KR20200049237A - Pump unit of washing machine - Google Patents

Abstract

According to one embodiment of the present invention, a pump unit of a washing machine includes: a pump housing of which one inlet is formed at one side, a first outlet and a second outlet spaced apart from each other are formed at the other side and in which a chamber allowing the first outlet and the second outlet to communicate with the inlet is formed; a first impeller rotationally arranged in the pump housing to be adjacent to the first outlet; a second impeller rotationally arranged in the pump housing to be adjacent to the second outlet and arranged to face the first impeller; and a bidirectional motor connected to a rotating shaft of the first impeller and a rotating shaft of the second impeller to be rotated.

Description

Pump unit of washing machine

The present invention relates to a pump unit of a washing machine, and more particularly, to a pump unit of the washing machine that can change the discharge direction of the fluid by changing the rotation direction of the motor.

In general, a washing machine is a mechanical device that washes laundry by performing a washing process, a rinsing process, and a dehydration process according to a predetermined algorithm.

The drum washing machine using the drum-type washing method is widely used because it has advantages such as a minimum washing damage rate and a minimum washing amount compared to other types of washing machines.

Hereinafter, a conventional drum washing machine introduced in Korean Patent Publication No. 2002-0089776 will be described with reference to FIGS. 1 and 2 as follows.

1 is a schematic diagram showing the position and connection of the pump housing of the conventional drum washing machine, Figure 2 is a schematic view showing the flow direction of the washing water pumping device and the washing water of the drum washing machine of Figure 1;

1 and 2, the conventional drum washing machine is largely installed on a main body (not shown), a control panel (not shown) installed on the upper portion of the main body, and a user inputs a washing function and a washing time, and inside the main body. In the tub (1) fixed by a damper, the drum (2) is installed in the tub (1), the laundry is put, and the drum (2) by transmitting a driving force through a belt while rotating the drum (2) It consists of a motor (3) for performing laundry-related administration.

In addition, a detergent container (not shown) for injecting detergent, a water supply hose (not shown) for supplying laundry or laundry water mixed with detergent in the detergent container connected to the detergent container, and washing water used in the washing administration. And a bellows hose 11 for discharging the tub 1 and a pump 13 and a pump housing 12 connected to the bellows hose 11 for forcibly pumping wash water.

Looking at the operation of the drum washing machine configured as described above, when the user opens the door attached to the front of the main body, inputs laundry, and then presses a button on the control panel (not shown) to enter the washing command, the water valve (not shown) opens. The water used for washing flows into the tub 1 through the detergent container, whereby wash water and detergent are introduced into the drum 2.

In such a drum washing machine, when the washing water is filled to a certain height in the tub 1 and the drum 2, the water supply of the washing water is stopped and the motor 3 rotates with a constant cycle.

Accordingly, the laundry flows according to the rotation of the drum 2, and the laundry is washed by friction with washing water and decomposition of detergent.

When the washing process is completed, the pump discharged to the pump housing through the bellows hose 11 connected to the tub 1 by operating the pump connected to the pump housing 12 to generate a predetermined pressure in the pump housing 12 The water is discharged to the outside through the drain hose 14 as shown in the direction of the arrow in FIG. 2.

Subsequently, after the washing water is discharged through the drain hose 14, clean water is supplied to the tub 1 again through the water supply hose to start the rinsing process, and the rinsing process is completed by the same action as during the washing process. do.

After the rinsing process is repeated a number of times set by the user on the control panel, the washing water is discharged to the outside through the drain hose 14, and then a dehydration process is started in which water contained in the laundry is drained by centrifugal force. .

As described above, the drum washing machine completes washing of the laundry while sequentially performing the washing process, the rinsing process, and the dehydration process.

However, when water and detergent are introduced into the tub 1 at the beginning of the washing cycle of the drum washing machine, water and detergent are mixed in the tub. At this time, a small amount is attached to the bellows hose 11 connected to the lower surface of the tub 1 Detergents are introduced and accumulate.

At this time, since the detergent collected on the bellows hose 11 does not help any washing of the laundry even if the drum 2 is rotated, it does not affect the washing efficiency because the detergent is wasted.

In addition, after the washing process was completed, the detergent that was collected in the bellows hose 11 while the washing water contained in the tub 1 was discharged to the outside through the bellows hose 11, the pump housing 12, and the drain hose 14 Also mixed with wash water and discharged to the outside.

Accordingly, when washing laundry, a larger amount of detergent must be used, which may increase water pollution.

Due to the above problems, a washing water pumping device as shown in FIG. 3 was invented.

Referring to FIG. 3, the washing machine pumping apparatus of the drum washing machine includes a pump housing 22 having one end connected to a bellows hose 11 connected to a tub 1 for receiving washing water, and the pump housing 22. A circulation pump 24 connected to one side, a circulation hose 24a having one end connected to the circulation pump 24 and the other end connected to the tub 1, and a drainage pump connected to the other side of the pump housing 22 (23) and a drain hose (23a) connected to one end of the drain pump (23).

In the drum washing machine having such a structure, when a user inputs washing instructions by pressing a button on the control panel after inputting laundry to the drum 2, a water supply valve (not shown) is opened and water used for washing opens the detergent container. Through the tub (1).

Accordingly, various detergents such as washing water and fabric softener are put into the drum 2.

The detergent introduced into the drum 2 may be mixed with the washing water, but the detergent may also be collected while the detergent sinks in the bellows hose 11 connected to the tub 1 or communicating with the tub 1.

When the washing cycle of the washing machine is prepared as described above, the washing cycle for rotating the drum 2 is started, and the circulation pump 24 installed on one side of the pump housing 22 is operated.

A predetermined pressure is generated in the pump housing 22 by the rotation of the circulation pump 24, and the washing water flowing into the pump housing 22 by the pressure is supplied to the tub 1 through the circulation hose 24a. Circulate the wash water by supplying the wash water.

That is, the washing water of the tub 1 flows into the pump housing 22 through the bellows hose 11 as shown in the direction of the dotted arrow in FIG. 3, and the washing water of the pump housing 22 uses a circulation hose 24a. Through the tub (1).

Since the detergent precipitated in the bellows hose 11 as the washing water flows flows along the washing water, all the detergents introduced into the tub 1 are used to wash the laundry.

Therefore, even if a smaller amount of detergent is added to the tub 1, the same washing power can be obtained, and thus water pollution due to the detergent can be somewhat reduced.

However, in the conventional case as described above, separate motors are installed in each of the circulation pump and the drain pump. That is, in the conventional case, a motor for the circulation pump and a motor for the drainage pump were separately provided.

Therefore, in the conventional case, there has been a problem that the manufacturing cost of the washing machine increases due to the installation of a plurality of motors, and there is also a problem that the utilization of the space inside the washing machine is lowered.

The present invention was invented to solve the above problems, and an object of the present invention is to provide a pump unit of a washing machine capable of operating a circulation pump and a drainage pump using one motor.

The present invention for solving the above problems

A pump housing that forms a suction port on one side, and a first discharge port and a second discharge port spaced apart from each other, and a chamber in which a chamber communicating the suction port with the first discharge port and the second discharge port is formed inside, A first impeller rotatably disposed in the pump housing adjacent to the first discharge port, a second impeller rotatably disposed in the pump housing adjacent to the second discharge port, and facing the first impeller, and the It may include a bi-directional motor that is connected to the rotation axis of the first impeller and the rotation axis of the second impeller.

In addition, when the bidirectional motor rotates in the first direction, the fluid introduced into the pump housing is discharged only through the first discharge port, or discharged through the first discharge port and the second discharge port, and the motor is opposite to the first direction. When rotating in two directions, the fluid flowing into the pump housing can be discharged only through the second discharge port.

In addition, the pump housing, the suction chamber formed adjacent to the suction port in communication with the suction port, and formed in communication with the suction chamber, the common chamber formed between the first and second impellers, and the common It is formed on the side of the first impeller in communication with the chamber, and the first discharge chamber in communication with the first discharge port and the second discharge in communication with the second discharge port, formed on the side of the second impeller in communication with the common chamber It may include a chamber.

In addition, the first discharge chamber, the common chamber and the second discharge chamber are formed side by side along the rotation axis direction of the bidirectional motor, and the suction chamber may be formed in a direction perpendicular to the rotation axis direction of the bidirectional motor. .

In addition, the pump housing, a suction pipe extending outwardly to communicate with the suction port, a first discharge pipe extending outwardly to communicate with the first discharge port, and a second discharge extending outwardly to communicate with the second discharge port It may contain a coffin.

In addition, the first impeller and the second impeller may have the same shape.

In addition, the first impeller may be provided as the impeller for the friction pump, the second impeller.

In addition, the first impeller and the second impeller can transmit fluid only when rotating in one direction.

In addition, when the bidirectional motor rotates in the first direction, fluid is transmitted only from the first impeller to the first discharge port. When the bidirectional motor rotates in the second direction, fluid is transmitted only from the second impeller to the second discharge port side. Can be.

In addition, the first impeller and the second impeller include a disk-shaped first disk, a circular first rotor protruding from the center of one surface of the first disk to one side, and an outer peripheral surface of the first rotor, in a circumferential direction It may include a groove formed at equal intervals.

In addition, the first impeller and the second impeller may be provided in different forms.

In addition, the first impeller may be provided as an impeller for a friction pump, and the second impeller may be provided as an impeller for a centrifugal pump.

In addition, the first impeller is capable of delivering fluid only when rotating in one direction, and the second impeller is capable of sending fluid even when rotating in one direction and in two directions opposite to one direction.

In addition, when the bidirectional motor rotates in the first direction, fluid is delivered from the first impeller to the first discharge port, and at the same time, the fluid is also sent from the second impeller toward the second discharge port, and when the bidirectional motor rotates in the second direction, The fluid can be discharged only from the second impeller to the second discharge port.

In addition, the second impeller is a disc-shaped second disc, a second rotor of a circular shape protruding to one side from the center of one surface of the second disc, and formed on one surface of the second disc, the circumference of the second rotor It is disposed at equal intervals along the direction, and may include a passage portion having a spiral shape.

In addition, the first discharge port and the second discharge port may be opened in the tangential direction of the first impeller and the second impeller, respectively.

According to the proposed invention, it is possible to operate the circulation pump and the drainage pump using one motor.

In addition, the circulation pump is operated during the washing process in which the drum is rotated by the motor to circulate the washing water to the upper portion of the drum.

In addition, the manufacturing cost of the washing machine is reduced by using a single motor, and the utilization of the space inside the washing machine may be increased.

1 is a block diagram showing the structure of a conventional drum washing machine.
2 to 3 is a block diagram showing the structure of a pump unit of a conventional washing machine.
4 is a perspective view of a pump unit of a washing machine according to the present invention.
5 is an exploded perspective view of the pump unit with the outer cover removed.
6 to 7 are front views showing various embodiments of the impeller.
8 to 9 are perspective views showing an embodiment in which the first impeller and the second impeller are configured in the same form.
10 to 11 are perspective views illustrating an embodiment in which the first impeller and the second impeller are configured in different forms.

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

In the following description, the washing machine to which the pump unit of the present invention is applied will be described as an example of a drum washing machine. However, the scope of application of the present invention is not limited to a drum washing machine, and the pump unit according to the present invention can be applied to a variety of known washing machines.

In general, the drum washing machine, the main body forming the outer shape, the tub fixed by a damper inside the body, the drum is installed in the tub into which laundry is charged, the motor for rotating the drum and the washing water forcibly And a pumping unit for pumping.

In addition, the pumping unit may include a circulation pump and a drainage pump.

When the drain pump is operated, the washing water discharged from the tub passes through the drain pump and is then drained to the outside of the washing machine. On the other hand, when the circulation pump is operated, the washing water discharged from the tub may be re-supplied into the tub after passing through the circulation pump.

The pumping unit may include one inlet and two outlets.

The washing water discharged from the tub is introduced through the one inlet. Then, one of the two outlets is connected to the pipe extending toward the tub side, and the other one is connected to the pipe extending outside the washing machine.

In the conventional case, separate motors are installed in each of the circulation pump and the drain pump. That is, in the conventional case, the motor for the circulation pump and the motor for the drainage pump are separately provided.

And, when the circulation pump is operated, only the motor for the circulation pump is driven, and when the drain pump is operated, only the motor for the drain pump is driven.

Therefore, in the conventional case, there is a problem in that the manufacturing cost of the washing machine increases as a plurality of motors are installed, and there is also a problem that the utilization of the space inside the washing machine is lowered.

On the other hand, in the present invention, it is possible to drive the drain pump and the circulation pump at the same time with one motor. In detail, in the case of the present invention, while rotating one motor in both directions, a discharge pump or a circulation pump is selectively operated according to the rotational direction, and a structure in which the discharge position of washing water is changed is implemented.

For example, when the bidirectional motor rotates to one side, the washing water flowing into the pump unit may be discharged outside the washing machine. Then, when the bidirectional motor rotates to the other side, the washing water flowing into the pump unit may be re-supplied to the tub side.

According to this, there is an advantage that the discharge direction of the washing water flowing into the pump unit can be easily changed with only one motor.

Hereinafter, the pump unit of the washing machine according to the present invention will be described with reference to the drawings.

4 is a perspective view of a pump unit of a washing machine according to the present invention. 5 is an exploded perspective view of the pump unit with the outer cover removed. 6 to 7 are front views showing various embodiments of the impeller.

4 to 7, the pump unit according to the present invention includes a pump housing 100, a first impeller 210 and a second impeller 220 disposed opposite each other, and a bidirectional motor 300. It can contain.

First, the pump housing 100 forms one suction port 101 on one side, and forms a first discharge port 102 and a second discharge port 103 spaced apart from each other, and the suction port 101 inside ) And a chamber communicating the first discharge port 102 and the second discharge port 103 is formed.

In addition, the first impeller 210 is rotatably disposed in the pump housing 100 adjacent to the first discharge port 102.

In addition, the second impeller 220 is rotatably disposed in the pump housing 100 adjacent to the second discharge port 103, and is disposed to face the first impeller 210. Here, the meaning that the first impeller 210 and the second impeller 220 are disposed to face each other may mean that the surfaces on which the wings of the first impeller 210 and the second impeller 220 are formed face each other. . That is, it may mean that the surfaces on which the wings of the first impeller 210 and the second impeller 220 are formed are disposed toward the center side.

The first impeller 210 and the second impeller 220 may be applied to a variety of known impellers in a range capable of delivering fluid.

The two-way motor 300 is capable of rotating in both directions in the forward and reverse directions, and is connected to the rotation shaft 211 of the first impeller 210 and the rotation shaft 221 of the second impeller 220, while rotating, the first impeller The 210 and the second impeller 220 are rotated.

The rotating shaft 310 of the bidirectional motor 300, the rotating shaft 211 of the first impeller 210, and the rotating shaft 221 of the second impeller 220 are disposed on a straight line and are axially coupled. Accordingly, when the bidirectional motor 300 rotates, the first impeller 210 and the second impeller 220 axially coupled to the bidirectional motor 300 rotate together.

At this time, the first impeller 210 and the second impeller 220 are facing each other.

Therefore, when the bidirectional motor 300 rotates in one direction, the first impeller 210 rotates in one direction when viewed in the axial direction. In detail, when viewed from right to left based on FIG. 5, the first impeller 210 rotates in one direction. That is, when the first impeller 210 is viewed from the front, the first impeller 210 rotates in one direction.

However, the second impeller 220 rotates in this direction as opposed to one direction when viewed in the axial direction. In detail, when viewed from left to right based on FIG. 5, the second impeller 220 rotates in this direction opposite to one direction. That is, when the second impeller 220 is viewed from the front, the second impeller 220 rotates in this direction opposite to one direction.

As described above, when the first impeller 210 and the second impeller 220 are symmetrically arranged, when the bidirectional motor 300 rotates in the first direction (forward, counterclockwise with reference to FIG. 6), the pump The fluid introduced into the housing 100 may be discharged only through the first discharge port 102. In addition, when the bi-directional motor 300 rotates in a second direction (reverse direction, clockwise reference with reference to FIG. 6) opposite to the first direction, the fluid flowing into the pump housing 100 is transferred only to the second discharge port 103. Can be discharged.

In addition, depending on the type of the first impeller 210 and the second impeller 220, when the bidirectional motor 300 rotates in the first direction (forward, counterclockwise with reference to FIG. 6), the pump housing 100 ) May be discharged to the first discharge port 102 and the second discharge port 103.

The pump housing 100 may be composed of an inner cover 100a and an outer cover 100b. The inner cover 100a is disposed inside the outer cover 100b. That is, the outer cover 100b covers the inner cover 100a.

The pump housing 100 shown in FIG. 4 is an outer cover 100b, and the pump housing 100 shown in FIG. 5 is an inner cover 100a.

The pump housing 100 is formed in communication with the suction port 101 and the suction chamber 110 formed adjacent to the suction port 101 and the suction chamber 110, and the first impeller ( 210) and the second impeller 220 is formed between the common chamber 120 and the common chamber 120, the first impeller 210 is formed in communication with the first discharge port 102 and the communication The first discharge chamber 130 and the common chamber 120 to communicate with the second impeller 220 is formed on the side, and includes a second discharge chamber 140 in communication with the second discharge port 103 Can be.

A communication hole may be formed between the suction chamber 110 and the common chamber 120. In addition, a communication hole may be formed between the common chamber 120 and the first discharge chamber 130 and between the common chamber 120 and the second discharge chamber 140. Each of the communication holes may be formed in the inner chamber 100a.

At this time, the common chamber 120, the first discharge chamber 130, the second discharge chamber 140 is defined by the inner cover (100a) and the outer cover (100b), the suction chamber 110 is the outer cover ( 100b).

The inner cover 100a may serve to divide the common chamber 120, the first discharge chamber 130, and the second discharge chamber 140 from the inside of the outer cover 100b. In addition, the inner cover 100a may function as an impeller cover that covers the first impeller 210 and the second impeller 220 from the inner side of the outer cover 100b.

In addition, the first discharge chamber 130, the common chamber 120 and the second discharge chamber 140 are formed side by side along the rotation axis direction of the bidirectional motor 300, the suction chamber 110 is It may be formed in a direction perpendicular to the direction of the rotation axis of the bidirectional motor 300.

In addition, the pump housing 100, the suction pipe 104 extending outwardly to communicate with the suction port 101, and the first discharge pipe 105 extended outwardly to communicate with the first discharge port 102 , A second discharge pipe 106 extending outwardly to communicate with the second discharge port 103 may be included.

Therefore, the washing water discharged from the tub is introduced into the suction chamber 110 through separate pipes, through the suction pipe 104 and the suction port 101. Thereafter, the first discharge chamber 130 and the second discharge chamber 140 are introduced through the common chamber 120 in communication with the suction chamber 110. And, by the rotation of the first impeller 210 and the second impeller 220, the first discharge port 102 and the first discharge pipe 105 is discharged, or the second discharge port 103 and the second discharge pipe ( 106).

For example, the washing water discharged through the first discharge port 102 and the first discharge pipe 105 may be re-supplied inside the tub, and the washing discharged through the second discharge port 103 and the second discharge pipe 106 The water can be drained out of the washing machine.

As another example, the washing water discharged through the first discharge port 102 and the first discharge pipe 105 may be drained outside the washing machine, and the washing water discharged through the second discharge port 103 and the second discharge pipe 106 Can be fed back into the tub.

Meanwhile, the suction pipe 104, the first discharge pipe 105, and the second discharge pipe 106 may be formed in the outer cover 100b.

In addition, the suction pipe 104 may be formed in parallel with the rotation axis of the bidirectional motor 300. In addition, the first and second discharge pipes 105 and 106 may be formed perpendicular to the rotational axis of the bidirectional motor 300.

8 to 9 are perspective views showing an embodiment in which the first impeller and the second impeller are configured in the same form.

8 to 9, the first impeller 210 and the second impeller 220 may have the same shape. In addition, the first impeller 210 and the second impeller 220 may be provided with the same size.

For example, the first impeller 210 and the second impeller 220 may be provided as an impeller for a friction pump.

For reference, a friction pump is another name for a vortex pump, also called a wesco pump or a cascade pump. A friction pump refers to a pump in which a rotor with many grooves at the edges rotates on the highway, and pressure is generated and transmitted by frictional energy with the casing main wall.

In addition, the first impeller 210 and the second impeller 220 can transmit fluid only when rotating in one direction.

For example, the first impeller 210 and the second impeller 220 may not transmit fluid when rotating in the forward direction and may not transmit fluid when rotating in the reverse direction.

In addition, when the bi-directional motor 300 rotates in the first direction, fluid is transmitted only from the first impeller 210 to the first discharge port 102, and the bi-directional motor 300 is opposite to the first direction. When rotating in the two directions, the fluid can be sent only from the second impeller 220 to the second discharge port 103.

Therefore, when the bidirectional motor 300 rotates in one direction (counterclockwise in FIG. 8), the fluid introduced into the pump housing 100 is firstly discharged by the first impeller 210 and the first discharge port 102 and the first, respectively. It can be discharged only through the discharge pipe 105. At this time, fluid discharge does not proceed to the second discharge port 103 and the second discharge pipe 106.

In addition, when the bi-directional motor 300 rotates in this direction (clockwise direction in FIG. 9) opposite to one direction, the fluid flowing into the pump housing 100 is driven by the second impeller 220 and the second discharge port 103. ) And the second discharge pipe 106 only. At this time, fluid discharge does not proceed to the first discharge port 102 and the first discharge pipe 105.

In addition, the first impeller 210 and the second impeller 220 are disc-shaped first discs 201 and a circular first rotor projecting to one side from the center of one surface of the first disc 201. 202 and groove portions 203 formed at equal intervals along the circumferential direction on the outer circumferential surface of the first rotor 202.

In addition, the groove portion 203 may be defined by a plurality of protrusions 204 formed at equal intervals along the circumferential direction on the outer circumferential surface of the first rotor 202.

The protrusion 204 has a shape protruding from one surface of the first disk 201 to one side. The protrusion 204 is a plane 204a on one side, and the other side may form an inclined surface 204b. In addition, the inclined surface 204b may be formed to be round in the circumferential direction to form a curved surface. In addition, one side of the inclined surface 204b may start around the first disk 201, and the other side of the inclined surface 204b may end around the first rotor 202. That is, when viewed from the axial direction, at least a portion of the inclined surface 204b may be curved.

10 to 11 are perspective views illustrating an embodiment in which the first impeller and the second impeller are configured in different forms.

10 to 11, the first impeller 210 and the second impeller 220 may be provided in different forms.

For example, the first impeller 210 'may be provided as an impeller for a friction pump, and the second impeller 220' may be provided as an impeller for a centrifugal pump. In particular, the second impeller 220 ′ may be provided as an impeller for a two-way centrifugal pump.

Conversely, the first impeller 210 'may be provided as an impeller for a centrifugal pump, and the second impeller 220' may be provided as an impeller for a friction pump.

Centrifugal pump (centrifugal pump) refers to a pump that raises water from a low to a high place by rotating the impeller in a filled casing to generate pressure by applying centrifugal force to water.

In addition, the first impeller 210 ′ provided as an impeller for a friction pump sends fluid only when rotating in one direction. And, the first impeller 210 'provided as an impeller for a friction pump does not transmit fluid when rotating in this direction opposite to one direction.

On the other hand, the second impeller 220 'provided as an impeller for the centrifugal pump sends fluid when rotating in one direction. In addition, the second impeller 220 ′ provided as an impeller for a centrifugal pump can transmit fluid even when rotating in this direction opposite to one direction.

Therefore, when the bidirectional motor 300 rotates in one direction (counterclockwise in FIG. 10), the fluid introduced into the pump housing 100 is first and second impellers 210 'and 220', respectively. It may be discharged to the first discharge port 102 and the first discharge pipe 105, the second discharge port 103 and the second discharge pipe 106.

In addition, when the bidirectional motor 300 rotates in this direction (clockwise direction in FIG. 11) opposite to one direction, the fluid flowing into the pump housing 100 is supplied by the second impeller 220 ′, and the second discharge port ( 103) and the second discharge pipe 106. At this time, fluid discharge does not proceed to the first discharge port 102 and the first discharge pipe 105.

In addition, when the bidirectional motor 300 rotates in the first direction, fluid is transmitted from the first impeller 210 'to the first discharge port 102, and at the same time, the second discharge port 103 is also provided by the second impeller 220'. When the fluid is sent to the side, and the bidirectional motor 300 rotates in the second direction, the fluid can be discharged only from the second impeller 220 'to the second discharge port 103 side.

Referring again to FIG. 7, the second impeller 220 ′ includes a disk-shaped second disk 206 and a circular second rotor protruding to one side from the center of one surface of the second disk 206. 207 and a plurality of passage portions 208 formed on one surface of the second disk 206, disposed at equal intervals along the circumferential direction of the second rotor 207, and having a spiral shape. .

The passage portion 208 is disposed at equal intervals along the circumferential direction of the second rotor 207 and may be defined by a plurality of guide portions 209 having a spiral shape.

The guide part 209 has a shape protruding from one surface of the second disk 206 to one side. When viewed in the axial direction, the guide portion 209 is formed in a spiral shape and may extend from an outer peripheral surface of the second rotor 207 to an outer peripheral surface of the second disk 206.

In addition, the first impeller 210 ′ includes a disc-shaped first disc 201 and a circular first rotor 202 protruding from the center of one surface of the first disc 201 to one side. On the outer circumferential surface of the first rotor 202, a groove portion 203 formed at equal intervals along the circumferential direction may be included.

In addition, the groove portion 203 may be defined by a plurality of protrusions 204 formed at equal intervals along the circumferential direction on the outer circumferential surface of the first rotor 202.

The protrusion 204 has a shape protruding from one surface of the first disk 201 to one side. The protrusion 204 is a plane 204a on one side, and the other side may form an inclined surface 204b. In addition, the inclined surface 204b may be formed to be round in the circumferential direction to form a curved surface. In addition, one side of the inclined surface 204b may start around the first disk 201, and the other side of the inclined surface 204b may end around the first rotor 202. That is, when viewed from the axial direction, at least a portion of the inclined surface 204b may be curved.

In addition, the first discharge port 102 and the second discharge port 103 may be opened in a tangential direction of the first impeller 210 and the second impeller 220, respectively. Therefore, the fluid can be discharged more smoothly.

8 to 11, it can be seen that the fluid is discharged in the tangential direction of the first impeller 210 and the second impeller 220 from the first impeller 210 and the second impeller 220.

Therefore, when the first discharge port 102 and the second discharge port 103 are opened in the tangential direction of the first impeller 210 and the second impeller 220, the first impeller 210 and the second impeller 220 ) Can be smoothly discharged.

Furthermore, the first discharge pipe 105 and the second discharge pipe 106 communicating with the first discharge port 102 and the second discharge port 103 are also connected to the first impeller 210 and the second impeller 220 Direction. Therefore, the fluid discharged to the first discharge port 102 and the second discharge port 103 can flow smoothly to the first discharge pipe 105 and the second discharge pipe 106.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains may make various modifications and variations without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments.

The scope of protection of the present invention should be interpreted by the claims below, and all technical spirits within the equivalent range should be interpreted as being included in the scope of the present invention.

100: pump housing 101: inlet
102: first outlet 103: second outlet
104: suction pipe 105: first discharge pipe
106: second discharge pipe 110: suction chamber
120: common chamber 130: first discharge chamber
140: second discharge chamber 210,210 ': first impeller
220, 220 ': Second impeller 300: Bi-directional motor

Claims (15)

A pump housing which forms a suction port on one side, a first discharge port and a second discharge port spaced apart from each other, and a chamber in which a chamber communicating the suction port with the first discharge port and the second discharge port is formed;
A first impeller rotatably disposed in the pump housing adjacent to the first discharge port;
A second impeller rotatably disposed in the pump housing adjacent to the second discharge port, and facing the first impeller; And
It is connected to the rotating shaft of the first impeller and the rotating shaft of the second impeller, and includes a bidirectional motor to rotate,
When the bidirectional motor rotates in the first direction, the fluid flowing into the pump housing is discharged only to the first discharge port, or discharged to the first discharge port and the second discharge port, and the motor is opposite to the first direction in the second direction. When rotated, the fluid flowing into the pump housing is discharged only to the second discharge port, the pump unit of the washing machine.
According to claim 1,
The pump housing,
A suction chamber formed adjacent to the suction port in communication with the suction port;
A common chamber formed in communication with the suction chamber and formed between the first and second impellers;
A first discharge chamber formed on the side of the first impeller in communication with the common chamber and communicating with the first discharge port; And
A pump unit of the washing machine including a second discharge chamber formed on the side of the second impeller in communication with the common chamber and communicating with the second discharge port.
According to claim 2,
The first discharge chamber, the common chamber and the second discharge chamber are formed side by side along the rotation axis direction of the bidirectional motor,
The suction chamber is a pump unit of the washing machine is formed in a direction perpendicular to the direction of the rotation axis of the bidirectional motor.
According to claim 1,
The pump housing,
A suction pipe extending outwardly to communicate with the suction port;
A first discharge pipe extending outwardly to communicate with the first discharge port;
A pump unit of a washing machine including a second discharge pipe extending outwardly to communicate with the second discharge port.
According to claim 1,
The first impeller and the second impeller are pump units of the washing machine having the same shape.
The method of claim 5,
The first impeller is a pump unit of the washing machine, the second impeller is provided with an impeller for a friction pump.
The method of claim 5,
The first impeller and the second impeller are pump units of a washing machine that transmits fluid only when rotating in one direction.
The method of claim 5,
When the bi-directional motor rotates in the first direction, fluid is transmitted only from the first impeller to the first discharge port,
When the bi-directional motor rotates in the second direction, the pump unit of the washing machine that fluid is sent only from the second impeller to the second discharge port.
The method of claim 5,
The first impeller and the second impeller,
A disk-shaped first disc;
A circular first rotor protruding from the center of one surface of the first disk to one side;
The pump unit of the washing machine including a groove formed at equal intervals along the circumferential direction on the outer circumferential surface of the first rotor.
According to claim 1,
The first impeller and the second impeller are pump units of the washing machine provided in different forms.
The method of claim 10,
The first impeller is provided as an impeller for a friction pump, and the second impeller is a pump unit of a washing machine provided as an impeller for a centrifugal pump.
The method of claim 10,
The pump unit of the washing machine, wherein the first impeller sends fluid only when rotating in one direction, and the second impeller sends fluid even when rotating in one direction and two directions opposite to one direction.
The method of claim 10,
When the bidirectional motor rotates in the first direction, fluid is sent from the first impeller to the first discharge port, and at the same time, fluid is also sent from the second impeller toward the second discharge port.
When the bi-directional motor rotates in the second direction, the pump unit of the washing machine discharges fluid only from the second impeller to the second discharge port.
The method of claim 10,
The second impeller,
A disc-shaped second disc;
In the center of one surface of the second disk, a circular second rotor protruding to one side;
The pump unit of the washing machine, which is formed on one surface of the second disc, is disposed at equal intervals along the circumferential direction of the second rotor, and includes a passage portion having a spiral shape.
According to claim 1,
The first outlet and the second outlet respectively
A pump unit for a washing machine that opens in a tangential direction between the first and second impellers.

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