KR102577089B1 - Drain pump for laundry treating appratus - Google Patents

Abstract

The present invention includes a housing having an inlet on the front to accommodate washing water; a drain and a circulation port extending upward from one side of the housing to be spaced apart from each other and communicating with the interior of the housing; A driving unit installed on one side of the housing and transmitting rotational force through a rotating shaft to flow the washing water; and a plurality of impellers located inside the housing and each installed at different positions on the rotation axis, wherein each impeller is configured to be selectively rotatable along the rotation axis, thereby discharging the washing water accommodated in the housing. It relates to a drain pump that can perform both drainage and circulation while preventing backflow of washing water by discharging it toward the drain or circulation port.

Description

Drainage pump for clothing treatment equipment {DRAIN PUMP FOR LAUNDRY TREATING APPRATUS}

The present invention relates to a drain pump for a clothing treatment device that drains or circulates washing water flowing from a drum.

A clothing treatment device is a device that removes contamination from laundry by putting clothes, bedding, etc. (hereinafter referred to as laundry) into a drum, and performs processes such as washing, rinsing, dehydration, and drying.

Clothing treatment devices are divided into top loading and front loading methods based on the method of loading laundry into the drum. Front-loading washing machines are generally called drum washing machines.

In a drum washing machine, when laundry is stored in the drum and water is supplied, the washing process is performed through the rotation of the drum, and then goes through a process such as rinsing and dehydration, and then discharges the washing water to the outside by a drain pump. Accordingly, a drum washing machine requires a circulation pump to circulate water inside the drum during the washing process and a drain pump to discharge the washing water generated during the washing process to the outside.

Conventionally, it was common to configure pumps for circulation and drainage of wash water in drum washing machines using separate motors. In this case, the installation space is limited and multiple motors are required, so there is a problem that it is not cost-effective.

Accordingly, by using one drainage pump to perform the roles of a circulation pump and a drainage pump respectively by changing the direction of rotation of the impeller, the structure of the drainage pump is designed to achieve both space utilization and economic benefits. It was requested.

In addition, when a drainage process or circulation process is performed by a single drainage pump, it has a structure that can limit this so that the washing water flowing in the process does not flow back through the flow path, and a space where the washing water remains is provided. There is a need for a drain pump that can prevent a decrease in efficiency by forming a smooth flow of washing water.

The present invention is intended to propose a structure of a drainage pump having a structure that can respectively perform a circulation process and a drainage process of washing water using a single drainage pump.

The present invention is intended to propose a structure of a drain pump including impellers that rotate in different directions during the washing process and the draining process.

The present invention is intended to propose a structure of a drain pump that can limit backflow of wash water by spatially separating the flow of wash water inside the housing during the wash water circulation or drainage process.

A drain pump related to an embodiment of the present invention for realizing the above-described problem includes a housing having an inlet on the front to accommodate washing water; a drain and a circulation port extending upward from one side of the housing to be spaced apart from each other and communicating with the interior of the housing; A driving unit installed on one side of the housing and transmitting rotational force through a rotating shaft to flow the washing water; and a plurality of impellers located inside the housing and each installed at different positions on the rotation axis, wherein each impeller is configured to be selectively rotatable along the rotation axis, thereby discharging the washing water accommodated in the housing. It has the feature of being able to be discharged toward the drain or circulation hole.

According to an example related to the present invention, the impeller includes: a first impeller that is located adjacent to the drain and rotates along the rotation axis to move washing water accommodated in the housing toward the drain; and a second impeller installed to face the first impeller, located adjacent to the circulation port, and rotating along the rotation axis to move the washing water received in the housing toward the circulation port.

According to an example related to the present invention, a unidirectional bearing may be installed at the center of the first impeller and the second impeller so that each impeller can rotate only in one direction.

According to an example related to the present invention, the driving unit includes a motor capable of rotating in both directions to generate driving force, and the motor may be a BLDC motor whose driving direction and speed can be controlled.

According to an example related to the present invention, the first impeller and the second impeller are respectively fixed to the rotation shaft, are arranged to be spaced apart from each other by a set distance on the rotation shaft, and are connected to the rotation shaft by a rotational force by the driving unit. It can be rotated as one piece.

According to an example related to the present invention, a control unit that transmits a signal for driving the BLDC motor to vary the rotation direction and speed of the impeller may be further included.

According to an example related to the present invention, the first impeller is configured to rotate only in a first direction, and the second impeller is configured to rotate only in a second direction that is different from the first direction. When the rotation shaft is rotated in the first direction, the first impeller rotates in the first direction, but the rotation of the second impeller is limited, and when the rotation shaft is rotated in the second direction, the first impeller rotates in the first direction. 2 The impeller rotates in the second direction, but the rotation of the first impeller may be limited.

According to an example related to the present invention, a plurality of curved protrusions may be formed on the inner surfaces of the drain hole and the circulation hole, thereby preventing backflow of washing water.

By means of the above-mentioned means, the present invention can perform both the circulation process and the drainage process through a single drainage pump, thereby enabling more efficient use of space in the clothing treatment device and providing economic advantages. can be obtained.

Additionally, by placing two impellers on the rotation axis to rotate in different directions, each impeller can perform a drainage process or a circulation process, respectively.

Additionally, in the circulation process and the drainage process, by forming different flow directions of the washing water inside the housing, it is possible to prevent reverse flow to another flow path during the process.

1 is a perspective view showing the interior of a clothing treatment device including a drainage pump according to the present invention.
Figure 2 is a perspective view of a drainage pump according to the present invention.
Figure 3 is a cross-sectional view of the drainage pump of Figure 2 cut along line A.
Figure 4 is a conceptual diagram showing the first impeller rotating in the first direction by the driving unit.
Figure 5 is a conceptual diagram showing a second impeller rotating in a second direction by a driving unit.
Figure 6 is an enlarged view showing the inner surfaces of the drain and circulation port.

Hereinafter, the drainage pump for a clothing treatment device related to the present invention will be described in more detail with reference to the drawings.

In this specification, singular expressions include plural expressions, unless the context clearly dictates otherwise.

In describing the embodiments disclosed in this specification, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in this specification, the detailed descriptions will be omitted.

The attached drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed in this specification is not limited by the attached drawings, and all changes, equivalents, and changes included in the spirit and technical scope of the present invention are not limited. It should be understood to include water or substitutes.

FIG. 1 is a diagram showing the internal appearance of a laundry treatment device 10 including a drainage pump 100.

The laundry treatment device 10 includes a cabinet (not shown) forming the exterior, a tub 18 accommodated inside the cabinet (not shown), and a drum 21 rotatably mounted inside the tub 18 into which laundry is placed. ) includes. In addition, since air must be circulated to dry the laundry inside the drum 21, the clothing processing device 10 includes a duct 15, a heat exchanger (not shown), a fan motor 17, and a compressor 16. ) and a compressor support (not shown) to support the compressor 16. In addition, the clothing treatment device 10 includes a condensate discharge pipe 23, a drain pump room 19, and a drain pump 100 for discharging condensate generated from the air passing through a heat exchanger (not shown) to the outside as the air circulates. ), a drain hose 20, and a drain connector (not shown).

The drainage pump 100 (hereinafter referred to as 'drainage pump') for a clothing processing device according to the present invention is located at the lower part of the clothing processing device 10.

The conventional clothing treatment device 10 was generally configured to include pumps for circulation and drainage of washing water. In this case, it becomes difficult to utilize the internal space of the clothing treatment device, and since motors must be installed and driven separately, there is a problem in terms of power use that is not efficient. Accordingly, the drainage pump according to the present invention can perform both the drainage process and the circulation process.

When the washing water in the tub 18 moves to the drainage pump room 19 and flows into the housing 110 of the drainage pump 100, the drainage pump 100 drives the motor (not shown) to circulate the washing water. It performs a circulation process of moving the washing water through 130 toward the tub 18, or performs a drainage process of moving the inflowed washing water toward the drain 140 and discharging it to the outside.

Figure 2 shows a perspective view showing the structure of the drainage pump 100 according to the present invention.

The drain pump 100 includes a housing 110 and a driving unit 150, and an inlet 120, a circulation port 130, and a drain port 140 are formed in the housing 110, respectively.

The housing 110 forms the exterior of the drain pump 100 and has a space to accommodate the washing water flowing in from the water inlet 120. The housing 110 can be supported in a balanced state by the housing support member 112 protruding downward from the bottom. The housing support member 112 may be fixed to a base (not shown) formed on the lower surface of a cabinet (not shown).

The housing 110 has a cylindrical shape, and an inlet 120 is formed on the front. Washing water can flow in through the inlet port 120. A drain 140 is formed on one side of the housing 110 and extends upward, communicates with the inside of the housing 110 and serves as a pipe through which washing water can move, and an upper portion on the other side of the housing 110. It extends toward and communicates with the inside of the housing 110 to form a circulation port 130 that serves as a passage through which washing water can move. The drain 140 and the circulation port 130 are arranged to be spaced apart from each other and are positioned to face each other on one side of the housing 110.

A driving unit 150 is installed on one side of the housing 110 to transmit rotational force through the rotation shaft 163 to rotate the impeller within the housing 110 to create a flow of washing water. The driving unit 150 includes motors (not shown) for rotating the rotation shafts 163 in different directions. Here, the motor (not shown) may refer to a BLDC motor (brush-less direct current motor).

BLDC motors (not shown) are capable of rotating in both directions and changing the rotation speed. Unlike DC motors, they do not have brushes, so their lifespan is semi-permanent. Since they can be controlled by semiconductor devices, current control is easy and accurate speed control is possible. possible. In addition, it is a motor that has high torque and is capable of high-speed rotation.

The driving direction and speed of the BLDC motor (not shown) can be adjusted, and the rotation direction and speed of the impeller connected to the rotation shaft 163 can be changed. The driving unit 150 may include a control unit (not shown) for controlling the rotation direction and speed of the BLDC motor (not shown). The control unit (not shown) controls the power value input to the motor (not shown), thereby allowing the rotation speed and direction of the motor (not shown) to be adjusted.

When power is supplied to the driving unit 150, the rotation shaft 163 connected to the driving unit 150 rotates, and the impellers 161 and 162 rotate along the rotation shaft 163. When the impellers 161 and 162 rotate, the washing water contained in the housing 110 rotates to form a vortex. Depending on the flow of washing water formed by the rotation of the impellers 161 and 162, a drainage process or a circulation process can be performed.

Washing water flowing inside the housing 110 moves to the circulation port 130 or the drain port 140 depending on the rotation direction of the impellers 161 and 162, respectively. However, during the washing process, if the direction of rotation of the impellers 161 and 162 is selected to move the wash water to the circulation port 130 or the drain port 140, the wash water will flow back toward a flow path other than the corresponding flow path. Problems may arise. In particular, if wash water flows back into the drain 140 during the circulation process, a problem occurs in which the amount of water to be circulated to the tub (not shown) is reduced. Accordingly, a method for preventing backflow of washing water flowing inside the housing 110 is required.

FIG. 3 shows a cross-sectional view of the drainage pump 100 of FIG. 2 cut along line A.

Inside the housing 110, washing water can flow due to the rotation of the impeller.

Inside the housing 110, impellers installed at different positions of the rotation axis 163 are located.

As shown in Figure 3, the impellers 161 and 162 may be installed at both ends of the rotation shaft 163, and each impeller 161 and 162 extends in a direction intersecting the direction in which the water inlet 120 extends. Each is fixedly installed on one side of the formed rotation axis 163. Here, the rotation shaft 163 has the shape of a circular metal rod and serves to connect the drive unit 150 and the impeller to transmit the rotational force generated in the drive unit 150. The rotation axis 163 can be fixed to both ends across the housing 110, respectively.

Impellers 161 and 162 are respectively installed adjacent to the drain 140 or circulation port 130. The impellers 161 and 162 include a first impeller 161 located adjacent to the drain 140 and a second impeller 162 located adjacent to the circulation port 130. The impellers 161 and 162 include a boss portion (not shown) formed at the center and a plurality of blades (not shown) that can rotate to form a flow of washing water. Since the impellers 161 and 162 used in the present invention can be impellers having a general shape, their description will be omitted.

The first impeller 161 is located adjacent to the drain 140 and rotates along the rotation axis 163 to move the washing water contained in the housing 110 toward the drain 140. . The rotation of the first impeller 161 allows washing water to flow out through the drain hole 140 during the draining process.

The second impeller 162 is located adjacent to the circulation port 130, is installed to face the first impeller 161, and rotates along the rotation axis 163 to accommodate the laundry in the housing 110. It serves to move water toward the circulation port 130. The rotation of the second impeller 162 allows washing water to flow out through the circulation port 130 during the circulation process.

The first impeller 161 and the second impeller 162 can rotate integrally along the rotation axis 163 and can be selectively rotated by receiving rotational force from the driving unit 150. The first impeller 161 and the second impeller 162 may be formed to rotate in the same or different directions. Accordingly, the washing water accommodated in the housing 110 can be selectively discharged toward the drain 140 or the circulation port 130 through the first impeller 161 and the second impeller 162. However, if the rotation directions of the first impeller 161 and the second impeller 162 are different, backflow to the circulation port 130 in the drainage process and backflow to the drain 140 in the circulation process may be limited. It works.

In order to rotate the first impeller 161 and the second impeller 162 in different directions, a one-way bearing 164 is installed at the center of the first impeller 161 and the second impeller 162. ) can be installed. The one-way bearing 164 is a member that allows rotation in only one direction, and transmits rotational force only when rotating in a set direction, and serves the role of not transmitting rotational force in directions other than the set direction. .

The unidirectional bearing 164 may be installed on the rotation shaft 163 and at the center of the first impeller 161 and the center of the second impeller 162, respectively. The unidirectional bearing 164 installed at the center of the first impeller 161 is called the first bearing 164a, and the unidirectional bearing 164 installed at the center of the second impeller 162 is called the second bearing 164b. It is called. The first bearing 164a and the second bearing 164b serve to allow the rotation directions of the first impeller 161 and the second impeller 162 to be different from each other.

For example, when the rotation shaft 163 rotates in the first direction (or clockwise) by the drive unit 150, the first impeller 161 is integrated with the rotation shaft 163 and the first bearing 164a. Rotation in the first direction is possible. However, since the second bearing 164b located at the center of the second impeller 162 rotates freely with respect to the rotation of the rotation shaft 163 in the first direction, the second impeller 162 does not rotate.

Likewise, when the rotating shaft 163 rotates in the second direction (or counterclockwise) by the driving unit 150, the second impeller 162 is formed integrally with the rotating shaft 163 and the second bearing 164b. Rotation in two directions is possible. However, since the first bearing 164a located at the center of the first impeller 161 spins in the rotation direction of the rotation shaft 163 in the second direction, the first impeller 161 does not rotate. .

FIG. 4 shows the first impeller 161 rotating in the first direction by the driving unit 150, and FIG. 5 shows the second impeller 162 rotating in the second direction by the driving unit 150. This is a drawing showing rotation.

The first impeller 161 is located adjacent to the drain 140 and rotates along the rotation axis 163 to move the washing water contained in the housing 110 toward the drain 140. . The rotation of the first impeller 161 allows washing water to flow out through the drain hole 140 during the draining process.

The second impeller 162 is located adjacent to the circulation port 130, is installed to face the first impeller 161, and rotates along the rotation axis 163 to accommodate the laundry in the housing 110. It serves to move water toward the circulation port 130. The rotation of the second impeller 162 allows washing water to flow out through the circulation port 130 during the circulation process.

As shown in FIG. 4, when power is supplied to the motor (not shown) forming the drive unit 150 and the rotation shaft 163 rotates in the first direction (or clockwise) by the drive unit 150, the first The impeller 161 can rotate in the first direction integrally with the rotation shaft 163 and the first bearing 164a. However, since the second bearing 164b located at the center of the second impeller 162 rotates freely with respect to the rotation of the rotation shaft 163 in the first direction, the second impeller 162 does not rotate. That is, when the motor (not shown) transmits rotational force in the first direction through the rotation shaft 163, the first impeller 161 rotates in the first direction, but the rotation of the second impeller 162 is limited. .

In this case, the first impeller 161, which is located adjacent to the drain 140 and rotates along the rotation axis 163, moves the washing water received in the housing 110 toward the drain 140, During the draining process, it is possible for washing water to flow out through the drain hole 140. At this time, since the rotation of the second impeller 162 is limited, washing water does not leak into the circulation port 130 by the second impeller 162 located adjacent to the circulation port 130.

In addition, as shown in FIG. 4, the second impeller 162 is positioned while maintaining only a predetermined gap with the housing 110 where the circulation port 130 is located, so the drainage process according to the rotation of the first impeller 161 In this way, backflow to the circulation port 130 can be minimized. At this time, the washing water continues to flow out into the drain hole 140 due to the rotation of the first impeller 161, allowing smooth flow during the draining process.

As shown in FIG. 5, when the rotating shaft 163 rotates in the second direction (or counterclockwise) by the driving unit 150, the second impeller 162 is connected to the rotating shaft 163 and the second bearing 164b. becomes one with and rotates in the second direction. At this time, the first bearing 164a located at the center of the first impeller 161 rotates freely with respect to the rotation direction of the rotation shaft 163 in the second direction, so the first impeller 161 does not rotate. .

In this case, the second impeller 162, which is located adjacent to the circulation port 130 and rotates along the rotation axis 163, moves the washing water received in the housing 110 toward the circulation port 130. By doing so, it becomes possible for the washing water to flow out through the circulation port 130 during the circulation process. At this time, since the rotation of the first impeller 161 is limited, washing water does not leak into the circulation port 130 by the second impeller 162 located adjacent to the drain port 140.

In addition, as shown in FIG. 5, the first impeller 161 is positioned to maintain only a predetermined gap with the housing 110 where the drain 140 is located, so in the circulation process according to the rotation of the second impeller 162 , it is possible to minimize backflow into the drain 140. At this time, the washing water can continue to flow out into the circulation port 130 due to the rotation of the second impeller 162, so there is no problem with smooth flow in the circulation process.

Figure 6 shows an enlarged view showing the inner surfaces of the drain 140 and the circulation port 130.

As shown in FIG. 6, a plurality of curved protrusions 170 are formed on the inner surfaces of the drain hole 140 and the circulation hole 130. Here, the protrusion 170 may mean a dimple.

Dimple means that the inner surface is curved and bumpy, and has a shape similar to the surface of a golf ball. Due to the dimples, when the washing water moves along the water outlet, instead of moving uniformly, the particles of the washing water are dispersed into several moving paths of the washing water. Accordingly, when backflow occurs, the flow occurs. The effect of limiting can be achieved.

As shown in FIG. 6, the inner surfaces of the drain 140 and the water outlet are curved, so that a plurality of dimples having an embossed shape can be formed, respectively. Additionally, the dimples may be arranged uniformly, but they may also be arranged without a certain pattern.

What has been described above is only an embodiment for carrying out the drain pump for a clothing treatment device according to the present invention, and the present invention is not limited to the above embodiments, and as claimed in the following patent claims, the present invention It will be said that the technical idea of the present invention is such that anyone with ordinary knowledge in the field to which the invention pertains can make various changes without departing from the gist of the invention.

100: Drain pump for clothes processing device
110: housing
120: Inlet
130: Circulation sphere
140: drain
161: first impeller
162: second impeller
163: rotation axis
164: One-way bearing

Claims (8)

A housing with an inlet at the front to accommodate washing water;
a drain and a circulation port extending upward from one side of the housing to be spaced apart from each other and communicating with the interior of the housing;
A driving unit installed on one side of the housing and transmitting rotational force through a rotating shaft to flow the washing water; and
It is located inside the housing and includes a plurality of impellers each installed at different positions on the rotation shaft,
Each impeller is configured to be selectively rotatable along the rotation axis, and discharges the washing water contained in the housing toward the drain or circulation port,
A drain pump for a clothes treatment device, characterized in that a plurality of curved protrusions are formed on the inner surfaces of the drain hole and the circulation hole. According to paragraph 1,
The impeller is,
a first impeller located adjacent to the drain and rotating along the rotation axis to move wash water received in the housing toward the drain; and
Clothing comprising a second impeller installed to face the first impeller, located adjacent to the circulation port, and rotating along the rotation axis to move the washing water received in the housing toward the circulation port. Drainage pump for treatment equipment. According to paragraph 2,
A drainage pump for a clothing treatment device, wherein the first impeller and the second impeller have a unidirectional bearing installed at the center so that each impeller can rotate only in one direction. According to paragraph 1,
The driving unit includes a motor capable of rotating in both directions to generate driving force,
A drainage pump for a clothing treatment device, characterized in that the motor is a BLDC motor capable of controlling the driving direction and speed. According to paragraph 3,
The first impeller and the second impeller are,
Each is inserted and fixed to the rotation axis and is spaced apart from each other by a set distance on the rotation axis,
A drain pump for a clothing treatment device, characterized in that it is rotated integrally with the rotation shaft by the rotational force generated by the drive unit. According to paragraph 4,
A drainage pump for a clothing treatment device, further comprising a control unit that transmits a signal for driving the BLDC motor to change the rotation direction and speed of the impeller. According to paragraph 2,
The first impeller is configured to rotate only in the first direction,
The second impeller is configured to rotate only in a second direction that is different from the first direction,
When the rotation shaft is rotated in the first direction, the first impeller rotates in the first direction, but the rotation of the second impeller is limited,
When the rotation shaft rotates in the second direction, the second impeller rotates in the second direction, but the rotation of the first impeller is limited. delete

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