KR20120121776A - Hybrid type cooling equipment - Google Patents

Abstract

PURPOSE: A hybrid cooling device is provided to perform humidification by supplying some of air of low temperatures and low moisture generated by a hybrid cooling device to an air conditioning space, thereby preventing dew condensation on a surface. CONSTITUTION: A hybrid cooling device comprises a dehumidification cooling device(100) and a cold water supplying device(300). The dehumidification cooling device comprises a dehumidification cooling housing(110), a dehumidifying rotor(140), a heat exchanger(180), cooler(150), and a blower(170). The inside of the dehumidification cooling housing is divided into a dehumidification cooling path(112) and a recycling path(113) by a partitioning wall. The dehumidifying rotor eliminates moisture included in air flowing into the dehumidification cooling path. The heat exchanger heats the air passing through the recycling path for recycling the dehumidifying rotor. The cooler is installed in the dehumidification cooling path and makes the air in which the moisture is eliminated by passing through the dehumidifying rotor pass through water sprayed from a water injection device, thereby obtaining cold water by using the evaporative latent heat of the water. The blower forcibly ventilates the air in the recycling path and dehumidification cooling path. The cold water supplying device collects the cold water generated by the cooler, thereby circulation-supplying the same by passing through an air conditioning space. [Reference numerals] (AA) Indoor unit; (BB,FF) Outdoor air; (CC,DD) Exhaust; (EE) Air supply

Description

Hybrid type cooling equipment

The present invention relates to a hybrid cooling device, and more particularly, a dehumidifying cooling device for making cold water or cold air by passing dry air passed through a dehumidifying rotor to a cooler, and heating or cold water for regeneration of a dehumidifying rotor. The present invention relates to a hybrid cooling device capable of minimizing the consumption of power or hot water supply energy while maximizing cooling efficiency by combining a cooling system for supplying cold water to the air conditioning space and a compressed air cooling device for further cooling the air.

Due to global warming and progress to the subtropical climate of the Korean Peninsula, the demand for cooling in the summer is getting bigger and instantaneous power consumption is increasing, resulting in a national energy consumption imbalance.

The prospect of the recent high oil price situation is not a temporary problem but will continue to be sustained. Accordingly, the world's major energy consumers are trying to secure stable energy resources.

In addition, with the entry into force of the Tokyo Protocol to reduce greenhouse gas emissions to prevent global warming, international pressure on restrictions on fossil energy use and energy efficiency standards is expected to increase.

On the other hand, energy consumption in the home / commercial sector is reported to be about 25.2% of the country's total energy consumption, which is about 41.9% based on electricity consumption, and energy consumption in the home / commercial sector continues to increase. .

Therefore, in order to develop a sustainable energy field through efficient use of energy and compliance with international conventions, it is necessary to improve the energy use efficiency for air conditioning in the home and commercial sectors.

Most of the energy consumed in the house is consumed by heating and cooling energy, which is equivalent to 40%. Most of them are consumed for long time heating and hot water, and the increase of cooling consumption is increasing.

Indoor cooling is classified into convective cooling and radiative cooling according to heat flow.

Convection cooling is a method in which more than 80% of the air conditioners and fan coil units using absorption cold and water heaters use convection of air. This shows a rapid cooling effect in a manner used in homes, commercial, business spaces, while the energy consumption is high, there is a problem such as discomfort or noise caused by cold air flow.

On the other hand, radiant cooling refers to a cooling method in which the ratio of radiation is more than 50% among heat exchange methods, and in reality, both heat transfer of radiation, convection, and conduction occurs.

A feature of the radiant cooling system is that it uses low-temperature radiant heat to maintain comfort in the human body. In addition, the existing cooling equipment can be used as it is, reducing equipment installation costs, unifying the cooling and heating system, and contributing to energy saving by low temperature cooling. When the radiant cooling can prevent condensation caused by the cooling such as the floor or ceiling and maintain the body contact temperature properly, it can be said to be a preferred cooling method.

Radiation heating and radiant cooling systems started from Ondol, a winter heating method that had a great impact on our living, building style and customs. Ondol heating has been continuously studied from 1970 to the present, and it does not require a radiator, generates no noise or dust, and provides sufficient heating and heating feeling even at low room temperature compared to other heating methods. It is considered to be superior to any other heating method because of its structure.

In addition, many of the new homes in Europe, such as Germany, Switzerland, and Denmark, which have used convection-heating fireplaces and radiators, are adopting ondol, which is floor heating, and are rapidly spreading in Japan without ondol. Doing. As such, the research on the floor radiant heating method has been developed and has the possibility of research and development with the global heating method.

On the other hand, studies on radiative cooling systems are inadequate and there are not many applications compared to heating applications, which may be due to the characteristics of the cooling distribution and the short cooling period. In addition, cooling can be maintained by natural ventilation. There are also climate and environmental causes. The increase in cooling demand will continue due to the rise in summer temperature and the improvement of living standards due to global warming, and the bottom radiant cooling system is seen as the ideal cooling method to prepare for future climate.

In order to spread the floor radiant cooling system, a device for efficiently making and supplying cold water and a technique for preventing condensation on the surface of the radiant due to the low temperature of the radiant for radiant cooling are required.

As a device for making cold water, a freezer is widely used, but a freezer is generally a product suitable for industrial use rather than a home because it requires a large amount of auxiliary equipment such as a cooling tower. There is this. There are cases of using absorption type chiller which uses local supply heat as heat source in the area using collective energy, but there is a limitation in improving performance due to the low heat source temperature, and it cannot use the temperature below 80 ℃, so the return temperature is high. Due to the problem of a small temperature difference between the return water, there is a problem in that the cold water pipe should be additionally installed separately from the hot water supply pipe.

If you look at papers or academic papers on radiant floor cooling, if you cool the floor by supplying cold water, condensation may occur on the floor when humidity is high, you need to install additional air conditioners to dehumidify it. There is a problem.

The present invention has been made to solve the above problems, as a device for supplying the cold water required for radiative cooling, such as convection cooling, floor cooling or ceiling cooling using a fan coil unit, in a small space, such as home Instead of using a refrigerator that requires excessive power consumption and has a separate cooling tower, it is possible to manufacture cold water while reducing energy consumption by utilizing hot water obtained through waste heat of solar cogeneration or solar heat. When condensation occurs on the surface during radiative cooling, it prevents condensation on the floor or ceiling without installing a separate air conditioner, and also uses a hybrid cooling device that can selectively perform floor cooling and heating using existing hot water heating facilities. The purpose is to provide.

The hybrid cooling device of the present invention for achieving the above object, the dehumidification cooling housing is separated into a dehumidification cooling passage and the regeneration passage by the partition wall, the dehumidification cooling passage and the regeneration passage in the dehumidification cooling housing. A dehumidification rotor rotatably installed over the dehumidifier and removing moisture contained in the air flowing into the dehumidification cooling passage, and a heat exchanger for heating the air passing through the regeneration passage for regeneration of the dehumidification rotor; A cooler that is installed in the dehumidification cooling passage and passes through the dehumidification rotor and removes moisture, passes through the water sprayed from the water injector to make cold water using latent heat of evaporation of water, and the air of the dehumidification cooling passage and the regeneration passage Dehumidification cooling apparatus including a blower forcibly blown; And a cold water supply device for collecting and supplying cold water made by the cooler to circulate through the air conditioning space.

The cooler may include: a dry channel through which dry air passing through the dehumidification rotor passes; A wet channel for recovering some or all of the air passing through the dry channel; A water supply device for spraying water into the wet channel; And an exhaust port for discharging the air passing through the wet channel to the outside.

In addition, the flow direction of air passing through the dry channel and the flow direction of air passing through the wet channel are opposite to each other, and the flow direction of air flowing through the wet channel and the flow direction of water injected into the wet channel are Characterized in opposite directions to each other.

In addition, a part of the water injected into the wet channel is evaporated by the air passing through the wet channel, and heat evaporated with the latent heat of the evaporated water to evaporate at the same time as cooling the air passing through the dry channel. It is characterized by making the cold water by cooling the temperature of the remaining water.

In addition, the cooler is provided with an air supply damper and an air supply air supply so that a part of the air passing through the gun channel is sent to the wet channel, and the remainder of the air passing through the gun channel is directly supplied to the air conditioning space. It features.

In addition, during the cooling operation of the air conditioning space, the air supply damper is closed so that no air is supplied to the air conditioning space, and all of the air passing through the dry channel is sent to the wet channel to supply the cold water generated in the cooler to the air conditioning space. A driving mode; During the dehumidification and cooling operation of the air conditioning space, the air supply damper is opened so that a part of the air passing through the gun channel is supplied to the air conditioning space through the air conditioning air supply, and the remaining air passing through the gun channel is It is sent to the wet channel to make the cold water in the cooler to supply a cold water to the air conditioning space; second operation mode; characterized in that it is operated in the.

In addition, the cold water supply apparatus, the drain plate for collecting the cold water produced in the cooler; Cold water storage tank for storing the cold water collected in the drain plate; A cold water line for supplying cold water from the cold water storage tank to an air conditioning space; A three-way valve provided at a branch point of a hot water connection line connecting the cold water line and the hot water line of the heat exchanger to switch a flow path to selectively supply hot water or cold water to the air conditioning space; And a circulation pump for circulating the cold water into the air conditioning space and the water supply device or circulating the hot water supplied to the heat exchanger to the air conditioning space.

In addition, the air-conditioning space is installed in the cold and hot water line is circulated through the cold water or hot water selectively supplied by switching the flow path of the three-way valve, the cold and hot water line is characterized in that the cold water line and hot water line is used in combination. .

The hybrid cooling device may further include a compression type cooling device including a compressor, a condenser, an expansion valve, an evaporator, and a refrigerant pipe connecting them, wherein the compressor and the condenser are installed at an air input side of the heat exchanger of the regeneration passage. Preheating the outside air input to the heat exchanger by using the waste heat generated when the compressor is driven and the heat of condensation generated during the condensation of the refrigerant in the condenser; The evaporator is installed in a cold water storage tank in which cold water made by the cooler is stored, and cools the cold water primarily cooled by the cooler secondly by latent heat of evaporation of the refrigerant.

In addition, the heat source of hot water supplied to the heat exchanger is characterized in that it is provided using waste heat, geothermal or solar heat of cogeneration.

According to the hybrid cooling device according to the present invention, the energy consumption is high and is suitable for applying to a small space such as a home instead of a cooling tower or a refrigerator suitable for a large capacity, and utilizes a small amount of hot water supplied from the waste heat of cogeneration and geothermal or solar heat sources. It has the advantage of making cold water at energy cost.

In addition, it is easy to apply radiant cooling such as floor cooling or ceiling cooling to commercial / home air-conditioning space by using the made cold water, and to prevent surface condensation due to radiative cooling, By supplying a part of the low temperature and low humidity air produced in the hybrid cooling device to the air conditioning space, dehumidification is possible, which has the advantage of preventing surface condensation.

In addition, cooling and heating of the air conditioning space can be selectively performed by connecting a hot water line for regenerating the dehumidifying rotor of the dehumidifying air conditioner and a cold water line made in the hybrid air conditioner to the hot water connection line through the 3-way valve. There is an advantage that can be used as a hot water line for the existing heating without the need to install additional cooling line.

1 is a block diagram showing a hybrid cooling device according to an embodiment of the present invention.
Figure 2 is a block diagram showing the flow of evaporative cooler and air and water in accordance with an embodiment of the present invention.
3 is a block diagram showing the dry channel and the wet channel, and the water direction of the evaporative cooler according to an embodiment of the present invention.

The hybrid cooling device according to the present invention is a method of making cold water by using a dehumidifying rotor and an evaporative cooler of the dehumidifying cooling device, and condensation on the surface of a radiator such as a floor or a ceiling of an air conditioning space when radiative cooling is performed using cold water. In this case, we propose a method to prevent condensation by using a hybrid cooling device and suggest a method to selectively perform floor cooling in connection with an existing on-floor heating system.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the hybrid cooling device according to an embodiment of the present invention.

As shown in Figure 1, the hybrid cooling device according to an embodiment of the present invention, the dehumidification cooling device 100 for cooling the dry air passing through the dehumidification rotor 140 by the cooler 150 or to create cold water, In the process of circulating the refrigerant additionally cools the cold water produced by the cooler 150 and at the same time supply air for the regeneration of the dehumidification rotor 140 and the air conditioning in the dehumidification air conditioner (100) It is made by combining the cold water supply device 300 for supplying cold water to the space 400, characterized in that configured to selectively perform the cooling or heating of the air conditioning space 400 utilizing each of these advantages.

To this end, the dehumidification cooling device 100, the dehumidification cooling housing 110 is divided into a dehumidification cooling passage 112 and the regeneration passage 113, the air or air intake in the air conditioning space 400 Intake air through the air supply blower 130 and the air blower 130, and the air blown along the dehumidification cooling passage 112 by suction through the dehumidification cooling passage 112 and along the regeneration passage 113 The dehumidification rotor 140, which is dried and regenerated by forced air blowing, the cooler 150 that cools the air flowing into the air-conditioning air intake port 120 and passes through the dehumidification rotor 140 or makes cold water, and outside air. Regeneration blower 170 for sucking the outside air through the inlet 160 and forcibly blowing the air to the outside air outlet 161 along the regeneration passage 113 and the outside air blown by the regeneration blower 170 to dehumidify the rotor 140. Dehumidification rotor 140 is appropriate by increasing the drying rate of And a heat exchanger 180 to be reproduced.

The dehumidification cooling housing 110 has a partition wall 111 installed at the center side to partition the interior into two spaces, and one of the two spaces partitioned by the partition wall 111 is an air conditioning space 400 or an exterior. The air is used as a dehumidification cooling passage 112 in which a process of removing moisture from the air and cooling or making cold water is performed, and another space is dehumidified by drying the dehumidification rotor 140 that absorbs moisture in the dehumidification cooling process. It is used as a regeneration passage 113 in which a process of regenerating the rotor 140 is performed.

In addition, by installing a cold water storage tank 320 inside or outside the dehumidification cooling housing 110 is configured to supply cold water to the air conditioning space (400).

In addition, the air inlet side 120 of the dehumidification cooling passage 112 provided at the upper portion of the dehumidification cooling housing 110 and the air conditioning air inlet 120 and integrally or adjacently installed therein to filter various foreign substances or bacteria harmful to the human body. An intake filter 120a is provided.

In addition, the air intake side of the regeneration passage 113 provided in the lower portion of the dehumidification cooling housing 110, the outside air intake port 160 and the air intake filter that is installed integrally or adjacent to it to filter various foreign substances or bacteria harmful to the human body ( 160a).

The air supply blower 130 sucks air or outside air in the air conditioning space 400 to forcibly blow the air along the dehumidification cooling passage 112, and is installed side by side in the dehumidification cooling passage 112. From the air-conditioning air exhaust port 155 or the air-conditioning air supply port 121, the air-conditioning air is forcibly blown.

In addition, an air supply air damper 122 is installed at the front end of the air supply air supply 121 to exhaust the air through the air volume and air conditioning air outlet 155 according to the opening degree of the air supply damper 122 to the outside. Allow the air volume to be adjusted.

When a large amount of cold water is required, the air supply damper 122 is closed to send the cooled air passing through the gun channel 151 of the cooler 150 to the wet channel 152 to be exhausted to the outside through the air conditioning air exhaust port 155. When the air conditioning space 400 is moist and condensation occurs, and dehumidification is required, the air supply damper 122 is opened to pass through the dry channel 151 of the cooler 150, and then a part of the cooled air is supplied to the air conditioning air supply 121. Air supply to the air conditioning space 400 through). The amount of air supplied to the air conditioning space 400 through the air conditioning air supply 121 is about 50 to 70% of the total amount of air passing through the gun channel 151.

The dehumidification rotor 140 absorbs moisture from the air conditioning space 400 or air introduced from the outside in the dehumidification cooling passage 112 in the process of rotating during the cooling operation, and continues to be dried by outside air in the regeneration passage 113. By absorbing moisture as above, it is installed to be rotatable in the dehumidification cooling housing 110, a dehumidifying material such as silica gel or zeolite (zeolite) is embedded, the dehumidifying material is a predetermined pattern (eg honeycomb pattern, etc.) ), And the radius of the dehumidification rotor 140 is approximately the length corresponding to the width of the dehumidification cooling passage 112 and the regeneration passage 113, along the dehumidification cooling passage 112 and the regeneration passage 113. Flowing air is configured to pass through the dehumidification rotor 140.

Therefore, when a part of the rotating dehumidification rotor 140 is located in the dehumidification cooling passage 112, the part of the dehumidification rotor 140 that absorbs moisture of the air-conditioning air in the corresponding part and continuously rotates to absorb moisture. When moved to the regeneration passage 113 is dried again by the outside air, and repeats the absorption and regeneration process through the rotation.

The cooler 150 is installed at the output side of the dehumidification rotor 140, and the high temperature and low humidity air conditioner (dry bulb temperature 42 ° C., relative humidity) is removed while passing through the dehumidification rotor 140 as shown in FIGS. 2 and 3. Humidity 15%) is passed through the dry channel 151 of the cooler 150 to produce low-temperature dry air (dry bulb temperature 22 ℃, relative humidity 75%), the low-temperature dry air conditioning air in the wet channel of the cooler 150 By passing through 152, it becomes high temperature humid air (dry bulb temperature of 32 degreeC, relative humidity of 95%), and is exhausted outside through the air-conditioning air exhaust port 155.

As shown in FIG. 2, the dehumidification cooling passage 112 at the upper side of the cooler 150 is provided with an outlet separation guide 153, and the air introduced into the dehumidification cooling passage 112 is supplied to the cooler 150. And the flow path of the air discharged to the air-conditioning air exhaust port 155 after passing through the cooler 150 are separated from each other.

In the process of passing low temperature dry air passing through the dry channel 151 of the cooler 150 through the wet channel 152 of the cooler 150, after passing through the air conditioning space 400, it follows the cold water line 330. The recovered water or water stored in the cold water storage tank 320 is poured into the wet channel 152 through the water pouring device 157, and the injected water is evaporated in the wet channel 152 to take away the latent heat. The latent heat exchanges heat with the gun channel 151 of the cooler 150 to cool the air passing through the gun channel 151. In addition, the latent heat of evaporation cools the water passing through the wet channel 152 without being evaporated in the water poured into the wet channel 152, thereby making cold water.

In order to lower the temperature of the water flowing along the wet channel 152 without evaporating water in the wet channel 152, the flow direction of the water to be poured is opposite to the flow direction of the air passing through the wet channel 152. Must be maintained. If the flow direction of the injected water is the same as the flow direction of the air passing through the wet channel 152, the latent heat of evaporation absorbed by the wet air passing through the wet channel 152 is transferred back to the water, so the water being poured is not cooled. This is because the temperature of the water becomes high as it is heated.

Since the temperature of the water flowing without being evaporated and evaporated to the cooler 150 is lowered, there is an advantage of preventing propagation of Lazionella bacteria. Since the water is preferably flowing through the wet channel 152 by free fall, the air flow of the dry channel 151 is from the top to the bottom, the air flow of the wet channel 152 is preferably from the bottom to the top.

Cold water produced in the wet channel 152 of the cooler 150 is collected in the drain plate 310 provided below the cooler 150 and stored in the cold water storage tank 320 installed below. The cold water stored in the cold water storage tank 320 is secondarily cooled through heat exchange with the evaporator 240 of the compressed air cooling apparatus 200 installed in the cold water storage tank 320, and thus the cold water line 330 by the circulation pump 350. Will be sent to the air conditioning space (400).

In addition, the cold water sent to the air conditioning space 400 is returned to the cold water storage tank 320 by the circulation pump 350 or sent to the water supply device 157.

When cooling water is supplied to the air conditioning space 400 to radiate cooling such as floor cooling, condensation may occur on the floor surface or ceiling when the humidity of the air conditioning space 400 is high, and in order to prevent condensation, Dehumidification of the air conditioning space 400 through a separate dehumidifier such as. As such, when dehumidification of the air conditioning space 400 is required, the air supply damper 122 installed at the lower end of the cooler 150 is opened to partially remove the low temperature dry air passing through the dry channel 151 of the cooler 150. It is configured to be sent to the air conditioning space 400 through the air supply 121.

The regenerative blower 170 installed in the regeneration passage 113 of the dehumidifying air conditioner 100 sucks outside air and forcibly blows the air along the regeneration passage 113. It is provided in the direction which forcibly blows outside air toward the outside air exhaust port 161 from 160.

The heat exchanger 180 heats the outside air blown by the regenerative blower 170 to increase the drying rate of the dehumidification rotor 140 so that the dehumidification rotor 140 is properly regenerated. The preheated outside air while passing through the compressor 210 and the condenser 220 is further heated to a temperature suitable for heating and removing (ie, evaporating) moisture absorbed in the dehumidifying rotor 140.

The heat exchanger 180 includes a heat exchanger 181 configured to circulate hot water through the heat exchange housing, and a hot water line 182 that supplies hot water to the heat exchanger 181.

In particular, hot water is most preferably heated and supplied using waste heat generated by cogeneration in a cogeneration plant (not shown), and when such hot water is used to dry the dehumidification rotor 140, In the reality that the heat production ratio is fixed at 3: 5, the ratio of power load and heat load is properly maintained even in summer when the heat load is relatively small, and the effect of the group energy project can be maximized.

Of course, such hot water may be used by using geothermal or solar heat in addition to the waste heat generated from cogeneration.

On the other hand, the present invention is characterized in that it is configured to be cooled by the compression type cooling device 200 in parallel with the cooling is performed by the dehumidifying cooling device 100 as described above.

To this end, the compression type cooling device 200 is installed in the regeneration passage 113 and the compressor 210 for compressing the refrigerant at high temperature and high pressure, and is installed in the regeneration passage 113 and connected to the refrigerant output terminal of the compressor 210. A condenser 220 for condensing the refrigerant compressed to high temperature and high pressure, an expansion valve 230 connected to the output terminal of the condenser 220 to expand the refrigerant, and a cold water storage tank 320 installed in the expansion valve 230. Is connected to the output terminal evaporator 240 and the compressor 210 to evaporate the refrigerant expanded at low pressure, the condenser 220, expansion valve 230 and the evaporator 240 is connected to each other to achieve a refrigerant circulation cycle A refrigerant pipe 201 is included.

Therefore, in the process of compressing, condensing, expanding, and evaporating the refrigerant circulating through the refrigerant pipe 201, the condenser 210, the condenser 220, the expansion valve 230, and the evaporator 240, the regeneration passage ( The compressor 210 and the condenser 220 installed at 113 preheat the outside air, and the evaporator 240 installed at the dehumidification cooling passage 112 further cools the cold water stored in the cold water storage tank 320.

That is, the compressor 210 compresses the refrigerant using a motor (not shown), and in this process, preheats the outside air using waste heat generated when the motor is driven, and the condenser 220 provides the refrigerant provided by the compressor 210. By exchanging heat with the outside air in the process of condensation, the temperature of the outside air is increased, and the evaporator 240 exchanges heat with cold water in the cold water storage tank 320 in the process of evaporating the refrigerant expanded to low pressure in the expansion valve 230. The cold water temperature of the cold water storage tank 320 is lowered.

In this way, the compressor 210 and the condenser 220 is installed on the air input side of the heat exchanger 180 to preheat the outside air input to the heat exchanger 180 by drying efficiency for regeneration of the dehumidification rotor 140. The evaporator 240 is installed in the cold water storage tank 320 to further cool the cold water primarily cooled in the cooler 150 by using the latent heat of evaporation of the refrigerant to further cool the cold water. Can be lowered.

On the other hand, the hybrid cooling device according to the present invention, hot water between the hot water line 182 connected to the heat exchanger 180, and the cold water storage tank 320 and the cold water line 330 connecting between the air conditioning space 400. By connecting the connection line 183, by installing a three-way valve 340 at the branch point of the cold water line 330 and the hot water connection line 183, it is possible to selectively perform the cooling and heating of the air conditioning space 400 , Hot and cold water line (330a) installed in the air conditioning space 400 is characterized in that it is configured to be used in combination with the hot water line for floor heating.

When cooling the air conditioning space 400, the three-way valve 340 forms a flow path so that the cold water of the cold water storage tank 320 flows through the air conditioning space 400, the cold water stored in the cold water storage tank 320 The air flows along the cold water line 330 by the operation of the circulation pump 350 to cool the air conditioning space 400 while passing through the cold and hot water line 330a in the air conditioning space 400, and the air conditioning space 400 The cold water passed through is stored in the cold water storage tank 320 or supplied to the wet channel 152 of the cooler 150 through the water supply device 157.

When heating the air conditioning space 400, the three-way valve 340 is switched to the flow path so that the hot water through the air conditioning space 400 along the hot water line 182 and the hot water connection line 183, the cold water storage tank ( Cold water supply between the 320 and the air conditioning space 400 is blocked. In this case, the hot water introduced into the hot water line 182 passes through the cold and hot water line 330a installed in the air conditioning space 400 along the hot water connecting line 183 by the operation of the circulation pump 350 to the air conditioner 400. The heating is performed, and the hot water passing through the air conditioning space 400 is returned to the hot water line 182 along the hot water connection line 183.

According to the present invention having the above-described configuration, when only the cold water is supplied to the air conditioning space 400 when the air conditioning space 400 is cooled, the air supply damper 122 is closed so that the cold water produced by the cooler 150 is not supplied. In the first operation mode for supplying the air conditioning space 400, and the air conditioning space 400 is cooled and dehumidification is required when the air supply damper 122 is opened to supply air to the air conditioning space 400 and at the same time to create cold water air conditioning space It may be operated in the second operation mode to supply to the 400, when heating the air conditioning space 400 it is possible to heat the air conditioning space 400 by circulating the hot water in the air conditioning space 400.

The specific embodiments of the present invention have been described above. It is to be understood, however, that the scope and spirit of the present invention is not limited to these specific embodiments, and that various modifications and changes may be made without departing from the spirit of the present invention. If you have, you will understand.

Therefore, the embodiments described above are provided to fully inform the scope of the invention to those of ordinary skill in the art, and should be understood as illustrative and not limiting in all respects. The invention is only defined by the scope of the claims.

100: dehumidification cooling device 110: dehumidification cooling housing
111: bulkhead 112: dehumidification cooling passage
113: regeneration passage 120: air intake
120a: air conditioning air intake filter 121: air conditioning air supply
122: air supply damper 130: air supply blower
140: dehumidification rotor 150: cooler
151: dry channel 152: wet channel
153: exit guide 155: air conditioning vent
157: water supply device 160: outside air intake
160a: outside air intake filter 161: outside air exhaust port
170: regenerative blower 180: heat exchanger
181: heat exchanger 182: hot water line
183: hot water connection line 200: compressed air cooling device
210: compressor 220: condenser
230: expansion valve 240: evaporator
300: cold water supply device 310: drain plate
320: cold water storage tank 330: cold water line
330a: cold / hot water line 340: three-way valve
350: circulation pump 400: air conditioning space

Claims (10)

A dehumidification cooling housing whose interior is divided into a dehumidification cooling passage and a regeneration passage by a partition wall, and installed in the dehumidification cooling housing to be rotatable over the dehumidification cooling passage and the regeneration passage, and a dehumidifying material is built into the dehumidification cooling passage. A dehumidification rotor to remove moisture contained in the air, a heat exchanger for heating the air passing through the regeneration passage for regeneration of the dehumidification rotor, and installed in the dehumidification cooling passage and passing through the dehumidification rotor to remove moisture. A dehumidification cooling apparatus including a cooler for making cold water by using latent heat of evaporation of water by passing air through water injected from a drinking water device, and a blower for forcibly blowing air of the dehumidification cooling passage and the regeneration passage; And
And a cold water supply device for collecting and circulating the cold water produced by the cooler to pass through the air conditioning space. The method of claim 1,
The cooler,
A dry channel through which dry air passing through the dehumidification rotor passes;
A wet channel for recovering some or all of the air passing through the dry channel;
A water supply device for spraying water into the wet channel; And
And an exhaust port for discharging the air passing through the wet channel to the outside. The method of claim 2,
The flow direction of air passing through the dry channel and the flow direction of air passing through the wet channel are opposite to each other, and the flow direction of air flowing through the wet channel and the flow direction of water injected into the wet channel are opposite to each other. Hybrid cooling device, characterized in that the direction. The method of claim 3,
A part of the water poured into the wet channel is evaporated by the air passing through the wet channel, and heat exchanges with the dry channel by the latent heat of evaporation of the evaporated water, thereby cooling the air passing through the dry channel to the temperature of the remaining water. Hybrid cooling device, characterized in that to make cold water by cooling. The method of claim 2,
The cooler is provided with an air supply damper and an air supply air supply so that a part of the air passing through the gun channel is sent to the wet channel, and the remainder of the air passing through the gun channel is directly supplied to the air conditioning space. Hybrid air conditioning unit. The method of claim 5,
In the cooling operation of the air conditioning space, the air supply damper is closed so that the air is not supplied to the air conditioning space, and all the air passing through the dry channel is sent to the wet channel to supply the cold water generated in the cooler to the air conditioning space. Wow;
During the dehumidification and cooling operation of the air conditioning space, the air supply damper is opened so that a part of the air passing through the gun channel is supplied to the air conditioning space through the air conditioning air supply, and the remaining air passing through the gun channel is And a second operation mode which is sent to a wet channel to form cold water in the cooler to supply cold water to an air conditioning space. The method of claim 1,
The cold water supply device,
A drain plate collecting cold water made by the cooler;
Cold water storage tank for storing the cold water collected in the drain plate;
A cold water line for supplying cold water from the cold water storage tank to an air conditioning space;
A three-way valve provided at a branch point of a hot water connection line connecting the cold water line and the hot water line of the heat exchanger to switch a flow path to selectively supply hot water or cold water to the air conditioning space; And
And a circulation pump configured to circulate the cold water to the air conditioning space and the water supply device or to circulate the hot water supplied to the heat exchanger to the air conditioning space. The method of claim 7, wherein
In the air conditioning space, the cold and hot water line is circulated through the cold water or hot water selectively supplied by switching the flow path of the three-way valve is installed, the cold and hot water line is a hybrid cooling, characterized in that used in combination with cold water line and hot water line Device. 9. The method according to any one of claims 1 to 8,
The hybrid cooling device further comprises a compressor, a condenser, an expansion valve, an evaporator and a compression cooling device consisting of a refrigerant pipe connecting them,
The compressor and the condenser are installed at the air input side of the heat exchanger of the regeneration passage, and the outside air inputted to the heat exchanger using the waste heat generated when driving the compressor and the condensation heat generated in the process of condensing the refrigerant in the condenser. Preheat;
And the evaporator is installed in a cold water storage tank in which cold water made by the cooler is stored, to cool the cold water primarily cooled by the cooler secondly by latent heat of evaporation of the refrigerant. The method of claim 1,
Heat source of the hot water supplied to the heat exchanger is a hybrid cooling device, characterized in that provided using the waste heat, geothermal or solar heat of cogeneration.

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