KR20000006824A - Cooling apparatus for making drinkable water - Google Patents

Abstract

PURPOSE: A cooling device for producing pure water is provided to drink pure water in a place where water is in short supply. CONSTITUTION: The cooling device for producing pure water having an inner device(200) and an outer device(100) includes:a collecting container(220) for collecting the freezing water generated from an evaporator(207) of the inner device(200); a I-shaped first filter(230) placed downwards of the collecting container(220); a first and a second moisture generator(240, 241) for generating the moisture by vibrating the firstly filtrated freezing water with microwave; a freezing water can(250) placed on the second moisture generator(241) and a water tub(270); a second filter(231) placed to sending the filtrated freezing water to a pump(260); and a push cock(210) for exhausting the filtrated pure water from the second filter(231) to outside.

Description

Cooling apparatus for making drinkable water

The present invention relates to a cooling apparatus for producing clean water, and more particularly, to regenerate with clean water and drink as drinking water without discharging the condensed water generated by heat exchange between the heat exchanger and the air installed in the cooling apparatus to the outside, The present invention relates to a cooling apparatus for manufacturing a clean water for controlling humidity of a room space which is dried and cooled.

In general, the cooling device exchanges heat with ambient air when the refrigerant in a liquid state evaporates, and supplies cooling air to the indoor space to cool the indoor space, and performs dehumidification in addition to such cooling. Cooling devices with this function cause cooling bottles to those who work in long-running environments. This phenomenon occurs when the humidity in the air decreases due to the dehumidification of the air conditioner, and the mucous membranes of the throat and nasal cavity, which are the immune system that filters dust, bacteria, and fungi, are dried.

In addition, the cooling device inevitably generates condensed water in a heat exchanger in which relative temperature differences appear when cooling the air in the atmosphere. In general, condensed water refers to water such as dew in which condensation occurs in moisture in the air at which the temperature is lowered due to the difference in saturation of moisture with temperature, and condensed moisture in the condensed air is converted.

The condensed water generated according to the operation of the cooling device is regarded as an unnecessary cooling by-product, and is discharged to the outside by using a water drain or a water drain, or is evaporated by using cold air inside.

In general, the air release and water drainage of a cooling system is provided with a vessel-shaped cooling fan assembly that collects condensed water at the bottom of the evaporator, as found in US Pat. No. 5,117,653 in 1992. . Here, the cooling fan assembly is equipped with a water drain and a damper open / close adjustment unit formed integrally with the air discharge duct. The air discharge and water drainage of such a cooling system open and close the damper opening / closing damper to supply the cool air to the air discharge duct, and simultaneously flow the collected condensed water to evaporate the condensed water.

However, the general air discharge and water drainage for the cooling device to discharge or remove the condensed water, there is a disadvantage that can not reuse the condensed water.

At present, each country is paying much attention to environmental issues and tightening regulations on the use of air conditioners. Accordingly, a lot of research and efforts are being conducted on devices that reuse condensed water without discharging it to the outside. .

Air conditioner having a humidification function according to the prior art, as shown in Figure 1, can be found in 1999, Korean Utility Model Registration Publication No. 11451. An air conditioner having such a conventional humidification function receives condensed water generated in the evaporator 2 on the vehicle duct 1 by the humidification duct 3, generates steam in the vibration generator 4, and then moves downstream to the duct 1. It is supposed to send.

In the conventional air conditioner having a humidification function, the vibration generator 4 is energized when both the air conditioner switch 5 and the blower switch 6 are turned on, thereby generating moisture by ultrasonic vibration. Reference numeral 7 is a blower, 8 is a collection tank, and 9 is a compressor.

However, the conventional air conditioner having a humidification function has a disadvantage in that efficiency is low because moisture is generated using a slight amount of moisture after operating the evaporator for a predetermined time.

In addition, the conventional air conditioner having a humidification function has a disadvantage that can not immediately generate moisture during the initial operation.

In addition, a conventional air conditioner having a humidification function has a disadvantage in that it is not possible to process the condensation water continuously generated even when the humidification operation is not performed.

In addition, the conventional air conditioner having a humidification function has a disadvantage that can not be performed by distinguishing the dehumidification operation and the humidification operation.

In addition, the conventional air conditioner having a humidification function has a disadvantage in that it does not generate an appropriate amount of moisture in the steam generator because it uses condensed water not filtered.

In addition, the conventional air conditioner having a humidification function has a disadvantage in that it cannot continuously generate moisture due to the condensation water generated limitedly.

In addition, since the conventional air conditioner having a humidification function cannot continuously generate moisture, there is a disadvantage in that a major component such as a steam generator or a frequent failure occurs.

Accordingly, the present inventors have made a lot of research and efforts on the technology to reuse the condensed water generated in the air conditioning system, as a result of devising the condensed water treatment device of the refrigerator in which the air conditioner function of Utility Model Registration No. 156725 was installed in 1997 There is a bar.

In addition, since then, the inventors have conducted experiments and studies for the development of an efficient cooling system with reuse of condensed water, and in 1999, a method and apparatus for treating condensed water generated in the cooling device of Patent Application No. 99-36475 The same patent application No. 99-44225 has filed a device for producing clean water using a cold air blower.

In addition, the present inventors have secured the problems found in the development of the actual product, and have continued the research that can produce condensed water into a clean drinking water that can actually drink.

Accordingly, an object of the present invention is to include a reservoir, a pump, a multi filter unit, a multi humidification diaphragm, and a push cock so that continuous moisture generation is possible, and water such as a ship lacking drinking water, a crashed plane, a broken car, etc. It is to provide a cooling device for producing clean water that can drink clean water in this shortage.

1 is a simplified view for explaining the configuration of an air conditioner having a humidification function according to the prior art,

Figure 2 is a perspective view for explaining the cooling device for manufacturing clean water according to an embodiment of the present invention,

3 is a cross-sectional view taken along the line A-A 'to explain the configuration of the cooling apparatus for producing clean water shown in FIG.

4a and 4b are enlarged exploded perspective views for explaining the shape of an important part of the cooling device with a clean water production apparatus shown in FIG.

5 is an enlarged perspective view for explaining an important part of the cooling apparatus for manufacturing clean water shown in FIG.

6A is a cross-sectional view taken along line B-B 'to illustrate a coupling relationship between important portions of the cooling apparatus for manufacturing clean water shown in FIG. 5;

FIG. 6B is a cross-sectional view taken along line B-B 'to explain an operation relationship of important portions of the refrigeration apparatus with the clean water production apparatus shown in FIG. 5;

7 is a circuit diagram for explaining a wiring relationship of the cooling apparatus for manufacturing clean water shown in FIG. 3;

8 to 10 are views for explaining the operating relationship of the cooling apparatus for producing clean water shown in FIG.

11 and 12 are diagrams illustrating a state of use of the cooling apparatus for manufacturing clean water shown in FIG. 3.

♣ Explanation of symbols for main part of drawing ♣

100: outdoor unit 200: indoor unit

207: evaporator 210: push cock

220: collection container 230, 231: filter

240, 241: moisture generator 250: condensation bottle

270: reservoir 260: pump

An object of the present invention described above is a cooling device for manufacturing clean water having an outdoor unit and an indoor unit using a refrigerant, a rectangular container-shaped collection container coupled to the lower part of the evaporator to collect condensed water generated in the evaporator of the indoor unit, First and second moisture generators, which are piped downward of the collection container, and first and second moisture generators, which are piped downward of the first filter and generate moisture by ultrasonically vibrating the primary filtered condensed water, and the second moisture generator. The condensation water tank formed in the shape of a rectangular container connected to the generator and the water tank, the second filter piped so as to pressurize the primary filtered condensed water of the condensation water pump, and the clean water filtered by the second filter to the outside Or, a press cock fixed to protrude to the front of the indoor unit so as to change the channel to supply the reservoir. It is achieved by the room unit.

In addition, according to the present invention, it is preferable that the filters are filled with a plurality of filter materials separated by a filtration sponge pad in the inside of the straight container which can be disassembled and assembled into a cover.

Further, according to the present invention, the first moisture generator is provided with a first water level detection switch electrically connected to the control circuit portion to operate the second moisture generator and the first moisture generator in an on / off state. It is desirable to.

Further, according to the present invention, it is preferable that the second filter is piped upward of the pump so that the water in the condensation bucket flows from the bottom up to prevent the plurality of filter materials from being blocked by various dirts and organic substances.

In addition, according to the present invention, it is preferable that the outer surface of the evaporator is silicone coated to help produce condensed water.

Further, according to the present invention, it is preferable that the cover of the opening and closing operation is hinged to the water outlet hole of the collection container by a buckle with a water level adjusting strap.

In addition, according to the present invention, it is preferable that the water tank is arranged vertically on the rear surface of the indoor unit, and is formed to be foldable to increase the internal volume by being folded and unfolded in the horizontal direction.

In addition, according to the present invention, it is preferable that the quick coupler is respectively coupled to the reservoir so as to be connected to the extension pipe and the clean water delivery pipe connected to the condensation tank in one-touch manner.

Further, according to the present invention, it is preferable that the first and second moisture generators are connected to a moisture pipe having a branch pipe.

Further, according to the present invention, it is preferable that a nozzle fixed to the lower end of the exhaust port of the indoor unit is formed at the end of the moisture pipe.

In addition, according to the present invention, the push cock is provided with a bent type discharge pipe that can be restored to its original position during sliding operation by using the elastic force of the spring, and piped to the clean water delivery pipe by the "T" shaped prefabricated connector It is preferable that it is done.

In addition, according to the present invention, the inner end surface of the water extraction pipe of the push cock is blocked with a rectangular flange shape, it is preferable to form a jaw in the rim so that the water extraction pipe is not released from the prefabricated connector when sliding.

In addition, according to the present invention, it is preferable that the push cock is equipped with a push switch for controlling the operation of the pump.

In addition, according to the present invention, it is preferable that the third water level detecting switch for detecting the water level of the condensation water tank and controlling the operation of the pump at the water outlet portion of the extension pipe.

In addition, according to the present invention, the collection container is formed to correspond to the size of the vehicle evaporator, and is additionally provided by being connected to a first water filter, a pump, and a clean water supply pipeline connecting the second filter and the push cock. It is desirable to be able to produce a drinkable drinking water in an automobile.

In addition, according to the present invention, it is preferable that the reservoir is formed to a size that can additionally be mounted to the trunk of the vehicle.

In addition, according to the present invention, it is preferable that the condenser piped to the evaporator is equipped with an additional heating wire so that condensed water can be generated in winter.

Further, according to the present invention, it is preferable to have a curved casing so that it can be installed in the duct hole formed in the wall of the warehouse so as to supply cold air to the inside of the warehouse and to drink clean water from the inside of the warehouse.

In addition, according to the present invention, it is preferable that the clean water supply pipeline connecting the collection vessel, the first filter unit, the pump, the second filter unit, the push cock and the water reservoir extends into the warehouse.

In addition, according to the present invention, it is preferable to be equipped with a ship and an airplane having an evaporator, to prepare a drinkable clean water and to store in a reservoir, and to supply drinking water by separating the reservoir in case of emergency.

Hereinafter, a cooling apparatus for manufacturing clean water according to a preferred embodiment of the present invention will be described in detail with reference to FIGS. 2 to 14.

2 is a perspective view illustrating a cooling apparatus for manufacturing clean water according to one embodiment of the present invention, and FIG. 3 is cut along the line A-A 'to explain the configuration of the cooling apparatus for manufacturing clean water shown in FIG. 2. One cross section. 4A and 4B are enlarged exploded perspective views for explaining the shape of an important part of the cooling apparatus with the clean water production apparatus shown in FIG. 3, and FIG. 5 is an important view of the cooling apparatus for clean water production illustrated in FIG. 3. 6 is a cross-sectional view taken along line B-B 'to illustrate a coupling relationship between important portions of the cooling apparatus for producing clean water shown in FIG. 4, and FIG. 6B is shown in FIG. It is sectional drawing cut | disconnected by the line B-B 'in order to demonstrate the operation relationship of the important part of the refrigeration apparatus which has the clean water manufacturing apparatus. 7 is a circuit diagram illustrating a wiring relationship of the cooling apparatus for manufacturing clean water shown in FIG. 3, and FIGS. 8 to 10 are views for explaining an operation relationship of the cooling apparatus for manufacturing clean water shown in FIG. 3.

As shown in FIG. 2, the cooling apparatus for manufacturing clean water of the present invention includes an outdoor unit 100 equipped with a compressor for compressing a refrigerant and a condenser for condensing the compressed refrigerant. In addition, the cooling apparatus for manufacturing clean water of the present invention has an indoor unit 200 equipped with an evaporator for cooling the air by receiving a low temperature refrigerant from the condenser of the outdoor unit 100.

The indoor unit 200 of the present invention is a console type, and is formed of a rectangular box-shaped casing that can be placed on one side of an office and a home. In the upper portion of the front of the casing, an exhaust port 201 is formed to adjust the channel of cold air with a plurality of wings so that cold air and moisture can be discharged.

In addition, below the exhaust port 201, an operating state of the indoor unit 200 is displayed, and a display panel having a power switch capable of turning the power on / off, and a cooling switch, a humidification and a dehumidification switch ( 202 is formed. In addition, a control circuit portion is formed on the rear surface of the display panel 202.

Further, the push cock 210 protrudes toward the front of the indoor unit 200 so that the user can drink the clean water below the display panel 202. At the bottom of the push cock 210, a cup holder 205 is formed to support a cup used for containing clean water discharged.

In addition, a plurality of suction ports 204 are formed below the cup holder 205 to suck air during operation of the indoor unit 200.

As shown in FIG. 3, the cooling apparatus for manufacturing clean water of the present invention is equipped with a cooling fan 206 so that the air inside the indoor unit 200 can be directed to the exhaust port 201. In addition, an evaporator 207 having a relatively large evaporation area is mounted at the center of the indoor unit 200 so as to generate a large amount of condensed water although the cooling efficiency is relatively low.

In particular, the outer surface of the evaporator 207 is siliconized to aid in the generation of condensed water.

Indoor unit 200 of the present invention for producing clean water using the condensed water generated from the outside of the evaporator 207 is a collection vessel 220, two filters (230, 231), two moisture generators ( 240 and 241, the condensation tank 250, the pump 260, the water tank 270, and a control circuit (not shown) are mounted.

First, the collection container 220 is a rectangular container extending in the lateral direction and is formed corresponding to the width of the evaporator 207. This collection vessel 220 is fixed to the casing so that it can be placed at the bottom of the evaporator 207. A water outlet hole of the collection container 220 is hinged to a cover 222 that opens and closes by a water level adjusting strap with a bridle 221. The bure 221 and the cover 222 is normally closed the water exit hole, and serves to open the water exit hole when a predetermined amount of condensation water is collected in the collection container 220 by the length of the water level adjusting strap.

In addition, the two filters 230 and 231 are a first filter 230 having a two-stage water filter and a second filter 231 having a three-stage water filter, as shown in FIGS. 4A and 4B. From here,

The first filter 230 as shown in Figure 4a is piped to allow the condensed water to pass through the lower surface of the collection container 220 as described above. The first filter 230 is divided into an activated carbon 234 for filtering dirt and dust by separating the sponge pad 233 for filtering into the inside of the straight container 232 that can be disassembled and assembled with the cover 236, and organic matter. It is filled with a filter material such as zeolite (235; zeolite) for filtration. Therefore, the first filter 230 cleans the water quality of the condensed water necessary for the generation of clean moisture by removing dirt, dust and organics from the condensed water flowing by gravity.

As shown in FIG. 4B, the second filter 231 has the same shape as the first filter so that a user may drink by filtering the water of the condensation bucket 250 pressurized by the pump 260 as described above. Filtered sponge pads 233 'inside the straight container 237 of, such as activated carbon 234', zeolite 235 'and nitric cell cellulose membrane filter (238; nitric cellulous membrane filter) It is filled with filter material. Here, the acetate cellulose membrane filter has a density of 0.22 micrometers of membrane structure and serves to filter microorganisms and bacteria.

In addition, as shown in Figure 3, the two moisture generators 240 and 241 are the first moisture generator 240 fixed to one side of the upper surface of the condensation bottle 250, and the lower portion of the first moisture generator 240 The second moisture generator 241 is disposed and fixed inside the condensation bottle 250. These two moisture generators (240, 241) is a device for generating moisture by mounting the diaphragm vibrating ultrasonically by the piezoelectric phenomenon in the casing. Two such moisture generators 240 and 241 are equipped with water level detection switches 243 and 244, respectively, such as a general float switch. In particular, the first water level detection switch 243 opens the drain 242 of the first moisture generator 240 by operating the first relay and the second relay in accordance with the presence or absence of moisture in the first moisture generator 240. And closes. The first water level detection switch 243 serves to turn on / off the second moisture generator 241 and the first moisture generator 240.

In addition, the second water level detection switch 244 opens and closes the inlet 244 of the second moisture generator 241 by operating the second relay in accordance with the presence or absence of moisture in the second moisture generator 241. Do it. In addition, each of the moisture generators 240 and 241 is piped to the moisture pipe 245 having a branch pipe. The nozzle 246 from which moisture escapes from the moisture pipe 245 is fixed to the lower end of the exhaust port 201 of the indoor unit 200.

In addition, the condensation water bottle 250 is formed in a rectangular container shape to be used as a temporary storage container of the filtered condensed water, and is fixed to the lower surface of the casing of the indoor unit 200. One side of the condensation water bottle 250 is connected to the drain 242 of the second moisture generator 241, and is also connected to the extension pipe 271 of the reservoir 270. Here, the third water level detection switch 274 is attached to the water outlet portion of the extension pipe 271. The third level detection switch installed as described above serves to intercept the operation of the pump 260 by sensing the level of the condensation water bottle 250.

In addition, the pump 260 serves to pressurize the primary filtered water toward the second filter 231 at a predetermined pressure of the condensation water bottle 250. In particular, the second filter 231 is piped upward of the pump 260. This can prevent the water of the condensation bottle 250 from flowing up from the bottom, thereby preventing the plurality of filter materials 234, 235, 234 ', 235', and 238 from being blocked by various dirt and organic matter.

In addition, the second filter 231 is piped with a clean water delivery pipe 272. Then, the second filter 231 is filtered twice and the drinkable clean water is stored in the reservoir 270.

In addition, the reservoir 270 is a removable type for the purpose of storing and drinking the important drinking water necessary for a person to live in an abnormal environment, such as a ship equipped with a cooling device for manufacturing a clean water of the present invention, a broken down car, a crashed plane, to facilitate movement. It is formed to be folded and unfolded.

Such a reservoir 270 is disposed perpendicular to the rear surface of the indoor unit 200, and is formed to be foldable to be folded and unfolded in a horizontal direction. Such, when a lot of clean water is supplied to the interior of the reservoir 270 to expand and increase the internal volume. Such a reservoir 270 can reduce the installation area occupied by the indoor unit 200 in normal times, and can be effectively stored when a lot of clean water is stored. Particularly, a general quick coupler 273 that can be connected to the extension pipe 271 and the clean water delivery pipe 272 by one-touch is coupled to the lower and upper portions of the reservoir 270, respectively. The quick coupler 237 can open the channel when the pipes 271 and 272 are inserted by the tension of the spring, and close the channel when the pipes 271 and 272 are separated. The reservoir 270 stores the drinking water that is drinkable during the operation of the indoor unit 200, and is separated by the quick coupler 237 and can be easily moved to a place requiring water.

In the following, the coupling relationship and operation relationship of the push cock 210 used to drink the prepared clean water will be described in detail.

As illustrated in FIG. 6, the push cock 210 may change the channel of the clean water supplied by being piped to the clean water delivery pipe 272. Such a push cock 210 has a curved exit pipe 212 coupled to the protrusion side of the "T" shaped prefabricated connector 211. Here, the coupling portion of the prefabricated connector 211 and the outlet pipe 212 has a rectangular cross section. In addition, a push button 203 is attached to the water outlet pipe 212 to increase the user's convenience.

As shown in Figure 6a, the lower surface of the water extraction pipe 212 of the push cock 210 using the tension of the spring 214 to be returned to its original position during the sliding operation (p) in the horizontal direction (p) 213 is formed. The spring support jaw 213 is provided with an integral protrusion bar. The protruding bar 215 of the spring support jaw 213 is coupled to the spring mounting portion 218 to control the push switch 216 of the prefabricated connector 211. In addition, the inner end surface of the water extraction pipe 212 is blocked with a rectangular flange shape, and the jaw is formed on the rim to be coupled so that the water extraction pipe 212 is not separated from the prefabricated connector 211 during the sliding operation (p). The shock-absorbing rubber block 219 is fixed to the outside of the inner end surface of the water extraction pipe 212. In addition, the lower surface of the inner end of the water extraction pipe 212 is open. A rectangular sealing ring made of rubber is attached to the inside of the end face of the rectangular flange shape.

In addition, the prefabricated connector 211 is bolted to the top and bottom of the flange formed on the rim, O-ring 217 to prevent water leakage during the sliding operation (p) to the inner diameter of the protrusion side of the prefabricated connector 211 ) Are mounted.

As shown in FIG. 6B, the water extraction pipe 212 of the push cock 210 coupled as described above is connected to the prefabricated connector 211 when the user pushes the push button 203 in the horizontal direction c. Sliding inside. This outlet pipe 212 is stopped by contacting the shock-absorbing rubber block 219 to the inner surface of the prefabricated connector 211. At this time, the outlet pipe 212 is in communication with the prefabricated connector 211 to flow the clean water (d). At the same time, the end of the protruding bar 215 formed on the spring support jaw 213 contacts the push switch 216 and operates the pump connected to the push switch 216. Therefore, the clean water d pressurized by the pump flows along the clean water delivery pipe 272, and after the water channel is changed toward the water discharge pipe 212, it is discharged to the outside. In addition, when the user removes the force applied to the push button 203, the water extraction pipe 212 is returned to its original position by the tension of the spring 214.

In the following, a circuit configuration of a cooling device having a clean water production apparatus of the present invention as described above will be described.

As illustrated in FIG. 7, the control circuit unit includes a magnetic connector 281 that controls one side of a line connected in parallel to the power supply unit 209 of the indoor unit. This magnetic connector 281 is connected with a red indicator light 282 showing that there is an abnormal operation. The water level detection switch 294 for preventing the overflow of water level when a motor abnormality occurs is connected to the line to which the magnetic connector 281 and the red indicator light 282 are connected in this way.

In addition, the electric relays 283, 284, 285, and 287 may detect moisture of the water level detection switches 243, 244, and 274 of the moisture generator and the extension pipe, and turn on / off the push switch 216 during sliding of the push cock. Due to (ON / OFF) operation, it is wired to switch selectively when power is applied. In addition, the green indicator 286 indicates the operating state of the pump, and the humidification switch 288 serves to turn on / off the power of the humidification generators.

Here, when the humidification switch 288 is turned ON, the first and second electric machinery 283 and 284 are positioned according to the position (left or right) of the first water level detection switch 243 on the first humidifier side. Works. At this time, when there is no water in the first moisture generator, the second moisture generator is operated, and if there is no water in the second moisture generator, all the moisture generators are stopped. And, when the push switch 216 is in contact, it operates the pump. At this time, if there is no water in the condensation bottle, the pump is stopped by the first terminal "s" of the third water level detection switch 274. If there is much water in the condensation water bottle, the second terminal "t" of the third water level detection switch 274 is stopped. Pump is operated. In addition, when an abnormality occurs in the pump, the operation of the air conditioner, the moisture generators, the pump, and the humidifier is stopped by the overflow overflow switch 294, and the red indicator light 282 lights up. In addition, the green light 286 lights up only when the pump is operating.

In the following, it will be described the operation method of the cooling device with a clean water production apparatus of the present invention as described in detail above.

As shown in FIG. 8, the power of the air conditioner is turned on. Then, the user turns on a humidification switch (not shown) of the display panel. In such a case, in the outdoor unit 100, the refrigerant is brought into a low temperature state by the compressor and the condenser. This refrigerant is delivered to the evaporator 207 of the indoor unit 200. In addition, as the cooling fan 206 rotates, air flows into the inlet 204 of the indoor unit 200. The introduced air has a cold temperature by heat exchange in the evaporator 207 and is discharged to the exhaust port 201 of the indoor unit 200.

At this time, moisture in the air passing around the evaporator 207 is condensed by the relative temperature difference, thereby becoming condensed water such as dew. This condensed water flows down the evaporator 207 and is collected in the collection vessel 220. The condensation water of the collection container 220 is stored in a predetermined amount by a cover 222 that is opened and closed by a corded bridle 221. The cover 222 is opened by the bridle 221 only when the predetermined amount of condensed water is stored, and the condensed water flows into the first filter 230 along the outlet hole of the collection container 220. The second filter 230 filters the condensed water to the extent necessary to produce clean moisture. The filtered condensed water is introduced into the first humidifier (240). At this time, the first water level detection switch 243 of the first moisture generator 240 closes the drain 242 as the water rises, and operates the first moisture generator 240. Accordingly, clean moisture is generated in the first moisture generator 240, and the generated clean moisture moves to the exhaust port 201 of the indoor unit 200 through the moisture pipe 245. At this time, the moisture is made by vibrating the cold condensed water, combined with the cold passing through the exhaust port 201, is supplied to the indoor space of the home or office in a state that hardly condensed.

As shown in FIG. 8, when the user turns off the humidification switch (OFF) for the purpose of dehumidifying the air in the indoor space during the operation of the air conditioner, the first humidifier generator 240 does not operate. In addition, when the continuously filtered filtered condensate reaches the highest water level in the first moisture generator 240, the first water level detection switch 243 opens the drain 242. Therefore, the filtered condensed water flows into the condensation water bottle 250. In addition, the second water level detection switch 244 operates opposite to the first water level detection switch 243, so that the filtered condensed water turns off the power of the second moisture generator 241. In addition, the third water level detection switch 274 that detects the filtered condensed water of the condensation water bottle 250 operates the pump 260. The filtered condensed water pressurized by the pump 260 becomes clean water that can be drunk through the second filter 231. This clean water continues to move upward by the water pressure of the pump 260, and is filled in the reservoir 270.

In addition, when the user presses the water extraction pipe 212 of the push cock 210 in the horizontal direction (c), clean water is discharged and the user may drink. In addition, the reservoir 270 is expanded by the clean water supplied when the push cock 210 is not used to store a large amount of clean water.

In addition, as shown in FIG. 10, the user turns on the humidification switch (ON) for the purpose of humidifying the air in the indoor space during the operation of the air conditioner. At this time, when the amount of condensation water generated in the evaporator 207 is small and there is no water in the first moisture generator 240 and the condensation water bottle 250, the second water level detection switch 244 and the third water level detection switch 274. At the same time the power of the second moisture generator 241 is turned on (ON), the water of the reservoir 270 is introduced into the condensation tank 250 and the second moisture generator 241. Accordingly, the moisture is generated in the second moisture generator 241 and moves toward the exhaust port 201 of the indoor unit 200 through the moisture pipe 245.

In the following, with reference to the use state diagram of Figures 11 and 12, the application field of the cooling device for producing a clean water of the present invention as described in detail above will be described.

Cooling device for producing a clean water of the present invention can be applied to a vehicle, such as automobiles, trucks, buses, heavy equipment, as shown in FIG. That is, the first filter 330, the pump 360 and the second filter 331 are piped using the collection container 322 having a size corresponding to the evaporator 307 of the basic cooling system 101 of the vehicle. The clean water supply pipeline 372 is passed through the instrument panel on the passenger seat side, and the push cock 310 connected to the clean water supply pipeline 372 is projected to the front of the passenger seat instrument panel, thereby cooling the clean water production of the present invention. The device can produce clean water applicable to a vehicle. The prepared clean water is detachable from the clean water supply pipeline 372 by a quick coupler 373 and is filled with a folding reservoir 370 mounted in the trunk of the vehicle.

In the same way, the cooling device for manufacturing clean water of the present invention is applied to a small air conditioner of a ship and an evaporator inside an airplane, so that drinkable clean water is produced and stored in a reservoir, and then wrecked and crashed. It is possible to produce clean water used as a drinking water source for passengers in the city.

In addition, the cooling device for producing clean water of the present invention can be used for the warehouse, as shown in FIG.

This clean water manufacturing cooling apparatus of the present invention is applied to a general warehouse cooling system (102). Here, the general warehouse cooling system 102 condenses the refrigerant compressed by the compressor 103 in the condenser 104, and exchanges the high temperature refrigerant with the low temperature refrigerant using the air supply of the blower 408. Doing.

In particular, the clean water producing air conditioner of the present invention applicable to a warehouse is equipped with an additional coiled heating wire 405 in the condenser 104. This serves to warm the condenser 405 in winter, so that condensed water is generated in the evaporator 407.

Such a cooling apparatus for producing clean water is provided to the wall 401 of the warehouse 400 so as to heat the outside air in the evaporator 407 by the cooling fan 406 and heat the inside of the warehouse 400 to supply the cooled air. It is installed. In addition, the cooling apparatus for manufacturing clean water of the present invention is fixed to the outside of the wall 401 by a support bracket 403. The casing 402 of the cooling apparatus for manufacturing clean water is formed in a refractive type so that a part is inserted into the duct hole 409 formed in the wall 401 of the warehouse 400. In this casing 402, the collection vessel 422, the first filter 430, the pump 460, and the second filter as described above, to collect the condensed water generated in the evaporator 407 to produce clean water. 231 and the push cock 410 are piped to the clean water supply pipeline 472. The clean water supply pipeline 472 is extended to the interior of the warehouse 400, is connected to the foldable reservoir 470 by a quick coupler.

Therefore, the cooling device for producing clean water applied to the warehouse of the present invention has a cooling function and a clean water producing function in summer, but in winter, by heating the condenser 405 with a heating wire 405, condensed water is made in the evaporator 407 to clean water. Can be prepared.

As described in detail above, the cooling device for manufacturing clean water of the present invention can generate a large amount of moisture quickly and continuously even after operating two moisture generators, a plurality of water level detection switches, and a reservoir for a predetermined time, thereby maximizing operation efficiency. There is an advantage to this.

In addition, the cooling apparatus for producing clean water of the present invention has the advantage of keeping the condensed water continuously generated even when the humidification operation is not performed.

In addition, the cooling device for producing clean water of the present invention has the advantage of providing clean water that can generate clean moisture and can be applied by using a filter and a push cock to double filter.

In addition, the cooling device for producing clean water of the present invention has an advantage that can generate moisture quickly through the first moisture generator even during the initial operation.

In addition, the cooling apparatus for manufacturing clean water of the present invention has the advantage that it can not be performed by separating the dehumidification operation and the humidification operation using a humidification switch.

In addition, the cooling apparatus for manufacturing a clean water of the present invention has an advantage of minimizing the occurrence of failures of the moisture generators by operating the water level detection switches.

Although the technical concept of the cooling apparatus for manufacturing a clean water of the present invention described above has been described with the accompanying drawings, this is illustrative of the best embodiment of the present invention and is not intended to limit the present invention. In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Claims (20)

In the cooling device for manufacturing a clean water provided with an outdoor unit 100 and an indoor unit 200 using a refrigerant, A rectangular container-shaped collection container 220 coupled to the lower part of the evaporator 207 to collect condensed water generated in the evaporator 207 of the indoor unit 200; A first linear filter 230 piped downward of the collection container 220, The first and second moisture generators 240 and 241, which are connected to the lower portion of the first filter 230 and generate moisture by ultrasonically vibrating the first filtered condensed water, A condensation water bottle 250 formed in a rectangular container shape piped to the second moisture generator 241 and the water storage tank 270, A second filter 231 piped to pressurize the first filtered condensed water of the condensation water bottle 250 to the pump 260, and The push cock 210 fixed to protrude to the front of the indoor unit 200 to discharge the clean water filtered in the second filter 231 to the outside, or to change the channel to supply to the reservoir 270. Cooling device for producing a clean water comprising a. The method of claim 1, The filter units 230 and 231 are divided into filter pads 233 and 233 'inside the linear containers 232 and 237 that can be disassembled and assembled into the covers 236 and 236'. , 235, 234 ', 235', 238) The cooling device for producing clean water, characterized in that the filling. The method of claim 1, The first moisture generator 240 is electrically connected to a control circuit unit to operate the second moisture generator 241 and the first moisture generator 240 to be turned on / off. And a water level detection switch (243). The method of claim 1, As the water in the condensation can 250 flows from the bottom up, the pump 260 to prevent the plurality of filter materials 234, 235, 234 ′, 235 ′, 238 from being blocked by various dirt and organic matter. Cooling device for producing a clean water, characterized in that the second filter 231 is piped upward. The method of claim 1, Cooling device for producing a clean water, characterized in that the outer surface of the evaporator (207) has a silicon coating, to help the generation of condensed water. The method of claim 1, Cooling device for producing a clean water, characterized in that the water outlet of the collection container 220 is hinged by a cover 222 that is opened and closed by the water level adjusting strap with a bridle (221). The method of claim 1, The reservoir 270 is disposed vertically on the rear surface of the indoor unit 200, folded and unfolded in the horizontal direction, thereby forming a foldable to increase the internal volume, the cooling apparatus for producing a clean water. The method of claim 1, The quick coupler 273 is coupled to the reservoir 270 so that the extension pipe 271 and the clean water delivery pipe 272 piped to the condensation tank 250 can be connected in one-touch fashion, respectively. Cooling device for clean water production. The method of claim 1, The first and second moisture generators (240, 241) is a cooling apparatus for producing a clean water, characterized in that the pipe is connected with a moisture pipe (245) having a branch pipe. The method of claim 1, Cooling device for producing a clean water, characterized in that the nozzle 246 fixed to the lower end of the exhaust port 201 of the indoor unit 200 is formed at the end of the moisture pipe (245). The method of claim 1, The push cock 210 is provided with a bent outflow pipe 212 that can be restored to its original position during the sliding operation (p) by using the elastic force of the spring 214, the "T" shaped prefabricated connector ( Cooling device for producing a clean water, characterized in that the pipe is connected to the clean water delivery pipe (272) by 211). The method according to claim 1 or 10, The inner end surface of the water extraction pipe 212 of the pressing cock 210 is blocked with a rectangular flange shape, and the jaw is formed at the rim so that the water extraction pipe 212 is separated from the prefabricated connector 211 during the sliding operation (p). Cooling device for producing clean water, characterized in that not. The method of claim 1, The push cock 210 is equipped with a push switch 216 for intermittent operation of the pump 260 is clean water manufacturing apparatus, characterized in that the. The method of claim 1, Cooling water production cooling, characterized in that the water outlet portion of the extension pipe 271 is equipped with a third water level detection switch 274 for detecting the water level of the condensation tank 250 to control the operation of the pump 260. Device. The method of claim 1, The collection container 320 is formed to correspond to the size of the vehicle evaporator 307, the first filter 330, the pump 360, the second filter 331 and the push cock 310 Cooling device for producing a clean water, characterized in that by being connected to the clean water supply pipeline 372 connected in sequence, it is possible to additionally produce clean drinking water in the automobile. 16. The cooling apparatus of claim 1 or 15, wherein the water tank (370) is additionally formed to a size that can be mounted on the trunk of the vehicle. The method of claim 1, Cooling device for producing a clean water, characterized in that the condenser 104 piped to the evaporator (407) is equipped with an additional heating wire (405) so that condensed water can be generated in winter. The method according to claim 1 or 17, The curved casing (S) may be installed in the duct hole 409 formed in the wall 401 of the warehouse 400 to supply cold air to the interior of the warehouse 400 and to drink clean water from the inside of the warehouse 400. Cooling apparatus for producing a clean water, characterized in that having a 402. The method of claim 17, The clean water connecting the collection container 422, the first filter 430, the pump 460, the second filter 231, the push cock 410, and the reservoir 470. Supply pipeline 472 is a cooling device for producing clean water, characterized in that extending into the interior of the warehouse (400). The method of claim 1, Cooling apparatus for producing a clean water, characterized in that mounted on the vessel and the plane having the evaporator, to prepare a drinkable clean water and to store in the reservoir, and to supply the drinking water by separating the reservoir tank in case of similar.