JP2008180459A - Dehumidifying air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dehumidifying air conditioner, capable of satisfactorily performing heating operation even in an intermediate period while saving energy. <P>SOLUTION: The humidifying air conditioner comprises a dehumidifying rotor 20; an air supply unit 30 for supplying introduced treatment air into a store 1 while passing it through a moisture adsorption area 21; an air release unit 40 for releasing introduced regenerated air while passing it through a moisture releasing area 41; and a heat pump unit 50. The air conditioner further comprises a second condenser 62 which heats, when a heating operation is instructed, and the heat pump unit 50 is stopped to drive, the treatment air passed therethrough toward the moisture adsorption area 31 by use of the waste heat of a showcase 2 disposed in the store 1. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a dehumidifying air conditioner, and more specifically, for example, a dehumidifying air conditioner that is applied to a store such as a supermarket, a convenience store, or a shopping center and has functions of ventilation, dehumidification, and air conditioning by introducing outside air into the room. Regarding improvements.

  2. Description of the Related Art Conventionally, as a dehumidifying air conditioner applied to, for example, a store such as a supermarket, a convenience store, or a shopping center, a device including a dehumidifying rotor, an air supply unit, an air discharge unit, and a heat pump unit is known.

  The dehumidification rotor is provided with, for example, a short-axis columnar moisture adsorbent. The moisture adsorbent is partitioned and divided into two, and rotates in such a manner as to alternately pass through the moisture adsorption region and the moisture release region that constitute the air flow path. When the moisture adsorbent rotates in this way, the portion located in the moisture adsorption area moves to the moisture release area and then moves again to the moisture adsorption area.

  The air supply unit has an air supply path incorporating the moisture adsorption region. This air supply unit becomes a target after the outside air (process air) is taken into the air supply path and the taken process air is passed through the moisture adsorption region by the operation of the blower fan disposed in the air supply path. It is supplied to the room (hereinafter also referred to as the target room).

  The air discharge unit is provided in parallel with the air supply path in a partitioned manner, and has an air discharge path that incorporates the moisture discharge region. This air discharge unit takes in outside air (regeneration air) into the air discharge path by operating a blower fan arranged in the air discharge path, and discharges the recovered air after passing it through the moisture discharge area. To do.

  The heat pump unit includes a refrigerant circulation circuit. The refrigerant circulation circuit is configured by sequentially connecting a compressor, a first heat exchanger, and a second heat exchanger with pipes, and a refrigerant is enclosed therein. The compressor compresses the refrigerant into a high temperature and high pressure state. The first heat exchanger is disposed in the upstream area of the moisture adsorption region in the air supply path, and exchanges heat between the refrigerant and the ambient air, that is, the processing air passing toward the moisture adsorption region. . The second heat exchanger is disposed in the upstream area of the moisture discharge area in the air discharge path, and exchanges heat between the refrigerant and the ambient air, that is, the regenerative air passing toward the moisture discharge area. .

  In such a heat pump unit, when the dehumidifying air conditioner performs a dehumidifying operation, that is, when a dehumidifying operation command is given, the first heat exchanger acts as an evaporator and the second heat exchanger acts as a condenser. The refrigerant is circulated in Accordingly, the first heat exchanger evaporates the refrigerant in the dehumidifying operation mode and cools the processing air passing therearound, and the second heat exchanger condenses the refrigerant in the dehumidifying operation mode. The regeneration air passing through the surroundings is heated. Accordingly, in the dehumidifying operation mode, the heat pump unit draws heat (absorbs heat) from the processing air through the first heat exchanger, and heats the regeneration air with the heat absorbed by the first heat exchanger through the second heat exchanger. become.

  In the conventional dehumidifying air-conditioning apparatus having the above-described configuration, when performing the dehumidifying operation, the processing air is taken into the air supply path and the processing air passing through the first heat exchanger is cooled by the action of the blower fan. Then, by passing the cooled processing air through the moisture adsorption region, the moisture of the passing processing air is adsorbed by the moisture adsorbing body of the dehumidifying rotor and dehumidified, and the dehumidified air is introduced into the target chamber. Also, by the action of the blower fan, the dehumidification rotor absorbs moisture by introducing the regenerated air into the air discharge path, heating the regenerated air passing through the second heat exchanger, and passing the heated regenerated air through the moisture discharge region. Moisture is released to the body and dried, and the regenerated air that has passed through the moisture release region is released to the outside (see, for example, Patent Document 1).

JP 2005-201624 A

  By the way, in the dehumidifying air conditioner as described above, by reversing the circulation direction of the refrigerant in the refrigerant circuit constituting the heat pump unit, that is, the first heat exchanger is a condenser and the second heat exchanger is evaporated. It is also possible to perform the heating operation by circulating the refrigerant in a mode that acts as a heater.

  When such a heating operation is performed, the driving of the dehumidifying rotor is stopped, and the circulation direction of the refrigerant in the refrigerant circuit constituting the heat pump unit is reversed. As a result, the regenerated air passing through the air discharge path is cooled through the second heat exchanger, and the cooled regenerated air is allowed to pass through the moisture discharge region and then released to the outside. Here, the regeneration air is cooled through the second heat exchanger, and this means that heat is generated in the refrigerant from the regeneration air through the second heat exchanger. Then, the processing air passing through the air supply path is heated through the first heat exchanger, and more specifically, the processing air passing through the second heat exchanger is heated using the heat generated from the regeneration air and heated. The process air is passed through the moisture adsorption region and then introduced into the target chamber.

  However, when the outside air temperature is relatively high compared to the winter season such as spring or autumn, or when the outside air temperature is high even in the winter season (hereinafter referred to as an intermediate period), the heat pump unit has a configuration thereof. It was difficult to draw heat from the regenerated air through the upper second heat exchanger, and thus it was difficult to perform the heating operation in the intermediate period. In recent years, it has become a technical problem to save energy even when such heating operation is performed.

  An object of this invention is to provide the dehumidification air-conditioning apparatus which can perform a heating operation favorably also in an intermediate period, aiming at energy saving in view of the said situation.

  In order to achieve the above object, a dehumidifying air-conditioning apparatus according to claim 1 of the present invention circulates and moves a moisture adsorbent between a moisture adsorption region and a moisture release region that are partitioned when a dehumidifying operation command is given. On the other hand, when a heating operation command is given, a dehumidification rotor that stops the circulation movement of the moisture adsorbent, and an air supply means that supplies process air introduced from the outside in a mode of passing through the moisture adsorption region into the target chamber And an air release means for releasing the regeneration air introduced from the outside in a mode of passing through the moisture release region, a compressor for compressing the refrigerant, and heat exchange between the refrigerant and the ambient air A refrigerant circulation circuit in which a first heat exchanger and a second heat exchanger are sequentially connected by piping, and when a dehumidifying operation command is given to the moisture adsorption region through the first heat exchanger; Passing towards A dehumidifying air conditioner comprising: a heat pump unit that cools the treated air and heats the regenerated air that passes through the second heat exchanger toward the moisture release region; When the unit stops driving, it is provided with processing air heating means for heating the processing air passing toward the moisture adsorption region using the exhaust heat of the refrigeration equipment arranged in the target chamber. Features.

  The dehumidifying air conditioner according to claim 2 of the present invention is the dehumidifying air conditioner according to claim 1, wherein the processing air heating means is disposed in an upstream region of the first heat exchanger. The process air passing toward the vessel is heated.

  Moreover, the dehumidifying air-conditioning apparatus according to claim 3 of the present invention is the above-described claim 1 or 2, wherein the processing air heating means compresses the working fluid and an evaporator built in the refrigeration equipment. A fluid circulation circuit that circulates the working fluid together with a compressor is configured, the working fluid compressed by the compressor is condensed, and the processing air is heated.

  A dehumidifying air conditioner according to a fourth aspect of the present invention is the dehumidifying air conditioner according to any one of the first to third aspects, wherein a heating operation command is given and the heat pump unit is in a refrigerant circulation direction in the refrigerant circulation circuit. When the processing air that passes through the first heat exchanger toward the moisture adsorption region is heated, the regeneration that passes toward the moisture release region using the exhaust heat of the refrigeration equipment is used. A regenerative air heating means for heating the air is provided.

  The dehumidifying air-conditioning apparatus according to claim 5 of the present invention is the dehumidifying air conditioner according to claim 4, wherein the regeneration air heating means is disposed in an upstream region of the second heat exchanger. The regenerative air passing toward the vessel is heated.

  The dehumidifying air-conditioning apparatus according to claim 6 of the present invention is characterized in that, in the above-described claim 4 or 5, the regeneration air heating means constitutes the fluid circulation circuit.

  According to the dehumidifying air-conditioning apparatus according to the present invention, when the processing air heating means is given a heating operation command and the heat pump unit stops driving, the exhaust heat of the refrigeration equipment arranged in the target chamber is removed. Since the processing air passing toward the moisture adsorption region is heated by using it, there is an effect that the heating operation can be favorably performed in the intermediate period while saving energy.

  Exemplary embodiments of a dehumidifying air conditioner according to the present invention will be described below in detail with reference to the accompanying drawings. In the present embodiment, the target room of the dehumidifying air conditioner will be described as being a store such as a supermarket, a convenience store, a shopping center, or the like.

  FIG. 1 is a schematic diagram schematically showing a configuration of a dehumidifying air conditioner in an embodiment of the present invention. The dehumidifying air conditioner 10 illustrated here performs ventilation, dehumidification, and air conditioning by introducing outside air into the store 1. A showcase (freezer / refrigerator) 2 is provided inside the target store 1.

  The showcase 2 is for cooling goods etc. displayed inside. The showcase 2 includes an evaporator 3. Although details will be described later, the evaporator 3 cools the products displayed inside the showcase 2 by evaporating the working fluid passing through the inside. In practice, a plurality of showcases 2 are generally provided inside the store 1, but in the present embodiment, one showcase 2 is provided inside the store 1 for convenience of explanation. Only an example will be described.

  The dehumidifying air conditioner 10 applied to the store 1 includes a dehumidifying rotor 20, an air supply unit (air supply means) 30, an air discharge unit (air discharge means) 40, a heat pump unit 50, a first condenser (regenerative air heating means). ) 61 and a second condenser (process air heating means) 62.

  The dehumidifying rotor 20 is provided with a moisture adsorbing body 21 such as paper or zeolite that is formed in a short-axis cylindrical shape. The moisture adsorber 21 rotates around its central axis by driving a motor M (see FIG. 2). More specifically, the moisture adsorbing body 21 rotates in such a manner as to alternately pass between the moisture adsorbing region 31 and the moisture releasing region 41 that are partitioned from each other and that constitute the air flow path. That is, the dehumidification rotor 20 circulates and moves the moisture adsorbent 21 between the partitioned moisture adsorption region 31 and the moisture release region 41. Thus, when the moisture adsorbing body 21 rotates, the portion located in the moisture adsorption region 31 moves to the moisture release region 41 and then moves to the moisture adsorption region 31 again in order.

  The air supply unit 30 is for supplying the introduced processing air (outside air) to the inside of the store 1, and has an air supply path 300.

  The air supply path 300 is provided inside the housing constituting the dehumidifying air conditioner 10, and is a path for supplying the processing air taken in from the processing air inlet 301 into the store 1 through the processing air outlet 302. The water adsorption region 31 and the supply fan 32 are provided in this order from the processing air intake 301 side.

  As will be described in detail later, the moisture adsorption region 31 is a region for allowing the moisture adsorbent 21 to adsorb moisture of the processing air that passes when the dehumidifying air conditioner 10 performs a dehumidifying operation. As a result, the process air passing therethrough is dehumidified in the moisture adsorption region 31.

  The supply fan 32 serves as a blast source for introducing processing air through the processing air inlet 301 and sending (supplying) processing air into the store 1. Therefore, the processing air that has passed through the air supply path 300 is supplied into the store 1 through the processing air discharge port 302 by driving the supply fan 32. In addition, a temperature / humidity sensor S is disposed near the outlet of the processing air discharge port 302. The air temperature / humidity sensor S detects the temperature and humidity of the processing air discharged from the processing air discharge port 302. The temperature / humidity detected by the air supply / humidity sensor S is given to the controller 70 described later as a supply air measurement value.

  The air discharge unit 40 has an air discharge path 400. The air discharge path 400 is provided inside the housing constituting the dehumidifying air conditioner 10, and is arranged in parallel with the air supply path 300 in a manner partitioned from the air supply path 300. The air discharge path 400 is a path for discharging the regeneration air (outside air) taken from the regeneration air intake port 401 to the outside through the regeneration air discharge port 402, and the moisture discharge region 41 and the discharge fan 42 are connected to the regeneration air intake. They are provided in order from the entrance 401 side.

  Although the details will be described later, the moisture release area 41 is an area for allowing the moisture adsorbent 21 to release moisture when the dehumidifying air conditioner 10 performs a dehumidifying operation.

  The discharge fan 42 serves as a blast source for introducing the regeneration air through the regeneration air intake port 401 and sending out (releases) the regeneration air to the outside. Therefore, when the discharge fan 42 is driven, the regenerated air that has passed through the air discharge path 400 is discharged to the outside through the regenerative air discharge port 402.

  The heat pump unit 50 includes a refrigerant circulation circuit 50a. The refrigerant circulation circuit 50a is configured by sequentially connecting a refrigerant compressor 51, a first heat exchanger 52, and a second heat exchanger 53 with refrigerant pipes, and the refrigerant is enclosed inside. is there. Here, various refrigerants can be used. For example, chlorofluorocarbon, hydrochlorofluorocarbon, hydrofluorocarbon, fluorocarbon, a mixed solvent thereof, methyl bromide, ammonia, carbon dioxide, water, or the like can be used.

  The refrigerant compressor 51 is disposed in the air discharge path 400 in the vicinity of the regeneration air intake 401, more specifically, in the downstream area in the immediate vicinity of the regeneration air intake 401. The refrigerant compressor 51 compresses the refrigerant to a high temperature and high pressure state. The refrigerant compressor 51 is connected to each of a refrigerant pipe connected to the first heat exchanger 52 and a refrigerant pipe connected to the second heat exchanger 53 via the valve body 54. The valve body 54 adjusts the direction of the refrigerant flowing through the refrigerant circulation circuit 50a. For example, the valve body 54 directs the refrigerant compressed by the refrigerant compressor 51 to the second heat exchanger 53 when a dehumidifying operation command is given when the dehumidifying air conditioner 10 performs a dehumidifying operation. When the dehumidifying air conditioner 10 performs the heating operation, the refrigerant compressed by the refrigerant compressor 51 is sent toward the first heat exchanger 52. It adjusts so that it may do (the broken line arrow direction in a figure).

  The first heat exchanger 52 is disposed upstream of the moisture adsorption region 31 in the air supply path 300. The first heat exchanger 52 exchanges heat between the refrigerant and the ambient air, that is, the processing air that passes toward the moisture adsorption region 31. More specifically, when the dehumidifying operation command is given, the first heat exchanger 52 acts as an evaporator, while the heating operation command is given and a predetermined condition described later is satisfied. Acts as a condenser. That is, when a dehumidifying operation command is given, the refrigerant is evaporated and the processing air passing through the surroundings is cooled, in other words, the heat is absorbed in a mode of generating heat from the processing air, while a heating operation command is given, And when satisfy | filling predetermined conditions, the process air which condenses a refrigerant | coolant and passes the circumference | surroundings is heated.

  The second heat exchanger 53 is disposed in the upstream area of the moisture discharge area 41 in the air discharge path 400, that is, in a predetermined area between the refrigerant compressor 51 and the moisture discharge area 41. The second heat exchanger 53 exchanges heat between the refrigerant and ambient air, that is, regeneration air that passes toward the moisture release region 41. More specifically, when the dehumidifying operation command is given, the second heat exchanger 53 acts as a condenser, while when the heating operation command is given and a predetermined condition is satisfied, It acts as an evaporator. In other words, when the dehumidifying operation command is given, the refrigerant is condensed and heated by the regenerated air passing through the surroundings. On the other hand, when the heating operation command is given and the predetermined condition is satisfied, the refrigerant is evaporated. Thus, the regenerative air passing through the surroundings is cooled, in other words, absorbed in such a manner that heat is generated from the regenerated air.

  As described above, when a dehumidifying operation command is given, the heat pump unit 50 draws up heat from the processing air through the first heat exchanger 52 (absorbs heat), and passes through the first heat exchanger 52 through the second heat exchanger 53. When the regenerative air is heated by the heat absorbed in the above, while a heating operation command is given and a predetermined condition is satisfied, heat is drawn from the regenerative air through the second heat exchanger 53 (heat absorption), and the first The processing air is heated by the heat absorbed by the second heat exchanger 53 through the heat exchanger 52.

  The first condenser 61 is disposed in the upstream area of the second heat exchanger 53 in the air discharge path 400, that is, in a predetermined area between the refrigerant compressor 51 and the second heat exchanger 53.

  The second condenser 62 is disposed in an upstream area of the first heat exchanger 52 in the air supply path 300, that is, in a predetermined area between the processing air inlet 301 and the first heat exchanger 52.

  The first condenser 61 and the second condenser 62 constitute a fluid circulation circuit L together with the evaporator 3 incorporated in the showcase 2 and the fluid compressor 4.

  Here, the fluid circulation circuit L is configured by connecting the fluid compressor 4, the first condenser 61, the second condenser 62, the expansion mechanism 5, and the evaporator 3 with fluid pipes, The working fluid is sealed inside. More specifically, the fluid compressor 4, the first condenser 61, the expansion mechanism 5, and the evaporator 3 are sequentially connected by fluid piping, and the fluid compressor 4 and the first condenser 61 are connected. An inlet side of the second condenser 62 is connected to a fluid pipe branched at a branch point in the middle of the connected fluid pipe, and the fluid pipe connected to the outlet side of the second condenser 62 is expanded with the first condenser 61. It is configured to be connected in the middle of the fluid piping connecting the mechanism 5. That is, the first condenser 61 and the second condenser 62 are connected in parallel between the fluid compressor 4 and the expansion mechanism 5. A three-way valve 60 is provided at the branch point of the fluid pipe connecting the fluid compressor 4 and the first condenser 61. Moreover, the code | symbol 6 in a figure is an internal heat exchanger which heat-exchanges between the working fluid and external air which pass.

  Various working fluids can be used as the working fluid sealed in the fluid circulation circuit L. For example, chlorofluorocarbon, hydrochlorofluorocarbon, hydrohydrocarbon, and the like, as in the refrigerant sealed in the refrigerant circulation circuit 50a of the heat pump unit 50. Fluorocarbon, fluorocarbon, a mixed solvent thereof, methyl bromide, ammonia, carbon dioxide, water and the like can be used.

  The fluid compressor 4 compresses the supplied working fluid into a high temperature and high pressure state. The first condenser 61 condenses the working fluid supplied from the fluid compressor 4, that is, the working fluid compressed to a high temperature and high pressure state by the fluid compressor 4. As a result, the regenerated air passing around the first condenser 61 is heated by condensing the working fluid. That is, the first condenser 61 heats the regeneration air that passes toward the second heat exchanger 53.

  The second condenser 62 condenses the working fluid supplied from the fluid compressor 4, that is, the working fluid compressed to a high temperature and high pressure state by the fluid compressor 4. Thereby, the process air which passes the circumference | surroundings of the 2nd condenser 62 is heated by condensing a working fluid. That is, the second condenser 62 heats the processing air that passes toward the first heat exchanger 52.

  The expansion mechanism 5 adiabatically expands the working fluid supplied from the first condenser 61 or the second condenser 62, that is, the working fluid condensed by the first condenser 61 or the working fluid condensed by the second condenser 62. That is, the working fluid is depressurized to a low temperature and low pressure state. The evaporator 3 evaporates the refrigerant adiabatically expanded to a low temperature and low pressure state by the expansion mechanism 5. Thereby, the goods displayed inside the showcase 2 are deprived of heat and cooled.

  The three-way valve 60 provided in the fluid circulation circuit L allows the supply of the working fluid from the fluid compressor 4 to the first condenser 61 when given a command from a controller 70 described later, and the fluid compression It switches to the case where supply of the working fluid from the machine 4 to the second condenser 62 is allowed. When the three-way valve 60 allows the supply of the working fluid from the fluid compressor 4 to the first condenser 61, the three-way valve 60 supplies the working fluid from the fluid compressor 4 to the second condenser 62. On the other hand, when supply of the working fluid from the fluid compressor 4 to the second condenser 62 is permitted, supply of the working fluid from the fluid compressor 4 to the first condenser 61 is prohibited. It is regulated.

  In such a fluid circulation circuit L, the working fluid is constantly circulated in order to cool the product inside the showcase 2. More specifically, the fluid compressor 4 → the first is switched by the switching operation of the three-way valve 60. The working fluid circulates in the order of the condenser 61 → the expansion mechanism 5 → the evaporator 3 → the fluid compressor 4 or the fluid compressor 4 → the second condenser 62 → the expansion mechanism 5 → the evaporator 3 → the fluid compressor 4. .

  FIG. 2 is a block diagram schematically showing a control system of the dehumidifying air conditioner shown in FIG. As illustrated in FIG. 2, the dehumidifying air conditioner 10 includes a controller 70.

  The controller 70 incorporates a memory (not shown) of the dehumidifying air conditioner and controls the overall operation of the dehumidifying air conditioner according to data and programs stored in the memory. The controller 70 includes various processing units, but particularly includes a reference value setting storage unit 71, a compressor drive processing unit 72, and a valve switching processing unit 73 as those related to the present invention.

  The reference value setting storage unit 71 sets an air supply reference value in advance and stores it. This air supply reference value relates to temperature and humidity, and is a threshold value for determining whether or not the heating effect obtained experimentally is exhibited.

  The compressor drive processing unit 72 performs drive processing of the refrigerant compressor 51 that constitutes the heat pump unit 50. More specifically, when a dehumidifying operation command is given, a process of driving the refrigerant compressor 51 at a determined rotation speed (frequency), a process of increasing the rotation speed of the refrigerant compressor 51, as necessary The process which stops the drive of the refrigerant compressor 51 is performed.

  The valve switching processing unit 73 performs switching processing of the three-way valve 60, that is, the case where supply of the working fluid from the fluid compressor 4 to the first condenser 61 is permitted, and the operation from the fluid compressor 4 to the second condenser 62. A switching process is performed for the case where the supply of fluid is permitted.

  In the dehumidifying air conditioner 10 having the above configuration, the dehumidifying operation and the heating operation are performed as follows. In the following description, it is assumed that in the fluid circulation circuit L, the fluid compressor 4 is driven and the working fluid is constantly circulated.

  First, the case where the dehumidifying operation is performed will be described. As a premise of this description, the valve body 54 constituting the heat pump unit 50 is adjusted so that the refrigerant compressed by the refrigerant compressor 51 is sent out toward the second heat exchanger 53, and the three-way valve 60 is adjusted to allow the supply of the working fluid from the fluid compressor 4 to the first condenser 61.

  The controller 70 to which the dehumidifying operation command is given gives drive commands to the motor M, the supply fan 32 and the discharge fan 42 to drive them.

  When the motor M is driven, the moisture adsorbing body 21 rotates. In the heat pump unit 50, the refrigerant compressed by the refrigerant compressor 51 (high-temperature and high-pressure) is adjusted so that the refrigerant compressed by the refrigerant compressor 51 is sent out toward the second heat exchanger 53. Of the refrigerant) is sent to the second heat exchanger 53, exchanged heat with the regenerated air in the second heat exchanger 53, then sent to the first heat exchanger 52, and processed air in the first heat exchanger 52. The refrigerant circulation circuit 50a is circulated in such a manner as to return to the refrigerant compressor 51 after heat exchange with the refrigerant. That is, the first heat exchanger 52 acts as an evaporator, while the second heat exchanger 53 acts as a condenser.

  By driving the supply fan 32, the processing air is taken into the air supply path 300 through the processing air intake port 301, and the introduced processing air passes through the second condenser 62 and reaches the first heat exchanger 52. The processing air that has reached the first heat exchanger 52 is cooled by the evaporation of the refrigerant passing through the inside of the first heat exchanger 52 and reaches the moisture adsorption region 31. In the moisture adsorption region 31, moisture contained in the processing air is adsorbed by a corresponding portion of the moisture adsorbing body 21, and the humidity of the processing air is lowered. That is, the processing air is dehumidified. Further, the moisture adsorbed on the portion of the moisture adsorbing body 21 corresponding to the moisture adsorbing area 31 moves from the moisture adsorbing area 31 to the moisture releasing area 41 as the moisture adsorbing body 21 rotates. The processing air dehumidified in the moisture adsorption region 31 flows toward the downstream region by driving the supply fan 32, and is then supplied into the store 1 through the processing air discharge port 302.

  On the other hand, when the discharge fan 42 is driven, the regeneration air is taken in through the regeneration air intake 401, and the introduced regeneration air passes around the refrigerant compressor 51. The regenerated air that passes around the refrigerant compressor 51 is slightly heated by drive heat generated from the refrigerant compressor 51 (actually heat generated from a motor or the like) and reaches the first condenser 61. The regeneration air that has reached the first condenser 61 is heated by condensation of the working fluid flowing inside the first condenser 61, and reaches the second heat exchanger 53. The regenerative air that has reached the second heat exchanger 53 is further heated by the refrigerant passing through the second heat exchanger 53 condensing, and reaches a moisture release region 41. In the moisture release region 41, when the regeneration air heated by the first condenser 61 and the second heat exchanger 53 passes, moisture is released from the corresponding part of the moisture adsorbent 21, and the humidity of the regeneration air is reduced. To rise. Thereafter, the regeneration air that has passed through the moisture release region 41 is discharged to the outside through the regeneration air discharge port 402 by driving the discharge fan 42.

  The portion of the moisture adsorbing body 21 corresponding to the moisture releasing region 41 is dried by releasing moisture, and the temperature rises. The corresponding portion of the dried moisture adsorbent 21 is moved from the moisture release area 41 to the moisture adsorption area 31 with the rotation of the moisture adsorbent 21, and the above operation is repeated, so that the dehumidifying operation is performed. Is done.

  Thus, in the dehumidifying air conditioner 10, when performing the dehumidifying operation, the process air introduced from the outside is cooled by the first heat exchanger 52, and the cooled process air is passed through the moisture adsorption region 31 to absorb moisture. The body 21 adsorbs moisture to dehumidify it and supplies the dehumidified treated air to the inside of the store 1, while the introduced regeneration air is heated by the first condenser 61 and further heated by the second heat exchanger 53. Then, the water is released to the moisture adsorbent 21 by passing the regeneration air through the moisture release region 41 at a high temperature. That is, heat is drawn up (absorbed) from the process air through the first heat exchanger 52, and the regenerated air is heated by the heat absorbed by the first heat exchanger 52 through the second heat exchanger 53.

  And in the said dehumidification air conditioner 10, since the 1st condenser 61 heats the reproduction | regeneration air which passes toward the moisture discharge | release area | region 41 separately from the heat pump unit 50 (2nd heat exchanger 53), dehumidification operation is performed. In some cases, the regeneration air can be sufficiently heated even when the outside air temperature is low. That is, even if the amount of heat absorbed from the processing air through the first heat exchanger 52 is small, the regeneration air can be sufficiently heated regardless of this. As a result, the regenerated air passes through the moisture release region 41, so that the moisture adsorbent 21 can sufficiently release the moisture. Accordingly, when performing the dehumidifying operation, it is possible to suppress a decrease in the dehumidifying ability of the processing air by sufficiently heating the regenerated air.

  In particular, the first condenser 61 constitutes a fluid circulation circuit L together with the evaporator 3 built in the showcase 2 disposed inside the store 1 and the fluid compressor 4 that compresses the working fluid, and the fluid compression circuit L Since the regeneration air is heated by condensing the working fluid compressed by the machine 4, the exhaust heat of the showcase 2 can be used effectively, and a new heat source is not required, so the cost required for operation can be reduced. Can be planned.

  Next, a case where the heating operation is performed will be described. As a premise of this explanation, the valve body 54 constituting the heat pump unit 50 is adjusted so that the refrigerant compressed by the refrigerant compressor 51 is sent out toward the first heat exchanger 52, and the three-way valve 60 is adjusted to allow the supply of the working fluid from the fluid compressor 4 to the first condenser 61. Further, it is assumed that each of the motor M, the supply fan 32, and the discharge fan 42 is driven.

  By adjusting the valve body 54 in this way, the refrigerant (high-temperature and high-pressure refrigerant) compressed by the refrigerant compressor 51 is sent to the first heat exchanger 52, and the first heat exchanger 52 After the heat exchange, the refrigerant is sent to the second heat exchanger 53, and after the heat exchange with the regenerated air in the second heat exchanger 53, the refrigerant is circulated through the refrigerant circulation circuit 50a in a manner of returning to the refrigerant compressor 51. That is, the first heat exchanger 52 acts as a condenser, while the second heat exchanger 53 acts as an evaporator.

  FIG. 3 is a flowchart showing the processing contents performed by the controller. The case where the dehumidifying air conditioner 10 performs the heating operation will be described with reference to FIG. 3 as appropriate.

  When the heating operation command is given (step S101: Yes), the controller 70 stops the driving of the motor M and controls the driving of the refrigerant compressor 51 through the compressor driving processing unit 72 (step S102, Step S103). Thus, when the drive of the motor M is stopped, the rotation of the moisture adsorbing body 21 is stopped. Accordingly, moisture adsorption in the moisture adsorption region 31 and moisture release in the moisture release region 41 are hardly performed. As a result, the processing air simply passes through the moisture adsorption region 31, and the regeneration air simply passes through the moisture release region 41.

  FIG. 4 is a flowchart showing the processing contents of the refrigerant compressor drive control in FIG. The processing content of step S103 will be described with reference to FIG. 4 as appropriate. In this refrigerant compressor drive control, the controller 70 detects the temperature and humidity of the processing air (hereinafter also referred to as supply air) discharged from the processing air discharge port 302 through the supply air temperature and humidity sensor S and supplied to the store 1 ( Step S201), comparing the detected air supply temperature and humidity, that is, the air supply measurement value, with the air supply reference value stored in the reference value setting storage unit 71, and whether or not the air supply measurement value is equal to or less than the air supply reference value. Is determined (step S202).

  When the air supply measurement value is equal to or less than the air supply reference value (step S202: Yes), the processing air (air supply) supplied to the store 1 is heated sufficiently and sufficiently when the heat pump unit 50 is driven at this time. The controller 70 increases the rotational speed of the refrigerant compressor 51 through the compressor drive processing unit 72 (step S203), ends the current process, and returns the procedure. By increasing the rotational speed in this way, the heating level of the processing air can be increased through the first heat exchanger 52.

  On the other hand, when the air supply measurement value exceeds the air supply reference value (step S202: No), the heating effect by the heat pump unit 50 is exhibited, and the processing air supplied to the store 1 by driving the heat pump unit 50 is necessary. It is said that it has been sufficiently heated, and the current process is terminated while maintaining the state as it is, and the procedure is returned.

  By maintaining the state as it is, it becomes as follows. By driving the supply fan 32, the processing air is taken into the air supply path 300 through the processing air intake port 301, and the introduced processing air passes through the second condenser 62 and reaches the first heat exchanger 52. The processing air that has reached the first heat exchanger 52 is heated by condensation of the refrigerant passing through the inside of the first heat exchanger 52, passes through the moisture adsorption region 31, and then passes through the processing air discharge port 302 to the store 1. Supplied inside.

  On the other hand, when the discharge fan 42 is driven, the regeneration air is taken in through the regeneration air intake 401, and the introduced regeneration air passes around the refrigerant compressor 51. The regenerated air that passes around the refrigerant compressor 51 is slightly heated by drive heat generated from the refrigerant compressor 51 (actually heat generated from a motor or the like) and reaches the first condenser 61. The regeneration air that has reached the first condenser 61 is heated by condensation of the working fluid flowing inside the first condenser 61, and reaches the second heat exchanger 53. The regenerated air that has reached the second heat exchanger 53 is cooled by the evaporation of the refrigerant passing through the second heat exchanger 53, that is, the heat is absorbed by the second heat exchanger 53, and the moisture release region 41. And then discharged to the outside through the regeneration air discharge port 402.

  As described above, in the dehumidifying air conditioner 10, when the heating operation is performed and the heat pump unit 50 is driven, the processing air introduced from the outside is heated by the first heat exchanger 52, and the heated processing air is stored in the store. 1, while the introduced regeneration air is heated by the first condenser 61 and absorbed by the second heat exchanger 53. That is, heat is drawn up (absorbed) from the regenerated air through the second heat exchanger 53, and the process air is heated by the heat absorbed by the second heat exchanger 53 through the first heat exchanger 52.

  According to the dehumidifying air conditioner 10, the first condenser 61 is disposed in the upstream region of the second heat exchanger 53 constituting the heat pump unit 50 and passes toward the second heat exchanger 53. Since the regenerative air is heated, it is possible to prevent the moisture of the regenerative air from icing on the heat transfer surface of the second heat exchanger 53 when the heating operation is performed, and a frosted state can be avoided. The amount of heat absorbed by the heat exchanger 53 can be ensured, so that the processing air can be satisfactorily heated through the first heat exchanger 52, and as a result, a decrease in the heating capacity of the processing air can be suppressed. . Even if the moisture of the regenerated air is frosted on the heat transfer surface of the second heat exchanger 53, defrosting is performed by stopping the operation of the heat pump unit 50 and passing the regenerated air heated by the heater. Is possible.

  The controller 70 that has performed the refrigerant compressor drive control as described above then performs the three-way valve switching control (step S104). FIG. 5 is a flowchart showing the processing contents of the three-way valve switching control in FIG. The processing content of step S104 will be described with reference to FIG.

  The controller 70 in the three-way valve switching control terminates the current process and returns the procedure without performing the process described later when the rotation speed is not increased in the refrigerant compression drive control (step S301: No). Let Thereby, the heating operation state as described above is maintained.

  On the other hand, when the rotational speed is increased in the refrigerant compression drive control (step S301: Yes), the supply air temperature and humidity are detected through the supply air temperature and humidity sensor S (step S302), and the supply air measurement value and the supply air are detected. By comparing with the reference value, it is determined whether or not the air supply measurement value is equal to or less than the air supply reference value (step S303). In this step S303, when the air supply measurement value exceeds the air supply reference value (step S303: No), the current process is terminated and the procedure is returned without performing the process described later. Thereby, the heating operation state as described above is maintained.

  In step S303, if the supply air measurement value is equal to or less than the supply air reference value (step S303: Yes), the controller 70 determines whether or not the rotational speed is the upper limit value through the compressor drive processing unit 72. However, if it is not the upper limit value (step S304: No), the current process is terminated and the procedure is returned without performing the process described later. Thereby, in the next process, the refrigerant compressor drive control in step S103 can be performed again to increase the rotational speed.

  In step S304, when it is the upper limit value (step S304: Yes), the controller 70 stops driving the refrigerant compressor 51 through the compressor drive processing unit 72 (step S305), and then through the valve switching processing unit 73. Switching processing of the three-way valve 60 is performed (step S306).

  By performing the switching process of the three-way valve 60 in this way, the three-way valve 60 is switched to allow the supply of the working fluid from the fluid compressor 4 to the second condenser 62. Accordingly, the processing air is taken into the air supply path 300 through the processing air intake port 301 by driving the supply fan 32, and the introduced processing air reaches the second condenser 62. The processing air that has reached the second condenser 62 is heated by the condensation of the working fluid flowing inside the second condenser 62, passes through the first heat exchanger 52 and the moisture adsorption region 31, and then the processing air discharge port. It is supplied to the inside of the store 1 through 302.

  In the dehumidifying air conditioner 10, when the heating operation command is given and the driving of the heat pump unit 50 is stopped, the processing air introduced from the outside is converted into the second condenser by performing the switching process of the three-way valve 60. The heated processing air is supplied to the interior of the store 1 by heating at 62. In other words, the processing air passing toward the moisture adsorption region 31 is heated using the heat acquired by the evaporator 3 through the fluid circulation circuit L, that is, using the exhaust heat of the showcase 2. The controller 70 that has performed the three-way valve switching control as described above ends the current process (see FIG. 3).

  As described above, according to the dehumidifying air conditioner 10 in the embodiment of the present invention, when the second condenser 62 is given a heating operation command and the heat pump unit 50 stops driving, the showcase 2 Since the processing air that passes toward the moisture adsorption region 31 is heated using the exhaust heat, the heating operation can be performed well even in the intermediate period while saving energy.

  Further, according to the dehumidifying air conditioner 10, the refrigerant compressor 51 constituting the heat pump unit 50 is disposed in the vicinity of the regeneration air intake 401, more specifically, in the downstream area immediately adjacent to the regeneration air intake 401. The regeneration air can be preliminarily heated by the driving heat generated from the refrigerant compressor 51. With this, when the dehumidifying operation is performed in combination with the action and effect of the first condenser 61, the regeneration air is sufficient. When the heating operation is performed, a decrease in the dehumidifying capacity of the processing air can be suppressed. In addition, when the heating operation is performed, a decrease in the heating capacity of the processing air can be suppressed.

  Although the preferred embodiment of the present invention has been described above, the present invention is not limited to this, and various modifications can be made. For example, in the above-described embodiment, the case where the first condenser 61 is disposed in the air discharge path 400 has been described. However, in the present invention, the first condenser may be disposed outside the air discharge path. I do not care.

  As described above, the present invention is applied to stores such as supermarkets, convenience stores, and shopping centers, and is useful as a dehumidifying air conditioner having functions of ventilation, dehumidification, and air conditioning by introducing outside air into the store.

It is the schematic diagram which showed typically the structure of the dehumidification air conditioning apparatus in embodiment of this invention. It is a block diagram which shows typically the control system of the dehumidification air conditioning apparatus shown in FIG. It is a flowchart which shows the processing content which a controller performs. It is a flowchart which shows the processing content of the refrigerant compressor drive control in FIG. FIG. 5 is a flowchart showing the processing contents of the three-way valve switching control in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Store 2 Showcase 3 Evaporator 4 Compressor 5 Expansion mechanism 10 Dehumidification air conditioner 20 Dehumidification rotor 21 Moisture adsorption body 30 Air supply unit 31 Moisture adsorption area 40 Air release unit 41 Moisture release area 50 Heat pump unit 50a Refrigerant circulation circuit 51 Compression Machine 52 First heat exchanger 53 Second heat exchanger 54 Valve body 60 Three-way valve 61 First condenser 62 Second condenser 70 Controller 71 Reference value setting storage section 72 Compressor drive processing section 73 Valve switching processing section L Fluid Circulation circuit S Temperature / humidity sensor

Claims (6)

When the dehumidifying operation command is given, the moisture adsorbent is circulated between the partitioned moisture adsorption region and the moisture releasing region, and when the heating operation command is given, the circulation of the moisture adsorbent is stopped. A dehumidifying rotor,
Air supply means for supplying processing air introduced from the outside in a mode of passing through the moisture adsorption region into the target chamber;
An air release means for releasing the regeneration air introduced from the outside in a mode of passing through the moisture release region;
A refrigerant circulation circuit in which a compressor for compressing the refrigerant, and a first heat exchanger and a second heat exchanger for exchanging heat between the refrigerant and ambient air are sequentially connected by piping; When the dehumidifying operation command is given, the processing air passing toward the moisture adsorption region through the first heat exchanger is cooled and passed toward the moisture release region through the second heat exchanger. In a dehumidifying air conditioner equipped with a heat pump unit for heating regenerated air,
When the heating operation command is given and the heat pump unit stops driving, the processing air passing toward the moisture adsorption region is heated using the exhaust heat of the refrigeration equipment arranged in the target chamber. A dehumidifying air conditioner comprising processing air heating means.   The said process air heating means is arrange | positioned in the upstream area of the said 1st heat exchanger, and heats the process air which passes toward this 1st heat exchanger, It is characterized by the above-mentioned. Dehumidifying air conditioner.   The processing air heating means constitutes a fluid circulation circuit that circulates the working fluid together with an evaporator built in the refrigeration refrigerator and a compressor that compresses the working fluid, and the working fluid compressed by the compressor The dehumidifying air conditioner according to claim 1 or 2, wherein the processing air is heated by condensation.   When a heating operation command is given and the heat pump unit reverses the refrigerant circulation direction in the refrigerant circulation circuit and heats the processing air passing toward the moisture adsorption region through the first heat exchanger, The regenerative air heating means for heating the regenerative air that passes toward the moisture release region using exhaust heat of the refrigeration equipment is provided. Dehumidifying air conditioner.   The said regeneration air heating means is arrange | positioned in the upstream area of the said 2nd heat exchanger, and heats the regeneration air which passes toward this 2nd heat exchanger, It is characterized by the above-mentioned. Dehumidifying air conditioner.   The dehumidifying air conditioner according to claim 4 or 5, wherein the regeneration air heating means constitutes the fluid circulation circuit.

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