KR101735432B1 - Bi-directional pump - Google Patents

Abstract

Disclosed is a bidirectional pump. According to the present invention, the bidirectional pump comprises: a housing which comprises: an inlet through which a fluid flows in; and a first outlet and a second outlet through which the fluid is discharged; an impeller which rotates in a normal or reverse direction in the housing and transfers kinetic energy to the fluid; and a swing valve which is pressurized in the opposite direction by the kinetic energy of the fluid in the rotation direction of the impeller, and blocks the first outlet and the second outlet. According to the present invention, the bidirectional pump has no component, which hinders the movement of a fluid in between an impeller and an outlet. When a fluid is discharged through an outlet, the other outlet is automatically closed even without depending on an electronic valve. In addition, a counterflow of a fluid through an outlet is prevented.

Description

Bi-directional pump {BI-DIRECTIONAL PUMP}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bidirectional pump, and more particularly, to a bidirectional pump that does not require a structure for preventing fluid movement between an impeller and a discharge port, The discharge port is automatically closed, and the backflow of the fluid through the discharge port is prevented.

Equipment requiring water circulation, such as washing machines and dishwashers, must change the water supply direction according to the operation modes such as drainage operation and circulation operation. In general, two pumps are installed in the washing machine to change the water supply direction according to the operation mode, and a technique of switching the water supply direction by a single pump has been studied.

In this respect, the bi-directional pump structure is disclosed in Korean Utility Model Publication No. 1998-062744, and in the Utility Model No. 1998-062744, an inlet is formed at the center in the axial direction, An impeller installed inside the casing, a motor for rotating and rotating the impeller, a first passage formed on both sides of the impeller in the space around the impeller, and a second passage formed on both sides of the impeller, and a second passage A partition wall separating both outflow ports is formed in a central portion of the outflow pipe, and when water flows out through the first passage or the second passage, some water flows strongly toward the second passage or the first passage on the opposite side, And the water curtain passage is formed in the partition wall.

However, in the bidirectional pump disclosed in the Utility Model Publication 1998-062744, kinetic energy is received by the rotation of the impeller as the partition occupies a substantial portion of the space between the impeller and the first passage and the second passage, A considerable number of water moving toward the passage is obstructed by the partition wall and flows into the impeller again, resulting in a low discharge efficiency of water.

In addition, in the bi-directional pump disclosed in Korean Utility Model Publication No. 1998-062744, since the first passage and the second passage always communicate with the inside of the casing, in the process of discharging water through the first passage (due to a failure or the like) When the water flows back into the casing from the passage, the backflowed water is discharged through the first passage. In equipment where cleanliness is required, such as washing machines or dishwashers, backflow of contaminated water is perceived as a fatal flaw in the device.

On the other hand, there is also a technique in which an electromagnetic valve is provided for each flow path to selectively open and close the flow path to switch the water supply direction or to prevent reverse flow, but the price of the device is increased by the expensive electronic valve, If there is a malfunction, there is a defect that can not prevent backflow of polluted water.

(0001) Korean Utility Model Publication No. 1998-062744 (published on November 16, 1998)

It is an object of the present invention to provide an air conditioner in which a discharge port is automatically closed when a fluid is discharged through one discharge port without depending on an electromagnetic valve without forming a structure for obstructing the movement of fluid between the impeller and the discharge port, To prevent reverse flow of the fluid through the fluid passage.

According to an aspect of the present invention, there is provided a fluid ejecting apparatus comprising: a housing having an inlet through which fluid flows, a first outlet through which fluid is discharged, and a second outlet; An impeller that rotates in a forward direction or a reverse direction inside the housing to transmit kinetic energy to the fluid; And a swing valve that is pressed in opposite directions to each other by the kinetic energy of the fluid in accordance with the rotational direction of the impeller to block the first discharge port or the second discharge port.

Wherein the swing valve includes: a hinge portion rotatably coupled between the first discharge port and the second discharge port in the housing; A first cover extending from the hinge portion and closing the first discharge port when the impeller is rotated forward; And a second cover extending from the hinge portion and closing the second discharge port when the impeller is rotated in the reverse direction.

A first contact surface to which the first cover is closely contacted is formed at an edge of the first discharge port in the housing, and a second contact surface to which the second cover is closely attached is formed at an edge of the second discharge hole in the housing, Can be formed.

Wherein the first contact surface is provided with a first electromagnet which is magnetized when the impeller rotates in the forward direction and forms a coupling force with the first cover, And a second electromagnet which is magnetized and forms a coupling force with the second cover.

Wherein each of the opposite surfaces of the first cover and the second cover is provided with a torsion spring for preventing the kinetic energy of the fluid caused by the first and second contact surfaces from being reduced, 2 cover member to be pressed toward the inner wall of the discharge port is formed.

According to the present invention, since the swing valve blocks the first discharge port or the second discharge port in accordance with the rotating direction of the impeller, a configuration for preventing the fluid from moving between the impeller and the discharge port is not formed, It is possible to provide a bi-directional pump in which, when the fluid is discharged through the discharge port of the discharge port, the other discharge port is automatically closed and the back flow of the fluid through the discharge port is prevented.

1 and 2 are cross-sectional views of an bidirectional pump in accordance with an embodiment of the present invention.
FIG. 3 and FIG. 4 are cross-sectional views showing the use state of the bidirectional pump of FIG. 1;
5 is a partial cross-sectional view of an bidirectional pump in accordance with another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, the well-known functions or constructions are not described in order to simplify the gist of the present invention.

INDUSTRIAL APPLICABILITY The bidirectional pump of the present invention is characterized in that, when a fluid is discharged through one discharge port without depending on an electromagnetic valve, a discharge port is automatically closed without forming a structure that interferes with the movement of fluid between the impeller and the discharge port, So that backflow of the fluid through the discharge port is prevented.

FIG. 5 is a perspective view of a bidirectional pump according to another embodiment of the present invention. FIG. 5 is a cross-sectional view of a bidirectional pump according to another embodiment of the present invention. Fig.

1 to 4, the bidirectional pump 10 according to an embodiment of the present invention does not have a structure for preventing fluid movement between the impeller 200 and the discharge ports 110 and 120, When the fluid is discharged through one discharge port 110 or 120 without depending on the valve, the other discharge port 110 or 120 is automatically closed to prevent the back flow of the fluid through the discharge ports 110 and 120, 100, an impeller 200, and a swing valve 300.

1 and 2, the housing 100 includes an upper housing 140 and a lower housing 150. The impeller 200 is rotatably installed inside the housing 100. As shown in FIG. The upper housing 140 and the lower housing 150 may be manufactured in various forms in addition to the accuracy of manufacture and assembly of the bidirectional pump 10, ease of repair, and the like.

The impeller 200 is configured to transmit kinetic energy to the fluid, and rotates in the forward direction or the reverse direction inside the housing 100 to pressurize the fluid. 4, the reverse rotation of the impeller 200 means the rotation direction (clockwise direction) shown in FIG.

In FIG. 1, the impeller 200 is shown as a turbine type, but it may be provided in a rotating type or a propeller type. However, since the bidirectional pump 10 of the present invention is configured to transmit kinetic energy to the fluid during the forward rotation and the reverse rotation of the impeller 200, the guide blades are not inclined to either side, And is formed in a shape parallel to the rotation axis of the rotor.

As shown in FIG. 1, the impeller 200 is rotated by the rotational force of the motor M. The impeller 200 may be directly connected to the motor M, and may receive rotational force by a belt and a pulley.

The bidirectional pump 10 of the present invention is installed in a washing machine, a dishwasher, or the like, and the motor M is rotated in the forward direction or the reverse direction under the control of the control unit.

When the user operates the washing machine or dishwasher by operating an operation panel (not shown) formed in the washing machine or the dishwasher, the controller of the washing machine or dishwasher performs one or more operation modes (drain operation, circulation operation, Thereby controlling the pump 10. 3, the fluid is discharged through the second discharge port 120 during the circulation operation (see FIG. 4). In the discharge operation, the fluid is discharged through the first discharge port 110,

1 and 2, an inlet 130, a first outlet 110, and a second outlet 120 are formed in the housing 100.

The inlet 130 is a conduit through which the fluid flows, and is formed in a direction parallel to the axis of rotation of the impeller 200. The first discharge port 110 and the second discharge port 120 are respectively formed in a direction perpendicular to the rotational axis of the impeller 200,

The fluid introduced through the inlet 130 receives kinetic energy by the centrifugal force of the rotating impeller 200 and moves toward the first outlet 110 or the second outlet 120. 4). When the impeller 200 is rotated in the reverse direction (draining operation), the fluid is discharged from the first discharge port 110 (see FIG. 4) (See Fig. 3)

1 and 2, the swing valve 300 is configured to open or close the first discharge port 110 or the second discharge port 120 by being pressed by the kinetic energy of the fluid, and the hinge portion 330, A first cover 310, and a second cover 320. As shown in FIG.

The hinge portion 330 is rotatably coupled between the first discharge port 110 and the second discharge port 120 in the housing 100. The hinge portion 330 is rotatably engaged with the housing 100 by a pin P. [ Although not shown in detail, the hinge portion 330 is formed with a through hole into which the pin P is inserted, and the housing 100 is formed with an insertion hole into which the both ends of the pin P are respectively inserted.

The first cover 310 is configured to block or open the first discharge port 110 and is formed in a plate shape having a constant area. The second cover 320 is formed in a plate shape having a constant area as a structure for blocking or opening the second discharge port 120.

As shown in FIG. 2, the first cover 310 and the second cover 320 extend in different directions from the hinge 330 to form a constant angle.

The first cover 310 and the second cover 320 are pressed by the kinetic energy of the fluid when the impeller 200 rotates and rotate around the hinge part 330. The center of gravity of the swing valve 300 is positioned below the hinge portion 330 by gravity when the impeller 200 is not rotated.

3, the impeller 200 rotates clockwise in the reverse direction, that is, in the illustrated state, by the rotational force of the motor M during the drainage operation.

The fluid introduced into the housing 100 through the inlet port 130 moves clockwise by the urging force of the impeller 200 and the left and right sides of the first cover 310 and the second cover 320 Kinetic energy is transmitted.

Accordingly, the swing valve 300 rotates in the counterclockwise direction about the hinge part 330 by the kinetic energy of the fluid, and the second cover 320 closes the second discharge port 120. As shown in FIG. 3, a second contact surface 121, to which the second cover 320 is closely attached, is formed at the edge of the second discharge port 120 in the housing 100.

The fluid is restricted from moving toward the second discharge port 120 by the first cover 310 and discharged through the first discharge port 110 while the second cover 320 covers the second discharge port 120.

4, the impeller 200 rotates counterclockwise in the forward direction, that is, the illustrated state, by the rotational force of the motor M in the circulating operation.

The fluid introduced into the housing 100 through the inlet 130 moves in the counterclockwise direction due to the urging force of the impeller 200 and the fluid is supplied to the right side of the first cover 310 and the second cover 320, The kinetic energy of the magnetism is transmitted.

Accordingly, the swing valve 300 is rotated in the clockwise direction around the hinge part 330 by the kinetic energy of the fluid, and the first cover 310 closes the first discharge port 110. As shown in FIG. 4, a first contact surface 111 to which the first cover 310 is closely attached is formed at the edge of the first discharge port 110 in the housing 100.

The fluid is restricted from moving toward the first discharge port 110 by the second cover 320 while the first cover 310 covers the first discharge port 110 and is discharged through the second discharge port 120.

As shown in FIG. 5, the bi-directional pump 20 according to another embodiment of the present invention may be further provided with a structure for increasing the discharge efficiency of the fluid.

The first contact surface 111 is provided with a first electromagnet S1 which is magnetized when the impeller 200 rotates in the forward direction to form a coupling force with the first cover 310, A second electromagnet S2 which is magnetized in the reverse rotation of the impeller 200 and forms a coupling force with the second cover 320 may be installed on the surface 121. [

The first electromagnet S1 and the second electromagnet S2 are provided as a solenoid. The solenoid is made by winding a coil around a cylindrical iron core. When a current is applied to a coil wound in a cylindrical shape, a magnetic field is formed, and a strong magnetic field is formed when an iron core is inserted into the coil.

The control unit supplies current to the coils of the first electromagnet S1 or the second electromagnet S2 according to the rotational direction of the impeller 200. [

As shown in FIG. 5, the control unit rotates the impeller 200 in the reverse direction and supplies current to the coil of the second electromagnet S2 during the drain operation.

The swing valve 300 rotates in the counterclockwise direction about the hinge part 330 by the kinetic energy of the fluid and the second cover 320 rotates about the second discharge port 120 . Therefore, when the second electromagnet S2 is magnetized in the drain operation, the second electromagnet S2 forms a coupling force with the second cover 320, so that the second cover 320 is firmly attached to the second contact surface 121 Thereby maintaining a close contact state.

When the second cover 320 is formed of a semi-magnetic material such as synthetic resin, a ferromagnetic material such as steel is bonded to a position of the second cover 320 contacting the second electromagnet S2.

In the bidirectional pump disclosed in Korean Utility Model Publication No. 1998-062744, since the first passage and the second passage always communicate with the inside of the casing, in the process of discharging water through the first passage (due to a failure or the like) When the water flows back into the casing, there is a problem that the backflowed water is discharged through the first passage. In equipment where cleanliness is required, such as washing machines or dishwashers, backflow of contaminated water is perceived as a fatal flaw in the device.

The bidirectional pump 20 according to another embodiment of the present invention is configured such that the second discharge port 120 is closely contacted with the second cover 320 by the second electromagnet S2 while the fluid is discharged to the first discharge port 110 So that even if a backward flow of fluid occurs at the second outlet 120 while the fluid is being discharged to the first outlet 110, the backward flow fluid is directly introduced into the housing 100, The phenomenon of being discharged to the discharge port 110 is prevented.

During the circulating operation, the control unit rotates the impeller 200 in the forward direction and simultaneously supplies current to the coil of the first electromagnet S1. When the first cover 310 is formed of a semi-magnetic material such as synthetic resin, a ferromagnetic material such as steel is bonded to a portion of the first cover 310 which contacts the first electromagnet S1.

Although not shown in detail, the first discharge port 110 is kept in close contact with the first cover 310 by the first electromagnet S1 while the fluid is being discharged to the second discharge port 120, 2, even if backflow of the fluid occurs in the first discharge port 110 while being discharged to the discharge port 120, the backflowed fluid is prevented from being introduced into the housing 100 and discharged to the second discharge port 120.

5, the first cover 310 and the second cover 320 are respectively provided with the torsion springs TS on the opposite sides of the first discharge port 110 and the second discharge port 120 A cover member C to be pressed toward the inner wall can be formed.

5, when the first contact surface 111 is formed along the edge of the first discharge port 110, when the fluid enters the first discharge port 110 during the reverse rotation of the impeller 200, It may strike the first contact surface 111 and cause a decrease in kinetic energy.

The fluid which has been guided to the first discharge port 110 along the left side surface of the first cover 310 hits the first close contact surface 111 adjacent to the hinge portion 330 before entering the first discharge port 110 Kinetic energy can be greatly reduced.

When the cover member C is formed on each of opposite surfaces of the first cover 310 and the second cover 320, the fluid that is guided to the first discharge port 110 along the left surface of the first cover 310 The cover member C does not enter the first contact surface 111 adjacent to the hinge portion 330 and is turned toward the first discharge port 110 by the cover member C so that loss of kinetic energy is prevented.

The fluid that has been guided to the second discharge port 120 along the right side surface of the second cover 320 is discharged through the second discharge port 120 in the forward direction of the impeller 200, The cover member C does not enter the second contact surface 121 adjacent to the hinge portion 330 and the direction of the cover member C is switched to the second discharge port 120 so that loss of kinetic energy is prevented.

As shown in FIG. 5, a reinforcing rib 340 may be formed between the first cover 310 and the second cover 320. When the reinforcing rib 340 connects the first cover 310 and the second cover 320 to each other, not only the deformation of the first cover 310 and the second cover 320 is prevented, 1 vibration of the cover 310 and the second cover 320 and thus noise generation is suppressed.

According to the present invention, since the swing valve blocks the first discharge port or the second discharge port in accordance with the rotating direction of the impeller, a configuration for preventing the fluid from moving between the impeller and the discharge port is not formed, It is possible to provide a bi-directional pump in which, when the fluid is discharged through the discharge port of the discharge port, the other discharge port is automatically closed and the back flow of the fluid through the discharge port is prevented.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious to those who have. Accordingly, it should be understood that such modifications or alterations should not be understood individually from the technical spirit and viewpoint of the present invention, and that modified embodiments fall within the scope of the claims of the present invention.

10,20: Bi-directional pump
100: housing 200: impeller
110: first discharge port 300: swing valve
111: first contact surface 310: first cover
S1: first electromagnet 320: second cover
120: second discharge port 330: hinge part
121: second contact surface 340: reinforcing rib
S2: second electromagnet C: cover member
130: inlet TS: torsion spring
140: upper housing M: motor
150: Lower housing

Claims (5)

A housing having an inlet through which the fluid flows, a first outlet through which the fluid is discharged, and a second outlet; An impeller that rotates in a forward direction or a reverse direction inside the housing to transmit kinetic energy to the fluid; And a swing valve which is pressed in directions opposite to each other by the kinetic energy of the fluid in accordance with the rotational direction of the impeller to block the first discharge port or the second discharge port,
Wherein the swing valve includes: a hinge portion rotatably coupled between the first discharge port and the second discharge port in the housing; A first cover extending from the hinge portion and closing the first discharge port when the impeller is rotated forward; And a second cover extending from the hinge portion and blocking the second discharge port in the reverse rotation of the impeller,
A first contact surface to which the first cover is closely contacted is formed at an edge of the first discharge port in the housing, and a second contact surface to which the second cover is closely attached is formed at an edge of the second discharge port in the housing, Is formed,
Wherein each of the opposite surfaces of the first cover and the second cover is provided with a torsion spring for preventing the kinetic energy of the fluid caused by the first and second contact surfaces from being reduced, (2) A cover member is formed which is pressed toward the inner wall of the discharge port. delete delete The method according to claim 1,
Wherein the first contact surface is provided with a first electromagnet which is magnetized when the impeller rotates in the forward direction and forms a coupling force with the first cover,
Wherein the second contact surface is provided with a second electromagnet which is magnetized when the impeller is rotated in the reverse direction and forms a coupling force with the second cover. delete

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