KR20080060857A - A device for a discharge of condensed water in an airconditioner system - Google Patents

Abstract

A condensed water discharge device in an air conditioner is provided to prevent overflowing of condensed water by automatically stopping operation of the air conditioner when the amount of condensed water collected in the air conditioner exceeds a predetermined amount, while stopping discharge of condensed water when the amount of condensed water is below the predetermined amount. A condensed water discharge device in an air conditioner comprises a condensed water pump(60), a first switch(70), and a second switch(80). The condensed water pump is configured to pump condensed water, and is activated when the level of the condensed water is above the lowest level. The first switch is installed on one side of the condensed water pump for sensing the highest level of the condensed water to deactivate the operation of the air conditioner when the level of the condensed water reaches the highest level. The second switch is installed on the other side of the condensed water pump for sensing the lowest level of the condensed water.

Description

A device for a discharge of condensed water in an airconditioner system

1 is a partially cutaway perspective view of an indoor air conditioner indoor unit according to the prior art.

Figure 2 is a partial perspective view of the air conditioner showing a state in which a preferred embodiment of the condensate discharge device of the air conditioner according to the present invention is installed.

3 is a partial front view of FIG. 2;

Figure 4 shows the state of use of the condensate discharge device of the air conditioner according to the present invention, the use state showing the case where the level of condensate accumulated in the drain pan reaches the minimum level.

5 is a view showing a state of use of the condensate discharge device of the air conditioner according to the present invention, the use state showing the case where the level of condensate accumulated in the drain pan reaches the highest level.

Explanation of symbols on the main parts of the drawings

50. Case 60. Condensate pump

62. Pump Bracket 64. Condensate Line

66. Switch Bracket 70. First Switch

72. First float 74. First guide

76. First contact point 80. Second switch

82. Second float 84. Second guide

86. Contact 2 W. Condensate

The present invention relates to an air conditioner, and more particularly, to a condensate discharge device forcibly discharging condensate generated in a heat exchanger of the air conditioner to a certain place.

In general, an air conditioner is used to create a more comfortable indoor environment for humans by cooling and heating a room. The internal space of a building after heat-exchanging the intake air by using a refrigeration cycle consisting of a compressor, a condenser, an evaporator, and an expander. It is a device to supply.

Such air conditioners are largely divided into a window type and a separate type.

The integrated type and the separate type are functionally the same, but the integrated type is an indoor heat exchanger, a compressor, an outdoor heat exchanger, and an expansion device installed as a single device. An outdoor heat exchanger (condenser or evaporator), a compressor, and a blower are installed in the outdoor unit, and an expansion mechanism is installed in at least one of the indoor unit and the outdoor unit to connect two separate devices with a refrigerant pipe.

Figure 1 is a partially cutaway perspective view schematically showing the side of the indoor unit of the air conditioner according to the prior art.

As shown therein, the indoor unit of the air conditioner includes: a base 1 constituting the bottom of the indoor unit, a cabinet 2 coupled to the base 1 and having an air inlet and an air outlet through which air enters and exits; A heat exchanger (3) for exchanging the sucked air, a blower (4) for discharging the heat exchanged air to a space for air conditioning through the duct, and a drain pan for collecting the condensed water generated in the heat exchanger (3) (5) and the like.

In addition, a condensate pipe 6 for guiding condensate accumulated in the drain pan 5 to the outside is protruded forward from the front end of the drain pan 5.

However, such a drain pan 5 is generally provided at the lower end of the indoor unit. Therefore, when the indoor unit of the air conditioner is installed at a low position, it is difficult to discharge the condensed water accumulated in the drain pan 5 to the outside.

That is, when the condensed water is to be discharged to a position higher than the installation position of the drain pan 5, there is a problem that the drainage is not naturally performed.

Accordingly, an object of the present invention is to provide a condensate discharge device of an air conditioner capable of forcibly discharging condensate generated in an air conditioner.

Another object of the present invention is to stop the air conditioner when the amount of condensate accumulated in the air conditioner is equal to or higher than the set amount, so that the condensate is prevented from overflowing.

Still another object of the present invention is to stop the discharge of condensate when the amount of condensate accumulated in the air conditioner is equal to or less than the set amount.

Condensate discharge device of the air conditioner according to the present invention for achieving the above object, the condensate pump for pumping the condensate; A first switch provided at one side of the condensate pump and configured to detect a highest level of condensate; The condensate pump is provided on one side, the second switch for detecting the lowest level of the condensate; characterized in that it has a configuration including a.

The condensate pump is characterized in that when the level of the condensate is above the minimum level.

When the level of the condensate detected by the first switch reaches the highest level, the operation of the air conditioner is characterized in that the operation is stopped.

The first switch includes a first float floating on water, a first guide for guiding the first float to flow up and down, and a first contact point for selectively contacting the first float to sense that the condensate is at the highest level. It is characterized by having a configuration to.

The second switch includes a second float floating on water, a second guide for guiding the second float to flow up and down, and a second contact for selectively contacting the second float to sense that the condensate is at the lowest level. It is characterized by having a configuration to.

According to the present invention as described above, there is an advantage that smooth discharge of condensed water is possible.

Hereinafter, a preferred embodiment of the boundary stone structure according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a partial perspective view of a state in which the condensate discharge device according to the present invention is installed in an air conditioner, and FIG. 3 is a front view of the condensate discharge device shown in FIG. 2.

As shown in these figures, inside the case 50 forming the exterior of the air conditioner (front in FIG. 5), the drain pan 52 in which the condensate generated from the heat exchanger (not shown) is accumulated left and right. It is installed long. That is, a heat exchanger is installed above the drain pan 52, and in such a heat exchanger, heat exchange occurs between the refrigerant flowing inside and the outside air. Therefore, condensate is generated on the surface of the heat exchanger and flows downward. The condensate accumulates in the drain pan 52.

The condensate pump 60 for pumping condensate is installed inside the drain pan 52. That is, a pump bracket 62 protruding forwardly is formed on the front surface of the case 50, and the condensate pump 60 is suspended from the pump bracket 62.

The condensate pump 60 pumps condensate accumulated in the drain pan 52 to be discharged to the outside of the air conditioner or to move the condensate to another place inside the air conditioner. Therefore, the condensate pump 60 is connected to the condensate pipe 64 in which the condensate can flow.

Since the condensate pump 60 is a type of pump generally used for pumping fluid, a detailed configuration description thereof will be omitted.

The switch bracket 66 is installed outside the pump bracket 62. The switch bracket 66 is formed in a '∩' shape, the rear end is fixed to the case 50.

Switches 70 and 80 are installed at both lower ends of the switch bracket 66, respectively. The switches 70 and 80 are devices for detecting the level of condensate accumulated in the drain pan 52. Accordingly, the information on the level of the condensate detected by the switches 70 and 80 is transmitted to a controller (not shown) to stop the operation of the air conditioner or to operate or stop the condensate pump 60. .

The switches 70 and 80 include a first switch 70 for detecting the highest level of condensate and a second switch 80 for detecting the lowest level of the condensate.

The first switch 70 is fixedly installed at the lower right of the switch bracket 66, and the second switch 80 is fixedly installed at the lower left of the switch bracket 66.

The first switch 70 may include a first float 72 floating on water, a first guide 74 guiding the first float 72 to move up and down, and the first float 72. The first contact 76 and the like to selectively contact and detect that the condensate is the highest water level.

The first float 72 is generally referred to as a float, and is an object floating on water as shown in a buoy. The first float 72 is formed in an annular shape as shown, and is fitted to the first guide 74.

The first guide 74 has an upper end fixed to the lower right side of the switch bracket 66, is formed in a cylindrical shape, and is installed long up and down. Accordingly, the first float 72 flows up and down along the first guide 74.

The lower end of the first guide 74 is provided with a first lower end plate 78 to prevent the downward departure of the first float (72). The first lower end plate 78 is formed in a circular shape, and the first contact point 76 is provided on an upper side of the first lower end plate 78.

Although not shown, a wire or signal connection means for transmitting a signal generated at the first contact point 76 to a controller (not shown) is further provided inside the first guide 74. Therefore, when the first float 72 touches the first contact 76, this information is transmitted to the control unit to stop the operation of the air conditioner.

The second switch 80 has a configuration corresponding to the first switch 70, but is installed to be located at a relatively lower position than the first switch 70 as shown.

In more detail, the second switch 80 may include a second float 82 floating on water, a second guide 84 guiding the second float 82 to move up and down, and the second float 80. The float 82 is selectively in contact with a second contact 86 or the like for detecting that the condensate is at the lowest water level.

The second float 82 is made of an object floating on water, such as the first float 72, is formed in an annular shape, it is fitted to the second guide 84.

The second guide 84 has an upper end fixed to the lower left side of the switch bracket 66. That is, the left end of the switch bracket 66 is further extended to the lower side than the right end, the second guide 84 is installed in the lower left in the vertical direction long in the cylindrical shape. Accordingly, the second float 82 flows up and down along the second guide 84.

The lower end of the second guide 84 is provided with a second lower end plate 88 to prevent the downward departure of the second float 82. The second lower end plate 88 is formed in a circular shape, and the second contact 86 is provided on an upper side of the second lower end plate 88.

Therefore, when the second float 82 touches the second contact 86, this information is transmitted to the controller to stop the operation of the condensate pump 60. On the contrary, when the second float 82 is separated from the second contact 86, the condensate pump 60 is operated.

Hereinafter, the operating state of the condensate discharge device according to the present invention will be described with reference to FIGS. 4 and 5.

First, FIG. 4 illustrates a case where the level of the condensed water W accumulated in the drain pan 52 is the lowest level. At this time, the level of the condensed water W accumulated in the drain pan 52 is lowered to the minimum, and the second float 82 comes in contact with the second contact 86 provided at the lower end of the second guide 84. Therefore, at this time, the operation of the condensate pump 60 is stopped.

As such, when the condensate is at the lowest water level, the reason why the operation of the condensate pump 60 is stopped is that when the level of the condensate W is lowered, the float floating in the condensate W is drained. This is because it prevents the pumping of the condensate by stacking on the bottom surface or blocking the condensate inlet (not shown) formed at the bottom of the condensate pump 60.

When the condensate (W) is at the lowest water level as described above, since the operation of the condensate pump 60 is stopped, the condensate generated in the heat exchanger (not shown) continuously falls to the drain pan 52. Will accumulate.

Therefore, the amount of condensed water (W) in the drain pan 52 gradually increases, so that the second float 82 gradually increases upward along the second guide 84 as the condensed water (W) increases. Will move.

As such, when the second float 82 moves upward, the second float 82 is separated from the second contact 86. Therefore, this information is transmitted to the control unit (not shown) so that the control unit operates the condensate pump 60 again.

As such, when the condensate pump 60 is operated again, the condensate (W) accumulated in the drain pan 52 is discharged to the outside through the condensate pipe 64, the level of the condensate (W) is lowered again, As described above, when the minimum water level is reached, the operation of the condensate pump 60 is stopped again. As such, the amount of condensate (W) inside the drain pan 52 is adjusted by repetition of the operation and the stop of the condensate pump 60.

On the other hand, when the amount of condensate generated in the heat exchanger is greater than the amount of condensate discharged to the outside by the condensate pump 60, the amount of condensate W that accumulates inside the drain pan 52 is gradually increased. .

Therefore, the second float 82 is in contact with the upper end of the second guide 84, the first float 72 also moves upward along the first guide 74. And, if the amount of condensed water (W) continues to increase, the second float 82 moves to the upper end of the second guide 84, and eventually, the first float 72 also the first guide 74 It moves to the upper end of) and becomes as in FIG.

5 illustrates a case where the amount of condensed water W inside the drain pan 52 is at the highest level. As such, when the amount of the condensate (W) reaches the highest water level, the first float 72 moves upward to come into contact with the first contact point 76.

Therefore, this information is transmitted to the control unit, and the control unit stops the operation of the air conditioner according to this signal. At this time, the indication that the condensate (W) has reached the highest water level (full water) is preferably displayed to the outside through a display (not shown).

As such, the reason why the air conditioner is stopped when the amount of condensed water W inside the drain pan 52 reaches a predetermined level (highest level) is that the condensed water contaminates other parts around the drain pan 52. Or to prevent safety accidents such as electric shock due to such condensate.

When the operation of the air conditioner is stopped as described above, the user takes out the drain pan 52 to remove the condensate inside.

Of course, even when the air conditioner is stopped, the condensate pump 60 may be controlled to operate continuously. In this case, since the air conditioner is stopped, the generation of the condensate no longer occurs, and the condensate W in the drain pan 52 is automatically discharged to the outside continuously by the condensate pump 60.

Therefore, when the amount of condensed water in the drain pan 52 is reduced again, the first float 72 moves downward to be separated from the first contact 76. As such, when the first float 72 is separated from the first contact 76, this information is transferred to the control unit, and the air conditioner is operated again.

As such, after the air conditioner is stopped because the level of the condensed water W accumulated in the drain pan 52 reaches the highest level, the user manually removes the condensed water W of the drain pan 52 and again. In addition to operating an air conditioner, the condensate pump 60 may be set to continue to operate to discharge the condensate (W) in the drain pan 52 to the outside.

The scope of the present invention is not limited to the above-exemplified embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

As described above, in the condensate discharge device of the air conditioner according to the present invention, a condensate pump is provided to automatically discharge the condensate to an external or specific place. Therefore, since it is possible to install the air conditioner at a position lower than the ground, there is an advantage that the installability of the air conditioner is improved.

In addition, in the present invention, the condensate pump is selectively operated according to the condensate level accumulated in the drain pan. That is, the condensate is operated only when the level of the condensate is above the minimum level, and the condensate pump is stopped when the condensate falls below the minimum. Therefore, since the condensate inside the drain pan is always maintained above a certain level, foreign matters such as suspended matter floating in the condensate are introduced into the condensate pump, thereby preventing the condensate from being discharged.

In addition, in the present invention, the operation of the air conditioner is selectively stopped according to the level of the condensate accumulated in the drain pan. That is, when the level of the condensate accumulated in the drain pan is at the highest level, the operation of the air conditioner is stopped. Therefore, condensate overflows the drain pan to contaminate surrounding components, or short-circuit and electric shock due to condensate are prevented.

Claims (5)

A condensate pump for pumping condensate; A first switch provided at one side of the condensate pump and configured to detect a highest level of condensate; And a second switch provided at one side of the condensate pump and configured to sense a minimum level of condensate. The method of claim 1, wherein the condensate pump, A condensate drainage device for an air conditioner, characterized in that it is operated when the condensate level is above the minimum level. The condensate discharge device of claim 1 or 2, wherein the operation of the air conditioner is stopped when the level of the condensate detected by the first switch reaches a maximum level. The method of claim 3, wherein the first switch, The first float on the water, A first guide guiding the first float to flow up and down; Condensate discharge device of the air conditioner, characterized in that the first float selectively comprises a configuration including a first contact point for detecting that the condensate is the highest water level. The method of claim 3, wherein the second switch, The second float on the water, A second guide guiding the second float to flow up and down; Condensate discharge device of the air conditioner, characterized in that the second float is selectively in contact with the configuration including a second contact point for detecting that the condensate is the lowest water level.

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