KR20150120568A - Dehumidifying system with refrigerator using the waste heat of outdoor condensor - Google Patents

Abstract

The present invention relates to a thermo-hydrostat using a coolant. The present invention relates to a dehumidifying device improving dehumidifying efficiency in a thermo-hydrostat having a thermo-hydrostat function and a dehumidification function reusing condensed heat of an outdoor unit. The inventor lowers moisture introduced into an indoor space during cooling. The coolant passes through an expansion valve (70) to be phase-changed in an evaporator (10). A cooling cycle repeats the cycle compressing to high pressure at the high temperature with a compressor (C1) and condensation-liquefying the coolant with a condenser (20) and has the dehumidification cycle directly supplying a portion of the coolant to an auxiliary heat exchanger (1) to reduce relative humidity of an air. The present invention comprises a merge unit (100) where a secondary coolant is merged with a main coolant passage (50) to be supplied to the evaporator (10).

Description

[0001] The present invention relates to a dehumidifying apparatus and a dehumidifying apparatus, and more particularly,

The present invention relates to a constant temperature and humidity device using a refrigerant.

The present invention relates to a dehumidifying device for increasing the dehumidification efficiency in a constant temperature and humidity device having a constant temperature, humidity and dehumidification function by recycling the heat of condensation of an outdoor unit recycling heat discharged from an outdoor unit in a constant temperature and humidity apparatus using a refrigerant.

The present invention relates to a constant temperature and humidity control device in which temperature control and dehumidification are precisely controlled, and a dehumidification device having a constant temperature and humidity function having excellent dehumidification function.

It is necessary to precisely control the temperature and humidity for various laboratories, storage rooms, precision control devices, server devices, and precision product production facilities as well as the space where people live. The reason for this is that changes in the material are affected by various residents, plants, animals, and articles in the living space depending on the change in temperature. Also, the influence of the relative humidity with the temperature is large. That is, the influence of the temperature and humidity on the occupants and the various items, animals and animals stored in the room guarantees the comfort of living of the residents, and the storage room greatly affects the deterioration of the stored articles. Especially, a lot of high-priced books, books, semiconductors, laboratory instruments, ultra-precise control devices, and so on, have become factors of fatal change depending on temperature and humidity.

With this relationship, the inventor of the present invention has developed an air conditioning system capable of controlling the humidity in consideration of the fact that the humidity of the room is seriously influenced with the temperature while the air conditioner system for controlling the heating and cooling of the room is being developed and manufactured and installed . Especially, we developed a cooling and heating system with dehumidification function to control the humidity to prevent change of storage. In order to utilize the waste heat generated from the condenser for compressing the refrigerant for dehumidification, a portion of the high-temperature and high-pressure refrigerant is recirculated to the room, and the refrigerant is condensed by the auxiliary heat exchanger, and the humidity of the room air is removed by the heat generated during the condensation .

By reusing the condensation heat of these refrigerants and dehumidifying it, enormous energy saving effect is obtained. However, in addition to such dehumidification, the necessity of humidification for the ultra-precise humidity and temperature control is also increased. Dehumidification is also important for constant temperature and humidity, but it must be operated with humidification in reverse, so it is possible to achieve ultimate precision constant temperature and humidity.

Humidity is the 'absorbent material' that absorbs moisture while changing its size, and the 'hydrophilic (water-friendly) material' that absorbs water into the interior without changing the size. The absorbent material tends to balance with the surrounding environment, so if the moisture-laden wood is brought to the relatively humid room with a relatively humid outside air, the wood will absorb the faded moisture into the air . In the process, changes such as cracking, bending, etc. occur. Such damage is often found in paper, fabric, other plastic products, waxes, fruits, vegetables and other substances, which adversely affect product production more than temperature.

 The necessity of dehumidification in the case of seeds, plants, and museum artefacts due to the specificity of the storage, while maintaining the constant temperature and humidity of the installation site by implementing cooling and heating at the same time, A simultaneous necessity of humidification and dehumidification to maintain the humidity has occurred. That is, when preserving the seed, it is necessary not only to keep the temperature and humidity constant but also to maintain proper humidity in order to keep the seed activity constant. That is, when the humidity is lowered to a certain level or less as the dehumidification is constantly performed, a highly complicated system configuration of supplying the appropriate humidity is required.

In the same form, books, sculptures, and folk artifacts can be kept in optimum condition together with keeping the proper temperature and humidity together.

In order to solve such a problem, the present inventor's patent registration No. 10-0885061 discloses a refrigerator having a compressor (2) in which an outdoor fan is provided from an evaporator (1) equipped with a blowing fan (11) A cooling cycle 4 for repeatedly circulating the refrigerant from the compressor 2 of the cooling cycle 4 to the evaporator 1 after passing through the condenser 3, Is connected to the refrigerant condensed and condensed in the condenser (3) of the cooling cycle (4) via the auxiliary heat exchanger (31) influenced by the blowing fan (11) and connected to the evaporator To the defrost heat exchanger (32) for removing the property of the condenser (3) from the condenser (3) via the compressor (2) and adjacent to the auxiliary heat exchanger (31) and the outdoor condenser , The auxiliary heat exchanger (31), and the defrost heat exchanger (32) Heating and dehumidifying function ", which is characterized by comprising a heating cycle (6) joined to the heat exchanger (3), and is capable of constant temperature and humidity, in particular, the heat of the refrigerant is recycled through the auxiliary heat exchanger Thereby maximizing the power saving effect.

In order to achieve a more precise and efficient humidification effect, the inventor of the present invention has proposed in Patent Registration No. 10-1135424 that the refrigerant at a high temperature and high pressure at the indoor side is supplied to the filter Temperature low-pressure refrigerant in the heat exchange section 10 via the dryer 21 and the expansion valve 70. The refrigerant of low temperature and low pressure is introduced into the accumulator A by the four- The refrigerant is condensed and condensed by the condenser C after being compressed to a high temperature and a high pressure by the compressor C1 and the refrigerant is condensed and condensed by the condenser C, The refrigerant is condensed and liquefied by heat exchange. The refrigerant is subjected to a heating cycle in which the refrigerant is phase-changed at a low temperature and a low pressure via an expansion valve (70a) on the outdoor side and a condenser (C) A part of the high-temperature and high-pressure refrigerant of the outdoor side condenser C is directly supplied to the auxiliary heat exchanger 10 located on the rear side of the evaporator through another secondary refrigerant line 31, The auxiliary heat exchanging unit 10 and the evaporative humidifying unit 100 are passed through the back side of the indoor heat exchanging unit 30 in the above cooling and heating cycle so that the circulating air Temperature and humidity control device that can control both humidity and temperature with a humidification cycle that is configured to perform humidification operation in parallel ". In the above-mentioned patent No. 10-1135424, a device called a vaporizing type humidifying device is added to a humidifying device, so that the most accurate and economical humidification of the existing humidifying device makes the constant temperature and humidity more precise.

During the dehumidification operation, the cooling cycle is operated, and the condensation humidity (absolute humidity) below the dew point in the heat exchanger is condensed and drained and drained. The cool humidifier passing through the heat exchanger is dried by the heat source of the auxiliary heat exchanger of the present invention, . In this dehumidification, the present invention manages the humidity (relative humidity) of the room according to the set humidity using the heat source of the hot outdoor unit, which is discarded as mentioned above, and thereby the deformation of the object to be dehumidified in a certain place, the contamination, It prevents the malfunction of equipment.

When the outdoor temperature rises while operating the dehumidifying operation of the present invention, particularly in the case of high temperature and high humidity during the summer, when the fan is cooled in the condenser, the refrigerant passing through the condenser is also supplied while being maintained at a high temperature and supplied to the expansion valve And the cooling effect is reduced. If the dehumidification operation is performed in such a hot and humid summer season, the outdoor temperature may be in the range of 30 to 35 ° C. In a hot case, the refrigerant temperature of the condenser may exceed 40 ° C in some cases. At this time, the outside air temperature is cooled by the hot air of 30 to 35 ° C. by the dehumidifying operation. However, the high temperature and high pressure refrigerant supplied from the compressor for dehumidification flows into the auxiliary heat exchanger after the heat exchanger in the room, and the hot indoor air passes through the heat exchanger And the air is dehumidified by an auxiliary heat exchanger through which the high-temperature and high-pressure refrigerant passed through the compressor passes, in order to dehumidify it with saturated cold air of 10 to 13 ° C . This dehumidification lowers the supercooling degree on the Moriel diagram, so that the temperature of the refrigerant condensed into the room evaporation source during the dehumidification becomes 15 to 18 ° C, thereby lowering the supercooling degree.

The above-mentioned patents of the present invention disclose that the condensed refrigerant cooled by air at 30 to 35 ° C in outdoor air is heat-exchanged with a refrigerant of high temperature and high pressure of 40 ° C or more and a saturated cold moist air of 10 to 13 ° C passed through an indoor heat exchanger The dehumidifying effect is improved and the cooling effect is higher than the cycle in which the refrigerant temperature is in the range of 25 to 28 캜 while the temperature of the liquid refrigerant is mixed at the inlet of the expansion valve at the temperature of 15 to 18 캜.

In proceeding with the patented invention of the present invention, in the recycling of the energy of the refrigerant discarded in the heat exchanger installed in the outdoor unit, the theoretically obtained efficiency and the actually measured efficiency are different from each other. In other words, we often found anomalous phenomena in which the efficiency was lower than the theoretical target efficiency, especially during the summer when the temperature was high and humid.

In order to solve such a problem, when a refrigerant compressed by a compressor passes through a condenser of an outdoor unit, it is usually operated in a state of high temperature and high pressure (40 to 43 ° C., 17 to 18 kg / cm 2 or more) The refrigerant having passed through the auxiliary heat exchanger of the present invention is formed at a temperature of 15 to 18 캜 lower than the condensed liquefied temperature in the outdoor unit and 0.1 to 0.2 kg / cm 2 lower than the condensed liquefied pressure in the outdoor unit. Accordingly, it has been found that a phenomenon in which a low-pressure refrigerant can not be mixed with a high-pressure refrigerant due to such a pressure difference is found, and the present invention has been developed.

An object of the present invention is to provide a constant temperature and humidity device for recycling waste heat of an outdoor unit closest to the theoretically obtained efficiency in recycling the energy of refrigerant discharged from an outdoor unit.

The present invention finds a phenomenon that the cooling efficiency and the dehumidification efficiency are lowered unexpectedly during operation of the dehumidification cycle in the summer when the temperature of the outside air rises, and when the pressure difference between the refrigerant passing through the main refrigerant and the refrigerant passing through the auxiliary heat exchanger becomes large, The problem of deterioration of the cooling efficiency due to the reverse flow of the refrigerant generated while being broken,

The refrigerant accumulates in the auxiliary heat exchanger, and the refrigerant circulating in the cycle becomes less and the refrigerant becomes insufficient, so that the cooling and dehumidifying operation can not be performed.

The present invention also improves the dehumidifying effect by adjusting the number of revolutions of the indoor blower to increase the dehumidifying effect of the indoor humidifier by adjusting the degree of decompression of the expansion valve and keeping the dew point temperature low, I will.

As a result of a close study of the present inventor's conventional dehumidification cycle in order to solve the above problems,

A cooling cycle of an indoor expansion valve, a heat exchanger, an accumulator of an outdoor side, a compressor, and a condenser; and a dehumidifying cycle of lowering the relative humidity of air passing through the heat exchanger in the cooling cycle in the cooling cycle, And a junction portion in which the secondary refrigerant supplied through the furnace is combined with the refrigerant as the main refrigerant.

In particular, the present invention is characterized in that the merging portion is constituted by a Y-shaped branch portion so that the secondary refrigerant joins the main refrigerant in the oblique direction to facilitate joining.

The present invention further improves the method in which the refrigerant that has passed through the auxiliary heat exchanger condensed and liquefied by the indoor evaporation heat is not well joined at the expansion transition due to the refrigerant temperature and pressure difference condensed and liquefied by the outdoor air.

In the present invention, a refrigerant that has passed through an auxiliary heat exchanger condensed and liquefied by room heat of evaporation is not joined at the expansion transition, but a separate expansion valve is provided so that the required amount of refrigerant can be controlled in the decompression and evaporator, Pressure side of the main refrigerant circuit expansion side to prevent the refrigerant from flowing backward into the auxiliary condenser and to reduce the temperature of the liquid refrigerant condensed in the indoor auxiliary condenser, resulting in a cooling effect and a dehumidifying effect.

In order to improve the dehumidifying effect, the dehumidifying effect is enhanced by adjusting the rotational speed of the blower of the air circulating device to adjust the blowing amount of the indoor humidifier in the indoor heat exchanger to sufficiently dew.

The present invention relates to a method of increasing condensation phenomenon by keeping the evaporation temperature low in an indoor evaporator (heat exchanger) in order to enhance the indoor dehumidifying effect, a method of increasing the number of dewatering by keeping the dew point temperature low, The dehumidifying effect is enhanced by reducing the pressure, causing the indoor air to pass through the evaporator (heat exchanger) having a low dew point temperature to cause a lot of condensation.

Claim 1 of the present invention basically blocks the interference of some refrigerants due to the difference in pressure between the secondary refrigerant and the main refrigerant in a cooling cycle and a dehumidifying cycle using the discarded heat in the cooling cycle Efficiency is maximized.

According to a second aspect of the present invention, in constructing the merging portion, the Y-shaped structure is formed so that the secondary refrigerant enters at an inclination angle (A), thereby enhancing the efficiency by joining the refrigerant more easily by the venturi effect.

Claim 3 of the present invention increases the efficiency by combining the main refrigerant and the secondary refrigerant more accurately and stably by using the expansion valve for the secondary refrigerant in conjunction with the junction portion having the Y-shaped branch portion.

According to claim 4 of the present invention, in the case where the Y-shaped merging portion is difficult to construct, the efficiency is enhanced by incorporating the stable main refrigerant and the secondary refrigerant by using the expansion valve for the secondary refrigerant in combination while joining to the general T-shaped joint.

FIG. 1 is a circuit diagram of a representative air-conditioning and dehumidifying cycle of Patent No. 10-0885061 of the present inventor,
FIG. 2 is a schematic circuit diagram of a typical temperature and humidity cycle of the present inventor's patent registration No. 10-1135424,
3 is a circuit diagram of a cycle for performing a dehumidifying operation in the constant temperature and humidity apparatus of the present invention,
4 is a circuit diagram of another cycle of dehumidifying operation in the constant temperature and humidity apparatus of the present invention,
5 is a circuit diagram of another cycle of dehumidifying operation in the constant temperature and humidity apparatus of the present invention,
6 is a circuit diagram optimally implementing cooling and dehumidifying operations in the constant temperature and humidity apparatus of the present invention,
7 is a circuit diagram of still another embodiment for dehumidifying only operation of the present invention;
8 is a circuit diagram of a speed adjusting section of the indoor side fan in the dehumidifying exclusive operation of the present invention.

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

Although not shown in the present invention, in the circulation cycle of the main refrigerant, in addition to the accumulator (A), the compressor (C), the heat exchanger and the condenser, a distributor for homogeneous supply of refrigerant to the heat exchanger, And an air vent for discharging air, are omitted since they are well known in the art.

Fig. 3 is a circuit diagram of a cycle of dehumidifying operation in the constant temperature / humidity apparatus of the present invention, and Fig. 4 is a circuit diagram of another cycle of dehumidifying operation in the constant temperature / humidity apparatus of the present invention of the present invention.

The present invention is characterized in that the refrigerant at a high temperature and high pressure at the indoor side is changed in phase from the evaporator 10 to the low temperature and low pressure via the expansion valve 70 and the refrigerant of low temperature and low pressure is led to the accumulator A C1, and then condensed and liquefied by the condenser 20,

In the cooling cycle, a part of the high-temperature and high-pressure refrigerant of the outdoor side condenser 20 is directly supplied to the auxiliary heat exchanger 1 located on the rear side of the evaporator through another secondary refrigerant line 31, And a dehumidifying cycle for lowering the relative humidity of the air passing through the filter

And a merging unit 100 for merging the secondary refrigerant that has passed through the secondary heat exchanger 1 supplied through the secondary refrigerant path with the main refrigerant path 50 and supplying the secondary refrigerant to the evaporator 10 The present invention relates to a constant temperature and humidity device.

In the present invention, the main refrigerant path 50 is compressed in the condenser 20 through the indoor evaporator 10, the outdoor accumulator A and the compressor C, and then circulated to the condenser, Cycle. The dehumidifying cycle used in the present invention is provided with a separate auxiliary heat exchanger (1) adjacent to the heat exchanger in the room. In the auxiliary heat exchanger, a part of the refrigerant of the condenser (20) And the dehumidification function is performed by using the waste heat which is lowered by lowering the relative humidity in the air supplied to the room. The refrigerant that has passed through the auxiliary heat exchanger (generally referred to as secondary refrigerant in the present invention) is supplied to the main refrigerant passage again and circulated to the original refrigerant cycle.

In the present invention, the refrigerant circulating in the main refrigerant passage is heated to a high temperature and a high pressure while passing through the compressor (C), and the present invention circulates a part of the refrigerant of high temperature and high pressure to the auxiliary heat exchanger (1) The dehumidifying operation is performed. As a result of this dehumidification operation, not only the comfort due to the lowering of the indoor humidity during the cooling operation but also the efficiency of the cooling machine is maximized by recycling the waste heat. However, in the operation of the dehumidifying cycle of the present inventor, there has been found a problem that the operation of the dehumidifying cycle becomes poor when the temperature difference between the outside and the room is intense or the humidity is very high, and the present invention was developed to solve the problem.

The inventors of the present invention have studied various causes of such malfunctions and found that the pressure and temperature are lowered to some extent as the refrigerant passing through the compressor passes through the condenser 20 cooled by the outdoor fan F2 installed in the outdoor unit, The secondary refrigerant passing through the unit 1 (here, the secondary refrigerant refers to a refrigerant that has passed through the outdoor unit as a primary refrigerant and has passed through the indoor side auxiliary heat exchanger. For the sake of convenience, The name of the refrigerant refrigerant is added). Accordingly, it has been found that the secondary refrigerant passing through the auxiliary heat exchanger to the refrigerant (primary refrigerant) flowing in the main refrigerant can not be easily mixed due to the pressure difference, and a part of the refrigerant is accumulated in the auxiliary heat exchanger.

In the present invention, the Y-shaped branch pipe (101) is provided at the outlet side of the expansion valve (TEV) as the main refrigerant in the merging portion (100) of the main refrigerant path and the secondary refrigerant,

One end of the secondary refrigerant is joined to the other end of the Y-shaped branch tube and the other end of the secondary refrigerant is joined to the other end of the Y-type branch tube, and the combined refrigerant of the main refrigerant path and the secondary refrigerant flows through the expansion valve (10).

In the present invention, the Y-shaped branch tube has an inclination angle (A) between the main refrigerant path (50) and the secondary refrigerant. Due to such a constitution, the secondary refrigerant is easily mixed with the primary refrigerant flowing into the main refrigerant at high pressure.

Since the Y-shaped branch tube of the present invention contacts the flow of the primary refrigerant of the main refrigerant conveyed at a relatively high pressure with an inclination angle, suction power is generated due to the structure of a kind of venturi, so that the secondary refrigerant So that the refrigerant can be easily mixed with the refrigerant as the main refrigerant.

Because the primary refrigerant of the main refrigerant path 50 is at a high pressure and the traveling speed thereof is relatively faster than the secondary refrigerant path 30 due to the above-described configuration of the present invention, the secondary refrigerant is simply supplied to the T- The second refrigerant having a relatively low pressure is more easily drawn by the fast flow of the first refrigerant, so that the two different refrigerants can be easily joined together.

As shown in FIG. 4, in the merging portion 100 of the primary refrigerant and the secondary refrigerant, as shown in FIG. 4, immediately before the secondary refrigerant path 31 is joined to the main refrigerant path, (TEV2) and a check valve (CV). That is, in the low-temperature and low-pressure refrigerant expanded while passing the secondary refrigerant through the expansion valve, the low-temperature low-pressure refrigerant passing through the expansion valve (TEV) to the main refrigerant joins at the inlet of the evaporator 10 after the main expansion valve Temperature low-pressure refrigerant gas which absorbs heat from the object to be cooled and evaporated in the compressor 10 is introduced into the compressor by the suction pressure of the compressor, so that cooling and dehumidifying can be performed while constituting a cooling cycle.

The primary refrigerant and the secondary refrigerant can be mixed to some extent with the constitution of the merging portion at an inclination angle. However, in order to achieve more perfect mixing, a separate secondary refrigerant expansion valve is provided, So that the cooling effect and the dehumidifying effect can be enhanced. That is, the pressure of the primary refrigerant and that of the secondary refrigerant are equal to each other or the secondary refrigerant is slightly higher than the primary refrigerant so that the secondary refrigerant is completely mixed with the primary refrigerant.

The secondary expansion valve for the secondary refrigerant has various configurations such as a static pressure expansion valve, a thermostatic expansion valve, an electronic expansion valve, and a capillary expansion valve so as to have an optimal pressure for mixing according to the primary refrigerant pressure flowing through the main refrigerant passage. An expansion valve was employed. For example, the refrigerant that has passed through the expansion valve as the main refrigerant is provided with a sensing portion on the outlet side of the evaporator 10, and is driven to operate an operating portion such as a bellows or a diaphragm of the expansion valve in accordance with the temperature and pressure, And the valve was opened or closed at the optimum pressure.

In another embodiment of the present invention, as shown in FIG. 5, the high-temperature and high-pressure refrigerant in the indoor side is changed from the evaporator 10 to the low-temperature low-pressure via the expansion valve 70, The refrigerant is guided to an accumulator (A), compressed to a high temperature and a high pressure by a compressor (C1), and then condensed and liquefied by a condenser (20)

In the cooling cycle, a part of the high-temperature and high-pressure refrigerant of the outdoor side condenser 20 is directly supplied to the auxiliary heat exchanger 1 located on the rear side of the evaporator through another secondary refrigerant line 31, 10) for lowering the relative humidity of the humidifier,

A Y-shaped branch tube (101) is provided at an outlet side of an expansion valve (TEV) as a main refrigerant in a merging portion (100) of a main refrigerant path and a secondary refrigerant,

One end of the second refrigerant flows into one end of the Y-shaped branch tube, and the other end of the second refrigerant flows into the other end of the Y-

And a secondary refrigerant expansion valve (TEV2) is installed in the secondary refrigerant of the merging section to join the outlet side of the expansion valve (TEV) to the main refrigerant and supplied to the evaporator (10).

As the expansion valve and the check valve are used together with the Y-shaped branch pipe, the cooling and dehumidifying efficiency is improved by mixing the more perfect primary refrigerant and the secondary refrigerant.

The above-described structure facilitates the mixing of the primary and secondary refrigerants by virtue of the physical structure of inducing an easy mixing operation by the inclined structure and the combination of the phase change means such as the above-described expansion valve.

In another embodiment of the present invention,

And after the high-temperature and high-pressure refrigerant to the expansion valve 70 in the indoor unit a phase change to low-temperature and low-pressure by the evaporator 10, the refrigerant of low temperature and pressure is a compressor (C) and guided to the accumulator (A) of the outdoor A cooling cycle in which the refrigerant is condensed and liquefied by the condenser 20 after being compressed to a high temperature and a high pressure,

In the cooling cycle, a part of the high-temperature and high-pressure refrigerant of the outdoor side condenser 20 is directly supplied to the auxiliary heat exchanger 1 located on the rear side of the evaporator through another secondary refrigerant line 31, And a dehumidifying cycle for lowering the relative humidity of the air passing through the filter

And a merging unit 100 which merges with the primary refrigerant of the main refrigerant path 50 and supplies the secondary refrigerant that has passed through the auxiliary heat exchanger 1 supplied through the secondary refrigerant path to the evaporator 10 while doing,

And a dehumidifying exclusive furnace (150) provided with a warm-on-off valve (151) and a dehumidifying exclusive on-off valve (153) as a main refrigerant in the merging section and provided with a dehumidifying expansion valve (TEV3) The dehumidifying device is a dehumidifying device that enhances the dehumidification efficiency in a constant temperature and humidity device having a function of constant temperature, humidity and dehumidification by recycling the condensation heat of the outdoor unit.

The apparatus of the present invention basically has a constant temperature and humidity function, and when the indoor humidity is high during the cooling operation, the dehumidification function is simultaneously operated while cooling operation to prevent the cooling effect from being lowered.

In the present invention, a dehumidifying exclusive furnace (150) is installed to exert a dehumidifying function more effectively than the dehumidification in the cooling operation, and the on / off valve (151) and the dehumidifying expansion valve Is set to set the expansion valve for dehumidification so that the evaporator 10 in the room is lowered by at least 5 ° C from the refrigerant supply temperature during normal operation for cooling and the pressure is lowered so that the indoor dampers And maximizing the energy saving and dehumidification efficiency by using the reheating load as the outdoor condensation heat.

More specifically, in the dehumidifying operation, the dehumidifying expansion valve (TEV3) is set so that the temperature of the evaporator (10) installed in the room is 2 to 5 DEG C lower than the temperature during the cooling operation. During the normal cooling operation, the evaporation temperature of the heat exchanger is adjusted to around 0 캜, but in the present invention, the temperature is set to a lower temperature range of -1 to -4 캜.

The present invention can also be applied to a case in which the indoor side fan F provided on the indoor side is disconnected from the power supply to the contact point Q directly connected to the power supply part P in the dehumidifying operation, H to control the rotation operation of the indoor side fan by the control contact G controlled by the control unit CU. The rotation speed was reduced by 5 to 15% lower than the fan rotation speed during the cooling operation. Unlike the cooling operation, the dehumidifying operation removes the ambient humidity in the shortest possible time, not the cooling of the entire room. Therefore, the dehumidifying operation is performed to increase the time required for the moisture to pass through the evaporator 10 in contact with the surrounding moisture. If the fan rotation speed is lower than 5%, the condensation efficiency is not different from the normal fan rotation speed. Conversely, when the fan rotation speed is lower than 15%, the condensation phenomenon lowers the air circulation for cooling and lowers the cooling efficiency. The dehumidification effect on the indoor side is greatly increased by the proper speed control of the indoor side fan of the present invention.

In another embodiment of the present invention, as shown in FIG. 7,

The refrigerant at a high temperature and a high pressure at the indoor side changes phase to low temperature and low pressure in the evaporator 10 via the expansion valve 70. The refrigerant at low temperature and low pressure is led to the accumulator A at the outdoor side to be supplied to the compressor C1 A cooling cycle in which the refrigerant is condensed and liquefied by the condenser 20 after being compressed to a high temperature and a high pressure,

In the cooling cycle, a part of the high-temperature and high-pressure refrigerant of the outdoor side condenser 20 is directly supplied to the auxiliary heat exchanger 1 located on the rear side of the evaporator through another secondary refrigerant line 31, And a dehumidifying cycle for lowering the relative humidity of the air passing through the filter

The junction 100 between the main refrigerant path and the secondary refrigerant includes a Y-type branch tube 101 at the outlet side of the expansion valve (TEV) as the main refrigerant,

Type branch tube so that one end of the secondary refrigerant is joined to the other end of the secondary refrigerant,

Wherein the primary refrigerant flowing in the main refrigerant path is supplied to the evaporator (10) at two different pressures by an electronically regulated expansion valve (EEV) installed in the Y-type branch tube, and the condensation heat of the outdoor unit is recycled It is a dehumidifying device that improves the dehumidification efficiency in a constant temperature and humidity device that combines a constant temperature and humidity and a dehumidification function.

(Not shown) controls the electronic regulated expansion valve (EEV) to operate separately during cooling operation (only for one-stage control cooling) and dehumidification operation (only for two-stage control and dehumidification). That is, at the time of dehumidifying operation other than the cooling operation, the expansion valve is set and adjusted so that the temperature of the evaporator 10 is lower than that in the cooling operation as described above, thereby improving the dehumidifying effect at the time of dehumidifying operation. It is to increase together.

1: auxiliary heat exchanger 10: evaporator 20: condenser 31: secondary refrigerant 50: main refrigerant 100: merging portion C: compressor A: accumulator TEV: expansion valve for main refrigerant EEV: electronically regulated expansion valve TEV2: 2 Refrigerant expansion valve TEV3: Refrigerant expansion valve

Claims (8)

The refrigerant of high temperature and high pressure in the indoor side is changed in phase from the evaporator 10 to the low temperature and low pressure via the expansion valve and the refrigerant of low temperature and low pressure is led to the accumulator A on the outdoor side, And then condensed and liquefied by the condenser 20,
In the cooling cycle, a part of the high-temperature and high-pressure refrigerant of the outdoor side condenser 20 is directly supplied to the auxiliary heat exchanger 1 located on the rear side of the evaporator through another secondary refrigerant line 31, And a dehumidifying cycle for lowering the relative humidity of the air passing through the filter
And a merging unit 100 which merges with the primary refrigerant of the main refrigerant path 50 and supplies the secondary refrigerant that has passed through the auxiliary heat exchanger 1 supplied through the secondary refrigerant path to the evaporator 10 A dehumidifying device for increasing the dehumidifying efficiency in a constant temperature and humidity device having a constant temperature and humidity and a dehumidifying function by recycling the condensation heat of the outdoor device
The method according to claim 1,
A Y-shaped branch tube 101 is provided at an inlet side of an expansion valve (TEV) as a main refrigerant in a merging portion 100 of a main refrigerant path and a secondary refrigerant,
One end of the secondary refrigerant is joined to the other end of the Y type branch tube and the other end of the secondary refrigerant is joined to the other end of the Y type branch tube so that the combined refrigerant in the main refrigerant path and the secondary refrigerant is supplied to the evaporator 10 Dehumidification device that enhances the dehumidification efficiency in the constant temperature and humidity device that combines the constant temperature, humidity and dehumidification functions by recycling the condensation heat of the outdoor unit
The refrigerant of high temperature and high pressure in the indoor side is changed in phase from the evaporator 10 to the low temperature and low pressure via the expansion valve and the refrigerant of low temperature and low pressure is led to the accumulator A on the outdoor side, And then condensed and liquefied by the condenser 20,
In the cooling cycle, a part of the high-temperature and high-pressure refrigerant of the outdoor side condenser 20 is directly supplied to the auxiliary heat exchanger 1 located on the rear side of the evaporator through another secondary refrigerant line 31, And a dehumidifying cycle for lowering the relative humidity of the air passing through the filter
And a merging unit (100) for merging the secondary refrigerant that has passed through the secondary heat exchanger (1) supplied through the secondary refrigerant path with the main refrigerant path (50) and supplying the secondary refrigerant to the evaporator (10)
The merging portion 100 of the secondary refrigerant and the primary refrigerant connects the inlet side of the expansion valve TEV to the primary refrigerant and the outlet side of the secondary refrigerant expansion valve TEV2 to the secondary refrigerant, And a second refrigerant valve (TEV2) is installed so that the secondary refrigerant subjected to the pressure conversion treatment by the expansion valve for the refrigerant joins together. The dehumidifying / dehumidifying device of the present invention recycles the condensation heat of the outdoor unit, Dehumidifying device with increased efficiency The method of claim 3, wherein
Wherein the expansion valve installed in the merging portion is any one of a static pressure expansion valve, a thermostatic expansion valve, an electronic expansion valve, and a capillary expansion valve, wherein the condensation heat of the outdoor unit is recycled and the constant temperature and humidity Dehumidifying device with higher dehumidification efficiency in the device
The refrigerant at a high temperature and a high pressure at the indoor side changes phase to low temperature and low pressure in the evaporator 10 via the expansion valve 70. The refrigerant at low temperature and low pressure is led to the accumulator A at the outdoor side, A cooling cycle in which the refrigerant is condensed and liquefied by the condenser 20 after being compressed to a high temperature and a high pressure,
In the cooling cycle, a part of the high-temperature and high-pressure refrigerant of the outdoor side condenser 20 is directly supplied to the auxiliary heat exchanger 1 located on the rear side of the evaporator through another secondary refrigerant line 31, And a dehumidifying cycle for lowering the relative humidity of the air passing through the filter
The outlet side of the expansion valve (TEV) to the main refrigerant and one end of the Y-type branch tube are connected to the merging portion 100 of the main refrigerant path and the secondary refrigerant, and the opposite end is connected to the check valve (CV) of the second refrigerant,
And the second refrigerant expansion valve (TEV2) is installed so that the secondary refrigerant passing through the check valve (CV) to the secondary refrigerant can be supplied in a phase-change manner so as to be supplied. Dehumidifying device with high dehumidification efficiency in a constant temperature and humidity device having a dehumidifying function
The refrigerant at a high temperature and a high pressure at the indoor side is changed from the evaporator 10 to the low temperature and low pressure via the expansion valve 70 and the refrigerant at the low temperature and low pressure is led to the accumulator A A cooling cycle in which the refrigerant is condensed and liquefied by the condenser 20 after being compressed to a high temperature and a high pressure,
In the cooling cycle, a part of the high-temperature and high-pressure refrigerant of the outdoor side condenser 20 is directly supplied to the auxiliary heat exchanger 1 located on the rear side of the evaporator through another secondary refrigerant line 31, And a dehumidifying cycle for lowering the relative humidity of the air passing through the filter
A merging portion 100 which merges with the primary refrigerant of the main refrigerant path 50 and supplies the secondary refrigerant that has passed through the auxiliary heat exchanger 1 supplied through the secondary refrigerant path to the evaporator 10,
Off valve (151) and a dehumidifying dedicated on-off valve (153) as the main refrigerant and a dehumidifying dedicated on-off valve (153) are provided in the main refrigerant line and the dehumidifying exclusive line, respectively, and the dehumidifying expansion valve (TEV3) And a dedicated furnace (150). The dehumidifying apparatus has a dehumidifying device for increasing the dehumidifying efficiency in a constant temperature and humidity device having a constant temperature and humidity and a dehumidifying function by recycling the condensation heat of the outdoor device
The method according to claim 6,
In the dehumidifying operation, the dehumidifying expansion valve (TEV3) is set so that the evaporator (10) installed in the room is lower by 4 to 5 DEG C than the temperature during the cooling operation
The power supply to the indoor fan F provided on the indoor side is cut off from the power supply P and the contact Q directly connected to the indoor fan F and the power supply through the variable resistor H is controlled by the control unit CU And the indoor fan speed is controlled by the contact point (G) to reduce the fan rotation speed by 5 to 15%. The dehumidification efficiency is improved in the constant temperature and humidity control device having the constant temperature and humidity and dehumidification functions by recycling the condensation heat of the outdoor unit Increased dehumidification device.
The refrigerant at a high temperature and a high pressure at the indoor side changes phase to low temperature and low pressure in the evaporator 10 via the expansion valve 70. The refrigerant at low temperature and low pressure is led to the accumulator A at the outdoor side, A cooling cycle in which the refrigerant is condensed and liquefied by the condenser 20 after being compressed to a high temperature and a high pressure,
In the cooling cycle, a part of the high-temperature and high-pressure refrigerant of the outdoor side condenser 20 is directly supplied to the auxiliary heat exchanger 1 located on the rear side of the evaporator through another secondary refrigerant line 31, And a dehumidifying cycle for lowering the relative humidity of the air passing through the filter
The junction 100 between the main refrigerant path and the secondary refrigerant includes a Y-type branch tube 101 at the outlet side of the expansion valve (TEV) as the main refrigerant,
Type branch tube so that one end of the secondary refrigerant is joined to one end of the secondary refrigerant at the other end,
And the primary refrigerant flowing in the main refrigerant passage is supplied to the evaporator (10) at two different pressure by an expansion valve (TEV) provided in the Y-type branch tube, and the condensation heat of the outdoor unit is recycled, The dehumidifying device enhances the dehumidification efficiency in the constant temperature and humidity device which combines the dehumidification function.

Images