KR20200006996A - Drain pump - Google Patents

Abstract

The present invention provides a drain pump that can prevent water from entering the motor even when the drain pump is downsized. To this end, the drain pump of the present invention includes a motor including a rotor and a stator, a motor lower cover covering at least a portion of a lower part of the motor, a rotary blade member connected to the rotor so as to transmit power, and a rotary blade member. A pump housing having a pump chamber is provided. A through hole is provided in the upper wall of the pump housing. The motor lower cover also has a waterproof wall portion disposed between the motor and the upper wall of the pump housing.

Description

Drain pump

The present invention relates to a drain pump, and more particularly, to a technique for preventing water from entering the motor.

For example, in a drain pump which is assembled to an air conditioning indoor unit and used to drain drain water generated in an evaporator outdoors during cooling or dehumidification, the discharge port of the drain water when stopped from the state of the driving drain of the drain pump. The drain water condensed in the riser or the like flows back toward the pump chamber of the drain pump (that is, the space in which the rotary blade for drainage is accommodated). By this reverse flow, drain water is taken out to the motor side for driving the rotary blades and attached to the motor from the gap between the rotary shaft of the rotary blade and the through hole formed in the ceiling of the pump chamber for inserting the rotary shaft, and affects the durability of the motor and the like. There is a concern.

As a related technique, Patent Document 1 discloses a motor for a drain pump. In the motor for a drain pump described in patent document 1, the flange part which prevents the intrusion of water into a magnet rotor is provided below the magnet rotor.

Patent Document 1: Japanese Patent Application Laid-Open No. 2014-107893

In recent years, miniaturization and high performance of an air conditioning indoor unit are aimed at, and accordingly, the miniaturization and high performance of a drain pump are calculated | required.

In order to reduce the size of the drain pump (especially in the direction of the rotation axis of the rotary blade), it is necessary to shorten the distance from the pump chamber to the drive motor, and to achieve high performance (high efficiency), It may be necessary to increase the drainage capacity of the drain water.

Therefore, it is an object of the present invention to provide a drain pump that can prevent water from entering the motor even when the drain pump is downsized.

In order to achieve the above object, the drain pump according to the present invention includes a motor having a rotor and a stator, a motor lower cover covering at least a portion of a lower portion of the motor, and a rotary wing member connected to the rotor so as to transmit power. And a pump housing having a pump chamber for accommodating the rotary wing member. A through hole is provided in an upper wall of the pump housing. In addition, the motor lower cover has a waterproof wall portion disposed between the motor and the upper wall of the pump housing.

In the drain pump, the waterproof wall portion may be an inward flange portion that projects from the side wall of the motor lower cover in an inward direction.

In the said drainage pump, the said rotor may be provided with the rotor shade which prevents water from invading into the clearance gap between the said rotor and the said stator. In addition, a labyrinth passage may be formed by the rotor shade and the waterproof wall portion.

In the drain pump, the rotor shade may be disposed to face at least a portion of the lower surface of the stator.

In the drain pump, a space may be provided between the motor lower cover and the upper wall of the pump housing. In addition, the space may be opened without being covered by the wall.

In the said drain pump, the said motor lower cover may be provided with the 1st engagement part, and the said pump housing may be equipped with the 2nd engagement part. The motor lower cover and the pump housing may be detachably connected to each other via the first engaging portion and the second engaging portion.

In the drain pump, the rotary blade member may include a plurality of plate members including an upper plate and a lower plate, a large diameter wing disposed between the upper plate and the lower plate, and a small diameter wing disposed below the lower plate. A side opening may be formed between the upper plate and the lower plate. The upper plate may have a first hole through which the fluid can pass, and the lower plate may include a second hole through which the fluid can pass.

In the said drainage pump, the said some board member may be provided with the middle plate arrange | positioned between the said upper board and the said lower board. The middle plate may have a third hole through which the fluid can pass.

In the drain pump, the upper surfaces of the plurality of plate members may be inclined surfaces.

Even if the drainage pump is downsized by the present invention, it is possible to provide a drainage pump capable of preventing water from entering the motor.

BRIEF DESCRIPTION OF THE DRAWINGS The schematic diagram for demonstrating return water.
2 is a schematic diagram for explaining the through hole.
3 is a cross-sectional view schematically showing a drain pump in the embodiment;
4 is a schematic perspective view of a drain pump in the embodiment;
5 is a cross-sectional view schematically showing a drain pump in the embodiment.
6A is a schematic plan view illustrating an example of a rotary blade member of a drain pump in the embodiment.
6B is a schematic side view illustrating an example of the rotary blade member of the drain pump in the embodiment.
7 is a schematic perspective view showing a first modification of the rotary blade member of the drain pump in the embodiment;
FIG. 8 is a schematic two side view showing a plan view and a front view of a rotary wing member of a first modification. FIG.
9 is a bottom view of the rotary blade member of the first modification.
Fig. 10 is a schematic diagram showing Yang Xi where water moves over a large-sized wing.
11 is a front view of the rotary blade member of the first modification, and a schematic diagram for explaining the gas-liquid boundary surface.
12 is a cross-sectional view taken along the line AA in FIG. 8.
FIG. 13 is a cross-sectional view taken along the line BB of FIG. 8. FIG.
14 is a cross-sectional view taken along the line CC arrow of FIG. 8.
FIG. 15 is a schematic perspective view illustrating a second modification example of the rotary blade member of the drain pump in the embodiment. FIG.
Fig. 16 is a schematic two side view showing a plan view and a front view of a rotary wing member of a second modification.
17 is a cross-sectional view taken along the line DD of FIG. 16.
18 is a cross-sectional view taken along the line EE of FIG. 16.

EMBODIMENT OF THE INVENTION Hereinafter, the drainage pump in embodiment is demonstrated with reference to drawings. In addition, in description of the following embodiment, the same code | symbol is attached | subjected about the site | part and member which have the same function, and the description which repeats about the site | part and the same code | symbol which were attached | subjected is abbreviate | omitted.

(About bounce)

With reference to FIG. 1, the return number is demonstrated. 1 is a schematic diagram for explaining the return number.

In the example of FIG. 1, the drain pump 1 is connected to the drain hose 101. The drain pump 1 sucks in water from the suction port 68 and discharges water from the discharge port 69. Since water is discharged from the discharge port 69 at the time of the operation of the drain pump, the drain hose 101 is filled with water. In this state, it is assumed to stop the drain pump. In this case, the water in the drain hose 101 flows back toward the drain pump 1 by gravity. As a result, water flows into the pump chamber from the discharge port 69. What is water which flows into the pump chamber from the discharge port 69 is called "return water" in this specification.

(About the through hole)

Next, the through hole 61 will be described with reference to FIG. 2. 2 is a schematic diagram for explaining the through hole 61.

The through-hole 61 is a hole which communicates the pump chamber PS and the space SP above the pump chamber PS. A shaft 7 (for example, an output shaft of a motor) for rotating the rotary blade member 5 is inserted into the through hole 61. When the drain pump 1 starts, water enters the pump chamber PS. When water enters the pump chamber, air existing in the pump chamber passes through the through-hole 61 and is extruded into the space SP (see arrow A). 2, reference numeral BS denotes an interface between water and air.

In the state shown in FIG. 2, when the drain pump 1 stops, water filled in the drain hose flows into the pump chamber from the discharge port 69 as return water. Part of the return water flowing into the pump chamber is discharged from the suction port 68, and another part of the return water flows out into the space SP through the through hole 61. In the waste water pump 1 in the embodiment, intrusion of water flowing out into the space SP into the motor is suppressed. Details will be described later.

(Summary of embodiment)

With reference to FIG. 3, the outline | summary of the drain pump 1 in embodiment is demonstrated. FIG. 3: is sectional drawing which shows typically the drain pump 1 in embodiment.

The drain pump 1 according to the embodiment includes a motor 2 including a rotor 20 and a stator 30, a motor lower cover 4, a rotary wing member 5, and a rotary wing member. The pump housing 6 provided with the pump chamber PS which accommodates (5) is provided.

The motor 2 is a drive source for rotating the rotary blade member 5. The rotor 20 is rotated by the electromagnetic action between the coil and the rotor 20 by supplying current to the coil of the stator 30. Since the rotor 20 and the rotary blade member 5 are connected so that power can be transmitted, when the rotor 20 rotates, the rotary blade member 5 rotates around the rotation axis X. As shown in FIG.

The motor lower cover 4 covers at least a part of the lower portion 2a of the motor 2. In the example described in FIG. 3, the motor lower cover 4 includes a side wall 41 and a bottom wall functioning as the waterproof wall portion 42. However, the shape of the motor lower cover 4 is not limited to the example described in FIG. 3.

The rotary blade member 5 is connected to the rotor 20 so that power can be transmitted, and is disposed in the pump chamber PS. The rotary blade member 5 sucks water into the pump chamber PS through the suction port 68 by rotating the rotary blade member 5 around the rotary shaft X, and discharges the water sucked into the pump chamber. Through the pump chamber (PS).

The through hole 61 is provided in the upper wall 63 of the pump housing 6. When the drain pump 1 is stopped, part of the return water is discharged to the space SP through the through hole 61. In addition, in the example of FIG. 3, the shaft 7 is inserted through the through-hole 61. As shown in FIG. The shaft 7 arranged to cross the through hole 61 may be an output shaft of the motor 2 or may be a shaft member constituting a part of the rotary wing member 5, and an output shaft and rotation of the motor 2. The shaft may be separate from the shaft member of the wing member 5.

In the embodiment, the motor lower cover 4 includes a waterproof wall portion 42 disposed between the motor 2 and the upper wall 63. For this reason, the water discharged | emitted from the through-hole 61 to space SP is prevented from invading in the motor 2 (for example, the clearance gap between the rotor 20 and the stator 30). In addition, the motor lower cover 4 is not a member that rotates together with the rotor 20 as a stop member.

In addition, in the embodiment, since the waterproof wall portion 42 is provided, even if the height h of the space SP is small, that is, even when the drainage pump is downsized, water is effectively prevented from entering the motor 2. do.

The waterproof wall part 42 in embodiment may be an inward flange part which protrudes from the side wall 41 of the motor lower cover 4 in an inward direction. The inward flange portion has a ring shape in which the connecting portion with the side wall 41 is made an outer edge. When the motor lower cover 4 has an inward flange portion projecting from the side wall 41 and the side wall 41 in the inward direction, at least a part of the side portion of the motor 2 is covered by the side wall 41. At least a portion of the bottom of (2) is covered by the inward flange portion. For this reason, the waterproofness of the motor 2 improves. In addition, in the example described in FIG. 3, the side wall 41 and the inward flange portion are one member integrally molded. In addition, in this specification, an inward direction means the direction toward the rotation axis X (more specifically, the radial direction toward the rotation axis X).

The upper surface 42a of the waterproof wall portion 42 may be an inclined surface whose height is lowered toward the inward direction. Since the upper surface 42a is an inclined surface, even if water penetrates above the waterproof wall portion 42, the intruded water is quickly discharged through the through hole 42b defined by the internal combustion of the inward flange portion. do.

The rotor 20 in embodiment may be provided with the rotor shade 21 which prevents water from invading into the clearance gap G between the rotor 20 and the stator 30. When the rotor 20 includes the rotor shade 21, a labyrinth passage PA is formed between the rotor shade 21 and the waterproof wall portion 42. For this reason, intrusion of water into the motor 2 (for example, the clearance between the rotor 20 and the stator 30) is suppressed more effectively.

The above-mentioned rotor shade 21 may be arrange | positioned so that it may face at least one part of the lower surface 30a of the stator 30. As shown in FIG. When the lower surface 30a of the rotor shade 21 and the stator 30 are disposed to face each other, the passage PA3 between the rotor shade 21 and the lower surface 30a of the stator 30 is the labyrinth passage PA. Function as part of In this case, intrusion of water into the motor 2 (for example, the gap between the rotor 20 and the stator 30) is more effectively suppressed. 3, the labyrinth passage PA includes the passage PA1 between the lower surface of the rotor shade 21 and the upper surface of the waterproof wall portion 42, the outer circumferential surface of the rotor shade 21, and the side wall 41. Passage PA2 between the inner circumferential surface of the circumferential surface) and the passage PA3 between the upper surface of the rotor shade 21 and the lower surface of the stator 30.

As shown in FIG. 3, a space SP is provided between the motor lower cover 4 and the upper wall 63 of the pump housing 6. In the embodiment, the space SP may be opened without being covered by the wall. In this specification, it means that the space SP "the space is open without being covered by the wall" is not substantially enclosed by the wall. In the example of FIG. 3, the waterproof wall part 42 exists above the space SP, and the upper wall 63 exists below the space SP, but the side wall surrounding the space SP does not exist. not. For this reason, even if the amount of water discharged from the through hole 61 into the space SP is large, water does not accumulate in the space SP. In other words, the water discharged into the space SP passes through the periphery of the pump housing 6 (the space outside the pump housing 6) and quickly falls below the pump housing 6. For this reason, even if the amount of water discharged from the through hole 61 into the space SP is large and the height of the space SP is low, the motor 2 is not submerged. The water which falls below the pump housing 6 is taken in by the drain pan which is not shown, for example, and is sucked in again through the suction port 68 at the time of next drive of the drain pump 1.

(More detailed description of embodiment)

With reference to FIGS. 4-18, each structure of the drain pump 1 in embodiment is demonstrated in detail. 4 is a schematic perspective view of the drain pump 1 in the embodiment. FIG. 5: is sectional drawing which shows typically the drain pump 1 in embodiment. FIG. 6: A is a top view which shows an example of the rotary blade member 5 of the drain pump in embodiment. 6B is a side view illustrating an example of the rotary blade member 5 of the drain pump in the embodiment. FIG. 7: is a schematic perspective view which shows the 1st modified example of the rotary blade member 5A of the drain pump 1 in embodiment. 8 is a schematic two-sided view showing a plan view and a front view of the rotary blade member 5A of the first modification. 9 is a bottom view of the rotary blade member 5A of the first modification. FIG. 10: is a schematic diagram which shows the Yangshuo in which water moves over the large diameter wing 54a. FIG. 11: is a front view of 5 A of rotary blade members of a 1st modification, and is a schematic diagram for demonstrating gas-liquid interface DS. 12 is a cross-sectional view taken along the arrow A-A of FIG. 8. FIG. 13 is a cross-sectional view taken along the line B-B in FIG. 8. 14 is a cross-sectional view taken along the line C-C of FIG. FIG. 15 is a schematic perspective view showing a second modification example of the rotary blade member 5B of the drain pump 1 in the embodiment. FIG. 16 is a schematic two side view showing a plan view and a front view of the rotary blade member 5B of the second modification. 17 is a cross-sectional view taken along the line D-D of FIG. 16. 18 is a cross-sectional view taken along the line E-E of FIG. 16.

(Structure connecting the motor lower cover 4 and the pump housing 6)

An example of the structure which connects the motor lower cover 4 and the pump housing 6 is demonstrated. In the example shown in FIG. 4, the motor lower cover 4 includes a first engagement portion 44, and the pump housing 6 includes a second engagement portion 64. The motor lower cover 4 and the pump housing 6 are detachably connected to each other via the first engaging portion 44 and the second engaging portion 64. For this reason, the first engagement portion 44 and the second engagement portion 64 may be engaged with each other in assembling the drain pump 1. In addition, when disassembling (for example, performing inspection, repair, etc.) of the drain pump 1, the engagement of the 1st engagement part 44 and the 2nd engagement part 64 may be cancelled | released. In addition, the motor lower cover 4 supports a load (gravity or the like) acting on the pump housing 6 through the first engaging portion 44 and the second engaging portion 64.

As described above, in the example described in FIG. 4, the first engagement portion 44 and the second engagement portion 64 have a function of detachably connecting the motor lower cover 4 and the pump housing 6, and the pump housing 6. Has a function of supporting at least a portion of the load acting on). In the example described in FIG. 4, two engagement mechanisms F constituted by the first engagement portion 44 and the second engagement portion 64 are provided, and the first engagement mechanism F1 and the second engagement mechanism are provided. (F2) is arrange | positioned facing the longitudinal center axis of the drainage pump. In general, the number of the engagement mechanisms F may be three or more. When the number of the engagement mechanisms F is N (N is a natural number of two or more), it is preferable that the engagement mechanisms F are provided at equal intervals around the longitudinal central axis of the drainage pump every 360 / N degrees. . However, in embodiment, it is not limited that the engagement mechanism F was provided at equal intervals.

In addition, the engagement mechanism F is located outside the space SP between the motor lower cover 4 and the upper wall of the pump housing 6. For this reason, although the engagement mechanism F will prevent the discharge of the water from space SP, the engagement mechanism F will not cover most of space SP (it does not substantially cover space SP). ). For this reason, even in the example described in FIG. 4, it can be said that the space SP is open without being covered by the wall.

The engagement between the first engagement portion 44 and the second engagement portion 64 may be a snap fit engagement. In this case, the engagement between the two engagement portions is performed by using the elasticity of the first engagement portion 44 and / or the second engagement portion. In this case, the engagement work between the first engagement portion 44 and the second engagement portion 64 can be executed quickly and easily. In addition, in the example of FIG. 4, the material of the motor lower cover 4 is resin, the material of the 1st engagement part 44 is resin, the material of the pump housing 6 is resin, and the 2nd engagement part 64 is carried out. ) Is made of resin.

(Upper motor cover (8))

In the example described in FIG. 4, the drain pump 1 has a motor top cover 8 that covers at least a portion of the top of the motor 2. In the example described in FIG. 4, the motor upper cover 8 includes a fourth engagement portion 86, and the motor lower cover 4 includes a third engagement portion 46 that can be attached to and detached from the fourth engagement portion 86. do. It is preferable that the number of the engagement mechanisms H comprised by the 3rd engagement part 46 and the 4th engagement part 86 is two or more. When the number of the engagement mechanisms H is N (N is a natural number of two or more), the engagement mechanisms H are provided at equal intervals around the longitudinal center axis of the drainage pump every 360 / N degrees. desirable. However, in embodiment, the engagement mechanism H is not limited to being provided at equal intervals.

In the example described in FIG. 4, the motor upper cover 8 functions as a motor support member. In other words, the load (gravity or the like) acting on the motor 2 is substantially supported by the motor top cover 8. The motor upper cover 8 is provided with the attachment bracket 81 in the upper part. Moreover, the terminal T protrudes from the opening part provided in the motor top cover 8. As shown in FIG. In the terminal T, a lead wire W for feeding power to the coil of the stator is disposed.

(Structure of the Motor 2)

Next, an example of the structure of the motor 2 is demonstrated with reference to FIG. The motor 2 includes a rotor 20 and a stator 30.

The stator 30 is fixed to the motor upper cover 8. In the example described in FIG. 5, the stator 30 includes a coil 32, a core member 33, and a shaft member 34. When a current flows in the coil 32, the core member 33 is magnetized and functions as a magnet. In addition, the shaft member 34 functions as a member defining the center of rotation of the rotor 20.

The rotor 20 includes a magnet 23, a cylindrical portion 25, and an output shaft 27. The rotor 20 may be provided with the rotor shade 21 mentioned above.

The magnet 23 rotates around the rotational axis X by electromagnetic action with the coil 32. Since the magnet 23 is fixed to the cylindrical part 25, when the magnet 23 rotates, the whole rotor 20 will rotate around the rotation axis X. As shown in FIG.

The inner surface of the cylindrical portion 25 and the outer surface of the shaft member 34 are disposed to face each other via the bearing 24. In the example described in FIG. 5, the motor 2 includes an upper bearing 24a and a lower bearing 24b. When the motor 2 includes the upper bearing 24a and the lower bearing 24b, the rotation axis X of the rotor 20 and the central axis of the shaft member 34 coincide with each other, and the rotation shaft of the rotor 20 is matched. Position shift of (X) is suppressed.

Since the magnet 23 and the core member 33 of the stator 30 are engaged by each other, the vertical position of the rotor 20 including the magnet 23 is positioned by the magnetic force. In the operation of the drainage pump 1 by the positioning, a gap is formed between the rotor 20 and the waterproof wall 42, and the rotor 20 and the waterproof wall 42 are kept in a non-contact state. For this reason, even if a part of the rotor 20 is covered by the waterproof wall portion 42, the rotor 20 is smoothly rotated. In addition, the height h1 of the clearance gap between the rotor 20 and the waterproof wall part 42 at the time of the operation of the drain pump 1 is 0.1 mm or more and 2 cm or less, for example.

In addition, at the time of operation of the drain pump 1, the rotor 20 (for example, the rotor shade 21) and the lower surface 30a of the stator 30 are maintained in a non-contact state. For this reason, the rotor 20 rotates smoothly.

The output shaft 27 is connected to the lower part of the cylindrical part 25. In the example of FIG. 5, the output shaft 27 and the cylindrical part 25 are one member integrally molded. In the example shown in FIG. 5, the output shaft 27 is directly connected (for example, press-fitted) to the shaft member 52 (hollow shaft member) of the rotary blade member 5, and the output shaft 27 and shaft The shaft 7 is comprised by the member 52. In general, the output shaft 27 and the shaft member 52 may be indirectly connected through another member. In addition, in the example of FIG. 5, the rotary blade member 5 has the shaft member 52, the large diameter blade part 54, and the small diameter blade part 56 connected directly or indirectly to the output shaft 27 of a motor. Equipped. The whole large diameter wing part 54 is arrange | positioned in the pump chamber PS, the part of the small diameter wing part 56 is arrange | positioned in the pump chamber PS, and the other part of the small diameter wing part 56 is in the inlet port 68. As shown in FIG. It is arranged.

(Rotary wing member 5)

6A and 6B, an example of the rotary blade member 5 is demonstrated. In the example described in FIG. 6A, the large-diameter wing 54 includes a plurality of large-diameter wings 54a, a plurality of auxiliary large-diameter wings 54b, a dish portion 54c, and a ring portion 54d. The inner edge of the large-diameter blade 54a is connected to the shaft member 52. On the other hand, the inner edge of the auxiliary large diameter blade 54b is spaced apart from the shaft member 52. In addition, the auxiliary large diameter blade 54b may be abbreviate | omitted.

The through hole 540c is provided in the center of the dish part 54c, and the water sucked from the suction port 68 passes through the through hole 540c, and can flow into the space on the dish part 54c. The large diameter blade 54a and the auxiliary large diameter blade 54b are arrange | positioned at the upper surface of the dish part 54c. The ring portion 54d is connected to the dish portion 54c so as to surround the large-diameter blade 54a and the auxiliary large-diameter blade 54b. In addition, the ring portion 54d may be omitted.

Referring to FIG. 6B, a plurality of small-diameter wings 56a are disposed below the plate portion 54c.

The water imparted with the centrifugal force by the rotation of the rotary blade member 5 is discharged out of the pump chamber PS through the discharge port 69.

(First modification of rotating blade member)

7-11, the rotating blade member 5A for drainage pumps in a 1st modification is demonstrated.

The rotary blade member 5A for pumps in the first modification includes a plurality of plate members 58, a large diameter blade 55, and a small diameter blade 57.

In the example of FIG. 7, the some board member 58 includes the upper board 58a and the lower board 58b, and each external shape is circular. The upper plate 58a covers at least a part of the upper end of the large-diameter wing 55.

While referring to the rotary blade member 5 (an example in the case where the rotary blade member 5 for the drainage pump does not have an upper plate) shown in Figs. 6A and 6B, the rotary blade member 5A for the drainage pump The effect of the case where the upper board 58a is provided (for example, the example of FIG. 7) is demonstrated. In the example described in FIGS. 6A and 6B, the water moves over the large-diameter wing 54a (also, the Yangshuo in which the water over the large-diameter wing 54a is shown in FIG. 10). When the water moves over the large blade 54a, the water is mixed with the air, and many bubbles are drawn into the water. When water containing many bubbles collides with the wall surface of the drain pump, noise is generated. In contrast, the rotary blade member 5A for the drain pump in the example described in FIG. 7 includes an upper plate 58a. For this reason, the water does not move over the large diameter blade 55. Alternatively, less water moves over the large-diameter wing 55 (more specifically, the exposed portion 55c to be described later). In this way, mixing of water and air is suppressed and the quantity of bubbles contained in water is reduced. As a result, noise generated due to water colliding with the wall surface of the drain pump 1 or the like is reduced.

Referring to FIG. 7, the large diameter wing 55 is disposed between the upper plate 58a and the lower plate 58b. Moreover, the outer edge 551 of the blade | wing (large blade | wing 55) which is between the upper board 58a and the lower plate 58b is larger than the outer edge 571 of the blade | wing (small diameter blade 57) below lower board 58b. And a position far from the rotational center axis AX of the rotary blade member 5A for the drain pump. Therefore, the wings between the upper plate 58a and the lower plate 58b can be said to be "large blades", and the wings below the lower plate 58b can be said to be "small blades".

The rotary blade member 5A includes the side opening OP while referring to the rotary blade member 5 described in FIG. 6A (an example in which the entire outer edge of the large-diameter blade 54a is surrounded by the ring portion 54d). The effect of the case (for example, the example of FIG. 7) is demonstrated. In the example described in Fig. 6A, when the large-diameter blade 54a rotates around the central axis of rotation, centrifugal force is applied to the water that collides with the large-diameter blade 54a. The water imparted with the centrifugal force collides with the inner surface of the ring portion 54d and the momentum of the water decreases. As a result of the decrease in the momentum of the water, the lifting ability of the water of the rotary blade member 5 is lowered. On the other hand, in 5 A of rotary blade members in the example of FIG. 7, the side opening OP is formed between the upper board 58a and the lower board 58b. For this reason, the water given the centrifugal force is discharged from the rotary blade member 5A through the side opening OP while maintaining the momentum. For this reason, 5 A of rotary blade members in the example of FIG. 7 have a high ability of attracting water compared with the rotary blade member 5 of the example of FIG. 6A.

The small-diameter wing 57 is disposed below the lower plate 58b. The small-winged blade 57 pulls upwards water, such as the drain water which contacted the small-winged blade 57, by rotating the small-winged blade 57 about the rotation center axis AX.

As shown in FIG. 8, the upper plate 58a has a circular first hole 50a through which liquid such as drain water and gas such as air (ie, fluid) can pass. In the example of FIG. 8, the 1st hole 50a is formed in the center part of the upper board 58a. In addition, the center of the upper plate 58a and the first hole 50a are on the center of rotation axis AX.

As shown in FIG. 9, the lower plate 58b includes a second hole 50b through which liquid such as drain water and gas such as air can pass. In the example of FIG. 9, the 2nd hole 50b is formed in the center part of the lower board 58b. In addition, the center of the lower plate 58b and the center of the second hole 50b are on the center of rotation axis AX.

An effect of the upper plate 58a having the first hole 50a and the lower plate 58b having the second hole 50b will be described. Referring to FIG. 11, when the rotary blade member 5A rotates around the rotary center axis AX, centrifugal force is applied to the water collided with the rotary blade member 5A. As a result, the gas-liquid interface DS is formed in the pump chamber of the drain pump 1. Liquid (water) exists outside the gas-liquid interface DS, and gas (air) exists inside the gas-liquid interface DS.

When the upper plate 58a includes the first hole 50a and the lower plate 58b includes the second hole 50b, the gas-liquid boundary surface DS starts from the region AR1 below the lower plate 58b. It is formed over the area | region AR2 above lower plate 58b, and area | region AR3 above upper plate 58a. For this reason, the ability to pull up water by the rotary blade member 5A is high. On the other hand, when the first hole 50a through which liquid can pass is not provided in the upper plate 58a, since gas does not enter under the upper plate 58a, the ability of attracting water by the rotary blade member 5A is obtained. Is lowered. In addition, when the 2nd hole 50b which a liquid can pass through is not provided in the lower board 58b, since gas does not enter below the lower board 58b, the water by the small diameter wing 57 is pulled up (sucked up). ) Ability is reduced.

As described above, the rotary blade member 5A in the first modification includes an upper plate 58a covering at least a part of the upper end of the large-diameter blade 55. For this reason, mixing of water and air is suppressed and generation | occurrence | production of a noise is suppressed. In addition, the rotary blade member 5A in the first modification includes a side opening OP between the upper plate 58a and the lower plate 58b. Then, in the state where the momentum of water is maintained, the water passes through the side opening OP and is discharged to the outside of the rotary blade member 5A. For this reason, the water pulling capability of the rotary blade member 5A is high. In addition, in a 1st modification, the upper board 58a is equipped with the 1st hole 50a, and the lower board 58b is equipped with the 2nd hole 50b. For this reason, the gas-liquid interface DS is extensively formed.

As a result, the ability to pull water of the rotary blade member 5A is high.

In the rotary wing member 5A in the first modification, the upper plate 58a, the lower plate 58b, the large-diameter wings 55 disposed between the upper plate 58a and the lower plate 58b, and the lower plate 58b are formed. The small-diameter wing 57 disposed below, the first hole 50a provided in the upper plate 58a, and the second hole 50b provided in the lower plate 58b are combined to reduce noise and raise water. Two effects are synergistic: improvement of ability. In addition, the ability to attract water is synergistically improved by maintaining the momentum of the water and by the extensive formation of the gas-liquid interface DS.

(More detailed description of the first modification)

With reference to FIGS. 7-9 and 12-14, the rotating blade member 5A in a 1st modification is demonstrated in detail. FIG. 12 is a cross-sectional view of the arrow A-A of FIG. 8, FIG. 13 is a cross-sectional view of the arrow B-B of FIG. 8, and FIG. 14 is a cross-sectional view of the C-C arrow of FIG. 8.

In the example of FIG. 8, the upper board 58a has ring shape (annular annular shape of the same width which has a circular hole in the center). The upper plate 58a suppresses and prevents the drain water sucked up at the time of rotation of the rotary blade member 5A from above the large diameter blade 55. As a result, it becomes difficult to mix bubbles with the discharged drain water, and the noise at the time of driving the drain pump 1 can be reduced.

In addition, in the example of FIG. 9, the lower board 58b has ring shape. The lower plate 58b suppresses and prevents the drain water sucked up during the rotation of the rotary blade member 5A from passing below the large-diameter blade 55. As a result, it becomes difficult for air bubbles to mix with the discharged drain water, the noise at the time of driving the said drain pump 1 can be reduced, and the drainage efficiency of drain water improves.

In the example of FIG. 8, the upper surface 582a of the upper plate 58a is an inclined surface. When the upper surface 582a of the upper plate 58a is a horizontal plane, water stops at the upper surface 582a of the upper plate 58a when the rotary blade member 5A is stopped. In this case, there is a possibility that the solid component precipitates due to evaporation or the like of water remaining on the top surface 582a of the top plate 58a, and the precipitated solid component may be deposited on the top surface 582a of the top plate 58a. On the other hand, when the upper surface 582a of the upper plate 58a is an inclined surface, it is difficult for water to stay on the upper surface 582a of the upper plate 58a when the rotary blade member 5A is stopped. For this reason, a solid component hardly deposits on the upper surface 582a of the upper plate 58a.

In addition, it is preferable that the upper surface 582a of the upper plate 58a is an inclined surface in which the position in the vertical direction gradually decreases from the inner edge 583a of the upper plate to the outer edge 584a of the upper plate. However, the upper surface 582a of the upper plate 58a may be an inclined surface in which the position in the vertical direction gradually rises from the inner edge 583a of the upper plate to the outer edge 584a of the upper plate. In addition, in this specification, "an upper surface is an inclined surface" means that at least 50% or more of the area of an upper surface is an inclined surface. Therefore, a part (less than 50% of area) of an upper surface may be a horizontal surface.

Similarly, in the example of FIG. 8, the upper surface 582b of the lower board 58b is an inclined surface. When the upper surface 582b of the lower plate 58b is an inclined surface, it is difficult for water to stay on the upper surface 582b of the lower plate 58b when the rotary blade member 5A is stopped. For this reason, a solid component is hard to deposit on the upper surface 582b of the lower board 58b.

In addition, it is preferable that the upper surface 582b of the lower board 58b is an inclined surface in which the position in the vertical direction gradually descends from the inner edge 583b of the lower board to the outer edge 584b of the lower board. However, the upper surface 582b of the lower plate 58b may be an inclined surface in which the position in the vertical direction gradually rises from the inner edge 583b of the lower plate to the outer edge 584b of the lower plate.

In the example shown in FIG. 8, the upper end 550a of the large diameter blade 55 is connected to the lower surface of the upper plate 58a, and the lower end 550b of the large diameter wing 55 is connected to the upper surface of the lower plate 58b. Therefore, the strength of the structure constituted by the upper plate 58a, the large diameter wing 55, and the lower plate 58b is high. In addition, since the structural strength of the structure is high, the upper plate 58a, the large-diameter wings 55, and the lower plate 58b can be thinned.

In the example shown in FIG. 8 and FIG. 9, the outer edge 571 of the small diameter blade 57 is bottom view, and is arrange | positioned inside the inner edge 583b of the lower board 58b. For this reason, most of the water lifted toward the inclined upper side (upward and in the outward direction) by the small-diameter wing 57 smoothly in the space above the lower plate 58b through the second hole 50b. You are guided.

In the example of FIG. 8 and FIG. 9, the number of the large diameter blades 55 is four, and the large diameter blades 55 are arrange | positioned at intervals of 90 degrees around the rotation center axis AX. Moreover, the number of the small diameter blades 57 is four, and the small diameter blades 57 are arrange | positioned at intervals of 90 degrees around the rotation center axis AX. However, each of the number of large-diameter wings 55 and the number of small-diameter wings 57 is not limited to four, but is arbitrary. In addition, in the example shown in FIG. 8, although the inner edge 553 of all the large diameter blades 55 is directly connected to the shaft member 52, the inner edge 553 and the shaft member 52 of the at least one large diameter blade 55 are carried out. ) Does not have to be directly connected. Further, when the number of the large-diameter wings 55 is N (N is a natural number of 2 or more), the number of side openings OP formed between the upper plate 58a and the lower plate 58b is N. The side opening OP is an opening defined by the upper plate 58a, the lower plate 58b, and the two large-diameter wings 55.

Referring to Fig. 12 (A-A arrow sectional view in Fig. 8), the distance L1 between the center of rotation axis AX and the outer edge 551 of the large-diameter wing 55 is, for example, 10 mm or more and 20 mm or less. Since the rotary blade member 5A in the first modification has high water pulling capability, the rotary blade member 5A can be made small in size as compared with the rotary blade member 5 described in FIG. 6A. The distance L2 between the upper surface 582a of the upper plate and the lower surface 585b of the lower plate is, for example, 5 mm or more and 15 mm or less.

In the example described in FIGS. 12 and 13 (BB arrow cross-sectional view in FIG. 2), the outer edge 551 of the large-diameter wing 55 and the outer edge 571 of the small-diameter wing 57 have a lower end 550b of the large-diameter wing 55. Connected via In other words, one plate is comprised by one large-diameter wing 55 and one small-diameter wing 57, and there is a stepped portion between the large-diameter wing 55 and the small-diameter wing 57. The step portion corresponds to the lower end 550b of the large-diameter wing 55.

In the example shown in FIG. 13, the distance between the inner edge 553 of the large diameter blade 55 and the rotation center axis AX is smaller than the distance between the inner edge 583a of the upper plate 58a and the rotation center axis AX. In other words, the inner part of the large diameter blade 55 protrudes inward rather than the upper plate 58a. In this case, a part of the upper surface of the large-diameter wing 55 (exposed part 55c) is exposed to the first hole 50a. For this reason, when 5 A of rotary wing members rotate, there exists a possibility that a part of water may pass over the exposed part 55c (mixing of water and air may occur). However, since the gas-liquid interface DS is located outside the exposed portion 55c when the rotary blade member 5A is normally rotating, the exposed portion 55c is basically positioned within the area of the gas (air). do. Therefore, when the rotary blade member 5A rotates normally, water and air are not mixed in the exposed part 55c.

In the example shown in FIG. 13, the upper end of the outer part of the large diameter blade 55 is connected to the upper board 58a. For this reason, in the area | region (region of liquid) outside outer side of gas-liquid interface DS, it does not move so that water may pass over the upper end of the large diameter blade 55.

In the example described in FIG. 13, the rotary blade member 5A includes a shaft member 52. The shaft member 52 is arranged to pass through the first hole 50a of the upper plate 58a. For this reason, the gap between the outer peripheral surface 52a of the shaft member 52 and the inner edge 583a of the upper plate 58a functions as a gap G through which air or the like can pass.

In addition, in the example of FIG. 13, the shaft member 52 and the inner edge 553 of the large diameter blade 55 are directly connected. The large blade 55 is supported in three directions by the upper plate 58a, the lower plate 58b, and the shaft member 52. For this reason, the structural strength of the structure containing the large diameter blade 55, the upper board 58a, the lower board 58b, and the shaft member 52 is high.

In the example of FIG. 13, the shaft member 52 is provided with the shaft hole 520 which receives the output shaft of a motor. The engagement between the shaft member 52 and the output shaft of the motor is not limited to the contact between the shaft hole 520 and the output shaft (the output shaft is pressed into the shaft hole) and is arbitrary.

In the example described in FIG. 13, the upper portion 521 of the shaft member 52 is a portion connected to the output shaft of the motor. Moreover, the intermediate part 522 of the shaft member 52 functions as a support part of the large diameter blade 55, and the large diameter blade 55 is extended radially from the intermediate part 522. As shown in FIG. The lower portion 523 of the shaft member 52 passes through the second hole 50b of the lower plate 58b. And the small diameter blade 57 extends radially from the lower part 523 of the shaft member 52. As shown in FIG. In addition, the lower part 523 of the shaft member 52 may be provided with the shaft diameter part 524 which outer diameter decreases as it goes from upper to downward. The water pulled up by the small diameter blade 57 by the presence of the shaft diameter portion 524 is smoothly guided toward the large diameter blade 55.

In the example described in FIG. 13, the small-winged wing 57 has an upper portion 576, an intermediate portion 577, and a lower portion 578. The distance between the outer edge of the upper portion 576 and the rotation center axis AX is greater than the distance between the outer edge of the lower portion 578 and the rotation center axis AX. In addition, the outer edge of the intermediate portion 577 is an inclined surface in which the distance between the center of rotation axis AX decreases as it goes from the top to the bottom. The outer edge of the upper portion 576 and the outer edge of the lower portion 578 are connected through the outer edge of the middle portion 577.

In the example shown in FIG. 13, the distance between the outer edge of the small-winged wing 57 and the rotation center axis AX becomes large as it goes from downward to upward. For this reason, the water pulled up by the small diameter blade 57 is guided smoothly toward the large diameter blade 55. In the example described in FIG. 13, there is a gap between the outer edge of the upper portion 576 of the small-diameter wing 57 and the inner edge 583b of the lower plate 58b. In general, the outer edge of the upper portion 576 of the small-diameter wing 57 may be connected to the inner edge 583b of the lower plate 58b.

In the example of FIG. 13, the material of each of the upper board 58a, the large diameter blade 55, the lower plate 58b, the small diameter blade 57, and the shaft member 52 is resin. In addition, the upper plate 58a, the large diameter blade 55, the lower plate 58b, the small diameter blade 57, and the shaft member 52 are integrally formed. In general, the upper plate 58a, the large diameter blade 55, the lower plate 58b, the small diameter blade 57 and the shaft member 52 may be formed by two or more members, and the two or more members may be fixed to each other.

In the first modification shown in each drawing, the diameters of the upper plate 58a and the lower plate 58b and the diameters of the virtual circles connecting the outer edge 551 of the large-diameter wing 55 are all the same, but the first modification is the same. 5A of rotary blade members in this is not limited to this, The diameter of the virtual circle which connects the outer edge 551 of the large diameter blade 55, and the diameter of the upper board 58a and the lower board 58b may be another dimension. . When the diameter of the imaginary circle connecting the outer edge 551 of the large-diameter wing 55 is smaller than the diameter of the upper plate 58a and the lower plate 58b, the large-diameter wing 55 is similar to the first modified example shown in the above-described drawings. The movement of the drain water above and below is preferably suppressed and prevented. As a result, bubbles are less likely to mix with the drain water to be discharged, and noise during driving of the drain pump can be reduced. Improves drainage efficiency. It is natural that the diameter of the upper plate 58a and the diameter of the lower plate 58b may be different.

(2nd modification of a rotary blade member)

With reference to FIGS. 15-18, the rotary blade member 5B for drainage pumps in a 2nd modification is demonstrated. 15 is a schematic perspective view of the rotary blade member 5B in the second modification. Fig. 16 is a schematic two side view of the rotary blade member 5B in the second modification. A top view is shown on the upper side of FIG. 16, and a side view is described on the lower side of FIG. 16. 17 is a cross-sectional view taken along the line D-D of FIG. 16. 18 is a cross-sectional view taken along the line E-E of FIG. 16.

The rotary blade member 5B for the drainage pump in the second modification has a middle plate 58c disposed between the upper plate 58a and the lower plate 58b. It is different from the rotary blade member 5A. In other respects, the rotary blade member 5B for the drain pump in the second modification is the same as the rotary blade member 5A for the drain pump in the first modification. Therefore, in 2nd modification, it demonstrates centering around the middle board 58c, and abbreviate | omits the description which repeats about another structure.

As shown in FIG. 18, the middle plate 58c includes a third hole 50c through which liquid such as drain water and gas such as air can pass. In the example of FIG. 18, the 3rd hole 50c is formed in the center part of the middle board 58c. Further, the center of the middle plate 58c and the center of the third hole 50c are on the rotation center axis AX.

Referring to FIG. 15, the large diameter wing 55 includes an upper large diameter wing 55a disposed between the upper plate 58a and the middle plate 58c, and a lower large diameter wing disposed between the middle plate 58c and the lower plate 58b. 55b). The upper side opening OP1 is formed between the upper plate 58a and the middle plate 58c, and the lower side opening OP2 is formed between the middle plate 58c and the lower plate 58b.

When the distance between the upper plate 58a and the lower plate 58b is large and the middle plate 58c is not disposed between the upper plate 58a and the lower plate 58b, the upper plate 58a accompanies the rotation of the rotary blade member. ), There is a possibility that the momentum in the vertical direction of the water existing between the bottom plate 58b and the bottom plate 58b increases. Further, due to the large distance between the upper plate 58a and the lower plate 58b, there is a possibility that the moving direction of water existing between the upper plate 58a and the lower plate 58b is greatly disturbed. As a result, water between the upper plate 58a and the lower plate 58b collides with the upper plate 58a, the lower plate 58b, or the like, and there is a possibility that noise occurs. On the other hand, when the middle plate 58c is disposed between the upper plate 58a and the lower plate 58b, the amount of motion in the vertical direction of water existing between the upper plate 58a and the lower plate 58b is limited. In addition, since the distance between the upper plate 58a and the middle plate 58c and the distance between the middle plate 58c and the lower plate 58b are relatively small, the disturbance in the moving direction of water is reduced. As a result, noise is reduced.

The rotary blade member 5B of the second modification has the same effect as the rotary blade member 5A of the first modification. In addition, the rotary blade member 5B in the second modification includes a middle plate 58c. For this reason, the noise is further reduced.

(More detailed description of the second modification)

With reference to FIGS. 15-18, the rotating blade member 5B of a 2nd modification is demonstrated in detail.

In the example described in FIG. 15, the middle plate 58c has a ring shape. The middle plate 58c restricts the movement of the drain water sucked up and down at the time of rotation of the rotary blade member 5B (the movement in the space between the upper plate 58a and the lower plate 58b is almost limited in the middle). In addition, it is difficult to mix bubbles in the drain water, and the noise during driving of the drain pump is further reduced.

In the example described in FIG. 17 (D-D arrow cross-sectional view in FIG. 16), the upper surface 582c of the middle plate 58c is an inclined surface. When the upper surface 582c of the middle plate 58c is an inclined surface, water hardly stays on the upper surface 582c of the middle plate 58c when the rotary blade member 5B stops. For this reason, a solid component is hard to deposit on the upper surface 582c of the middle board 58c. The upper surface 582c of the middle plate 58c is preferably an inclined surface in which the position in the vertical direction gradually decreases from the inner edge 583c of the middle plate to the outer edge 584c of the middle plate. However, the upper surface 582c of the middle plate 58c may be an inclined surface in which the position in the vertical direction gradually rises from the inner edge 583c of the middle plate to the outer edge 584c of the middle plate.

In the example shown in FIG. 17, the upper end 550a of the upper large diameter wing 55a is connected to the lower surface of the upper plate 58a, and the lower end of the upper large diameter wing 55a is connected to the upper surface of the middle plate 58c. In addition, the upper end of the lower large diameter wing 55b is connected to the lower surface of the middle plate 58c, and the lower end 550b of the lower large diameter wing 55b is connected to the upper surface of the lower plate 58b. For this reason, the intensity | strength of the structure comprised by the upper board 58a, the upper large diameter blade 55a, the middle plate 58c, the lower large diameter blade 55b, and the lower board 58b is high. In addition, since the structural strength of the structure is high, the upper plate 58a, the upper large diameter wing 55a, the middle plate 58c, the lower large diameter wing 55b, and the lower plate 58b can be thinned.

In the example shown in FIG. 17, one plate is comprised by one upper large diameter blade 55a, one lower large diameter blade 55b, and one small diameter blade 57. As shown in FIG. That is, the inner portion of the upper large diameter wing 55a and the inner portion of the lower large diameter wing 55b are connected through the connecting portion 588, and the lower end of the lower large diameter wing 55b and the upper end of the small diameter wing 57 are connected to each other. Is also connected.

In addition, in the example of FIG. 17, each of the upper board 58a, the upper large diameter blade 55a, the middle plate 58c, the lower large diameter blade 55b, the lower plate 58b, the small diameter blade 57, and the shaft member 52, respectively. The material is resin. In addition, the upper plate 58a, the upper large diameter blade 55a, the middle plate 58c, the lower large diameter blade 55b, the lower plate 58b, the small diameter blade 57, and the shaft member 52 are integrally formed. In general, the upper plate 58a, the upper large diameter wing 55a, the middle plate 58c, the lower large diameter wing 55b, the lower plate 58b, the small diameter wing 57 and the shaft member 52 are formed by two or more members. Two or more members may be fixed to each other.

In the example shown in FIG. 15, the number of the upper large diameter blades 55a is four, and the upper large diameter blades 55a are arrange | positioned at intervals of 90 degrees around the rotation center axis AX. Moreover, the number of the lower large diameter blades 55b is four, and the lower large diameter blades 55b are arrange | positioned at intervals of 90 degrees around the rotation center axis AX. However, each of the number of the upper large diameter blades 55a and the number of the lower large diameter blades 55b is not limited to four, but is arbitrary. In addition, in the example shown in FIG. 16, although the inner edge 553 of all the upper large diameter blades 55a is directly connected to the shaft member 52, the inner edge 553 of the at least one upper large diameter blade 55a, and the shaft member 52 need not be connected directly. Similarly, the inner edge 553 of all the lower large-diameter wings 55b may be directly connected to the shaft member 52, and the inner edge 553 and the shaft member 52 of the at least one lower large-diameter blade 55b may It does not have to be connected directly. In addition, when each of the number of the upper large blades 55a and the number of the lower large blades 55b is N pieces (N is a natural number of two or more), the side opening OP formed between the upper plate 58a and the lower plate 58b. ) Is 2N. The upper side opening OP1 is an opening defined by the upper plate 58a, the middle plate 58c, and the two upper large-diameter wings 55a, and the lower side opening OP2 is the middle plate 58c. And an opening defined by the lower plate 58b and the two lower large-diameter wings 55b.

In the second modification, an example has been described in which the number of the heavy plates 58c is one. In general, the number of the middle plates 58c disposed between the upper plate 58a and the lower plate 58b may be two or more.

15 to 18, the diameters of the upper plate 58a, the middle plate 58c and the lower plate 58b, and the outer edges 551 of the large diameter wings 55, 55a and 55b are joined. Although the diameters of the virtual circles are all the same, the rotary blade member 5B in the second modification is not limited to this, and similarly to the first modification, the virtual blades connecting the outer edge 551 of the large-diameter blade 55 The diameter and the diameter of the upper plate 58a, the middle plate 58c, and the lower plate 58b may have different dimensions.

In addition, the diameters of the upper plate 58a, the middle plate 58c, and the lower plate 58b may also be such that at least one of them differs from other diameters. In particular, since the middle plate 58c only restricts the movement of the fluid between the upper plate 58a and the lower plate 58b, the diameter of the middle plate 58c is larger than that of the upper plate 58a and the lower plate 58b. If it is made small, the effect of both suppressing (or reducing weight) the weight increase by providing the middle plate 58c, and being silent can be obtained.

The rotary blade members 5A and 5B in the first modification or the second modification have high water pulling capability. For this reason, when employ | adopting the rotary blade members 5A and 5B in a 1st modification or a 2nd modification in the drainage pump 1 in embodiment, the drainage pump 1 can be miniaturized. Further, the synergistic effect between the waterproof wall portion 42 of the motor lower cover and the rotary lower members 5A and 5B in the embodiment enables further miniaturization of the drain pump 1, and furthermore, the drain pump 1 In spite of the reduction in size, the ingress of water into the motor is effectively suppressed.

(Pump housing 6)

5, an example of the pump housing 6 will be described. The pump housing 6 defines a pump chamber PS, and rotary vane members 5, 5A, and 5B are disposed in the pump chamber PS.

In the example described in FIG. 5, the pump housing 6 includes a housing main body 6a and a lid member 6b connected to an upper portion of the housing main body 6a. In the example of FIG. 5, the housing main body 6a and the lid member 6b are connected through seal members 67, such as an O-ring. The connection between the housing main body 6a and the lid member 6b may be a connection by fitting, a connection by a fastening member such as a bolt, a connection by welding, or a connection by adhesion.

In the example described in FIG. 5, the lid member 6b functions as the upper wall 63 described above. The upper surface 63a of the upper wall 63 is preferably an inclined surface whose height decreases as it faces the outward direction. Since the upper surface 63a is an inclined surface, water hardly forms on the upper surface 63a. Therefore, on the upper surface 63a, the solid precipitated with evaporation of water or the like is difficult to deposit.

In the example of FIG. 5, the cover member 6b is provided with the annular protrusion part 65 which protrudes upwards from an inner edge part. The direction of discharge of water into the space SP is appropriately defined by the gap between the annular projection 65 and the shaft 7 (output shaft 27, shaft member 52, etc.). In the example shown in FIG. 5, the shaft 7 (output shaft 27) has an inclined surface 72 (more specifically, an annular taper corresponding to a part of the circumferential surface of the virtual cone) in which the height increases as it faces the outward direction. Cotton). For this reason, the discharge direction of the water to space SP becomes a direction along the inclined surface 72. As a result, intrusion of water into the motor 2 (for example, the gap between the rotor 20 and the stator 30) is more effectively suppressed.

In the example shown in FIG. 5, the pump housing 6 includes a suction pipe 68a defining a suction port 68 and a discharge pipe 69a defining a discharge port 69. The suction pipe 68a extends downward from the pump chamber PS, and the discharge pipe 69a extends horizontally outward from the pump chamber PS. In the example shown in FIG. 5, the part which defines the pump chamber PS of the pump housing 6, and the suction pipe 68a and the discharge pipe 69a are integrally formed with the resin material. In general, the pump housing 6 may define a portion defining the pump chamber PS, the suction pipe 68a, and the discharge pipe 69a as separate bodies, and may be joined to each other.

In addition, this invention is not limited to embodiment mentioned above. Within the scope of the invention, modifications to any component of the above-described embodiments, or addition or omission of any component in the embodiments are possible.

1: drain pump 2: motor
2a: lower part 4: motor lower cover
5, 5A, 5B: rotary blade member 6: pump housing
6a: housing body 6b: cover member
7: shaft 8: motor top cover
20: rotor 21: rotor shade
23: magnet 24: bearing
24a: upper bearing 24b: lower bearing
25: cylindrical portion 27: output shaft
30: stator 30a: lower surface
32: coil 33: core member
34 shaft member 41 side wall
42: waterproof wall 42a: upper surface
42b: through hole 44: first engagement portion
46: third engagement portion 50a: first hole
50b: second hole 50c: third hole
52 shaft member 52a outer peripheral surface
54: large diameter wing part 54a: large diameter wing part
54b: auxiliary large diameter wing 54c: dish portion
54d: Ring part 55: Large diameter wing
55a: upper large diameter wing 55b: lower large diameter wing
55c: exposed part 56: small diameter wing part
56a: blind blade 57: blind blade
58 plate member 58a top plate
58b: Bottom 58c: Mid
61: through hole 63: upper wall
63a: upper surface 64: second engagement portion
65 annular projection 67 seal member
68: suction port 68a: suction pipe
69: discharge port 69a: discharge tube
72: slope 81: mounting bracket
86: fourth engaging portion 101: drain hose
520: shaft hole 521: upper part
522: middle part 523: lower part
524: shaft portion 550a: upper
550b: bottom 551: outer edge
553: internal combustion 571: external combustion
576: upper part 577: middle part
578: Lower 582a, 582b, 582c: Upper surface
583a, 583b, 583c: Internal combustion 584a, 584b, 584c: External combustion
585b: When 588: Connection Part
540c: through hole F: engagement mechanism
F1: first engagement mechanism F2: second engagement mechanism
G: clearance H: engagement mechanism
PA: labyrinth passage PA1: passage
PA2: Pathway PA3: Pathway
PS: Pump room SP: Space
T: Terminal W: Lead Wire
X: axis of rotation AR1: area
AR2: area AR3: area
AX: Center of rotation DS: Gas-liquid interface
OP: side opening OP1: side opening
OP2: side opening

Claims (9)

A motor having a rotor and a stator,
A motor lower cover covering at least a portion of a lower portion of the motor;
A rotary blade member connected to the rotor so as to transmit power;
A pump housing having a pump chamber for accommodating the rotary wing member;
A through hole is provided in the upper wall of the pump housing,
And the motor lower cover has a waterproof wall portion disposed between the motor and the upper wall of the pump housing. The method of claim 1,
And the waterproof wall part is an inwardly flanged part that protrudes in the inward direction from the side wall of the motor lower cover. The method according to claim 1 or 2,
The rotor has a rotor shade to prevent water from entering the gap between the rotor and the stator,
And a labyrinth passage formed by the rotor shade and the waterproof wall. The method of claim 3,
And the rotor shade is disposed to face at least a portion of the lower surface of the stator. The method according to any one of claims 1 to 4,
A space is provided between the motor lower cover and the upper wall of the pump housing;
And the space is opened without being covered by the wall. The method according to any one of claims 1 to 5,
The motor lower cover has a first engagement portion,
The pump housing has a second engagement portion,
And the motor lower cover and the pump housing are detachably connected to each other via the first engagement portion and the second engagement portion. The method according to any one of claims 1 to 6,
The rotary blade member,
A plurality of plate members including an upper plate and a lower plate,
A large diameter wing disposed between the upper plate and the lower plate,
It is provided with a small diameter wing arranged below the lower plate,
A side opening is formed between the upper plate and the lower plate,
The upper plate has a first hole through which the fluid can pass,
The lower plate has a second hole through which the fluid can pass. The method of claim 7, wherein
The plurality of plate members includes a middle plate disposed between the upper plate and the lower plate,
And the middle plate has a third hole through which the fluid can pass. The method according to claim 7 or 8,
And a top surface of each of the plurality of plate members is an inclined surface.

Images