KR101416675B1 - Thermohygrostat with enhanced dehumidification ability - Google Patents

Abstract

The present invention relates to a thermo-hygrostat having a reheat condenser and includes an indoor expansion valve input tube and a reheat condenser input tube capable of inputting refrigerant discharged from an outdoor heat exchanger of a thermo-hygrostat unit to an indoor expansion valve and a reheat condenser of an indoor unit And a first solenoid valve and a second solenoid valve selectively opened in each of the input tubes, wherein the refrigerant discharged from the reheat condenser output tube is connected to the indoor expansion valve without passing through the first solenoid valve, Wherein the first solenoid valve is opened and the second solenoid valve is opened to condense the high temperature and high pressure gas refrigerant compressed in the compressor into the outdoor heat exchanger to condense the refrigerant into liquid refrigerant, The refrigerant is sequentially introduced into the reheat condenser, the indoor expansion valve, and the indoor heat exchanger connected to the indoor expansion valve, And the indoor air is passed through the indoor heat exchanger where evaporation of the refrigerant is made to be dehumidified, and the dehumidified room air is again passed through the reheat condenser to reheat the room air reheat.

Description

{THERMOHYGROSTAT WITH ENHANCED DEHUMIDIFICATION ABILITY}

More particularly, the present invention relates to a constant temperature and humidity device, and more particularly, to an indoor / outdoor heat exchanger having an outdoor heat exchanger in an outdoor unit, an indoor heat exchanger and a reheat condenser in an indoor unit, The present invention relates to a thermo-hygrostat having a reheat condenser which does not change the room temperature even in the dehumidifying operation by reheating by a condenser and discharging it to the room.

Generally, the thermo-hygrostat is equipped with a control unit (also referred to as a hot gas controller) to detect when the temperature or humidity of the room deviates from the set temperature or the set temperature by more than an error range, Heating, dehumidifying or humidifying operation.

Since the room where the thermo-hygrostat is installed is a room mainly equipped with a system or device generating a lot of heat such as a medical equipment room, an IT room, a precision measuring room, an engine laboratory, a clean room of a semiconductor factory, and an electronic board production room, The humidification operation is mainly performed, but in the winter season, the heating operation is performed as necessary.

In the conventional thermo-hygrostat, the heating operation was performed by stopping the refrigeration cycle, operating only the heating heater, and circulating the indoor air by the blower. However, this type of heating method requires a long time to reach a set temperature, and has a disadvantage in that it consumes a large amount of power due to its inefficiency.

In a conventional thermo-hygrostat, cooling is performed by a compressor that is provided in an outdoor unit according to a normal refrigeration cycle and compresses a gas refrigerant to a high temperature and a high pressure, and a refrigerant that is provided in an outdoor unit and is discharged from a high- An outdoor heat exchanger for releasing the liquid refrigerant into a high-pressure liquid refrigerant and introducing it into the indoor heat exchanger, a low-pressure liquid which is easily evaporated in the indoor heat exchanger by dropping the pressure of the liquid refrigerant in advance before sending the high-pressure liquid refrigerant to the indoor heat exchanger An indoor heat exchanger for circulating the indoor heat exchanger for cooling ambient air while depriving the latent heat of evaporation from the air passing through the surroundings while vaporizing the refrigerant introduced into the indoor heat exchanger is introduced into the indoor heat exchanger through a blower to remove heat And then introduced into the room again.

In the conventional thermo-hygrostat, the dehumidification is performed by cooling the room air in the indoor heat exchanger while cooling the air to cool it by the dew-point phenomenon, collecting the air in the drain pan, and discharging the air through a drain At this time, since the air temperature is cooled below the dew point temperature of the set room humidity (usually around 12 ° C), it must be reheated to the set room temperature (usually about 22 ° C) and then sent out to the room. In order to reheat the cooled and moisture-depleted air, an outdoor heat exchanger and a reheat condenser are connected in parallel between the compressor and the indoor heat exchanger, and the dehumidified air passes through the indoor heat exchanger And a solenoid valve is provided in each of the refrigerant inlet pipes of the outdoor heat exchanger and the reheat condenser so that the solenoid valve is selectively opened and closed by the control unit to close the solenoid valve of the outdoor heat exchanger during the dehumidifying operation, The refrigerant circulation cycle through the compressor, the reheat condenser, the expansion valve, the indoor heat exchanger, and the compressor is formed by opening the solenoid valve of the pipe (Korean Utility Model Registration No. 20-0403736, Korean Patent No. 10- 774357, Korean Utility Model Registration No. 20-396562). During the cooling operation in the thermo-hygrostat of this structure, the solenoid valve of the reheat condenser input tube is closed and the solenoid valve of the outdoor heat exchanger input tube is opened to supply the refrigerant passing through the compressor -> outdoor heat exchanger -> expansion valve - indoor heat exchanger -> compressor Thereby forming a circulation cycle.

However, in order to reheat the dehumidified air by the condensation heat generated by the high-temperature high-pressure gas (normally 20 Kg / cm 2, temperature 90 ° C or more) compressed by the compressor through the electromagnetic valve and entering the reheat condenser, there are two problems .

First, there is a problem that the room temperature rises during the dehumidification operation of the thermo-hygrostat. In order to maintain the constant temperature by compensating for the air cooling by the indoor heat exchanger during the dehumidification operation of the thermo-hygrostat, the reheat is performed by the reheat condenser. However, the room temperature rises above the set temperature in the dehumidification process. This is because the heat released from the reheat condenser is equal to the sum of the heat absorbed by the evaporator and the heat applied by the compressor. That is, in the dehumidification process, since the heat released from the reheat condenser (condenser) is always larger than the heat absorbed by the indoor heat exchanger (evaporator) where evaporation occurs, the indoor air is circulated through the indoor heat exchanger The indoor air will gradually rise in the dehumidification process because it gets more heat from the reheat condenser (condenser) than the heat from the room heat exchanger (evaporator).

Next, when the high-temperature and high-pressure gas refrigerant of the compressor is directly supplied to the reheat condenser via the solenoid valve of the reheat condenser input pipe, there is a problem that the solenoid valve is damaged in a short period of time. In order to control the refrigerant circulation in the refrigeration cycle, a 2-way valve, a 3-way valve and a 4-way valve are used in the refrigeration cycle. Among them, the three-way valve and the four-way valve are formed so that two or more flow paths are formed, so that the high-temperature refrigerant and the low-temperature refrigerant pass simultaneously, so that they are not exposed to high temperatures. However, when the high-temperature high-pressure gas refrigerant of the compressor is directly introduced into the two-way valve, as in the case of the solenoid valve used in the reheat condenser input tube, the valve is exposed to high temperature, .

A first object of the present invention is to provide a thermo-hygrostat having a reheat condenser not accompanied by an increase in room temperature during dehumidification .

A second problem to be solved by the present invention is to provide a constant temperature and humidity device that can extend the service life without damaging the solenoid valve of the input tube of the reheat condenser.

The above objects of the present invention are achieved by providing an indoor expansion valve input tube and a reheat condenser input tube capable of inputting refrigerant discharged from an outdoor heat exchanger of a thermo-hygrostat to an indoor expansion valve and a reheat condenser of an indoor unit, The refrigerant discharged from the reheat condenser output pipe is connected to the indoor expansion valve without passing through the first solenoid valve, and the refrigerant discharged from the reheat condenser output pipe The first solenoid valve is closed and the second solenoid valve is opened so that the high temperature and high pressure gas refrigerant compressed in the compressor is introduced into the outdoor heat exchanger to condense the refrigerant into the liquid refrigerant and the liquid refrigerant condensed in the outdoor heat exchanger is introduced into the reheat condenser , The indoor expansion valve, and the indoor heat exchanger connected to the indoor expansion valve, and the liquid refrigerant is introduced into the reheat condenser and the indoor heat exchanger, At the same time, allowing the room air to be dehumidified while passing through the indoor heat exchanger in which the evaporation of the refrigerant is performed, and allowing the dehumidified room air to pass through the reheat condenser again so as to be reheated. have.

According to the present invention having the above-described configuration, the high-temperature and high-pressure refrigerant compressed by the compressor at the time of dehumidification is not directly introduced into the reheat condenser but is first condensed in the outdoor heat exchanger, The room temperature is not increased during the dehumidification operation because the indoor air is balanced with the heat loss of the indoor heat exchanger and the heat absorbed by the reheat condenser so that the indoor temperature of the reheat condenser input pipe The temperature of the liquid refrigerant injected into the solenoid valve is not too high, so that damage to the solenoid valve can be prevented.

FIG. 1 is a view showing a refrigerant circulation structure in a dehumidification operation of a thermo-hygrostat according to the present invention.
FIG. 2 is a view showing a refrigerant circulation structure during a heating operation of the thermo-hygrostat according to the present invention.
FIG. 3 is a view showing a structure of a refrigerant circulation during a cooling operation of the thermo-hygrostat according to the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 3, in the thermo-hygrostat according to the present invention, unlike the conventional thermo-hygrostat having a reheat condenser, the reheat condenser HE3 is selectively or alternatively connected to the outdoor heat exchanger HE1 It is not a component of the refrigeration cycle but is added to the refrigeration cycle only during the dehumidification operation and excluded during other operations. Further, in the constant temperature and humidity chamber of the present invention, the outdoor heat exchanger (HE1) is always operated in all operations, unlike the constant temperature and humidity chamber having the conventional reheat condenser. The liquid refrigerant compressed and condensed while passing through the compressor (CP) and the indoor heat exchanger (HE3) during cooling or dehumidification selectively flows into the indoor expansion valve (E2) do.

As shown in Fig. 1, the circulation direction of the refrigerant is controlled by a four-way valve (FW). As the control unit controls the four-way valve (FW), the E port of the four-way valve FW is connected to the S port when the compressor high-pressure gas pipe 1 is connected to the C port of the four-way valve FW The C port of the four-way valve FW is connected to the S port when the high-pressure gas pipe 1 of the compressor is connected to the E port of the four-way valve FW 2 during the heating operation). The C port of the four-way valve FW is connected to the outdoor heat exchanger HE1, the E port of the four-way valve FW is connected to the indoor heat exchanger HE2, and the S port of the four- And is connected to the liquid gas heat exchanger (LG) by a low-pressure gas pipe (29). And the front end of the S port low-pressure gas pipe 29 is exposed at the open end in the liquid-gas heat exchanger LG. The compressor low-pressure gas pipe (31) is opened at its tip end in the liquid-gas heat exchanger (LG). Accordingly, the low-pressure gas refrigerant introduced into the liquid-gas heat exchanger LG through the S port low-pressure gas pipe 29 is sucked into the compressor low-pressure end through the compressor low-pressure gas pipe 31. The refrigerant pipe (3) connecting the C port of the four-way valve (FW) and the outdoor heat exchanger (HE1) becomes a high-pressure gas pipe during dehumidification and cooling operation and becomes a low-pressure gas pipe during heating operation. The refrigerant pipe (27) connecting the E port of the four-way valve (FW) and the indoor heat exchanger (HE2) becomes a low-pressure gas pipe during dehumidification and cooling operation and a high-pressure gas pipe during heating operation. Liquid pipes 5 to 25 are provided between the outdoor heat exchanger HE1 and the indoor heat exchanger HE2 and the reheat condenser HE3. The refrigeration cycle according to the present invention includes an outdoor expansion valve E1 on the side of the outdoor heat exchanger HE1 for performing a cooling function and a dehumidifying function as well as an indoor expansion valve E2 on the side of the indoor heat exchanger HE2 . Only the liquid refrigerant flowing from the indoor heat exchanger HE2 side to the outdoor heat exchanger HE1 passes through the outdoor expansion valve E1 and flows from the outdoor heat exchanger HE1 side to the indoor heat exchanger HE2 side, The first check valve C1 is disposed in parallel to the outdoor expansion valve E1 so as to bypass the outdoor expansion valve E1 and the flow direction of which is the side of the indoor heat exchanger HE2. Only the liquid refrigerant flowing into the indoor heat exchanger HE2 side from the outdoor heat exchanger HE1 passes through the indoor expansion valve E2 and flows into the outdoor heat exchanger HE1 side from the indoor heat exchanger HE2 side The liquid refrigerant is provided in parallel with the indoor expansion valve E2 so as to bypass the indoor expansion valve E1 and the second check valve C2 which is the side of the outdoor heat exchanger HE1 in the flow direction. A portion (11) of the liquid refrigerant tube is allowed to exchange heat with the low-pressure gas refrigerant while passing through the liquid-gas heat exchanger. The fresh gas of the liquid refrigerant can be removed and the superheating degree of the low-pressure gas refrigerant can be suitably increased.

An indoor expansion valve input tube 19 and a reheat condenser input tube 13 capable of injecting liquid refrigerant discharged from the outdoor heat exchanger HE1 into the indoor expansion valve E2 and the reheat condenser HE3, And a first solenoid valve S1 and a second solenoid valve S2 which are selectively or alternatively opened to the respective input tubes 19 and 13 are provided in the reheat condenser output tube HE3, And the refrigerant is directly connected to the indoor expansion valve E2 without passing through the first solenoid valve S1.

Between the output pipe 14 of the reheating condenser HE3 and the refrigerant pipe 27 connecting the E port of the four-way valve FW and the indoor heat exchanger HE2, a reheat condenser HE3 And a suction pipe 17 for introducing the liquid refrigerant remaining in the reheat condenser HE3 into the refrigerant circulation cycle when the refrigerant is not used in the refrigerant pipe 27. In the suction pipe 17, And a third solenoid valve S3 that is opened only during heating operation or cooling operation and closed during the dehumidification operation. By doing so, it is possible to solve the refrigerant shortage problem that may be caused by not using the reheat condenser HE3 during the heating operation or the cooling operation.

The operation of the present invention having such a configuration will be described below.

1, in the dehumidification operation of the thermo-hygrostat according to the present invention, the first solenoid valve S1 is closed, the second solenoid valve S2 is opened, and the third solenoid valve S3 is closed. Further, the compressor high-pressure pipe (1) is connected to the port c of the four-way valve (FW). Accordingly, the refrigerant flows from the compressor CP to the four-way valve FW, the outdoor heat exchanger HE1, the first check valve C1, the liquid-gas heat exchanger LG, ) -> Liquid refrigerant heat exchanger (LG) -> Reheating condenser (HE3) -> Third check valve (C3) -> Indoor expansion valve (E2) -> Indoor heat exchanger (HE2) -> compressor (CP).

Temperature refrigerant compressed by the compressor (CP) is introduced into the outdoor heat exchanger (HE1) to be condensed into liquid refrigerant, and the liquid refrigerant condensed in the outdoor heat exchanger (HE1) is supplied to the reheat condenser The refrigerant is sequentially introduced into the indoor expansion valve E2 and the indoor heat exchanger HE2 connected to the indoor expansion valve E2 to supercool the liquid refrigerant and evaporate in the reheat condenser HE3 and the indoor heat exchanger HE2 At the same time, the indoor air is caused to be dehumidified while passing through the indoor heat exchanger (HE2) in which evaporation of the refrigerant occurs, and the dehumidified room air is reheated through the reheat condenser (HE3).

That is, in the dehumidification operation of the thermo-hygrostat according to the present invention, the refrigerant passes through all of the outdoor heat exchanger HE1 and the reheat condenser HE3, and then is introduced into the indoor expansion valve E2. Therefore, the refrigerant is condensed in the outdoor heat exchanger HE1, then put into the reheat condenser HE3 in the liquid refrigerant state where the temperature is lowered, supercooled in the reheat condenser HE3, and then introduced into the indoor expansion valve E2. In this way, the high-temperature and high-pressure refrigerant compressed by the compressor during dehumidification is not directly fed into the reheat condenser, but is first condensed in the outdoor heat exchanger to make a low-temperature liquid refrigerant (typically 40 ° C to 50 ° C) The room temperature is balanced with the amount of heat lost by the indoor heat exchanger and the amount of heat absorbed by the reheating condenser, so that the room temperature does not rise during the dehumidifying operation. It is also possible to prevent the damage of the solenoid valve S2 of the reheat condenser input tube 13. [

2, in the heating operation of the thermo-hygrostat according to the present invention, the first solenoid valve S1 is opened, the second solenoid valve S2 is closed, and the third solenoid valve S3 is opened. Further, the compressor high-pressure pipe 1 is connected to the e port of the four-way valve FW. Therefore, the refrigerant flows from the compressor (CP) to the four-way valve (FW) to the indoor heat exchanger (HE2) to the second check valve (C2) to the liquid gas heat exchanger (LG) -> outdoor heat exchanger (HE1) -> 4-way valve (FW) -> liquid refrigerant heat exchanger (LG) -> compressor (CP). In this process, the refrigerant remaining in the reheat condenser HE3 flows into the refrigerant circulation cycle through the suction pipe 17.

3, in the cooling operation of the thermo-hygrostat according to the present invention, the first solenoid valve S1 is opened, the second solenoid valve S2 is closed, and the third solenoid valve S3 is opened. Further, the compressor high-pressure pipe (1) is connected to the port c of the four-way valve (FW). Accordingly, the refrigerant flows from the compressor (CP) to the four-way valve (FW) to the outdoor heat exchanger (HE1) to the first check valve (C1) to the liquid gas heat exchanger (LG) -> indoor heat exchanger (HE2) -> 4-way valve (FW) -> liquid refrigerant heat exchanger (LG) -> compressor (CP). In this process, the refrigerant remaining in the reheat condenser HE3 flows into the refrigerant circulation cycle through the suction pipe 17.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited thereto. Should be determined.

1 to 31: Refrigerant pipes C1 to C4: Check valve
CP: compressor E1, E2: expansion valve
FW: Four-way valve HE1: Outdoor heat exchanger
HE2: Indoor heat exchanger HE3: Reheating condenser LG: Liquid gas heat exchanger S1 to S3: Solenoid valve

Claims (1)

An indoor expansion valve input pipe 19 and a reheat condenser input pipe 13 capable of inputting the refrigerant discharged from the outdoor heat exchanger HE1 to the indoor expansion valve E2 and the reheat condenser HE3 of the indoor unit, The first solenoid valve S1 and the second solenoid valve S2 selectively open to the respective input tubes 19 and 13 are provided and the refrigerant discharged from the reheat condenser output tube 14 flows through the first solenoid valve S1 ) To be introduced into the indoor expansion valve (E2)
During the dehumidification operation of the thermo-hygrostat, the indoor air is sequentially passed through the indoor heat exchanger HE2 and the reheat condenser HE3 while the first solenoid valve S1 is closed and the second solenoid valve S2 is opened, Temperature refrigerant compressed by the compressor (CP) is introduced into the outdoor heat exchanger (HE1) and is primarily condensed in the outdoor heat exchanger (HE1) The condensed liquid refrigerant is introduced into the reheat condenser HE3 through the second solenoid valve S2 of the reheat condenser input tube 13 so that the refrigerant passing through the reheat condenser HE3 through the indoor heat exchanger HE2 The liquid refrigerant cooled by the outdoor heat exchanger HE1 is supercooled by the indoor air and the liquid refrigerant supercooled by the reheat condenser HE3 is introduced into the indoor expansion valve E2 and the indoor expansion valve E2 connected to the indoor expansion valve E2 It is supplied to the heat exchanger (HE2) to evaporate The room temperature is balanced with the amount of heat lost by the indoor heat exchanger HE2 and the amount of heat absorbed by the reheating condenser HE3 so that the room temperature does not rise during the dehumidifying operation, ) Of the electromagnetic valve (S2) is prevented from being damaged.

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