KR20180120877A - Cooling Fan Apparatus - Google Patents

Abstract

The present invention relates to a cooling fan apparatus which prevents a wind from flowing into an inlet sucking an outdoor wind, and improves cooling efficiency by supplying an appropriate amount of water to a water filter after cooling the water enough. The cooling fan apparatus comprises a first suction port (110) in a rear case of a body (100); and a discharge port (120) provided with a guide plate (121) capable of adjusting an angle to discharge heat generated by a cooling machine (141) in an upper case of the body (100), wherein heat discharged through the discharge port (120) is prevented from being sucked into the first suction port (110). Moreover, according to the present invention, the present invention comprises a pump (132) to enough perform cooling by being supplied with an appropriate amount of water from a cooling water tank (140) and an electronic valve (171) selectively supplying the cooled water to a filter (116). In addition, even though water is excessively supplied to the cooling water tank (140), a portion is naturally drained in the filter (116) with a pipe, thereby preventing the cooling water tank (140) from bursting and being broken.

Description

{Cooling Fan Apparatus}

More particularly, the present invention relates to a refrigerator, and more particularly, to a refrigerator having a suction port formed in a rear portion of a main body of a refrigerator to prevent warm wind discharged from a cooler from entering the refrigerator, The present invention relates to a refrigerator.

Cooling fans are used in a smaller space than air conditioners and their use is increasing due to their low power consumption. Such a refrigerator may generate cold air using an ice pack or ice, but a thermoelectric element (TEM) is often used for more efficient cooling.

Such a thermoelectric element is provided with a cooling plate and a heat dissipating plate at both ends thereof to provide a function as a cooler for cooling water, and this cooler is usually provided on the upper part of the refrigerator body. Therefore, the cold air is supplied to the water filter which is cooled down by the cooler, and the ambient air introduced into the air inlet formed at the rear of the air conditioner in the state of being wetted by the cooled water passes through the water filter, .

However, most of the coolers can not efficiently prevent the warm wind generated by the cooler from entering the inlet. For example, since the heat outlet of the cooler is formed at the rear of the main body of the air conditioner, the warm air discharged from the cooler is also introduced into the air inlet by the influence of the ambient air flowing into the air inlet. As a result, the temperature of the wind blown from the front of the cooler is increased due to the influence of the water filter, and the cooling efficiency is substantially lowered.

In addition, Korean Patent Laid-Open No. 10-2013-0022445 discloses a structure of a pump that is installed at one end of a water supply pipe to supply water in a water tank to a water supply pipe. The water in the water tank is continuously supplied to the water supply pipe from the time when power is supplied to the water supply pipe. However, when the pump continues to operate as described above, water can not be sufficiently cooled and supplied to the water filter (vaporization filter).

This problem is also seen in the structure of the cooling fan which is supplied with the water filter after cooling the water supplied from the water tank in the cooling water portion. That is, if water is continuously supplied according to the pump operation and more water is stored in the cooling water portion than the proper capacity, more time is required to cool the stored water, and in some cases, . ≪ / RTI > In this case, the cooling efficiency due to the deterioration of the cooler will inevitably be reduced. If the water is not drained by the water filter, water may be continuously supplied to the cooling water tank according to the operation of the pump. In such a case, the cooling water tank may blow or fail.

Accordingly, it is an object of the present invention to provide a refrigerator that prevents heat generated by driving a thermoelectric element from being sucked into a suction port side where a water filter is located, in a refrigerator having a thermoelectric device.

Another object of the present invention is to provide a refrigerator which further improves the cooling efficiency by sufficiently cooling the water in the cooling water portion where the thermoelectric element is located, and then supplying the water to the water filter. Another object of the present invention is to prevent the cooler from functioning or failing by allowing a part of the water supplied to the cooling water supply unit to be directly supplied to the water filter when the water supplied to the cooling water tank becomes the proper capacity or more to provide. And these objectives can be said to improve the performance of the refrigerator substantially.

According to an aspect of the present invention, there is provided an air conditioner comprising: a suction port for sucking wind from the outside in accordance with an operation of a driving fan; and a blowing hole for blowing a cold air passing through the water filter to the outside, A water tank installed at a lower portion of the main body and storing water; A cooling water receiving unit for receiving water stored in the water tank according to a pump operation; A cooler installed in the cooling water-cooling unit and cooling water stored therein; An electronic valve for supplying or blocking the water cooled by the cooler to the water filter through the first drain pipe; And a control unit for controlling the operation of the pump and the electromagnetic valve so that only the amount of water determined by the cooling water tank unit is supplied and the water stored in the cooling water storage unit is cooled and then supplied to the water filter, And when the cooled water is supplied to the water filter, the driving of the pump is repeatedly controlled so as to be supplied again from the water tank by the amount of the discharged water.

And a second drain pipe for draining a part of the excess water to be supplied to the cooling water receiving portion is further connected to the second water pipe, and an end portion of the second drain pipe is located at an upper portion of the water filter, Thereby allowing water to be drained through the water filter to be naturally supplied to the water filter.

In addition, the upper case of the main body is partially formed with a discharge port for discharging warm wind generated by the cooler, and the discharge port is formed with a guide plate for discharging wind toward the upper side of the main body. Here, it is preferable that the guide plate has a shape whose angle is adjusted around the hinge axis.

According to the present invention as described above, the pump provided in the water tank is driven only for a predetermined period of time to supply water to the cooling water tank, so that the cooling water tank can sufficiently cool the stored water. Since the control unit controls the electronic valve to supply the cooled water to the water filter for a predetermined time, the cooling efficiency can be improved accordingly.

Further, since the cooling water supply unit is provided with a separate drain pipe for draining the excessively supplied water, the water is discharged through the drain pipe even if the water is continuously supplied to the cooling water tank unit. Can be prevented.

Further, the present invention forms a discharge port for discharging the heat generated from the cooler to the upper part of the main body of the air conditioner during operation of the air conditioner. Accordingly, the heat of the cooler discharged from the discharge port is suppressed from entering the suction port of the rear case of the main body, and the cool air can be discharged to a desired temperature. This can effectively prevent the deterioration of the performance of the refrigerator, thus securing the competitive advantage of the product.

1 and 2 are a front perspective view and a rear perspective view of a refrigerator according to the present invention.
3 is a schematic diagram showing the overall internal structure of a refrigerator according to the present invention
4 is a block diagram illustrating the function of a blower according to the present invention.

Hereinafter, the present invention will be described in more detail based on the embodiments shown in the drawings. As shown in FIGS. 1 and 2, the cooler according to the present embodiment includes a first suction port 110 for sucking air from the outside to the rear case, and a second suction port 110 for discharging the cooled air to the front And a main body 110 in which a ventilation hole 112 is installed in a front case.

A coolant suction port (hereinafter referred to as a 'second suction port') 114 for sucking air required for driving the cooler is formed above the first suction port 110. That is, according to the present invention, since the cooler including the thermoelectric element is installed above the body 100 of the cooler, the second inlet 114 and the first inlet 110 Are formed together with being spaced apart from the rear case of the main body.

A discharge port 120 is formed in the upper case of the main body 100 to partially discharge the warm air (heat) generated by the operation of the cooler to the outside. In the present invention, the discharge port 120 is formed in such a manner that the heat generated and discharged according to the cooler drive is not sucked into the first suction port 110 and the second suction port 114. For example, referring to FIG. 3, the discharge port 120 may be formed with a guide plate 121 at an upper portion or an upper rear portion of the main body 100. The guide plate 121 may be pivoted about the hinge shaft 122 or may be formed so as to be inclined in the guide plate to facilitate the discharge. That is, the discharge port 120 may be formed in any shape unless the discharge heat enters the first discharge port 110 and the second discharge port 114 due to the swirling phenomenon caused by the flow of the air sucked into the first discharge port 110 and the second discharge port 114 will be. Therefore, the discharge port 120 may be formed on the side case of the main body 110. [

Next, the internal structure of the refrigerator will be described. As shown in FIG. 3, a water tank 130 storing water is installed under the main body 100 of the refrigerator. The water tank 130 is provided with a pump 132 and a cooling water receiving unit 140 is installed on the main body 100 to receive water according to the driving of the pump 132.

The cooling water hose 140 serves to store the water supplied from the water tank 130 through the supply pipe 160 and to supply the water cooled by the cooler 141 to the water filter 116. The cooler 141 is installed in an upper case of the cooling water receiving part 140 and includes a thermoelectric element 142 and a cooling plate 143 and a heat radiating plate 144 mounted on both ends of the thermoelectric element 142. That is, the cooling plate 143 is located in the cooling water receiving portion 140 and the heat sink 144 is located outside the cooling water receiving portion 140 to cool the water stored in the cooling water receiving portion 140. A heat dissipation fan 150 is installed above the heat dissipation plate 144 to discharge heat generated from the heat dissipation plate 144 through the discharge port 120. The heat discharged from the heat-dissipating fan 150 is discharged to the upper side or the upper side of the main body 100 along the discharge port 120 according to the driving of the heat-dissipating fan 150.

A first drain pipe 170 for supplying the cooled water to the water filter 116 is connected to the cooling water supply unit 140 and a nozzle 173 is connected to the end of the first drain pipe 170 . The nozzle 173 is located above the water filter 116. Accordingly, the water cooled in the cooling water portion 140 is supplied to the water filter 116 through the first drain pipe 170. The first drain pipe 170 is provided with an electronic valve 171 for supplying and blocking the water stored in the cooling water receiving unit 140 to the water filter 116. The electromagnetic valve 171 is turned on / off by the control unit 200 (FIG. 4) together with the pump 132, and the control unit 200 will be described in detail below.

Meanwhile, the upper case of the cooling water hose 140 is provided with a second drain pipe 172 having a predetermined length, the end of which is connected to the nozzle 173. The second drain pipe 172 is for discharging a part of the water to the water filter 116 when the water is excessively supplied into the cooling water receiving part 140. The reason for doing this is that the cooling air is supplied to the water filter 116 by cooling the water supplied from the water tank 130 and supplying the water falling from the water filter 116 back to the water tank 130 So that water that is naturally discharged from the cooling water hose 140 is supplied to the water tank 130 through the water filter 116.

The water filter 116 is installed inside the main body 100 adjacent to the first suction port 110. A driving fan 118 is installed in front of the water filter 116. That is, the mounting position of the driving fan 118 is between the water filter 116 and the blowing port 112. Therefore, when the driving fan 118 rotates, the wind is sucked through the first suction port 110 and the wind passes through the water filter 116 to discharge the cool wind toward the front of the fan 112.

The cooler of the present invention does not always supply the water stored in the water tank 130 to the cooling water receiving unit 140. [ When water is continuously supplied from the water tank 130 to the cooling water receiving portion 140 as in the related art, the water stored in the cooling water receiving portion 140 can be discharged to the water filter 116 without being sufficiently cooled . When the water not sufficiently cooled is supplied to the water filter 116, even if the external wind passes through the water filter 116, it is impossible to generate a proper cold air.

Therefore, according to the present invention, as shown in FIG. 4, the cooling water supply unit 140 receives water from the water tank 130 for a predetermined period of time to cool the cooled water, A control section 200 for controlling the operation of the pump 132 and the electromagnetic valve 171 to supply the gas to the valve 116 is provided. In this way, the controller 200 controls the driving of the pump 132 and the electromagnetic valve 171 so as to substantially supply only water sufficiently cooled by the water filter 116. When the water cooled by the cooling water hose 140 is supplied to the water filter 116 and the water level of the stored water is lowered, the control unit 130 drives the pump 132 to supply water to the cooling water hose 140 again And a series of operations for driving the electromagnetic valve 171 to supply the cooled water to the water filter 116 are repeatedly performed while the blower is driven.

In the present invention, the setting time for turning on / off the controller 200 may be variously set. For example, when a certain amount of water is supplied to the cooling water hose 140, the proper driving time of the cooler 141 is determined depending on whether the water can be cooled to an appropriate temperature or the amount of water stored in the cooling water hose 140 The control unit 200 checks whether it is sufficiently cooled and sets the setting time of the control unit 200. [ According to the operation of the control unit 200, the pump 132 is driven and the opening / closing operation of the electromagnetic valve 171 is also performed.

The control unit 200 also controls the operations of the driving fan 118 and the heat-dissipating fan 150. [ Of course, it is needless to say that such a control operation is performed according to the operation of the operation panel 220 installed in the main body 100.

Next, a description will be given of the driving of the air conditioner constructed as described above. When the user operates the operation panel 220 to drive the air conditioner, the controller 200 checks whether the water is sufficiently stored in the cooling water receiving unit 140. The water level sensor 210 installed in the cooling water can be used to store water.

If the water is sufficiently stored according to the check or not, the control unit 200 drives the cooler 141 to cool the water stored in the cooling water supply unit 140. On the other hand, when it is necessary to supply water to the cooling water hose 140, the pump 132 is driven for a predetermined time to supply water to the cooling water hose 140. Then, the controller 200 drives the cooler 141 So that the water stored in the cooling water receiving portion 140 is cooled. At this time, since the cooled water is not yet supplied to the water filter 116, it is preferable that the driving fan 118 is not driven. On the other hand, since the cooler 141 is driven, the heat-dissipating fan 150 must be driven to discharge heat generated through the cooler 141 through the discharge port 120.

The control unit 200 drives the driving fan 118 and opens the electromagnetic valve 171 so that the cooled water is supplied to the water filter 116). The water filter 116 will be wetted by the cooled water so that the wind drawn from the outside by the driving fan 118 through the inlet 110 is sucked by the water filter 116 in a state where the cooled water is wetted, So that the cold air is cooled and discharged to the front through the air outlet 112.

On the other hand, when water cooled by the water filter 116 is supplied, the amount of water stored in the cooling water receiving part 140 is reduced. Accordingly, the control unit 200 drives the pump 132 to supply only the amount of substantially drained water, so that the water stored in the cooling water receiving unit 140 is cooled again by the cooler 141.

As described above, according to the present invention, the pump 132 does not continue to supply water, but the water supplied to the cooling water receiving portion 140 is sufficiently cooled according to driving of the pump 132 operated only for a predetermined time, 116, thus substantially improving the cooling efficiency.

Meanwhile, in order to cool the water stored in the cooling water portion 140 and to discharge the cool air generated through the water filter 116 by the cooled water to the outside, the heat radiation fan 150 and the drive fan 118 operate do. At this time, it is natural that if the warm wind discharged by the heat dissipation fan 150 enters the first suction port 110, the cooling efficiency is lowered.

The discharge port 120 provided with the heat dissipating fan 150 is formed in the upper case of the main body 100 and the discharge port 120 is formed so as to discharge the discharged wind toward the upper side or the upper side of the main body 100 And a guide plate 121 for guiding the direction is provided. The air discharged from the discharge port 120 by the guide plate 121 is discharged without receiving any vortex caused by the flow of the air sucked into the first suction port 110. Therefore, It is possible to prevent an increase in the temperature of the exhaust gas. Here, since the angle of the guide plate 121 can be adjusted with the hinge shaft 122 as an axis, it is also possible to easily change the discharge direction.

In the refrigerator of the present invention employing the cooler as described above, the heat discharged by the cooler driving is originally blocked from being sucked into the suction port equipped with the water filter, and the adequate amount of water is supplied and stored in the cooling water supply portion So that it is possible to improve the cooling performance of the cooling fan.

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 exemplary embodiments. It will be apparent that modifications, variations and equivalents of other embodiments are possible. Therefore, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: blower body 110: first inlet
112: tuyere 114: second inlet
116: water filter 118: driving fan
120: outlet 121: guide plate
122: hinge shaft 130: water tank
132: Pump 140: Cooling water part
141: cooler 142: thermoelectric element
143: cooling plate 144: heat sink
150: heat dissipating fan 160: supply piping
170: first drain pipe 171: electronic valve
172: second drain pipe 200:
210: Level sensor 220: Operation panel

Claims (4)

A suction port 110 for sucking wind from the outside according to the operation of the driving fan 118 and a blowing port 112 for blowing the cold air having passed through the water filter 116 to the outside are provided in the rear case and the front case 100,
A water tank 130 installed at a lower portion of the main body 100 for storing water;
A cooling water receiving part 140 for receiving water stored in the water tank 130 according to the operation of the pump 132;
A cooler 141 installed in the cooling water receiving part 140 to cool the stored water;
An electronic valve 171 for supplying or blocking the water cooled by the cooler 141 to the water filter 116 through the first drain pipe 170; And
So that only the amount of water determined by the cooling water hose 140 is supplied and the water stored in the cooling water hose 140 is cooled and then supplied to the water filter 116. [ And a control unit (200) for controlling the operation,
The controller 200 controls the pump 132 to drive the water tank 116 so that the water cooled by the cooling water supply unit 140 is supplied to the water filter 116, And said control means repeatedly performs control. The method according to claim 1,
A second drain pipe 172 for draining a part of excess water to be supplied to the cooling water receiving part 140,
The end of the second drain pipe 172 is positioned at the upper portion of the water filter 116 so that water drained through the second drain pipe 172 from the cooling water hose 140 flows into the water filter 116 ). The method according to claim 1,
And a discharge port (120) for discharging warm wind generated by the cooler (141) is formed in a state that the upper surface case of the main body (100) is partly cut. The method of claim 3,
A guide plate 121 is formed on the discharge port 120 so as to discharge wind toward the upper side of the main body 100 and the angle of the guide plate 121 is adjusted around the hinge axis 122.

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