KR20110031934A - Easily-drainable dehumidifier - Google Patents

Abstract

PURPOSE: An easily drainable dehumidifier is provided to automatically or manually discharge the water from a water tank depending on the installed state or position of the dehumidifier. CONSTITUTION: An easily drainable dehumidifier comprises a case, a dehumidifying unit, a water tank(100), a connecting member(200), a drain pump(P), a first valve(108), and a second valve(208). The case comprises an air intake port and an air discharge port. The dehumidifying unit removes the moisture from the air, which flows into through the air intake port, and discharges the dry air to the air discharge port. The water from the dehumidifying unit is stored in the water tank. A connecting part(102) with a discharge hole(104) is formed on one side of the water tank. The connecting member comprises a connecting part(202), which is detachably connected to the connecting part of the water tank.

Description

Easy-to-drain dehumidifiers {EASILY-DRAINABLE DEHUMIDIFIER}

The present invention relates to a dehumidifier, and more particularly, to a drain easy dehumidifier configured to automatically or manually select and discharge water stored in a dehumidifier reservoir.

In general, the dehumidifier is a device for removing moisture contained in the air, and is manufactured using various dehumidification methods.

In most cases, a dehumidifier is a cooling dehumidifier that removes moisture by condensing moisture in the air when the air passes through an evaporator using a refrigeration cycle.

The dehumidifier has a case forming an external appearance, a fan installed inside the case to suck external air, dehumidifying means for condensing moisture contained in the sucked air to remove moisture, and water dehumidified by the dehumidifying means. It consists of a reservoir to be stored.

The dehumidification means includes a compressor for compressing a gaseous refrigerant at a high temperature and a high pressure, a condenser for condensing the high temperature and high pressure refrigerant gas discharged from the compressor, and a low pressure refrigerant passing through a capillary tube (expansion tube) through the condenser. It is composed of an evaporator to evaporate.

Such dehumidifiers are configured such that the refrigerant is circulated from the evaporator through the compressor to the evaporator through the condenser and capillary. At this time, when the air is sucked into the case by the rotation of the fan, the sucked air passes through the evaporator is cooled to below the dew point by the refrigerant and condensed, the moisture contained in the air is condensed with dew.

Removed moisture drops and flows into the reservoir, which must be discharged to the outside when the reservoir is filled with water.

A method for discharging the water stored in the dehumidifier's reservoir, by separating the reservoir installed inside the dehumidifier and manually discharging the water, or by installing a drain pump connected to the reservoir to operate the drain pump to operate the water in the reservoir. To discharge the water to the outside, or to discharge the water by the operation of the drain pump installed inside the dehumidifier.

However, the water discharge method of the water tank as described above may be limited to the inconvenience and place of use because it is made of only one method of the manual discharge method or the automatic discharge method using the drainage pump.

That is, there is a problem that the user can not selectively discharge or automatically discharge the water of the reservoir.

The present invention has been proposed in order to solve the conventional problems as described above, an object of the present invention is easy to drain dehumidifier configured to discharge the water stored in the dehumidifier reservoir automatically or manually according to the needs of the user To provide.

The dehumidifier easy to drain proposed by the present invention forms an external shape of the dehumidifier and has a case formed with an air inlet and an air outlet, and is installed inside the case to inhale air from the outside of the case with an air inlet to remove moisture from the air. Dehumidification means for discharging the dry air to the outside of the case, the dehumidification means is collected and stored through the dehumidifying means, the reservoir having a connection portion having an outlet on one side, and the other connection portion detachably connected to the connection portion of the reservoir, And a connection member having a discharge port configured to selectively communicate with the discharge port of the reservoir, and a drain pump connected to the connection member to discharge the water stored in the reservoir to the outside and detachably installed at the connection member.

When the reservoir is connected to the connecting member, the water in the reservoir is configured to flow to the connecting member. When the reservoir is separated from the connecting member, the water discharged from the reservoir is blocked.

The dehumidifier easy to drain according to the present invention can automatically discharge the water stored in the reservoir by simply connecting the drainage pump, or when the drainage pump is removed, the water is accumulated in the reservoir so that the water can be manually discharged. Can be. Therefore, according to the installation state or installation position of a dehumidifier, a user can perform automatic discharge or manual discharge suitably. In other words, in a place where the drainage pipe can be installed, the drainage pump can be automatically discharged.If the drainage pipe cannot be installed, the drainage pump will not work. You can just throw away the water.

1 is a perspective view of the easy-to-drain dehumidifier according to the present invention.
2 is a sectional view of Fig. 1;
3 is a view for explaining a dehumidifier easy to drain according to the present invention, an enlarged cross-sectional view of a state in which the reservoir and the connection member are separated.
Figure 4 is a view for explaining a dehumidifier easy to drain according to the present invention, an enlarged cross-sectional view of a state in which a reservoir and a connection member are connected.

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

1 is a perspective view of an easy-to-drain dehumidifier according to the present invention, FIG. 2 is a cross-sectional view of FIG. 1, and FIGS. 3 and 4 illustrate a connection structure of a reservoir and a drain pump provided in an easy-to-drain dehumidifier according to the present invention. An enlarged cross-sectional view of the main part for explanation is shown.

Generally used dehumidifiers, a case (2) forming the outer portion of the interior of the dehumidifier and the inside of the case 2, the dehumidification means for removing the moisture in the air by sucking the air, and the dehumidification It includes a reservoir (100) in which the dehumidified water is collected and stored through the means.

An air inlet 4 is formed in the front or front and side of the case 2 so that the outside air of the case 2 may be sucked into the dehumidifying means when the dehumidifying means is operated, and the upper or upper surface of the case 2 is provided. And an air outlet 6 is formed on the back so that the air from which moisture is removed through the dehumidification means is discharged to the outside.

The dehumidifying means includes a compressor (8) for compressing a gaseous refrigerant at a high temperature and a high pressure, a condenser (10) for condensing the high temperature and high pressure refrigerant gas discharged from the compressor (8), and a condenser (10). A cooling system including an evaporator 12 for evaporating a low pressure refrigerant passing through a capillary tube may be used, and a fan 14 for sucking air to the dehumidifying means is installed at the rear of the condenser 10.

And when the air passes through the evaporator 12, the bottom of the evaporator 12 is provided with a drip tray 16 to collect water that is condensed and dropped while the moisture is removed, the drip tray 16 is located below the drip tray 16 Reservoir 100 is positioned so that the water of the flow can be stored.

The reservoir 100 has a float 18 whose height is variable according to the water level, and a microcomputer operating in the switched-on state when the float 18 rises to a certain height, and the switch-off state when a predetermined time elapses therefrom. The switch 20 is installed.

A drain pump P is provided to discharge the water contained in the reservoir 100, and the reservoir 100 and the drain pump P are connected to each other through the connection member 200.

In the present invention, the user directly discharges the water contained in the reservoir 100 or is configured to discharge the water of the reservoir 100 by the operation of the drain pump (P) driven by the micro switch 20.

For that purpose, the reservoir 100 and the connection member 200 are each formed of connection portions 102 and 202, one side of which is detachably connected to each other. The connection member 200 is fixed to a fixed member (not shown) inside the dehumidifier, and the reservoir 100 is detachably mounted to the fixed connection member 200.

Assembly members 22a and 22b are formed at the connection member 200 to connect the drain pump P. Therefore, the inlet pipe P1 of the drain pump P can be inserted into the assembly port 22a and the outlet pipe P2 can be inserted into the assembly port 22b.

As shown in Fig. 3, the inclined groove 21 may be drilled in the side surface portion of the inlet conduit P1 so that the inclined groove 21 is approximately at the same position as the outlet 204.

The inclined groove serves to stop the movement of the second valve 208 which will be described later while allowing the water from the outlet 204 to flow into the inlet pipe (P1).

Alternatively, the length of the inlet conduit P1 may be such that the length of the inlet pipe line P1 is about 1/2 of the outlet port 204 of the connecting portion 202 without completely blocking the outlet port 204 formed in the connecting portion 202. Such length may allow water from the outlet 204 side to flow toward the inlet duct P1.

The connecting portions 102 and 202 have a shape corresponding to each other so as to be closely inserted into each other.

Outlets 104 and 204 are formed inside the connecting portions 102 and 202, respectively, and the outlets 104 and 204 are provided with opening and closing members, respectively, to open and close the outlets 104 and 204. . Each opening and closing member operates to open or close the respective outlets 104 and 204 when the reservoir 100 is connected to or separated from the connection member 200.

In addition, the locking projections 106 and 206 are formed on the inner circumferential surfaces of the discharge holes 104 and 204, respectively, and are configured to limit the operating range while maintaining the installed state of the opening and closing member.

The first opening / closing member formed at the connection portion 102 of the reservoir 100 may include a first valve 108 installed in the outlet 104 so as to be linearly movable to open or close the outlet 104, and the first valve. It is made of an elastic member 110 to press the valve 108 to maintain the outlet 108 is closed.

The first valve 108 is formed of a support plate 112 having a central portion extending to an outer periphery thereof, one side of the support plate 112 is supported by the elastic member 110, the other side of the first valve 108 O-ring 114 is inserted and supported to maintain the sealing force in the closed state.

And the first valve 108 is a portion located outside the outlet 104 is formed in the space portion 116 as a plurality of through holes 118 is drilled to one side when the first valve 108 is opened The water of the outlet 104 is configured to pass through and discharged to the outside.

The first valve 108 is an end of the outlet 104 is located outside the contact surface 120, the contact surface 120 is the connection portion 102 (202) of the reservoir 100 and the connecting member 200 ) Serves to operate the first valve 108 in the open position.

In the first valve 108 as described above, when the connecting portions 102 and 202 are not connected to each other, as illustrated in FIG. The ring 114 is in surface contact and closes the outlet 104.

On the other hand, the connecting portion 202 of the connecting member 200 is also provided with a second connecting member having the same structure as the structure of the first opening and closing member as described above.

That is, the second opening / closing member formed at the connecting portion 102 of the connecting member 200 may include a second valve 208 installed in the outlet 204 so as to be linearly movable to open or close the outlet 204. It is made of an elastic member 210 to pressurize the second valve 208 to maintain the outlet 208 closed.

The second valve 208 is formed of a support plate 212 having a central portion extending to an outer circumferential portion thereof, and an elastic member 210 is supported on one side of the support plate 212, and a second valve 208 on the opposite side thereof. O-ring 214 is inserted and supported to maintain the sealing force in the closed state.

In addition, the second valve 208 is located outside the outlet 204 is formed in the space portion 216, a plurality of through-holes 218 are drilled to one side and the second valve 208 is opened The water of the outlet 204 is configured to pass through and discharged to the outside.

The second valve 208 is the end of the outlet 204 is located outside the contact surface 220, the contact surface 220 is the connection portion 102 (202) of the reservoir 100 and the connecting member 200 ) Serves to operate the second valve 208 in the open position.

The second valve 208 is a locking step 206 and O- of the outlet 204 by the outward elasticity of the elastic member 210 as shown in FIG. Ring 214 is in surface contact and closes outlet 204.

When the first and second valves 108 and 208 as described above connect the connecting parts 102 and 202 to each other, the contact surfaces 120 and 220 are in contact with each other to compress the elastic members 110 and 210, respectively. Thus, the first and second valves 108 and 208 are all open so that the water contained in the reservoir 100 can pass through the outlets 104 and 204.

When the connecting parts 102 and 202 are separated from each other, the first and second valves may be formed by the outward elasticity, which is the restoring force of the elastic members 110 and 210 which are compressed while being in contact with each other. 108 and 208 move to their original positions to close the outlets 104 and 204 of the reservoir 100 and the connecting member 200, respectively.

When the connecting portions 102 and 202 are separated from each other, the elasticity provided in the first valve 108 so that the outlet 104 of the reservoir 100 can be closed earlier than the outlet 204 of the connecting member 200. The elastic force of the member 110 is greater than the elastic force of the elastic member 210 provided in the second valve 208.

Substantially, the elastic force of the elastic member 110 supporting the first valve 108 has a magnitude such that the second valve 208 is pushed to the left by the first valve 108 in the drawing. Accordingly, the elastic force of the elastic member 210 supporting the second valve 208 may be such that the second valve can be returned to its original position when there is no force applied to the second valve.

Therefore, when the reservoir 100 is separated from the connection member 200, since the outlet 104 of the reservoir 100 is first closed, and then the outlet 204 of the connection member 200 is closed, the water of the reservoir 100 is closed. Prevent spills.

The dehumidifier easy to drain of the present invention as described above can be installed and used in a desired place for dehumidification. When the dehumidifier is operated, the fan 14 is driven to dehumidify the air while the air is sucked into the dehumidifier through the air inlet 4. Air is discharged to the air outlet 6 while the moisture is removed through the means.

At this time, the sucked air is cooled below the dew point by the refrigerant while passing through the evaporator 12 of the dehumidifying means, and the moisture contained in the air is formed as dew. Flow down and stored in the reservoir (100).

The water stored in the reservoir 100 may be automatically discharged to the outside or manually discharged, first, the state of FIG. 4 in which the connection portion 102 of the reservoir 100 is connected to the connection portion 202 of the connection member 200. In can automatically discharge the water stored in the reservoir (100).

That is, when the connection member 200 is connected as shown in FIG. 4 while the drain pump P is mounted on the connection member 200 as shown in FIG. 3, the first valve 108 and the first valve 108 are formed. The two valves 208 meet each other. At this time, the second valve 208 is moved to the left side in the drawing by the turning force of the elastic member 110 supporting the first valve 108.

The movement of the second valve 208 is stopped by the end of the second valve in the inclined groove 21 of the inlet pipe (P1) inserted into the assembly opening (22a) and then stopped as shown in FIG. As the elastic member 110 supporting the first valve 108 is compressed, the first valve is moved to the right as shown in the drawing, and the outlets 104 and 204 are in communication with each other.

In this state, the float 18 is also raised while the reservoir 100 is filled with a predetermined amount of water. When the float 18 contacts the micro switch 20, the connection member 200 and the assembly holes 22a and 22b are opened. The drain pump (P) connected through is driven.

The water of the reservoir 100 is driven into the discharge port 104 by the driving of the drain pump P, and then discharged through the through holes 118 and 218 to the discharge port 204, and then through the drain pump P. Outflow to the outlet (24). A drainage pipe 26 is connected to the outlet 24 so that the discharged water can flow out.

As the water contained in the reservoir 100 is discharged, the float 18 is also lowered, and in this state, the drain pump P is operated for a predetermined time to discharge the water of the reservoir 100. After a predetermined time elapses, the micro switch 20 operates to cut off the power applied to the drain pump P to stop the driving of the drain pump P.

When the driving of the drain pump P is stopped, discharge of the water stored in the reservoir 100 is stopped, and when the float 18 is filled with water of a predetermined height or more, and the float 18 contacts the micro switch 20, the micro As the power is applied to the drain pump P by the operation of the switch 20, the water is discharged through the above process.

As such, the water stored in the reservoir 100 may be automatically discharged and then manually discharged. In this case, as illustrated in FIG. 3, the connection portion 102 of the reservoir 100 is separated from the connection portion 202 of the connection member 200. In this case, only the drain pump P may be separated from the connection member 200.

When the connecting portions 102 and 202 are separated from each other, the elastic force of the elastic member 110 provided on the first valve 108 on the reservoir 100 side is the elastic force provided on the second valve 208 on the connecting member 200 side. Since it is larger than the elastic force of the member 210, the outlet 104 of the reservoir 100 is first closed, and then the outlet 204 of the connecting member 200 is closed.

Thus, even when the water tank 100 is separated from the connection member 200, the first valve 108 is kept in a closed state, and the water tank 100 may be emptied by emptying the water in this state.

P; drainage pump
16; drip tray
22a; inlet line
22b; outlet pipeline
100; reservoir
102,202; connection
104,204; outlet
108; first valve
110,210; elastic member
200; connecting member
208; second valve

Claims (3)

A case in which an air inlet and an air outlet are formed;
Dehumidifying means for removing moisture in the air introduced into the air intake port and discharging dry air to the air outlet port;
A water tank in which water dehumidified by the dehumidifying means is collected and stored through the drip tray and has a connection part having an outlet at one side thereof;
A connection member having another connection portion detachably connected to the connection portion of the reservoir, the outlet member having an outlet configured to communicate with the outlet of the reservoir, and formed with assembly holes;
A drain pump having an inlet pipe and an outlet pipe which are detachably inserted into the assembly holes of the connection member as means for discharging the water stored in the reservoir;
A first valve having a through hole drilled in the state of being communicated with the outlet by being supported by the elastic member and installed in the outlet of the water tank;
When the connection member is coupled to the water tank, it is supported by an elastic member having an elastic force less than the elastic force of the elastic member so as to be pushed and moved by the first valve to open and close the operation, and another through hole is formed to form the water tank. And a second valve configured to communicate with the outlet of the outlet and the outlet of the connection member.
The second valve, which opens and closes at the outlet of the connection member, is easily drained so that the movement is stopped by the inlet pipe of the drain pump. The method according to claim 1,
The inlet conduit of the drain pump is easy to drain dehumidifier is formed with an inclined groove for stopping the movement of the second valve. The method according to claim 1,
An inlet pipe end of the drain pump is easy to drain is located on the same line as the outlet of the connecting member.

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