KR101632494B1 - Hybrid dehumidification system using supplying water of Indirect-Evaporation device in heat pump - Google Patents

Abstract

The present invention relates to a hybrid dehumidification cooling system using an indirect evaporative cooler drain in a heat pump.
The hybrid dehumidification cooling system using the indirect evaporative cooler drainage in the heat pump according to the present invention is characterized in that it comprises a evaporative cooler for spraying water to the wet channel, a wet channel (Wet channel) and a dry channel A condenser connected to an output end of the compressor to condense the compressed refrigerant; an expansion valve for expanding the refrigerant passing through the condenser; an evaporator connected to an output end of the expansion valve to evaporate the expanded refrigerant; And a heat exchanger disposed between the expansion valve and for exchanging heat between the water jetted into the wet channel and the refrigerant passing through the condenser.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hybrid dehumidification cooling system using indirect evaporation cooler drainage in a heat pump,

The present invention relates to a hybrid dehumidification cooling system using an indirect evaporative cooler drain in a heat pump.

Generally, the hybrid dehumidification cooling system is a hybrid of the latent heat of evaporation of water and the refrigerant cycle to supply cooling in the summer.

In the hybrid dehumidification cooling system, the moisture contained in the indoor air is removed from the dehumidifier, and the dehumidifier to which the moisture is adsorbed is regenerated by the outdoor air heated by the heat exchange medium such as the condenser and the hot water or heater.

Such a hybrid dehumidification cooling system includes a dehumidification rotor, an indoor blower, an evaporative cooler, and a water dispenser.

In the water purifier, water is sprayed to the evaporative cooler and sprayed to the wet channel, and the room air supplied by the indoor blower is dehumidified by the dehumidification rotor and then cooled by the latent heat of evaporation of water while passing through the wet channel.

Also, a hot water coil connected to the hot water pipe includes a refrigerant cycle system including a compressor, a condenser, an expansion mechanism, and an evaporator to form a coolant cycle.

After the outside air is heated in the process of passing through the hot water coil and the condenser, it is applied to the dehumidification rotor to remove (i.e., regenerate) the moisture adsorbed to the dehumidification rotor.

On the other hand, the evaporator further cools the room supply air with an evaporative cooler.

However, according to the conventional method as described above, when the outside air supplied to the condenser is not sufficiently supplied, the temperature of the outside air is abnormally high due to global warming, or the static pressure of the duct is higher than the designed value, If not sufficient, the refrigerant passing through the condenser may not be sufficiently liquefied.

Therefore, there has been a problem in that a high pressure rise occurs in the compressor and the cooling capacity is deteriorated.

An object of the present invention is to provide a hybrid dehumidification cooling system in which water is supplied from an water purifier to an evaporative cooler to perform heat exchange, and then water to be discharged is used as a medium for further cooling the condensed refrigerant in the refrigeration cycle.

A condenser for compressing the refrigerant; a condenser connected to the output of the compressor for condensing the refrigerant; and a condenser for condensing the condensed refrigerant, An evaporator connected to an output end of the expansion valve to evaporate the expanded refrigerant, and a condenser disposed between the condenser and the expansion valve, the condenser being connected to the condenser, And a heat exchanger for exchanging heat between the refrigerant passing through the condenser and the refrigerant.

Further, the apparatus may further include a housing including a dehumidification cooling space and a regeneration space, wherein the evaporator and the evaporation cooler are installed in the dehumidification cooling space, and the condenser may be installed in the regeneration space.

The dehumidifying rotor further includes a dehumidifying rotor rotatably installed in the housing and including a dehumidifying agent. The dehumidifying rotor may correspond to the dehumidifying cooling space and the regeneration space.

In addition, the evaporation cooler can cool the air that has passed through the dehumidification rotor.

The apparatus may further include a first fan installed in the dehumidification cooling space and a second fan installed in the regeneration space.

The hybrid cooling apparatus according to the present invention is characterized in that a heat exchanger is provided between a condenser and an expansion valve and heat exchanged between the water passing through the evaporator and the refrigerant passing through the condenser is performed using a heat exchanger to supercool the liquefied refrigerant, Thereby improving the cooling performance and reducing power consumption.

1 is a view for explaining a functional block of a hybrid dehumidification cooling system according to the present invention; And
2 to 3 are views for explaining the configuration of the hybrid dehumidification cooling system according to the present invention.

Hereinafter, a hybrid dehumidification cooling system using an indirect evaporative cooler drain in a heat pump according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a view for explaining a hybrid dehumidification cooling system using an indirect evaporative cooler drain in a heat pump according to the present invention.

1, a hybrid dehumidification cooling system 10 according to the present invention includes an evaporation cooler 100, an evaporator 110, a compressor 120, a condenser 130, a heat exchanger 140, and an expansion valve 160 .

The evaporative cooler 100 may include a wet channel and a dry channel and may spray water to the wet channel to lower the temperature of the air passing through the wet channel.

To this end, the evaporative cooler 100 may include a water injector 101 capable of spraying water.

The compressor (120) can compress the refrigerant under a high temperature and high pressure state.

The condenser 130 is connected to an output end of the compressor 120, and can condense the refrigerant compressed by the compressor 120.

The expansion valve 150 may expand the refrigerant that has passed through the condenser 130 to a low temperature and a low pressure.

The heat exchanger 140 may be disposed between the condenser 130 and the expansion valve 150. The heat exchanger 140 may exchange heat between the water sprayed into the wet channel of the evaporative cooler 100 and the refrigerant that has passed through the condenser 130.

The evaporator 110 may be connected to an output end of the expansion valve 150 to evaporate the expanded refrigerant. At this time, the refrigerant can take the surrounding heat and lower the ambient temperature.

Meanwhile, although not shown, the hybrid dehumidification cooling system 10 according to the present invention may include a temperature sensor and / or a pressure sensor for adjusting a refrigerant flow rate according to an indoor load.

The operation principle of the hybrid dehumidification cooling system 10 will be described below.

The main water pump 170 can supply water from the water reservoir 160 to the evaporative cooler 100.

Then, the water injecting apparatus 101 of the evaporative cooler 100 injects water to cool water passing through a wet channel (not shown).

In detail, the water injection apparatus 101 can spray water to wet the wet channel surface on the wet channel surface of the evaporative cooler 100.

Then, air passing through a dehumidification rotor (not shown) can be cooled by the latent heat of evaporation of water in the process of passing through the wet channel of the evaporative cooler 100.

Thereafter, the cooled air can be blown into the room to lower the room temperature.

The water supplied to the evaporative cooler 100 and cooled with air may be supplied to the heat exchanger 140. The refrigerant passing through the condenser 130 may be supplied to the heat exchanger 140.

Heat exchange between the water introduced from the evaporative cooler 100 and the refrigerant passing through the condenser 130 can be performed in the heat exchanger 140.

The water passing through the heat exchanger 140 can be drained. Or the water passing through the heat exchanger 140 may be recovered to the water tank 160.

An example of implementing a cooling apparatus having such a function block will be described below.

Figs. 2 to 3 are views for explaining a configuration of a hybrid cooling apparatus according to the present invention. Fig. In the following, the description of the parts described above may be omitted.

Referring to FIG. 2, the hybrid dehumidification cooling system 10 according to the present invention may include a housing 11.

The housing 11 may include a dehumidifying cooling space 11B and a regeneration space 11A.

The dehumidifying cooling space 11B and the regeneration space 11A can be divided into the partition 270.

The hybrid dehumidification cooling system 10 may further include a dehumidifying rotor (ROTOR) 200 installed to be rotatable in the housing 11 and containing a dehumidifying agent. The dehumidification rotor 200 can rotate in the housing 11 to remove moisture from the air passing through the dehumidification cooling space 11B. In addition, the dehumidification rotor 200 can be regenerated by discharging the adsorbed moisture in the regeneration space 11A.

To this end, the dehumidification rotor 200 may correspond to the dehumidification cooling space 11B and the regeneration space 11A in common.

The predetermined portion of the dehumidification rotor 200 adsorbs moisture in the dehumidification cooling space 11B and then the predetermined portion is discharged from the dehumidification cooling space 11B into the regeneration space 11A as the dehumidification rotor 200 rotates. . ≪ / RTI > Thereafter, the moisture adsorbed to a predetermined portion of the dehumidification rotor 200 in the regeneration space 11A can be removed.

The hybrid dehumidification cooling system 10 according to the present invention includes a first fan 220 for effectively circulating air in the dehumidification cooling space 11B and a second fan 220 for effectively circulating air in the regeneration space 11A. And a second fan (210).

To this end, the first blowing fan 220 may be installed in the dehumidification cooling space, and the second blowing fan 210 may be installed in the regeneration space.

At least one of the first blowing fan 220 and the second blowing fan 210 may be controlled in rotation speed. For example, when the load increases, the number of revolutions of the first blowing fan 220 and the second blowing fan 210 is increased. In the case where the load decreases, the number of rotations of the first blowing fan 220 and the second blowing fan 210 2 blowing fan 210 can be reduced.

In the dehumidification cooling space 11B of the housing 11, the dehumidified / cooled air is introduced into the air conditioning space in the first inlet 260 and the dehumidification cooling space 11B, through which the air in the air conditioning space (or the room) A first outlet 250 may be formed.

In addition, a second inlet 230, which is a passage through which the outside air is introduced, and a second outlet 230, which is a passage through which moisture obtained in the regeneration space 11A is discharged, is provided in the regeneration space 11A of the housing 11 240 may be formed.

When the dehumidification cooling space 11B is compared with the regeneration space 11A, dehumidification and evaporation cooling by the latent heat of evaporation of water are performed in the dehumidification cooling space 11B. In the regeneration space 11A, Can be achieved.

Accordingly, the evaporator 110 and the evaporative cooler 100 may be installed in the dehumidification cooling space 11B, and the condenser 130 may be installed in the regeneration space 11A.

For example, the first blowing fan 220, the evaporative cooler 100, the expansion valve 150, the evaporator 110, and the heat exchanger 140 may be disposed in the dehumidification cooling space 11B. In addition, the second blowing fan 210, the compressor 120, and the condenser 130 may be disposed in the regeneration space 11A.

The dehumidification cooling space 11B is referred to as a dehumidification cooling system, and the regeneration space 11A can be referred to as a cooling cycle system.

The dehumidification rotor 200 may be installed over the dehumidification cooling space 11B and the regeneration space 11A. The dehumidification rotor 200 can rotate around the partition 270.

Although not shown, at least one of the first inlet 260, the first outlet 250, the second inlet 230, and the second outlet 240 may be provided with a filter (Filter Can be disposed.

The operation of the hybrid dehumidification cooling system 10 having such a configuration will be described below.

When the first blowing fan 220 rotates, air in the air conditioning space can be introduced into the dehumidifying cooling space 11B through the first inlet 260. [

Then, the dehumidification rotor 200 can adsorb moisture from the air introduced into the dehumidification cooling space 11B. In detail, the dehumidifying material contained in the dehumidification rotor 200 can adsorb moisture.

Accordingly, the air that has passed through the dehumidification rotor 200 can be referred to as dry air.

It is possible to block the dehumidification cooling space 11B to improve the dehumidification efficiency of the dehumidification rotor 200. [ Ideally, the air introduced into the dehumidification cooling space 11B through the first inlet 260 can proceed toward the evaporation cooler 100 only through the dehumidification rotor 200. [

The dehumidification rotor 200 may be formed in a thin cylindrical shape including a rotating blade and a rotating shaft, though not shown in the drawing.

The dehumidifying rotor 200 is rotated around a rotating shaft by a motor (not shown), and the rotating blade can be provided with a dehumidifying material in a predetermined pattern, for example, a honeycomb pattern.

The dehumidifying material contained in the dehumidifying rotor 200 may be silica gel, zeolite, or the like.

As with the first and second blowing fans 220 and 210, the rotational speed of the dehumidifying rotor 200 can be increased as the load increases.

The dehumidified air passing through the dehumidification rotor (200) can be cooled while passing through the evaporative cooler (100).

For example, air that has passed through the dehumidification rotor 200 can pass through the wet channel 100B of the evaporative cooler 100 and the dry channel 100A.

Here, the water sprayed on the wet channel surface of the evaporative cooler 100 can cool the air passing through the wet channel 100B by latent heat of vaporization.

Through this process, the evaporative cooler 100 can cool the dry air.

The wet channel 100B and the dry channel 100A may mean a passage through which air can pass.

Thereafter, the air that has passed through the evaporative cooler 100 can be further cooled while passing through the evaporator 110.

The air sufficiently cooled through the evaporator 110 can be supplied to the air conditioning space through the first outlet 250.

It is also possible to provide another blowing fan at the first outlet 250 to improve the supply efficiency of the cooling air.

The heat exchanger 140 for exchanging heat between the refrigerant passing through the condenser 130 and the water passing through the evaporative cooler 100 may be applied to various types.

For example, the heat exchanger 140 may be a plate-type heat exchanger, a double-tube heat exchanger, or the like.

Preferably, heat exchanger 140 may be a dual tube heat exchanger.

The dual tube heat exchanger may include an inner tube and an outer tube surrounding the inner tube. Water can flow through either the inner tube or the outer tube and the refrigerant can flow through the other tube.

The refrigerant passing through the heat exchanger 140 may be supercooled.

Accordingly, even when the inflow amount of the outside air is insufficient or the temperature of the outside air is abnormally high, the refrigerant can be sufficiently condensed, so that the deterioration of the dehumidifying cooling ability can be prevented.

In addition, since the heat exchanger 140 uses water that has passed through the evaporative cooler 100 for heat exchange with the coolant, the cooling efficiency of the evaporative cooler 100 can be prevented from being lowered.

On the other hand, when the second blowing fan 210 rotates, external air can be introduced into the regeneration space 11A through the second inlet 230.

The temperature of the air flowing into the regeneration space 11A may increase while passing through the compressor 120 and the condenser 130. [

The air having passed through the compressor (120) and the condenser (130) and having a raised temperature can remove the moisture adsorbed by the dehumidification rotor (200) while passing through the dehumidification rotor (200). Thus, the dehumidification rotor 200 can be regenerated. That is, the dehumidification rotor 200 can be dried.

As described above, the dehumidification rotor 200 absorbs moisture in the dehumidification cooling space 11B, and then removes the moisture adsorbed in the regeneration space 11A by rotation using hot air.

In order to improve the drying efficiency of the dehumidification rotor 200, it is also possible to provide another blowing fan at the second outlet 240.

Although not shown, it may be possible to further include a heating device for heating the air introduced into the regeneration space 11A to further improve the drying efficiency of the dehumidification rotor 200. [

On the other hand, the heat exchanger 140 may be arranged at a position other than the dehumidification cooling space 11B.

For example, the heat exchanger 140 may be located in the regeneration space 11A as in the case of FIG.

Thus, the heat exchanger 140 can be positioned between the regeneration space 11A and the dehumidification cooling space 11B.

As described above, it is to be understood that the technical structure of the present invention can be embodied in other specific forms without departing from the spirit and essential characteristics of the present invention.

It should be understood, therefore, that the embodiments described above are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than the foregoing description, And all changes or modifications derived from equivalents thereof should be construed as being included within the scope of the present invention.

Claims (5)

An evaporative cooler including a wet channel and a dry channel for primarily cooling the indoor air by spraying water into the wet channel;
A compressor for compressing the refrigerant;
A condenser connected to the output of the compressor for condensing the compressed refrigerant;
An expansion valve for expanding the refrigerant that has passed through the condenser;
An evaporator connected to an output end of the expansion valve to evaporate the expanded refrigerant to thereby cool the room air secondarily;
A heat exchanger disposed between the condenser and the expansion valve for exchanging heat between water sprayed into the wet channel and the refrigerant passing through the condenser; And
A housing including a dehumidifying cooling space and a regeneration space,
Wherein the evaporator and the evaporation cooler are installed in the dehumidification cooling space, wherein the evaporator is installed on a downstream side of the evaporation cooler with respect to a flow direction of the indoor air,
The condenser is installed in the regeneration space,
A dehumidifying rotor rotatably installed in the housing and including a dehumidifying agent, wherein the dehumidifying rotor is commonly associated with the dehumidifying cooling space and the regeneration space,
Wherein the evaporation cooler cools the air passing through the dehumidification rotor. delete delete delete The method according to claim 1,
A first fan installed in the dehumidification cooling space and a second fan installed in the regeneration space.

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