press-fitting cylinder, and when the shaft end is pushed into the shaft press-fitting cylinder, the stopper contacts the positioning part of the shaft to determine the position of the cutting member. Drain pump, characterized in that provided. The method according to claim 6,
And said positioning portion of said shaft portion is an upper end surface of said shaft portion. The method according to claim 6,
The stopper has a shaft hole through which the motor shaft is inserted in a central portion thereof,
A drain pump is formed between the motor shaft and the stopper so that a capillary force does not act. The method of claim 8,
The gap is a drain pump, characterized in that formed above the lower end of the long hole. The method of claim 2,
The motor shaft press-fit recessed portion includes a large diameter portion that is larger in diameter than the motor shaft, and a small diameter portion that is smaller in diameter than the large diameter portion and is pressed in from the end face side of the shaft portion. Drain pump characterized in that. The method of claim 1,
A positioning portion is formed on the outer circumferential side of the shaft end portion,
The said water-receiving member is being fixed to the said positioning part, The drain pump characterized by the above-mentioned. The method of claim 11,
The shaft end portion extends upwardly from the water harvesting member. The method of claim 12,
The positioning portion is a circular stepped portion,
The said water-receiving member is a circular plate of fixed thickness, The inner peripheral part of the said circular plate is fixed to the said circular-shaped step part, The drain pump characterized by the above-mentioned. The method of claim 13,
The cutting member is press-fitted to the shaft end, and the shaft member is press-fitted to the cutting member, and the cutting member includes a shaft part press-fitting tube in which the shaft end is press-fitted.
The cutting member protrudes inward from the inner circumferential surface of the shaft press-fitting cylinder, and when the shaft end is pushed into the shaft press-fitting cylinder, the stopper contacts the positioning part of the shaft to determine the position of the cutting member. Drain pump, characterized in that provided. The method of claim 11,
The pump chamber housing includes a ring-shaped bottom plate including the through hole, an inner circumferential wall extending upward from an outer circumferential edge of the bottom plate, and a circle extending radially outward from an upper edge of the inner circumferential wall. An annular plate portion and an outer circumferential wall extending upwardly from an outer circumferential edge of the annular plate portion, and a long hole extending in the circumferential direction at equal angle intervals is formed in the lower end portion of the outer circumferential wall,
The cutting member has a collar portion that is wider from the positioning portion to the outside and whose outer circumferential edge is located outside the through hole in the radial direction.
The collar part is formed above the lower end of the said long hole, The drain pump characterized by the above-mentioned. The method of claim 12,
The positioning portion is an annular groove extending in the circumferential direction of the shaft end,
The cutting member is a circular plate of a constant thickness,
An inner circumferential portion of the annular plate is fixed by being fitted into the annular groove.

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