WO2013061564A1 - Dehumidification system - Google Patents

Abstract

Energy-saving properties are enhanced in a dehumidification system comprising: an air supply passage (40), the inflow end thereof being open to the outdoors so as to supply outdoor air to an indoor space (S), and the outflow end being open to the indoor space (S); an adsorption rotor (31) for dehumidifying the air that flows through the air supply passage (40); a recirculation passage (45), the inflow end and outflow end thereof being open to the space (S) so as to allow the air of the indoor space (S) to flow in, and to allow the air to flow back out to the space (S); and a dehumidification mechanism (111) for dehumidifying the air that flows through the recirculation passage (45).

Description

Dehumidification system

The present invention relates to a dehumidification system that supplies dehumidified air into a room.

Conventionally, a dehumidification system that supplies dehumidified air to the room is known. Patent Document 1 discloses this type of dehumidifying system.

In the dehumidifying system of Patent Document 1, an adsorption rotor is accommodated in an air passage in a casing. The outdoor air taken in the casing passes through the adsorption portion of the adsorption rotor. In the adsorption unit, moisture in the air is adsorbed by the adsorbent, and the air is dehumidified. The dehumidified air is supplied into the room. Moreover, the indoor air taken in in the casing passes through the regeneration unit of the adsorption rotor after being heated. In the regeneration unit, moisture in the adsorbent is released into the air. The air used for the regeneration of the adsorbent is discharged outside the room.

JP 2002-195607 A

In the dehumidification system as described above, the low-humidity air in the room to be dehumidified may be returned to the upstream side of the adsorption rotor and mixed with the outdoor air taken in. Thereby, the temperature and humidity of the air on the upstream side of the adsorption rotor can be lowered, and the moisture adsorption capability of the adsorption rotor can be improved.

However, when the outside air and the inside air having different humidity differences are mixed as described above, there is a problem in that energy loss is reduced because mixing loss occurs in the mixed air.

This invention is made | formed in view of this point, The objective is to provide the dehumidification system excellent in energy-saving property.

The first invention is directed to a dehumidification system, and is supplied with an inflow end opened to the outdoor space and an outflow end opened to the indoor space (S) so as to supply outdoor air to the indoor space (S). A passage (40), an adsorption rotor (31) for dehumidifying the air flowing through the air supply passage (40), and the air in the indoor space (S) is flowed in and is again flown out into the space (S) A circulation path (45) whose inflow end and outflow end are open to the space (S) and a dehumidifying mechanism (111) for dehumidifying the air flowing through the circulation path (45) are provided.

In the first invention, the air supplied from the outside to the indoor space (S) through the air supply passage (40) is dehumidified by the adsorption rotor (31). Thus, relatively fresh outside air is dehumidified by the adsorption rotor (31) and then taken into the room. On the other hand, the indoor air is sucked into the circulation passage (45) and dehumidified by the dehumidifying mechanism (111), and then returned to the room again.

Thus, in the first aspect of the invention, the outside air from the air supply passage (40) and the air circulating through the circulation passage (45) are supplied to the indoor space (S) without mixing, so that the humidity There is no mixing loss caused by mixing different air.

According to a second invention, in the first invention, the indoor space (S) is divided into a first space (S1) and a second space (S2), and the first space (S1) is provided with a partition part (15) in which an exhaust port (16) for discharging the air in the second space (S2) is formed, and the outflow end of the air supply passage (40) It opens to the first space (S1), and the inflow end and the outflow end of the circulation passage (45) are open to the second space (S2).

In the second invention, outdoor air dehumidified by the adsorption rotor (31) flows into the first space (S1). That is, the first space (S1) is filled with relatively fresh air. The air in the first space (S1) is discharged to the second space (S2) through the exhaust port (16). The air in the second space (S2) is sucked into the circulation passage (45) and dehumidified by the dehumidifying mechanism (111), and then returned to the second space (S2) again.

According to a third invention, in the first or second invention, an adsorption heat exchanger (22, 24) arranged upstream of the adsorption rotor (31) in the air supply passage (40) and carrying an adsorbent. And a heat medium circuit (20a) to which the heat medium for cooling the adsorbent flows, to which the adsorption heat exchanger (22, 24) is connected, and a dehumidifying unit (20).

In the third invention, the heat medium circuit (20a) to which the adsorption heat exchanger (22, 24) is connected is disposed upstream of the adsorption rotor (31). In the adsorption heat exchanger (22, 24), the adsorbent is cooled by the heat medium. When the outdoor air passes through the adsorption heat exchanger (22, 24), moisture in the air is adsorbed by the adsorbent on the surface of the adsorption heat exchanger (22, 24). At this time, the generated heat of adsorption is applied to the heat medium of the heat medium circuit (20a).

According to a fourth invention, in the third invention, a regeneration heat exchanger (65) disposed in the regeneration passage (52) of the adsorption rotor (31) and constituting a condenser, and the air supply passage (40) It is provided with a refrigerant circuit (70a, 120) that is arranged on the upstream side of the dehumidifying unit (20) and is connected to an outside air cooling heat exchanger (61) that constitutes an evaporator to perform a refrigeration cycle. To do.

In the fourth invention, the air flowing through the regeneration passage (52) is heated by the regeneration heat exchanger (65) and then passes through the adsorption rotor (31). As a result, moisture in the adsorbent of the adsorption rotor (31) is released into the air, and the adsorption rotor (31) is regenerated. The outdoor air is cooled by the outdoor air cooling heat exchanger (61) on the upstream side of the dehumidifying unit (20). As a result, the water vapor in the outdoor air is condensed, and the humidity and temperature of the air are reduced.

In the fourth invention, the regenerative heat exchanger (65) and the outside air cooling heat exchanger (61) are connected to the refrigerant circuit (70a, 120). In the refrigerant circuit (70a, 120), the compressed refrigerant flows through the regenerative heat exchanger (65) serving as a condenser. That is, in the regenerative heat exchanger (65), the refrigerant dissipates heat to the air and condenses. The condensed refrigerant flows through the outside air cooling heat exchanger (61) that becomes an evaporator after being decompressed. That is, in the outside air cooling heat exchanger (61), the refrigerant absorbs heat from the air and evaporates. As described above, in the present invention, the heat deprived from the air by the outside air cooling heat exchanger (61) is used for heating the air by the regenerative heat exchanger (65).

In a fifth aspect based on the fourth aspect, the refrigerant circuit is a single refrigeration cycle type refrigerant circuit (70a) in which the condenser (65) and the evaporator (61) are connected to one closed circuit. It is characterized by that.

In the fifth invention, the condenser (65) and the evaporator (61) described above are connected to the refrigerant circuit (70a) of the single refrigeration cycle type. Thereby, simplification of a refrigerant circuit (70a) is achieved.

According to a sixth aspect, in the fifth aspect, the refrigerant circuit (70a) has a condensing pressure when the required capacity on the condenser (65) side is higher than the required capacity on the evaporator (61) side. Rotation speed is controlled so that the pressure approaches the target pressure, and when the required capacity on the evaporator (61) side is higher than the required capacity on the condenser (65) side, the evaporation pressure rotates to approach the target pressure. A variable capacity compressor (80), the number of which is controlled, is connected.

The refrigerant circuit (70a) according to the sixth aspect of the invention is connected to a variable capacity compressor (80) whose rotation speed is adjustable. The rotation speed of the compressor (80) is adjusted according to the operating conditions. Specifically, when the required capacity on the condenser (65) side is higher than the required capacity on the evaporator (61) side, the rotational speed of the compressor (80) is controlled so that the condensation pressure approaches the target pressure. The As a result, the necessary capacity on the condenser (65) side can be ensured by quickly using the condensation pressure as the target pressure.

Also, when the required capacity on the evaporator (61) side is higher than the required capacity on the condenser (65) side, the rotation speed of the compressor (80) is controlled so that the evaporation pressure approaches the target pressure. As a result, the required capacity on the evaporator (61) side can be ensured by quickly setting the evaporation pressure as the target pressure.

In a seventh aspect based on the fourth aspect, the refrigerant circuit includes a high-pressure circuit (120a) in which the first compressor (130) and the regenerative heat exchanger (65) are connected to perform a refrigeration cycle. The low pressure side circuit (120b) in which the second compressor (150) and the outside air cooling heat exchanger (61) are connected to perform the refrigeration cycle, the low pressure refrigerant of the high pressure side circuit (120a), and the low pressure side A refrigerant circuit (120) of a two-stage refrigeration cycle type having an intermediate heat exchanger (140) for exchanging heat with the high-pressure refrigerant of the circuit (120b).

In the seventh invention, the high-pressure side circuit (120a) to which the regenerative heat exchanger (65) is connected and the low-pressure side circuit (120b) to which the outside air cooling heat exchanger (61) is connected are an intermediate heat exchanger. The refrigerant circuit (120) of the two-stage refrigeration cycle type is configured by being connected to each other via (140). Thereby, a sufficient difference between the condensation pressure of the regenerative heat exchanger (65) and the evaporation pressure of the outside air cooling heat exchanger (61) can be secured. As a result, the air heating capacity in the regenerative heat exchanger (65) is increased, and the cooling capacity of the outside air cooling heat exchanger (61) is also increased.

According to the first aspect, by dehumidifying the outside air taken into the room by the adsorption rotor (31), relatively fresh outside air can be dehumidified and taken into the room. Furthermore, according to the first invention, since the outside air taken into the room through the air supply passage (40) and the air circulating through the circulation passage (45) do not mix, no mixing loss occurs. As a result, the energy saving performance of the dehumidification system can be improved.

Further, according to the second invention, relatively fresh outside air can be dehumidified and taken into the first space (S1), and the first space (S1) can be filled with the fresh air. Thereby, for example, by configuring the space in which the relatively high cleanliness is required by the first space (S1), the space can be maintained at a high cleanliness.

Further, according to the third invention, the air dehumidified by the dehumidifying unit (20) is dehumidified by the adsorption rotor (31). Thereby, since the adsorption | suction capability of the water | moisture content in an adsorption | suction rotor (31) can be improved, the dehumidification capability of the whole dehumidification system can be improved.

According to the fourth invention, the regenerative heat exchanger (65) and the outside air cooling heat exchanger (61) are connected to the refrigerant circuit (70a, 120), so that the outside air cooling heat exchanger (61) The heat recovered from the air can be used to heat the air in the regenerative heat exchanger (65). As a result, the energy saving performance of the dehumidification system can be further improved.

According to the fifth aspect of the invention, since the condenser (65) and the evaporator (61) are connected to one refrigerant circuit (70a), the refrigerant circuit (70a) can be simplified and reduced in cost. Can do.

Further, according to the sixth invention, when the necessary capacity on the condenser (65) side is insufficient, the condensing pressure can be quickly reached the target pressure, and the necessary capacity of the condenser (65) can be secured. Further, when the required capacity on the evaporator (61) side is insufficient, the required pressure of the evaporator (61) can be ensured by causing the evaporation pressure to quickly reach the target pressure.

Further, according to the seventh aspect of the present invention, the difference in pressure between the regenerative heat exchanger (65) and the outside air cooling heat exchanger (61) can be reduced by using the refrigerant circuit (120) of the two-stage refrigeration cycle type. Enough can be secured. As a result, the capacity of both the regenerative heat exchanger (65) and the outside air cooling heat exchanger (61) can be sufficiently obtained.

FIG. 1 is a schematic configuration diagram illustrating an overall configuration of a dehumidifying system according to an embodiment, in which a dehumidifying unit is in a first operation. FIG. 2 is a schematic configuration diagram illustrating the overall configuration of the dehumidifying system according to the embodiment, in which the dehumidifying unit is in the second operation. FIG. 3 is a piping system diagram of the refrigerant circuit of the dehumidification system according to the embodiment. FIG. 4 is a piping system diagram of a refrigerant circuit of a dehumidification system according to a modification of the embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

The embodiment according to the present invention is a dehumidification system (10) for dehumidifying an indoor space (S). A dehumidification system (10) dehumidifies outdoor air (OA), and supplies this air to a room as supply air (SA). The indoor space (S) to be dehumidified is a dry clean area (S) of a lithium battery production line. The dry clean area (S) is partitioned into a first space (S1) and a second space (S2) by a partition (15). The first space (S1), for example, constitutes an injection chamber for injecting an electrolytic solution of a lithium battery, and a relatively high cleanliness is required. On the other hand, the second space (S2) constitutes an assembly chamber for assembling a lithium battery. Although the cleanliness of the second space (S2) is lower than that of the first space (S1), a certain degree of cleanliness is required. In addition, as a standard regarding the cleanliness of air, the ISO class prescribed | regulated by ISO (International * Organization | for * Standardization, International Standardization Organization) etc. are mentioned, for example.

The air pressure in the first space (S1) is kept higher than the air pressure in the second space (S2), and the air pressure in the second space (S2) is higher than the air pressure outside the dry clean area (S). To be kept. As a result, the air in the first space (S1) is exhausted to the second space (S2) through the first exhaust port (16), and the air in the second space (S2) is discharged into the dry clean area through the second exhaust port (17). (S) Discharged outside.

As shown in FIG. 1, the dehumidification system (10) includes a dehumidification unit (20), an air supply passage side rotor unit (30), and a circulation passage side rotor unit (110).

The dehumidifying unit (20) is connected to the compressor (21), the first adsorption heat exchanger (22), the expansion valve (23), the second adsorption heat exchanger (24), and the four-way switching valve (25). A dehumidification side refrigerant circuit (20a) is provided. The dehumidification side refrigerant circuit (20a) constitutes a heat medium circuit in which a refrigerant as a heat medium circulates. Each adsorption heat exchanger (22, 24) is configured by adsorbing an adsorbent on the surface of a fin-and-tube heat exchanger.

The four-way switching valve (25) has first to fourth ports, the first port being the discharge side of the compressor (21), the second port being the suction side of the compressor (21), and the third port. The port is connected to the end of the first adsorption heat exchanger (22), and the fourth port is connected to the end of the second adsorption heat exchanger (24). The four-way selector valve (25) has a first state (a state indicated by a solid line in FIG. 1) in which the first port and the third port are communicated and the second port and the fourth port are communicated, It is configured to be switchable to a second state (state indicated by a broken line in FIG. 1) in which the four ports are communicated and the second port and the third port are communicated.

The dehumidifying unit (20) includes a first flow path switching unit (26) for changing the flow of air flowing into the two adsorption heat exchangers (22, 24) and two adsorption heat exchangers (22, 24). A second flow path switching unit (27) for changing the flow of the outflowed air. Each flow path switching unit (26, 27) is composed of a plurality of open / close dampers. Each flow path switching unit (26, 27) is configured to be able to switch the air flow path between a state indicated by a solid line in FIG. 1 and a state indicated by a second solid line.

The air supply passage side rotor unit (30) has an air supply passage side adsorption rotor (31) and an air supply passage side regenerative heat exchanger (65). The supply passage side adsorption rotor (31) constitutes an adsorption rotor that dehumidifies the air flowing through the supply passage (40). The supply passage side adsorption rotor (31) is configured by carrying an adsorbent on the surface of a disk-shaped porous substrate. The air supply passage side adsorption rotor (31) is rotationally driven about an axis by a drive mechanism (not shown). The supply passage side adsorption rotor (31) includes a first adsorption portion (32) facing the third supply passage (43), and a second adsorption portion (33) facing the first exhaust passage (51). A regeneration section (34) facing the second exhaust path (52) is formed. The first adsorbing part (32) and the second adsorbing part (33) adsorb moisture in the air, and the regenerating part (34) releases moisture in the adsorbent into the air. The supply passage side regenerative heat exchanger (65) is a regenerative heat exchanger in which the supply passage side regenerative heat exchanger (65) is arranged in the second exhaust passage (52) as a regeneration passage to constitute a condenser. It is.

The circulation passage side rotor unit (110) has a circulation passage side adsorption rotor (111) and a circulation passage side regenerative heat exchanger (67). The circulation passage side adsorption rotor (111) constitutes a dehumidifying mechanism for dehumidifying the air flowing through the circulation passage (45). The circulation passage side adsorption rotor (111) is configured by adsorbing an adsorbent on the surface of a disk-shaped porous substrate. The circulation passage side adsorption rotor (111) is driven to rotate about an axis by a drive mechanism (not shown). The circulation passage side adsorption rotor (111) includes a first adsorption portion (112) facing the first passage (46), a second adsorption portion (113) facing the fifth exhaust passage (57), and a sixth A regeneration section (114) facing the exhaust path (58) is formed. In the first adsorption unit (112) and the second adsorption unit (113), moisture in the air is adsorbed, and in the regeneration unit (114), moisture in the adsorbent is released into the air. The circulation passage side regenerative heat exchanger (67) is a condenser disposed in the sixth exhaust passage (58).

The dehumidification system (10) includes an air supply passage (40) for supplying outdoor air (OA) to the dry clean area (S) as supply air (SA). The supply passage (40) has first to third supply passages (41, 42, 43). The first air supply path (41) is formed on the upstream side of the dehumidifying unit (20). The second air supply path (42) is formed between the dehumidification unit (20) and the air supply passage side rotor unit (30). The third air supply passage (43) is formed on the downstream side of the air supply passage-side rotor unit (30), and the outflow end thereof opens to the first space (S1) of the dry clean area (S).

The first air supply path (41) includes an outdoor air cooling heat exchanger (61) that cools and dehumidifies outdoor air, and a drain pan (62) that collects water condensed by the outdoor air cooling heat exchanger (61). Provided. The second air supply path (42) is provided with an air supply fan (63) for conveying air into the room. The third air supply path (43) is provided with a reheat heat exchanger (64) that heats the air flowing through the third air supply path (43).

The dehumidification system (10) includes an air supply passage side exhaust passage (50) for discharging a part of the air in the air supply passage (40) to the outside of the dry clean area (S) as exhaust (EA). The supply passage side exhaust passage (50) includes first to fourth exhaust passages (51, 52, 53, 54). The supply passage side exhaust passage (50) has an inflow end connected to the second supply passage (42) and an outflow end communicating with the outside of the dry clean area (S). The first exhaust passage (51) is formed on the upstream side of the second adsorption portion (33) of the supply passage-side adsorption rotor (31). The second exhaust passage (52) is formed between the second adsorption portion (33) of the supply passage side adsorption rotor (31) and the regeneration portion (34) of the supply passage side adsorption rotor (31). The The third exhaust passage (53) is formed between the regeneration portion (34) of the supply passage-side adsorption rotor (31) and the dehumidifying unit (20). The fourth exhaust path (54) is formed on the downstream side of the dehumidification unit (20).

The second exhaust passage (52) is provided with an air supply passage side regenerative heat exchanger (65). The fourth exhaust path (54) is provided with a first exhaust fan (66) for conveying air to the outside of the dry clean area (S). The first air supply path (41) and the third exhaust path (53) are connected via a branch path (55).

The dehumidification system (10) has a circulation passage (45) for circulating air in the dry clean area (S). Both the inflow end and the inflow end of the circulation passage (45) open to the second space (S2) of the dry clean area (S).

The circulation passage (45) has a first passage (46) and a second passage (47). The first passage (46) is formed on the upstream side of the circulation passage-side rotor unit (110), and the inflow end thereof opens to the second space (S2). The second passage (47) is formed on the downstream side of the circulation passage-side rotor unit (110), and the outflow end thereof opens to the second space (S2).

The first passage (46) is provided with a circulation fan (68) for circulating indoor air through the circulation passage (45). The second passage (47) is provided with a reheat heat exchanger (64) for heating the air flowing through the second passage (47). That is, the reheat heat exchanger (64) is disposed so as to straddle the third air supply path (43) and the second passage (47).

The dehumidification system (10) includes a circulation passage-side exhaust passage (56) for discharging a part of the air in the circulation passage (45) as exhaust (EA) to the outside of the dry clean area (S). The circulation passage side exhaust passage (56) includes fifth to seventh exhaust passages (57, 58, 59). The circulation passage side exhaust passage (56) has an inflow end connected to the first passage (46) and an outflow end communicating with the outside of the dry clean area (S). The fifth exhaust passage (57) is formed on the upstream side of the circulation passage-side adsorption rotor (111). The sixth exhaust path (58) is formed between the second adsorption part (113) of the circulation path side adsorption rotor (111) and the regeneration part (114) of the circulation path side adsorption rotor (111). The seventh exhaust path (59) is formed on the downstream side of the circulation path side rotor unit (110).

The sixth exhaust passage (58) is provided with a circulation passage side regenerative heat exchanger (67) for heating air in order to regenerate the circulation passage side adsorption rotor (111). The seventh exhaust path (59) is provided with a second exhaust fan (69) for conveying air to the outside of the dry clean area (S).

As shown in FIG. 3, the dehumidification system (10) of this embodiment includes a refrigeration unit (70) having a refrigerant circuit (70a) to which the heat exchangers (61, 64, 65, 67) are connected. ing. The refrigerant circuit (70a) of the present embodiment is a single refrigeration cycle type in which the refrigerant circulates through one closed circuit.

The compressor (80) is connected to the refrigerant circuit (70a). The compressor (80) is a rotary fluid machine such as a rotary type, a swing type, or a scroll type. The compressor (80) is configured as a variable capacity type in which the rotation speed is adjusted by an inverter circuit.

The discharge side of the compressor (80) branches into a first discharge line (71) and a second discharge line (72). In the first discharge line (71), the supply passage side regeneration heat exchanger (65), the circulation passage side regeneration heat exchanger (67), the first expansion valve ( 81), the reheat heat exchanger (64) and the second expansion valve (82) are connected. A condensation pressure adjusting heat exchanger (83) and a third expansion valve (84) are connected to the second discharge line (72) in order from the upstream side toward the downstream side. A first outdoor fan (85) for blowing outdoor air is provided in the vicinity of the condensing pressure adjusting heat exchanger (83).

The suction side of the compressor (80) branches into a first suction line (73) and a second suction line (74). The outdoor air cooling heat exchanger (61) and the check valve (86) are connected to the first suction line (73) in order from the upstream side to the downstream side. A bypass pipe (77) that bypasses the outside air cooling heat exchanger (61) and the check valve (86) is connected to the first suction line (73). The bypass pipe (77) is provided with an electromagnetic on-off valve (92). A fourth expansion valve (87) and an evaporation pressure adjusting heat exchanger (88) are connected to the second suction line (74) in order from the upstream side to the downstream side. A second outdoor fan (89) for blowing outdoor air is provided in the vicinity of the evaporation pressure adjusting heat exchanger (88).

A single junction pipe (75) is connected between the outlet end of each discharge line (71, 72) and the inlet end of each suction line (73, 74). The merge pipe (75) is provided with a gas-liquid separator (79). The inflow end of the injection pipe (76) is connected to the gas phase portion of the gas-liquid separator (79). The outflow end of the injection pipe (76) is connected to the suction pipe of the compressor (80). The injection pipe (76) is provided with a fifth expansion valve (91).

The supply passage side regenerative heat exchanger (65), the circulation passage side regenerative heat exchanger (67), the reheat heat exchanger (64), and the condensing pressure adjustment heat exchanger (83) allow the refrigerant to radiate heat to the air. Constitutes a condenser that condenses. The outside air cooling heat exchanger (61) and the evaporation pressure adjusting heat exchanger (88) constitute an evaporator in which the refrigerant absorbs heat from the air and evaporates. Each of the expansion valves (81, 82, 84, 87, 91) described above is an electronic expansion valve, for example, and constitutes a pressure reducing mechanism that adjusts the pressure of the refrigerant.

The dehumidification system (10) is equipped with various sensors. Specifically, the dehumidification system (10) includes a high pressure sensor (95) that detects the high pressure (condensation pressure) of the refrigerant circuit (70a), and a low pressure sensor that detects the low pressure (evaporation pressure) of the refrigerant circuit (70a). (96). The dehumidification system (10) includes a supply passage side regenerative heat exchanger (65), a circulation passage side regenerative heat exchanger (67), a reheat heat exchanger (64), and an outside air cooling heat exchanger (61). Load detecting means for detecting the necessary capacity of the vehicle. The load detecting means includes, for example, a first air temperature sensor (101) that detects an air temperature downstream of the supply passage side regenerative heat exchanger (65), and a downstream side of the circulation passage side regenerative heat exchanger (67). The second air temperature sensor (102) for detecting the air temperature of the air, the third air temperature sensor (103) for detecting the air temperature downstream of the reheat heat exchanger (64), and the outside air cooling heat exchanger (61). It comprises a fourth air temperature sensor (104) for detecting the downstream air temperature.

The dehumidification system (10) includes a controller (100). The controller (100) determines the rotation speed of the compressor (80), the expansion valves (81, 82, 84, 87, and so on) based on the detection values of the various sensors described above and various setting values input by the user. 91) opening degree, and the amount of air blown by each outdoor fan (85, 89).

-Driving operation-
The operation of the dehumidification system (10) will be described.

<Basic operation of dehumidifying unit>
During operation of the dehumidifying system (10), the dehumidifying unit (20) performs the first operation and the second operation alternately at predetermined intervals.

In the first operation, air is dehumidified by the second adsorption heat exchanger (24), and at the same time, the adsorbent of the first adsorption heat exchanger (22) is regenerated. Specifically, in the dehumidifying side refrigerant circuit (20a) during the first operation, the four-way switching valve (25) is in the state shown in FIG. 1, and the expansion valve (23) is opened at a predetermined opening. The first flow path switching unit (26) communicates the first air supply path (41) with the accommodation chamber (not shown) of the second adsorption heat exchanger (24), and the third exhaust path (53). The accommodation chamber (not shown) of the first adsorption heat exchanger (22) is communicated. The second flow path switching unit (27) communicates the storage chamber of the second adsorption heat exchanger (24) with the second air supply path (42), and the first adsorption heat exchanger (22). The accommodation chamber and the fourth exhaust path (54) are communicated with each other.

In the first operation, the refrigerant compressed by the compressor (21) passes through the four-way switching valve (25) and flows through the first adsorption heat exchanger (22). In the first adsorption heat exchanger (22), the adsorbent is heated by the refrigerant, and moisture in the adsorbent is released to the air. The refrigerant radiated and condensed by the first adsorption heat exchanger (22) is depressurized by the expansion valve (23) and then flows through the second adsorption heat exchanger (24). In the second adsorption heat exchanger (24), moisture in the air is adsorbed by the adsorbent, and adsorption heat generated at this time is imparted to the refrigerant. The refrigerant that has absorbed heat and evaporated in the second adsorption heat exchanger (24) is sucked into the compressor (21) and compressed.

In the second operation, air is dehumidified by the first adsorption heat exchanger (22), and at the same time, the adsorbent of the second adsorption heat exchanger (24) is regenerated.

In the dehumidifying side refrigerant circuit (20a) during the second operation, the four-way switching valve (25) is in the state shown in FIG. 2, and the expansion valve (23) is opened at a predetermined opening. The first flow path switching unit (26) communicates the first air supply path (41) with the accommodation chamber (not shown) of the first adsorption heat exchanger (22), and the third exhaust path (53). The accommodation chamber (not shown) of the second adsorption heat exchanger (24) is communicated. The second flow path switching unit (27) communicates the storage chamber of the first adsorption heat exchanger (22) with the second air supply path (42), and the second adsorption heat exchanger (24). The accommodation chamber and the fourth exhaust path (54) are communicated with each other.

In the second operation, the refrigerant compressed by the compressor (21) passes through the four-way switching valve (25) and flows through the second adsorption heat exchanger (24). In the second adsorption heat exchanger (24), the adsorbent is heated by the refrigerant, and moisture in the adsorbent is released to the air. The refrigerant radiated and condensed by the second adsorption heat exchanger (24) is depressurized by the expansion valve (23) and then flows through the first adsorption heat exchanger (22). In the first adsorption heat exchanger (22), moisture in the air is adsorbed by the adsorbent, and adsorption heat generated at this time is imparted to the refrigerant. The refrigerant that has absorbed heat and evaporated in the first adsorption heat exchanger (22) is sucked into the compressor (21) and compressed.

<Basic operation of refrigeration unit>
During operation of the dehumidification system, a refrigeration cycle is performed in the refrigeration unit (70). During basic operation of the refrigeration unit (70), the opening degrees of the first expansion valve (81), the second expansion valve (82), and the fifth expansion valve (91) are adjusted as appropriate, and the third expansion valve (84) The fourth expansion valve (87) is fully closed. Further, the first outdoor fan (85) and the second outdoor fan (89) are stopped.

The refrigerant compressed by the compressor (80) is sent to the first discharge line (71) and flows through the supply passage side regeneration heat exchanger (65) and the circulation passage side regeneration heat exchanger (67). In the supply passage side regenerative heat exchanger (65) and the circulation passage side regenerative heat exchanger (67), the refrigerant dissipates heat to the air and condenses. The refrigerant condensed in the supply passage side regenerative heat exchanger (65) and the circulation passage side regenerative heat exchanger (67) is decompressed to a slightly lower pressure by the first expansion valve (81), and then reheated. Flow (64). In the reheat heat exchanger (64), the refrigerant dissipates heat to the air and condenses. The refrigerant condensed in the reheat heat exchanger (64) is depressurized to a low pressure by the second expansion valve (82), passes through the gas-liquid separator (90), and is sent to the first suction line (73). The opening degree of the second expansion valve (82) is controlled by the degree of superheat of the refrigerant on the suction side of the compressor (80).

The refrigerant sent to the first suction line (73) flows through the outside air cooling heat exchanger (61). In the outdoor air cooling heat exchanger (61), the refrigerant absorbs heat from the air and evaporates. The refrigerant evaporated in the outside air cooling heat exchanger (61) passes through the check valve (86) and is then sucked into the compressor (80) and compressed.

<Operation of dehumidification system>
Next, the operation of the dehumidification system (10) will be described. During operation of the dehumidification system (10), the dehumidification unit (20) performs the first operation and the second operation alternately. In addition, the supply fan (63), the first exhaust fan (66), the circulation fan (68), and the second exhaust fan (69) are operated.

Outdoor air (OA) flows into the first air supply passage (41) of the air supply passage (40). This air is relatively hot and humid air. The air flowing through the first air supply path (41) is cooled by the outside air cooling heat exchanger (61). The condensed water generated from the air during cooling is collected in the drain pan (62). For example, in the first operation, the air cooled and dehumidified by the outside air cooling heat exchanger (61) passes through the second adsorption heat exchanger (24) of the dehumidifying unit (20). In the second adsorption heat exchanger (24), moisture in the air is adsorbed by the adsorbent. In the second operation, the air cooled and dehumidified by the outside air cooling heat exchanger (61) is dehumidified by the first adsorption heat exchanger (22) of the dehumidifying unit (20).

The air dehumidified by the dehumidifying unit (20) flows through the second air supply passage (42) and passes through the first adsorption portion (32) of the air supply passage side adsorption rotor (31). As a result, moisture in the air is adsorbed by the adsorbent of the supply passage side adsorption rotor (31). The air dehumidified by the supply passage side adsorption rotor (31) is heated by the reheat heat exchanger (64) and then supplied to the first space (S1) as supply air (SA). As a result, the first space (S1) is filled with air having a relatively high cleanliness, in which relatively fresh outside air is dehumidified.

A part of the air flowing through the second air supply passage (42) flows into the air supply passage side exhaust passage (50) and passes through the second adsorption portion (33) of the air supply passage side adsorption rotor (31). As a result, moisture in the air is adsorbed by the adsorbent of the supply passage side adsorption rotor (31). The air dehumidified by the supply passage side adsorption rotor (31) flows through the second exhaust passage (52) and is heated by the supply passage side regenerative heat exchanger (65). The heated air passes through the regeneration unit (34) of the supply passage side adsorption rotor (31). As a result, moisture is desorbed from the adsorbent of the supply passage side adsorption rotor (31) into the air, and the adsorbent is regenerated. The air used for regeneration of the supply passage side adsorption rotor (31) flows through the third exhaust passage (53) and is mixed with the air flowing out from the branch passage (55). In the first operation, this air passes through the first adsorption heat exchanger (22) of the dehumidification unit (20). In the first adsorption heat exchanger (22), moisture is desorbed from the adsorbent into the air, and the adsorbent is regenerated. The air used for regeneration of the adsorbent in the first adsorption heat exchanger (22) flows through the fourth exhaust path (54) and is discharged out of the dry clean area (S) as exhaust (EA). Further, in the second operation, air is regenerated from the adsorbent of the second adsorption heat exchanger (24), and then discharged out of the dry clean area (S) as exhaust (EA).

The air in the first space (S1) is discharged to the second space (S2) through the first exhaust port (16). Part of the air in the second space (S2) is discharged out of the dry clean area (S) as exhaust (EA). A part of the air in the second space (S2) flows into the first passage (46) of the circulation passage (45).

The air that has flowed into the first passage (46) passes through the first adsorption portion (112) of the circulation passage-side adsorption rotor (111). As a result, the moisture in the air is adsorbed by the adsorbent of the circulation path side adsorption rotor (111). The air dehumidified by the circulation passage side adsorption rotor (111) is heated by the reheat heat exchanger (64) and then supplied to the second space (S2).

Part of the air flowing through the first passage (46) flows into the circulation passage side exhaust passage (56) and passes through the second adsorption portion (113) of the circulation passage side adsorption rotor (111). As a result, the moisture in the air is adsorbed by the adsorbent of the circulation path side adsorption rotor (111). The air dehumidified by the circulation path side adsorption rotor (111) flows through the sixth exhaust path (58) and is heated by the circulation path side regenerative heat exchanger (67). The heated air passes through the regeneration unit (114) of the circulation path side adsorption rotor (111). As a result, moisture is desorbed from the adsorbent of the circulation path side adsorption rotor (111) into the air, and the adsorbent is regenerated. The air used for regeneration of the circulation passage side adsorption rotor (111) flows through the seventh exhaust passage (59) and is discharged out of the dry clean area (S).

<Other control operations of refrigeration unit>
In the refrigeration unit (70) shown in FIG. 3, the following control operations are appropriately executed according to the operating conditions of the dehumidification system.

During the operation of the dehumidifying system, the controller (100) has a condenser side (ie, a supply passage side regeneration heat exchanger (65), a circulation passage side regeneration heat exchanger (67), and a reheat heat exchanger (64)). Required capacity Qc on the side and the required capacity Qe on the evaporator side (that is, the outside air cooling heat exchanger (61) side) are calculated based on the detected temperature of each temperature sensor (101 to 104).

When the required capacity Qc on the condenser side is larger than the required capacity Qe on the evaporator side, the condensation pressure detected by the high-pressure sensor (95) reaches the target condensation pressure determined based on the required capacity Qc. Thus, the rotation speed of the compressor (80) is adjusted. As a result, the condensing pressure can be quickly reached the target condensing pressure, and the necessary capacity Qc can be ensured.

On the other hand, when the compressor (80) is controlled so that the condensation pressure reaches the target value, the evaporation pressure may exceed the target evaporation pressure, and the required capacity Qe on the evaporator side may be insufficient. In such a case, the third expansion valve (84) is opened at a predetermined opening. When the third expansion valve (84) is opened, the refrigerant on the discharge side of the compressor (80) flows through both the first discharge line (71) and the second discharge line (72), and the condensation pressure adjustment heat The refrigerant also condenses in the exchanger (83). Then, the rotation speed of the compressor (80) increases so as to maintain the condensation pressure at the target condensation pressure. As a result, the evaporation pressure can be reduced to approach the target evaporation pressure.

When the required capacity Qe on the evaporator side is larger than the required capacity Qc on the condenser side, the evaporation pressure detected by the low pressure sensor (96) becomes the target evaporation pressure determined based on the required capacity Qe. The rotational speed of the compressor (80) is adjusted to reach. Thereby, the required pressure Qe can be ensured by causing the evaporation pressure to quickly reach the target evaporation pressure.

On the other hand, when the compressor (80) is controlled so that the evaporation pressure reaches the target value, the condensation pressure may be lower than the target condensation pressure, and the required capacity Qc on the condenser side may be insufficient. Therefore, in such a case, the fourth expansion valve (87) is opened at a predetermined opening. When the fourth expansion valve (87) is opened, the refrigerant on the suction side of the compressor (80) flows through both the first suction line (73) and the second suction line (74), and evaporating pressure adjustment heat. The refrigerant also evaporates in the exchanger (88). Then, the rotation speed of the compressor (80) increases so as to maintain the evaporation pressure at the target evaporation pressure. As a result, the condensation pressure can be raised to approach the target condensation pressure.

In the refrigeration unit (70), the open / close valve (92) is opened when the temperature of the outdoor air (OA) detected by the outside air temperature sensor (not shown) is lower than the target evaporation pressure. As a result, the refrigerant can be sent to the compressor (80) by bypassing the outside air cooling heat exchanger (61).

-Effect of the embodiment-
In the above embodiment, relatively fresh outside air is dehumidified and supplied to the first space (S1) where a relatively high cleanliness is required, so the first space (S1) is made highly clean. be able to. On the other hand, for the second space (S2), which does not require as high cleanliness as the first space (S2), the air exhausted from the first space (S1) through the first exhaust port (16) is circulated (45) It is dehumidified while circulating in. Thereby, the second space (S2) can be maintained at a certain degree of cleanliness.

Furthermore, in the above embodiment, the air from the air supply passage (40) and the air circulating through the circulation passage (45) are supplied to the dry clean area (S) without mixing. In this way, since the mixing loss generated by mixing air of different humidity does not occur, the entire dehumidification system (10) can be energy-saving.

In the above embodiment, the air dehumidified by the dehumidifying unit (20) is dehumidified by the supply passage side adsorption rotor (31). Thereby, since the moisture adsorption capability of the supply passage side adsorption rotor (31) can be improved, the dehumidification capability of the entire dehumidification system (10) can be improved.

Further, in the refrigeration unit (70), the supply passage side regeneration heat exchanger (65), the circulation passage side regeneration heat exchanger (67), the outside air cooling heat exchanger (61), and the reheat heat exchanger (64) Are connected to the same refrigerant circuit (70a). As a result, the heat of the air recovered by the outside air cooling heat exchanger (61) is converted into the supply passage side regeneration heat exchanger (65), the circulation passage side regeneration heat exchanger (67), and the reheat heat exchanger (64). Can be used for heating air in As a result, the energy saving performance of the dehumidification system (10) can be improved.

<< Modification of Embodiment of Invention >>
As shown in FIG. 4, the dehumidification system (10) of the modification of embodiment differs in the structure of embodiment mentioned above and the freezing unit (70). The refrigeration unit (70) of the modified example is provided with a two-way refrigeration cycle type refrigerant circuit (120). That is, in the refrigerant circuit (120), the high-pressure side circuit (120a) and the low-pressure side circuit (120b) are connected to each other via the cascade heat exchanger (140) constituting the intermediate heat exchanger.

The high pressure side circuit (120a) includes a high pressure side compressor (130) as a first compressor, a supply passage side regeneration heat exchanger (65), a circulation passage side regeneration heat exchanger (67), and a high pressure side expansion. Valves (131) are connected in sequence. The first flow path (141) of the cascade heat exchanger (140) is connected to the downstream side of the high pressure side expansion valve (131). The high pressure side circuit (120a) is provided with a high pressure sensor (133) on the discharge side of the high pressure compressor (130) and a low pressure sensor (134) on the suction side of the high pressure compressor (130). .

The low-pressure circuit (120b) is provided with a low-pressure compressor (150) as a second compressor. The discharge side of the low-pressure compressor (150) branches into a first discharge line (122) and a second discharge line (123). A reheat heat exchanger (64) and a second flow path (142) of the cascade heat exchanger (140) are sequentially connected to the first discharge line (122). A condensation pressure adjusting heat exchanger (83) and a third expansion valve (84) are sequentially connected to the second discharge line (123).

The suction side of the low pressure side compressor (150) branches into a first suction line (124) and a second suction line (125). An external air cooling heat exchanger (61) and a check valve (86) are sequentially connected to the first suction line (124). Further, a bypass pipe (77) is connected to the first suction line (124) as in the first embodiment. A fourth expansion valve (87) and an evaporation pressure adjusting heat exchanger (88) are sequentially connected to the second suction line (125).

The low pressure side expansion valve (151) is connected to the low pressure side circuit (120b) between the outflow end of each discharge line (122, 123) and the inflow end of each suction line (124, 125). The low pressure side circuit (120b) is provided with a high pressure sensor (153) on the discharge side of the low pressure compressor (150) and a low pressure sensor (154) on the suction side of the low pressure compressor (150). .

In the modified refrigeration unit (70), a dual refrigeration cycle is performed. The refrigerant compressed by the high pressure side compressor (130) dissipates heat to the air and condenses in the supply passage side regenerative heat exchanger (65) and the circulation passage side regenerative heat exchanger (67), and then the high pressure side expansion valve The pressure is reduced at (131). The decompressed refrigerant flows through the first flow path (141) of the cascade heat exchanger (140). In the cascade heat exchanger (140), the refrigerant flowing through the first flow path (141) absorbs heat from the refrigerant flowing through the second flow path (142) and evaporates. The evaporated refrigerant is sucked into the high-pressure compressor (130) and compressed.

The refrigerant compressed by the low-pressure side compressor (150) dissipates heat to the air by the reheat heat exchanger (64) and condenses, and then flows through the second flow path (142) of the cascade heat exchanger (140). In the cascade heat exchanger (140), the refrigerant flowing through the second flow path (142) dissipates heat to the refrigerant flowing through the first flow path (141) and condenses. The condensed refrigerant is depressurized by the low pressure side expansion valve (151), and then flows through the outside air cooling heat exchanger (61). In the outside air cooling heat exchanger (61), the refrigerant evaporates by absorbing heat from the air. The evaporated refrigerant is sucked into the low-pressure compressor (150) and compressed.

As described above, in the refrigeration unit (70) of the modified example, the refrigerant circulates in the high-pressure side circuit (120a) and the low-pressure side circuit (120b), respectively, and a refrigeration cycle is performed. As a result, a sufficient differential pressure between the condensation pressure on the supply air passage side regenerative heat exchanger (65) side and the evaporation pressure on the outside air cooling heat exchanger (61) side can be secured. The heating capacity of the vessel (65) and the cooling capacity of the outside air cooling heat exchanger (61) can be sufficiently obtained.

Other operations and effects are the same as in the above-described embodiment.

<< Other Embodiments >>
About the said embodiment, it is good also as the following structures.

In the above embodiment, the dehumidifying mechanism for dehumidifying the air flowing through the circulation passage (45) is configured by the circulation passage-side adsorption rotor (111). However, the dehumidification mechanism is not limited to this, for example, a total heat exchanger Or you may comprise an absorption-type dehumidification unit.

In the above embodiment, the partition (15) is provided to partition the dry clean area (S) into two spaces (S1, S2). However, the present invention is not limited to this, and the dry clean area (S) is partitioned. The part (15) may not be provided. Even in such a case, the air from the air supply passage (40) and the air circulating through the circulation passage (45) can be taken into the dry clean area (S) without being mixed. As a result, since the mixing loss generated by mixing air of different humidity does not occur, the entire dehumidification system (10) can be energy-saving.

As described above, the present invention is useful for a dehumidification system that supplies dehumidified air into a room.

10 Dehumidification system 15 Partition 16 First exhaust port (exhaust port)
20 Dehumidification unit 20a Dehumidification side refrigerant circuit (heat medium circuit)
22 First adsorption heat exchanger (adsorption heat exchanger)
24 Second adsorption heat exchanger (adsorption heat exchanger)
31 Supply passage side adsorption rotor (adsorption rotor)
40 Air supply passage 45 Circulation passage 52 Second exhaust passage (regeneration passage)
61 Outside air cooling heat exchanger (evaporator)
65 Regenerative heat exchanger on the air supply passage (regenerative heat exchanger, condenser)
70a Refrigerant circuit 80 Compressor 111 Circulation passage side adsorption rotor (dehumidification mechanism)
120 Refrigerant circuit 120a High stage circuit 120b Low stage circuit 130 High stage compressor (first compressor)
140 Cascade heat exchanger (intermediate heat exchanger)
150 Low stage compressor (second compressor)
S Dry clean area (indoor space)
S1 first space S2 second space

Claims (7)

1. An air supply passageway (40) having an inflow end opened to the outdoor space and an outflow end opened to the indoor space (S) so as to supply outdoor air to the indoor space (S);
   An adsorption rotor (31) for dehumidifying the air flowing through the air supply passage (40);
   A circulation passage (45) having an inflow end and an outflow end opened to the space (S) so that air in the indoor space (S) flows in and flows out again into the space (S);
   A dehumidification system comprising: a dehumidification mechanism (111) for dehumidifying the air flowing through the circulation passage (45).
2. In claim 1,
   The indoor space (S) is divided into a first space (S1) and a second space (S2), and the air in the first space (S1) is divided into the second space (S1). A partition (15) provided with an exhaust port (16) for discharging to S2),
   The outflow end of the air supply passage (40) opens into the first space (S1),
   The dehumidification system, wherein an inflow end and an outflow end of the circulation passage (45) are open to the second space (S2).
3. In claim 1,
   The adsorption heat exchanger (22, 24) arranged on the upstream side of the adsorption rotor (31) in the supply passage (40) and carrying the adsorbent is connected to the adsorption heat exchanger (22, 24) A dehumidifying unit (20) having a heat medium circuit (20a) through which a heat medium for cooling the adsorbent flows.
4. In claim 3,
   A regenerative heat exchanger (65) arranged in a regeneration passage (52) of the adsorption rotor (31) to constitute a condenser, and an upstream side of the dehumidifying unit (20) in the air supply passage (40) A dehumidification system comprising refrigerant circuits (70a, 120) connected to an outside air cooling heat exchanger (61) constituting an evaporator to perform a refrigeration cycle.
5. In claim 4,
   The dehumidification system, wherein the refrigerant circuit is a single refrigeration cycle type refrigerant circuit (70a) in which the condenser (65) and the evaporator (61) are connected to one closed circuit.
6. In claim 5,
   In the refrigerant circuit (70a), when the required capacity on the condenser (65) side is higher than the required capacity on the evaporator (61) side, the rotation speed is controlled so that the condensation pressure approaches the target pressure. When the required capacity on the evaporator (61) side is higher than the required capacity on the condenser (65) side, the rotation speed is controlled so that the evaporation pressure approaches the target pressure. (80) is connected to the dehumidification system.
7. In claim 4,
   The refrigerant circuit includes a high-pressure circuit (120a) in which a refrigeration cycle is performed by connecting the first compressor (130) and the regenerative heat exchanger (65), a second compressor (150), and the outside air cooling. A low pressure side circuit (120b) connected to the heat exchanger (61) to perform a refrigeration cycle, and an intermediate for heat exchange between the low pressure refrigerant of the high pressure side circuit (120a) and the high pressure refrigerant of the low pressure side circuit (120b) A dehumidification system comprising a two-way refrigeration cycle refrigerant circuit (120) having a heat exchanger (140).

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