JP2013160459A - Humidity controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a humidity controller from being increased in size and a structure from being complicated when constituting the humidity controller without using an adsorption heat exchanger, and to prevent trouble such as the peeling of an adsorbent.SOLUTION: A humidity controller includes humidity control modules (20) each including an electrocaloric cooling material (21) being a material capable of generating an electrocaloric effect and a pair of electrodes (22) for applying electric fields from a power supply (25) to the electrocaloric cooling material (21) and forming adsorption layers (23) capable of adsorbing and non-adsorbing water in air on its surface, and a voltage controller (35) for switching the application of an electric field to the electrocaloric material (21) and the release of the electric fields.

Description

  The present invention relates to a humidity control module that adsorbs and desorbs moisture, a humidity control unit that includes the humidity control module and a voltage controller, and a humidity control apparatus for adjusting indoor humidity using the humidity control module. It is about.

  Conventionally, there is a humidity control apparatus using an air heat exchanger (adsorption heat exchanger) whose surface is coated with an adsorbent (see, for example, Patent Document 1). In the humidity control apparatus of Patent Document 1, an adsorption heat exchanger is used as the heat exchanger of the refrigerant circuit. In a humidity control apparatus using two adsorption heat exchangers, moisture in the air is adsorbed by one adsorption heat exchanger, moisture is released into the air by the other adsorption heat exchanger, and the adsorption heat exchanger Played. Then, while alternately switching the adsorption side heat exchanger and the regeneration side heat exchanger, the dehumidifying operation is performed by supplying the air that has passed through the adsorption side heat exchanger into the room, or the regeneration side heat exchanger. Humidification operation is performed by supplying air that has passed through the room.

  On the other hand, Patent Documents 2 and 3 disclose heat pump devices that use the property of generating heat when an elastic body such as rubber is adiabatically stretched and absorbing heat when adiabatic contraction is performed. In view of this, it is conceivable to use this property to adsorb and desorb moisture using a humidity control device in which an adsorbent is applied to an elastic body such as rubber instead of the adsorption heat exchanger.

JP 2005-114291 A JP-A-3-286975 Japanese Patent Laid-Open No. 10-259965

  However, in the configuration in which an adsorbent is applied to an elastic body such as rubber, a mechanism for expanding and contracting the elastic body is required, which complicates the structure of the apparatus and increases the size of the apparatus. Further, when an elastic body such as rubber coated with an adsorbent is stretched, the adsorbent layer may be peeled off.

  The present invention has been made in view of such problems, and the object thereof is to prevent an increase in the size of the apparatus and a complicated structure when a humidity control apparatus is configured without using an adsorption heat exchanger. At the same time, it is to prevent a problem that the adsorbent is peeled off.

  The first invention is premised on a humidity control module that adsorbs and desorbs moisture in the air.

  The humidity control module (20) is provided in the electrocaloric cooling material (21) so as to apply an electric field from the power source (25) to the electrocaloric cooling material (21) and the electrocaloric cooling material (21). A pair of electrodes (22) is provided, and an adsorption layer (23) capable of adsorbing and desorbing moisture in the air is provided on the surface.

  In this first invention, due to the electrocaloric effect of the electrocaloric cooling material (21), when a voltage (electric field) is applied to the electrocaloric cooling material (21), the electrocaloric cooling material (21) generates heat. Therefore, moisture contained in the adsorption layer (23) is desorbed. In addition, when the application of the electric field to the electrocaloric cooling material (21) is released (the electric field application is released after a certain period of time has elapsed after the electric field is applied), the electrocaloric cooling material (21) is cooled from room temperature. . Therefore, moisture is efficiently adsorbed to the adsorption layer (23).

  The second invention is an electrocaloric cooling material (21) and a pair of electrodes provided on the electrocaloric cooling material (21) so that an electric field is applied to the electrocaloric cooling material (21) from a power source (25). (22), a humidity control module (20) provided with an adsorption layer (23) capable of adsorbing and desorbing moisture in the air, and an electric field applied to the electrocaloric cooling material (21). The present invention relates to a humidity control unit comprising a voltage controller (35) for setting application and release.

  In the second aspect of the invention, the voltage controller (35) sets the application and release of the electric field to the electrocaloric cooling material (21), thereby absorbing moisture from the adsorbent and removing moisture from the adsorbent. A moisture release operation can be performed.

  A third invention is the electromechanical cooling material (21) from the power source (25) when the voltage controller (35) desorbs moisture from the adsorption layer (23) in the second invention. It is characterized by being configured to apply an electric field to.

  In the third aspect of the invention, an electric field is applied to the electrocaloric cooling material (21) by the voltage controller (35) to perform a moisture release operation.

  According to a fourth invention, in the second invention, when the voltage controller (35) absorbs moisture in the adsorption layer (23), the power source (25) supplies the electrocaloric cooling material (21). It is characterized by being configured to cancel the application of an electric field.

  In the fourth aspect of the invention, the voltage controller (35) releases the application of the electric field to the electrocaloric cooling material (21), and the moisture absorption operation is performed.

  According to a fifth invention, in the second invention, when the voltage controller (35) desorbs moisture from the adsorption layer (23) to the electrocaloric cooling material (21) from the power source (25). Moisture release operation to apply an electric field and moisture absorption operation to release the electric field application from the power source (25) to the electrocaloric cooling material (21) when moisture is absorbed by the adsorption layer (23) are alternately performed. It is characterized by being configured.

  In the fifth aspect of the invention, the voltage controller (35) performs a moisture releasing operation in which an electric field is applied to the electrocaloric cooling material (21) and a moisture absorption in which the application of the electric field to the electrocaloric cooling material (21) is released. The operation is performed alternately.

  According to a sixth invention, in the fifth invention, the voltage controller (35) changes the magnitude of the electric field applied to the electrocaloric cooling material (21), thereby changing the electrocaloric cooling material (21). The heat generation amount is adjusted, and the moisture absorption / release capacity is adjusted.

  In the sixth aspect of the invention, the amount of heat generated by the electrocaloric cooling material (21) is changed by changing the magnitude of the electric field applied to the electrocaloric cooling material (21) by the voltage controller (35). Ability is adjusted.

  According to a seventh invention, in the fifth invention, the voltage controller (35) changes the ratio of applying an electric field to the entire electrocaloric cooling material (21), thereby changing the electrocaloric cooling material (21). It is characterized by adjusting the calorific value and adjusting the moisture absorption and desorption capacity.

  In the seventh aspect of the invention, the heat generation amount of the electrocaloric cooling material (21) is adjusted by changing the ratio of applying the electric field to the whole electrocaloric cooling material (21), and the moisture absorption / release capacity is adjusted. The

  In an eighth aspect based on the fifth aspect, the voltage controller (35) adjusts the calorific value of the electrocaloric cooling material (21) by changing a time interval in which the moisture releasing operation and the moisture absorbing operation are repeated. The moisture absorption / release capacity is adjusted.

  In the eighth aspect of the invention, the calorific value of the electrocaloric cooling material (21) is adjusted by changing the time interval for repeating the moisture releasing operation and the moisture absorbing operation, thereby adjusting the moisture absorption / release capability.

  The ninth invention comprises an electrocaloric cooling material (21) and a pair of electrodes provided on the electrocaloric cooling material (21) so that an electric field is applied to the electrocaloric cooling material (21) from a power source (25). (22), a humidity control module (20) provided with an adsorption layer (23) capable of adsorbing and desorbing moisture in the air, and an electric field applied to the electrocaloric cooling material (21). A humidity control apparatus comprising a voltage controller (35) for setting application and release, and an air passage (P) for supplying air that has passed through the humidity control module (20) to a room It is.

  In the ninth aspect of the invention, by setting the application and release of the electric field to the electrocaloric cooling material (21) by the voltage controller (35), the moisture absorption operation for adsorbing moisture with the adsorbent and the moisture from the adsorbent are performed. The moisture releasing operation | movement which discharge | releases can be performed and the processed air can be supplied indoors from an air path (P).

  A tenth aspect of the invention is characterized in that, in the ninth aspect of the invention, the air passage (P) is configured to introduce the air that has been subjected to moisture absorption treatment by the humidity control module (20) into the room.

  In the tenth aspect of the invention, application of an electric field to the electrocaloric cooling material (21) is released by the voltage controller (35), and the moisture-reduced operation is performed to supply the dehumidified air into the room.

  An eleventh invention is characterized in that, in the ninth invention, the air passage (P) is configured to introduce the air subjected to moisture release treatment by the humidity control module (20) into the room.

  In the eleventh aspect of the invention, an electric field is applied to the electrocaloric cooling material (21) by the voltage controller (35), and the humidified air is supplied to the room by performing a moisture releasing operation.

  In a twelfth aspect of the invention according to the ninth aspect, a dehumidifying operation for introducing the air absorbed by the humidity control module (20) into the room, and introducing the air dehumidified by the humidity control module (20) into the room. It is characterized in that it can be switched between humidifying operations.

  In the twelfth aspect of the present invention, the voltage controller (35) cancels the application of the electric field to the electrocaloric cooling material (21), the dehumidifying operation in which the moisture absorption operation is performed and the dehumidified air is supplied to the room, An electric field is applied to the electrocaloric cooling material (21), and a humidifying operation in which a humidifying operation is performed and humidified air is supplied to the room can be switched and operated.

  According to a thirteenth aspect, in the ninth aspect, in addition to the humidity control module (20), the humidity control module (20) is configured to cool and heat the air without providing an adsorption layer (23). And the air passage (P) introduces the air absorbed by the humidity control module (20) into the room and the air cooled by the cooling and heating module (24) in the room. It is characterized in that it is configured to be introduced. In this configuration, the humidity control module (20) and the cooling and heating module (24) may be arranged in series with respect to the air flow, and the air may be continuously processed in each module (20, 24). The humidity control module (20) and the cooling / heating module (24) may be arranged in parallel, and the air that has passed through the modules (20, 24) may be merged and supplied to the room.

  In the thirteenth aspect of the invention, the dehumidifying and cooling operation is performed by introducing the moisture-treated air and the cooled air into the room.

  In a fourteenth aspect based on the ninth aspect, in addition to the humidity control module (20), the humidity control module (20) is configured to cool and heat air without providing an adsorption layer (23). The air passage (P) introduces the air dehumidified by the humidity control module (20) into the room, and the air heated by the cooling and heating module (24). It is characterized by being configured to be introduced indoors. The humidity control module (20) and the cooling / heating module (24) may be arranged in series or in parallel with respect to the air flow direction, as in the thirteenth invention.

  In the fourteenth aspect, the humidification heating operation is performed by introducing the moisture-treated air and the heat-treated air into the room.

  According to a fifteenth aspect, in the ninth aspect, in addition to the humidity control module (20), the humidity control module (20) is configured to cool and heat the air without providing the adsorption layer (23). A dehumidifying and cooling operation for introducing the air that has been adsorbed by the humidity control module (20) and the air cooled by the cooling and heating module (24) into the room, and the humidity control module (20) It is characterized in that it can be switched between the humidified heating operation for introducing the air dehumidified in the above and the air heated by the cooling and heating module (24) into the room. The humidity control module (20) and the cooling / heating module (24) may be arranged in series or in parallel with respect to the air flow direction, as in the thirteenth and fourteenth inventions.

  In the fifteenth aspect of the invention, the dehumidifying and cooling operation for introducing the moisture-treated air and the cooled air into the room and the humidifying and heating operation for introducing the moisture-treated air and the heat-treated air into the room are switched. it can.

  According to a sixteenth aspect of the present invention, in any one of the ninth to fifteenth aspects, the humidity control module (20) includes a front surface and a back surface of the electrocaloric cooling material (21) formed in a tube shape or a plate shape. The base module (47, 54, 64, 74) provided with the electrode (22) is provided, and the adsorbent is provided around the base module (47, 54, 64, 74). It is said.

  In the sixteenth aspect of the invention, the adsorbent can be heated and cooled with a simple configuration by using the tube-shaped or plate-shaped electrocaloric cooling material (21).

  According to a seventeenth aspect, in any one of the ninth to fifteenth aspects, the humidity control module (20) includes an inner peripheral surface and an outer peripheral surface of the electrocaloric cooling material (21) formed in a cylindrical shape. The base module (85) provided with the electrode (22) is provided, and the adsorbent is provided on the surface of the electrode (22).

  In the seventeenth aspect, by using the cylindrical electrocaloric cooling material (21), the adsorbent can be heated and cooled with a simple configuration.

  According to an eighteenth aspect of the present invention, in any one of the ninth to fifteenth aspects, the humidity control module (20) has the electrodes on both sides of the electrocaloric cooling material (21) formed in a block shape. A base module (95) provided with (22) is provided, and the adsorbent is provided on the surface of the electrode (22).

  In the eighteenth aspect of the invention, the adsorbent can be heated and cooled by providing the electrodes (22) on both sides of the electrocaloric cooling material (21).

  In a nineteenth aspect based on any one of the ninth to fifteenth aspects, the humidity control module (20) drives the plurality of fins (102) formed of the electrocaloric cooling material (21). A member (101) is provided, and is configured to switch between application and release of an electric field to the electrocaloric cooling material (21) in the air passage (P).

  In the nineteenth aspect of the invention, a plurality of fins (102) formed of an electrocaloric cooling material (21) are used, and the fins (102) are transported by a driving member (101), thereby heating and cooling the adsorbent. It can be carried out.

  According to the first aspect of the invention, due to the electrocaloric effect of the electrocaloric cooling material (21), when a voltage (electric field) is applied to the electrocaloric cooling material (21), the electrocaloric cooling material (21) generates heat. Since the moisture contained in the adsorption layer (23) is desorbed, the humidifying operation can be performed by supplying the desorbed moisture to the air and supplying it to the room. In addition, when the application of the electric field to the electrocaloric cooling material (21) is released, the electrocaloric cooling material (21) is cooled and moisture is efficiently adsorbed to the adsorption layer (23). A dehumidifying operation can be performed by supplying it indoors.

  And according to this invention, since the structure which apply | coats adsorption agent to elastic bodies, such as rubber | gum, is not employ | adopted, the mechanism for expanding / contracting an elastic body is unnecessary. Therefore, it is possible to prevent the device structure from becoming complicated and the device from becoming large. Further, since the configuration in which the adsorbent is applied to the elastic body is not employed, the adsorbent layer does not peel off even if no special measures are taken.

  According to the second aspect of the invention, by setting the application and release of the electric field to the electrocaloric cooling material (21) by the voltage controller (35), the moisture absorption operation for adsorbing moisture with the adsorbent, and the adsorbent A moisture releasing operation for releasing moisture can be performed. Since the humidity control unit can be configured compactly, using this humidity control unit in a humidity control device makes it possible to easily realize a humidity control device that suppresses the complexity and size of the structure, and sets the dehumidifying operation and humidifying operation. Can also be done easily.

  According to the third to fifth inventions described above, the configuration for performing only the dehumidifying operation (third invention), the configuration for performing only the humidifying operation (fourth invention), and further switching between the dehumidifying operation and the humidifying operation. The structure to be performed (fifth invention) can be easily realized.

  According to the sixth aspect, the calorific value of the electrocaloric cooling material (21) can be adjusted based on the magnitude of the applied electric field, and the moisture absorption / release capacity can be easily adjusted. Driving.

  According to the seventh aspect of the invention, the calorific value of the electrocaloric cooling material (21) can be adjusted based on the electric field application rate, and the moisture absorption / release capacity can be easily adjusted. It becomes possible to drive.

  According to the eighth aspect of the invention, the calorific value of the electrocaloric cooling material (21) can be adjusted based on the time interval of electric field application, and the moisture absorption / release capacity can be easily adjusted. Driving.

  According to the ninth aspect of the invention, by setting the application and release of the electric field to the electrocaloric cooling material (21) by the voltage controller (35), the moisture absorption operation for adsorbing moisture with the adsorbent, A moisture releasing operation for releasing moisture can be performed, and the treated air can be supplied into the room from the air passage (P).

  According to the tenth to twelfth aspects of the present invention, in the humidity control apparatus, the configuration for performing only the dehumidifying operation (the tenth aspect), the configuration for performing only the humidifying operation (the eleventh aspect), and further the dehumidifying operation and the humidifying operation. A configuration (a twelfth aspect of the invention) that switches between operation can be easily realized.

  According to the thirteenth aspect, by using the humidity control module (20) and the cooling and heating module (24), the configuration for performing the dehumidifying and cooling operation can be easily realized.

  According to the fourteenth aspect, by using the humidity control module (20) and the cooling and heating module (24), the configuration for performing the humidifying and heating operation can be easily realized.

  According to the fifteenth aspect of the invention, the dehumidifying and cooling operation for introducing the moisture-treated air and the cooled air into the room and the humidifying and heating operation for introducing the moisture-treated air and the heat-treated air into the room are switched. The configuration can be easily realized.

  According to the sixteenth to nineteenth aspects, by specifying the configuration of the humidity control module (20), it becomes possible to easily realize the humidity control apparatus according to the ninth to fifteenth aspects.

FIG. 1 is a schematic diagram illustrating a state in which the humidity control apparatus according to Embodiments 1 and 4 of the present invention is installed in a room. FIG. 1 (A) illustrates an operating state of a moisture absorption operation, and FIG. ) Shows the operating state of the moisture release operation. FIG. 2 is a schematic configuration diagram of a humidity control module used in the humidity control apparatus of FIG. FIG. 3A is a diagram illustrating a state of the moisture release operation in the schematic configuration diagram of the humidity control module, and FIG. 3B is a diagram illustrating a state of the moisture absorption operation in the schematic configuration diagram of the humidity control module. FIG. 4 is a schematic diagram illustrating a state in which the humidity control apparatus according to the first modification of the first embodiment and the first modification of the fourth embodiment is installed in a room, and FIG. 4A is a first operation state, FIG. 4 (B) shows the second operating state. FIG. 5 is a schematic diagram illustrating a state in which the humidity control apparatus according to the second modification of the first embodiment and the second modification of the fourth embodiment is installed in a room, and FIG. 5A is a first operation state, FIG. 5 (B) shows the second operating state. FIG. 6 is a schematic diagram illustrating a state in which a humidity control apparatus according to Modification 3 of Embodiment 1 and Modification 3 of Embodiment 4 is installed. 7 is a diagram illustrating a first operation operation of the humidity control apparatus of FIG. 6, where FIG. 7A is a plan structural diagram, FIG. 7B is a left side structural diagram, and FIG. 7C is a right side diagram. FIG. FIG. 8 is a diagram illustrating a second operation operation of the humidity control apparatus of FIG. 6, FIG. 8A is a plan structure diagram, FIG. 8B is a left side structure diagram, and FIG. FIG. FIG. 9 is a schematic diagram illustrating a state in which the humidity control apparatus according to Modification 4 of Embodiment 1 and Modification 4 of Embodiment 4 are installed indoors. FIG. 10 is a schematic diagram illustrating a state in which the humidity control apparatus according to the second and fourth embodiments is installed in a room. FIG. 10 (A) illustrates an operation state of the moisture release operation, and FIG. The operation state of the moisture absorption operation is shown. FIG. 11 is a schematic diagram illustrating a state in which the humidity control apparatus according to the first modification of the second embodiment and the first modification of the fourth embodiment is installed indoors, and FIG. 11A illustrates a first operation state, FIG. 11 (B) shows the second operating state. FIG. 12 is a schematic diagram illustrating a state in which the humidity control apparatus according to the second modification of the second embodiment and the second modification of the fourth embodiment is installed in a room. FIG. 12A illustrates a first operation state, FIG. 12 (B) shows the second operating state. FIG. 13 is a schematic diagram illustrating a state in which a humidity control apparatus according to Modification 3 of Embodiment 2 and Modification 3 of Embodiment 4 is installed. FIG. 14 is a diagram illustrating a first operation operation of the humidity control apparatus of FIG. 13, FIG. 14 (A) is a plan structure diagram, FIG. 14 (B) is a left side structure diagram, and FIG. 14 (C) is a right side diagram. FIG. FIG. 15 is a diagram illustrating a second operation operation of the humidity control apparatus of FIG. 13, in which FIG. 15 (A) is a plan structure diagram, FIG. 15 (B) is a left side structure diagram, and FIG. FIG. FIG. 16 is a schematic diagram illustrating a state in which the humidity control apparatus according to the fourth modification of the second embodiment and the fourth modification of the fourth embodiment is installed indoors. FIG. 17 is a schematic view showing a state in which the humidity control apparatus according to the third embodiment and the fifth modification of the fourth embodiment is installed in a room. FIG. 17A is a first operation state, and FIG. Indicates the second operating state. FIG. 18 is a schematic diagram illustrating a state in which the humidity control apparatus according to Modification 1 of Embodiment 3 and Modification 6 of Embodiment 4 is installed indoors. FIG. 19 is a schematic diagram illustrating a state in which the humidity control apparatus according to the second modification of the third embodiment and the fifth modification of the fourth embodiment is installed in a room, and FIG. 19A is a first operation state, FIG. 17 (B) shows the second operating state. FIG. 20 is a schematic diagram illustrating a state in which the humidity control apparatus according to Modification 3 of Embodiment 3 and Modification 6 of Embodiment 4 is installed indoors. FIG. 21 is a perspective view showing the structure of the humidity control module according to the fifth embodiment. 22A is a partially enlarged cross-sectional view of the humidity control module of FIG. 21, and FIG. 22B is a diagram showing a modification of FIG. 22A. FIG. 23 is a perspective view illustrating a structure of a humidity control module according to Modification 1 of Embodiment 5. FIG. 24 is a perspective view showing the structure of a humidity control module according to Modification 2 of Embodiment 5. FIG. 25 is a perspective view illustrating a structure of a humidity control module according to Modification 3 of Embodiment 5. FIG. 26 is a cross-sectional view illustrating the structure of the cooling and heating module according to the sixth embodiment. FIG. 27 is a cross-sectional view illustrating the structure of the cooling and heating module according to the seventh embodiment. FIG. 28 is a cross-sectional structure diagram of the humidity control module according to the eighth embodiment. FIG. 29 is a longitudinal sectional view of a humidity control module according to the eighth embodiment. FIG. 30 is a plan view of the humidity control module according to the eighth embodiment. FIG. 31 is a structural diagram of fins used in the humidity control module of the embodiment, FIG. 31 (A) is a front view, and FIG. 31 (B) is a side view.

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

Embodiment 1 of the Invention
A first embodiment of the present invention will be described.

-Overall configuration of the device-
FIG. 1 is a schematic diagram illustrating a state in which the humidity control apparatus (1) according to the first embodiment is installed in a room (air-conditioning target space) (3) of a building (2). FIG. The operation state is shown, and FIG. 1B shows the operation state of the moisture release operation. The humidity controller (1) of Embodiment 1 is configured as a dehumidifier.

  The humidity control apparatus (1) includes a casing (10), a humidity control module (20) housed in the casing (10), a fan (30) for flowing air to the humidity control module (20), and a humidity control And a voltage controller (35) for applying an electric field from a power source to the module (20). The humidity control module (20) and the voltage controller (35) constitute a humidity control unit (5). Moreover, the indoor unit (U) is comprised by the casing (10) and the functional component provided in the inside.

  An air passage (P) is formed in the casing (10) for supplying the air introduced into the casing (10) through the humidity control module (20) and supplying it to the room (3). In this embodiment, the moisture absorption operation can be performed by introducing the air subjected to the moisture absorption treatment by the humidity control module (20) into the room (3) through the air passage (P).

-Humidity control module-
As shown in FIG. 2, the humidity control module (20) includes an electrocaloric cooling material (21) and an electric field applied to the electrocaloric cooling material (21) from a power source (25). A pair of electrodes (22) provided on the surface of the caloric cooling material (21). An adsorption layer (23) capable of adsorbing and desorbing moisture in the air is provided on the surface of the humidity control module (20).

  The electrocaloric cooling material (21) is a material that generates an electrocaloric effect, and dissipates heat when an electric field is applied, and absorbs heat from the outside when the application of the electric field is canceled. In other words, if the electric field is removed in a state where the electric field is applied from the outside with a small entropy, the heat is absorbed to increase the entropy, and if an electric field is applied in a state where the entropy is large, the heat is released to reduce the entropy. For example, when an electric field is removed by heat insulation with a small entropy, the material cools by taking energy from molecular motion.

  Therefore, when a voltage (electric field) is applied to the electrocaloric cooling material (21) as shown in FIG. 3A, the electrocaloric cooling material (21) generates heat, and the electrode (22) and the adsorption layer (23) are heated. Is done. When the adsorption layer (23) is heated, the moisture adsorbed on the adsorption layer (23) is released into the air (moisture release operation). Therefore, the moisture in the air after passing through the humidity control module (20) is greater than before passing. On the contrary, as shown in FIG. 3B, when the application of the electric field to the electrocaloric cooling material (21) is released (the electric field application is released after a certain period of time has elapsed after the electric field is applied, the electrocaloric cooling material is released). (21) absorbs heat, and the electrode (22) and the adsorption layer (23) are cooled. When the adsorption layer (23) is cooled, moisture in the air is adsorbed on the adsorption layer (23) (moisture absorption operation). Therefore, the moisture in the air after passing through the humidity control module (20) is less than before passing. In the humidity control apparatus (1), the moisture releasing operation and the moisture absorbing operation are alternately performed.

  Note that the capacity of the electrocaloric cooling material (21) decreases when the capacity peak is exceeded from the start of operation during moisture absorption or moisture release. Therefore, the moisture absorbing operation and the moisture releasing operation are switched alternately.

  Specific examples of the electrocaloric cooling material (21) include poly (vinylidene fluoride-trifluoroethylene). In particular, when the above material is expressed as P (VDF-TrFE), a composition having a VDF of 90 to 10 mol%, a TrFE of 10 to 90 mol%, and a total of 100 mol% can be used. Moreover, it is preferable that VDF is 80 to 20 mol%.

-Electric field application operation-
In FIG. 3, the voltage controller (35) adjusts the heat generation amount of the electrocaloric cooling material (21) by changing the magnitude of the electric field applied to the electrocaloric cooling material (21). It is configured to adjust the wet capacity.

  In addition, the voltage controller (35) generates a calorific value of the electrocaloric cooling material (21) by changing the proportion of the portion to which an electric field is applied in the entire electrocaloric cooling material (21) in FIG. The moisture absorption / release capacity may be adjusted.

  Further, the voltage controller (35) adjusts the heat generation amount of the electrocaloric cooling material (21) by changing a time interval for repeating the moisture absorption operation and the moisture release operation, and adjusts the moisture absorption / release capability. You may comprise.

-Driving action-
This humidity control device (1) performs only dehumidification operation.

  Specifically, in FIG. 1A, the application of the electric field to the humidity control module (20) that has been heated is canceled. Then, the humidity control module (20) absorbs heat from the air (outdoor air (OA)), and the electrode (22) and the adsorption layer (23) in FIGS. 2 and 3 are cooled. The adsorbing layer (23) has already released moisture because it has been heated. Therefore, as shown in FIG. 1A, when air flows from the outside toward the room (3), moisture is adsorbed from the air. And the air (supply air (SA)) by which moisture was adsorbed and dehumidified is supplied to the room (3). At this time, since the humidity control module (20) is cooled, heat generation of the adsorption layer (23) due to heat of adsorption can be suppressed. Therefore, the moisture absorption operation is performed without reducing the adsorption performance.

  During the moisture release operation in FIG. 1B, the rotation direction of the fan (30) is switched, and the indoor air (RA) is discharged to the outside. At this time, an electric field is applied to the electrocaloric cooling material (21) of the humidity control module (20). Then, the humidity control module (20) dissipates heat, and the electrode (22) and the adsorption layer (23) are heated. When the adsorption layer (23) is heated, moisture contained in the adsorption layer (23) is released from the room (3) to the air flowing outside the room. Therefore, at the time of this moisture releasing operation, the adsorption layer (23) of the humidity control module (20) is regenerated, and moisture is discharged to the outside together with air (exhaust air (EA)).

  In the present embodiment, the dehumidifying operation is intermittently performed by repeatedly performing the moisture absorbing operation of FIG. 1A and the moisture releasing operation of FIG.

-Effect of Embodiment 1-
According to this embodiment, the humidity control module (20) does not employ an elastic body such as rubber coated with an adsorbent. Here, when an elastic body such as rubber coated with an adsorbent is used in the humidity control module, a mechanism for expanding and contracting the elastic body is required, and the structure of the humidity control apparatus (1) becomes complicated. In addition, the apparatus (1) is increased in size, whereas according to the present embodiment, since the elastic body is not used in the humidity control module (20), the humidity control apparatus (20) is increased in size and structure. Can be prevented from becoming complicated. In addition, since the electrocaloric cooling material constituting the humidity control module (20) is not an elastic body that greatly expands and contracts, it is possible to prevent the adsorbent from peeling off from the humidity control module (20). it can.

  Moreover, in this embodiment, since the calorific value of the electrocaloric cooling material (21) can be adjusted and the moisture absorption / release capacity can be adjusted, it is possible to operate according to the humidity control load.

-Modification of Embodiment 1-
(Modification 1)
Modification 1 shown in FIG. 4 is configured to install two indoor units (U1, U2) in a room (3) to be air-conditioned. In the figure, the first indoor unit (U1) is installed on one of the opposing wall surfaces (the right wall surface in the figure), and the second indoor unit (U2) is installed on the other wall surface (the left wall surface in the figure). ing. Since the configuration of each indoor unit (U1, U2) is the same as that of the indoor unit (U) of the humidity controller (1) in FIG. 1, the description of the configuration of each indoor unit (U1, U2) is omitted. Note that air passages (P1, P2) are formed in the indoor units (U1, U2), respectively.

  FIG. 4A shows a state in which a moisture absorption operation is performed in the first indoor unit (U1) and a moisture release operation is performed in the second indoor unit (U2). In the first indoor unit (U1), the application of the electric field to the electrocaloric cooling material (21) of the humidity control module (20) is released. Therefore, when the humidity control module (20) of the first indoor unit (U1) absorbs heat and outdoor air (OA) flows from the outdoor to the indoor (3), moisture in the air is adsorbed. Then, the air that has been moisture-adsorbed and dehumidified is supplied to the room (3) as supply air (SA).

  On the other hand, in the second indoor unit (U2), the fan (30) rotates in the direction in which the indoor air (RA) is discharged to the outside, and at the same time, an electric field is applied to the electrocaloric cooling material (21) of the humidity control module (20). Applied. Therefore, the moisture contained in the adsorption layer (23) is given to the air and released as exhausted air (EA) to the outside of the room, and the adsorption layer (23) of the humidity control module (20) is regenerated.

  FIG. 4B shows a state where the moisture absorption operation is performed in the second indoor unit (U2) and the moisture release operation is performed in the first indoor unit (U1). In the second indoor unit (U2), the application of the electric field to the electrocaloric cooling material (21) of the humidity control module (20) is released. Therefore, when the humidity control module (20) of the second indoor unit (U2) absorbs heat and outdoor air (OA) flows from the outdoor to the indoor (3), moisture in the air is adsorbed. Then, the air that has been moisture-adsorbed and dehumidified is supplied to the room (3) as supply air (SA).

  On the other hand, in the first indoor unit (U1), the fan (30) rotates in the direction in which room air (RA) is discharged to the outside, and at the same time, an electric field is applied to the electrocaloric cooling material (21) of the humidity control module (20). Applied. Therefore, the moisture contained in the adsorption layer (23) is given to the air and released as exhausted air (EA) to the outside of the room, and the adsorption layer (23) of the humidity control module (20) is regenerated.

  Thus, according to the first modification of the first embodiment, when one of the indoor units (U1, U2) dehumidifies the air and supplies the air to the room (3), the other room In the units (U2, U1), the dehumidifying operation can be continuously performed by alternately switching the operation of FIG. 4 (A) and the operation of FIG. 4 (B) for regenerating the adsorption layer (23).

(Modification 2)
The modification 2 shown in FIG. 5 is common to the apparatus (1) of FIG. 4 in that two indoor units (U1, U2) are installed in the air-conditioned room (3). The difference from Modification 1 of FIG. 4 is that both the first indoor unit (U1) and the second indoor unit (U2) are installed on the right wall surface of the drawing. The configuration of each indoor unit (U1, U2) is the same as that of the humidity control apparatus (1) shown in FIGS.

  FIG. 5A shows a state in which a moisture absorption operation is performed in the first indoor unit (U1) and a moisture release operation is performed in the second indoor unit (U2). In the first indoor unit (U1), the application of the electric field to the electrocaloric cooling material (21) of the humidity control module (20) is released. Therefore, when the humidity control module (20) of the first indoor unit (U1) absorbs heat and outdoor air (OA) flows from the outdoor to the indoor (3), moisture in the air is adsorbed. Then, the air that has been moisture-adsorbed and dehumidified is supplied to the room (3) as supply air (SA).

  On the other hand, in the second indoor unit (U2), the fan (30) rotates in the direction in which the indoor air (RA) is discharged to the outside, and at the same time, an electric field is applied to the electrocaloric cooling material (21) of the humidity control module (20). Applied. Therefore, the moisture contained in the adsorption layer (23) is given to the air and released as exhausted air (EA) to the outside of the room, and the adsorption layer (23) of the humidity control module (20) is regenerated.

  FIG. 5B shows a state in which the moisture absorption operation is performed in the second indoor unit (U2) and the moisture release operation is performed in the first indoor unit (U1). In the second indoor unit (U2), the application of the electric field to the electrocaloric cooling material (21) of the humidity control module (20) is released. Therefore, when the humidity control module (20) of the second indoor unit (U2) absorbs heat and outdoor air (OA) flows from the outdoor to the indoor (3), moisture in the air is adsorbed. Then, the air that has been moisture-adsorbed and dehumidified is supplied to the room (3) as supply air (SA).

  On the other hand, in the first indoor unit (U1), the fan (30) rotates in the direction in which room air (RA) is discharged to the outside, and at the same time, an electric field is applied to the electrocaloric cooling material (21) of the humidity control module (20). Applied. Therefore, the moisture contained in the adsorption layer (23) is given to the air and released as exhausted air (EA) to the outside of the room, and the adsorption layer (23) of the humidity control module (20) is regenerated.

  Thus, according to the second modification of the first embodiment, when one of the indoor units (U1, U2) dehumidifies the air and supplies the air to the room (3), the other room In the units (U2, U1), the dehumidifying operation can be continuously performed by alternately switching the operation of FIG. 5 (A) and the operation of FIG. 5 (B) for regenerating the adsorption layer (23).

(Modification 3)
In Modification 3 shown in FIG. 6, two humidity control modules (20) are provided in the casing (10) of the humidity control apparatus (1), and one humidity control module (20) (first humidity control module (20a)) is provided. ) Is supplied to the room (3) and the air that has passed through the other humidity control module (20) (second humidity control module (20b)) is discharged to the outside of the room. It is configured to switch between the second operation for supplying the air that has passed through the humidity control module (20b) to the room (3) and releasing the air that has passed through the first humidity control module (20a) to the outside of the room. is there.

  Specifically, the humidity control apparatus (1) is configured as shown in FIGS. This humidity control device (1) has an integrated configuration in which two humidity control modules (20a, 20b) and two fans (30a, 30b) are housed in one casing (10), and is installed behind the ceiling. ing. FIG. 7 shows a first operation operation in which the first humidity control module (20a) is on the moisture absorption side and the second humidity control module (20b) is on the moisture release side, and FIG. 8 is the second humidity control module (20b). ) Is the moisture absorption side, and the second operation operation is shown in which the first humidity control module (20a) is the moisture release side. 7 and 8, (A) is a plan view (showing the internal structure when the apparatus is viewed from above), (B) is a left side view, and (C) is a right side. FIG.

  The casing (10) of the humidity control device (1) is formed in a square box shape. A first suction port (11) for taking outdoor air (OA) into the casing (10) and a second air port for taking indoor air (RA) into the casing (10) are formed on one side wall surface of the casing (10). A suction port (12) is provided. Moreover, the 1st blower outlet (13) which supplies supply air (SA) to room | chamber (3), and exhaust air are in the side wall surface on either side of the side wall surface in which each said inlet (11,12) is provided. A second outlet (14) for discharging (EA) to the outside is provided. These first suction port (11), second suction port (12), first blower outlet (13) and second blower outlet (14) are respectively provided with ducts (4a, 4b, 4c, 4d) are connected.

  The casing (10) is provided with a humidity control chamber (C1, C2) in which the humidity control module (20) is disposed and a fan chamber (C3, C4) in which the fans (30a, 30b) are disposed. Yes. The humidity control chambers (C1, C2) are composed of a first humidity control chamber (C1) and a second humidity control chamber (C2) located adjacent to each other in the casing (10) in FIGS. ing. The fan chambers (C3, C4) are composed of a first fan chamber (C3) and a second fan chamber (C4) that are also adjacent to the left and right of the casing (10). An air supply fan (30a) is disposed in the first fan chamber (C3), and an exhaust fan (30b) is disposed in the second fan chamber (C4).

  An inlet-side ventilation chamber (C5, C6) is formed between each of the suction ports (11, 12) and the humidity control chamber (C1, C2). The inlet-side ventilation chambers (C5, C6) are composed of a first inlet-side ventilation chamber (C5) and a second inlet-side ventilation chamber (C6) arranged in two upper and lower stages of the casing (10). The first inlet side ventilation chamber (C5) is provided with a first suction port (11), and the second inlet side ventilation chamber (C6) is provided with a second suction port (12). There are four dampers (D1, D2, D3, D4) that can be opened and closed between each inlet-side ventilation chamber (C5, C6) and each humidity control chamber (C1, C2). Yes.

  Outlet ventilation chambers (C7, C8) are formed between the humidity control chambers (C1, C2) and the fan chambers (C3, C4). The outlet side ventilating chambers (C7, C8) are composed of a first outlet side ventilating chamber (C7) and a second outlet side ventilating chamber (C8) arranged in two upper and lower stages of the casing (10). A total of four dampers (D5, D6, D7, D8) that can be opened and closed are provided between each humidity control chamber (C1, C2) and each outlet-side ventilation chamber (C7, C8). Yes.

  The outlet side ventilation chambers (C7, C8) communicate with the fan chambers (C3, C4). The first air outlet (13) is provided on the first fan chamber (C3) side of the casing (10), and the second air outlet (14) is provided on the second fan chamber (C4) side of the casing (10). It has been.

  In the above configuration, during the first driving operation, the first damper (D1), the fourth damper (D4), the fifth damper (D5), and the eighth damper (D8) are opened, and the second damper (D2 ), The third damper (D3), the sixth damper (D6) and the seventh damper (D7) are closed. In the second driving operation, the second damper (D2), the third damper (D3), the sixth damper (D6), and the seventh damper (D7) are opened, and the first damper (D1), the fourth damper are opened. The damper (D4), the fifth damper (D5) and the eighth damper (D8) are closed.

  By controlling the open / closed state of the dampers (D1 to D8) in this way, in the first driving operation, as shown in FIG. 7, the damper (D1 to D8) was introduced into the casing (10) from the first suction port (11). Outdoor air (OA) is supplied to the room (3) from the first outlet (13) through the first damper (D1), the first humidity control module (20a) and the fifth damper (D5), The room air (RA) introduced into the casing (10) from the second inlet (12) passes through the fourth damper (D4), the second humidity control module (20b), and the eighth damper (D8). It is discharged outside through the two outlets (14). In the second driving operation, as shown in FIG. 8, outdoor air (OA) introduced into the casing (10) from the first suction port (11) is converted into the third damper (D3), the second The air is supplied from the first air outlet (13) to the room (3) through the humidity control module (20b) and the seventh damper (D7), and is introduced into the casing (10) from the second air outlet (14). The indoor air (RA) that has passed through the second damper (D2), the first humidity control module (20a), and the sixth damper (D6) is discharged from the second outlet (14) to the outside.

  And in the modification 3 of this Embodiment 1, the 1st driving | running operation | movement of FIG. 7 and the 2nd driving | running operation | movement of FIG. 8 are repeated alternately by switching the open / close state of a damper.

  Since this humidity control device (1) is configured as a dedicated dehumidifier, the humidity control module (20) through which the air supplied to the room (3) passes is the first humidity control module (20a) and the second humidity control module. It is the humidity control module (20) that performs the moisture absorption operation regardless of which one of the humidity modules (20b) is switched to. Therefore, dehumidified air is continuously supplied to the room (3). In addition, the humidity control module (20) through which the air exhausted to the outside passes can perform moisture release operation regardless of whether it is switched to the second humidity control module (20b) or the first humidity control module (20a). The humidity control module (20). Therefore, the humidity control module (20) through which the air released to the outside passes is always on the regeneration side.

  Thus, according to the third modification of the first embodiment, when one of the humidity control modules (20a, 20b) dehumidifies the air and supplies the air to the room (3), the other In the humidity control module (20b, 20a), the dehumidifying operation can be continuously performed by alternately switching the operation of FIG. 7 and the operation of FIG. 8 to regenerate the adsorption layer (23).

(Modification 4)
The modification 4 shown in FIG. 9 is an example regarding the humidity control apparatus (1) using the rotor type humidity control module (20). This humidity control apparatus (1) is also configured as a dedicated dehumidifier as in the examples of FIGS.

  An air supply side passage (P1) and an exhaust side passage (P2) are provided in the casing (10) of the humidity control apparatus (1). An air supply fan (30a) is provided in the air supply side passage (P1), and an exhaust fan (30b) is provided in the exhaust side passage (P2). The humidity control module (20) is formed in a disc shape, and is disposed across the air supply side passage (P1) and the exhaust side passage (P2) in the casing (10). The humidity control module (20) rotates around the rotation axis, so that the part located in the air supply side passage (P1) moves into the exhaust side passage (P2), and the exhaust side passage The portion located in (P2) can be moved into the supply side passage (P1).

  In the humidity control apparatus (1) of the fourth modification, the moisture absorption operation is performed in the supply side passage (P1), and the moisture release operation is performed in the exhaust side passage (P2). Specifically, the electric caloric cooling material (21) absorbs heat without the electric field being applied to the part where the humidity control module (20) is located in the supply side passage (P1), and the adsorbent is cooled, and the air Of water is adsorbed by the adsorbent. In addition, an electric field is applied to the portion where the humidity control module (20) is located in the exhaust side passage (P2), the electrocaloric cooling material (21) dissipates heat, and the adsorbent is heated and contained in the adsorbent. Moisture is released into the air and the adsorbent is regenerated.

  In this embodiment, the moisture absorbing operation and the moisture releasing operation are performed while rotating the humidity control module (20) continuously or intermittently. Therefore, while the humidity control module (20) can be regenerated in the exhaust side passage (P2) and simultaneously in the air supply side passage (P1), it can absorb moisture in the indoor (3) Can be supplied to.

<< Embodiment 2 of the Invention >>
A second embodiment of the present invention will be described.

  Embodiment 2 shown in FIG. 10 is an example in which the humidity control apparatus (1) of Embodiment 1 shown in FIG.

  Similar to the humidity control device (1) of FIG. 1, the humidity control device (1) includes a casing (10), a humidity control module (20) housed in the casing (10), and a humidity control module (20 ) And a voltage controller (35) for applying an electric field to the humidity control module (20), and the indoor unit (U) by the casing (10) and the functional parts provided in the casing (10). ) Is configured. Further, an air passage (P) is formed in the casing (10) for supplying the air introduced into the casing (10) through the humidity control module (20) and supplying the air into the room (3). .

  The humidity control apparatus (1) of the second embodiment can perform a humidification operation by introducing the air subjected to the moisture release treatment by the humidity control module (20) into the room (3) through the air passage (P). This is different from the humidity control apparatus (1) of FIG.

  In this humidity control apparatus (1), an electric field is applied to the electrocaloric cooling material (21) of the humidity control module (20) that has been cooled in FIG. 10 (A). Then, the humidity control module (20) dissipates heat, and the electrode (22) and the adsorption layer (23) are heated. When the adsorption layer (23) is heated, the moisture contained in the adsorption layer (23) is released from the outdoor to the outdoor air (OA) flowing into the indoor (3). Therefore, the humidified air is supplied to the room (3) as supply air (SA).

  On the other hand, in FIG. 10B, the rotation direction of the fan (30) is switched, and the indoor air (RA) is discharged to the outside. At this time, the application of the electric field to the electrocaloric cooling material (21) of the humidity control module (20) is released. Then, the humidity control module (20) absorbs heat, and the electrode (22) and the adsorption layer (23) are cooled. When the adsorption layer (23) is cooled, moisture in the air is adsorbed on the adsorption layer (23). Then, the air that has been dehumidified by adsorbing moisture is discharged outside the room as exhaust air (EA). At this time, since the electrocaloric cooling material (21) absorbs heat, the adsorption layer (23) can be prevented from generating heat due to the heat of adsorption. Therefore, the moisture absorption operation is performed without reducing the adsorption performance.

-Modification of Embodiment 2-
(Modification 1)
The modification 1 of Embodiment 2 shown in FIG. 11 is an example which comprised the humidity control apparatus (1) of FIG. 4 as a humidification exclusive machine. A configuration in which the first indoor unit (U1) is installed on one of the opposing wall surfaces (the right wall surface in the figure) and the second indoor unit (U2) is installed on the other wall surface (the left wall surface in the figure) Is the same as the humidity control apparatus (1) of FIG. The configuration of each indoor unit (U1, U2) is the same as that of the second embodiment in FIG.

  FIG. 11A shows a state where the moisture releasing operation is performed in the first indoor unit (U1) and the moisture absorbing operation is performed in the second indoor unit (U2). In the first indoor unit (U1), an electric field is applied to the electrocaloric cooling material (21) of the humidity control module (20). Therefore, the humidity control module (20) of the first indoor unit (U1) dissipates heat, and moisture is given to the outdoor air (OA) flowing from the outdoor to the indoor (3). Then, air humidified with moisture is supplied to the room (3) as supply air (SA).

  On the other hand, in the second indoor unit (U2), the fan (30) rotates in the direction in which the indoor air (RA) is discharged outside, and at the same time, the electric field applied to the electrocaloric cooling material (21) of the humidity control module (20). Application is released. Therefore, moisture in the air is adsorbed by the adsorption layer (23), and the dehumidified air is discharged to the outside as exhaust air (EA).

  FIG. 11B shows a state where the moisture releasing operation is performed in the second indoor unit (U2) and the moisture absorbing operation is performed in the first indoor unit (U1). In the second indoor unit (U2), an electric field is applied to the electrocaloric cooling material (21) of the humidity control module (20). Therefore, the humidity control module (20) of the second indoor unit (U2) dissipates heat, and moisture is given to the outdoor air (OA) flowing from the outdoor to the indoor (3). Then, air humidified with moisture is supplied to the room (3) as supply air (SA).

  On the other hand, in the first indoor unit (U1), the fan (30) rotates in the direction in which room air (RA) is discharged to the outside, and at the same time, the electric field applied to the electrocaloric cooling material (21) of the humidity control module (20). Application is released. Therefore, moisture in the air is adsorbed by the adsorption layer (23), and the dehumidified air is discharged to the outside as exhaust air (EA).

  Thus, according to Modification 1 of Embodiment 2, when one of the indoor units (U1, U2) humidifies the air and supplies the air to the room (3), the other room In the units (U2, U1), the humidification operation can be continuously performed by alternately switching between the operation of FIG. 11A and the operation of FIG.

(Modification 2)
Modification 2 of Embodiment 2 shown in FIG. 12 is configured to install two indoor units (U1, U2) in a room (3) to be air-conditioned, and is a modification of Embodiment 1 shown in FIG. It is the example which comprised the humidity control apparatus (1) of Example 2 as a humidification exclusive machine. In this modification, both the first indoor unit (U1) and the second indoor unit (U2) are installed on the right wall surface in the figure.

  FIG. 12A shows a state where the moisture releasing operation is performed in the first indoor unit (U1) and the moisture absorbing operation is performed in the second indoor unit (U2). In the first indoor unit (U1), an electric field is applied to the electrocaloric cooling material (21) of the humidity control module (20). Therefore, the humidity control module (20) of the first indoor unit (U1) dissipates heat, and moisture is given to the outdoor air (OA) flowing from the outdoor to the indoor (3). Then, air humidified with moisture is supplied to the room (3) as supply air (SA).

  On the other hand, in the second indoor unit (U2), the fan (30) rotates in the direction in which the indoor air (RA) is discharged outside, and at the same time, the electric field applied to the electrocaloric cooling material (21) of the humidity control module (20). Application is released. Therefore, moisture in the air is adsorbed by the adsorption layer (23), and the dehumidified air is discharged to the outside as exhaust air (EA).

  FIG. 12B shows a state in which a moisture releasing operation is performed in the second indoor unit (U2) and a moisture absorbing operation is performed in the first indoor unit (U1). In the second indoor unit (U2), an electric field is applied to the electrocaloric cooling material (21) of the humidity control module (20). Therefore, the humidity control module (20) of the second indoor unit (U2) dissipates heat, and moisture is given to the outdoor air (OA) flowing from the outdoor to the indoor (3). Then, air humidified with moisture is supplied to the room (3) as supply air (SA).

  On the other hand, in the first indoor unit (U1), the fan (30) rotates in the direction in which room air (RA) is discharged to the outside, and at the same time, the electric field applied to the electrocaloric cooling material (21) of the humidity control module (20). Application is released. Therefore, moisture in the air is adsorbed by the adsorption layer (23), and the dehumidified air is discharged to the outside as exhaust air (EA).

  Thus, according to Modification 2 of Embodiment 2, when one of the indoor units (U1, U2) humidifies the air and supplies the air to the room (3), the other room In the units (U2, U1), the humidification operation can be continuously performed by alternately switching between the operation of FIG. 12A and the operation of FIG.

(Modification 3)
Modification 3 of Embodiment 2 shown in FIG. 13 is an example in which the humidity control apparatus (1) of Modification 3 of Embodiment 1 shown in FIGS. Specifically, this humidity control apparatus (1) is provided with two humidity control modules (20a, 20b) in the casing (10) as in FIGS. 6 to 8, and one humidity control module (20) The air that has passed through the first humidity control module (20a) is supplied to the room (3), and the air that has passed through the other humidity control module (20) (second humidity control module (20b)) is released to the outside of the room. The first driving operation and the second driving operation for supplying the air that has passed through the second humidity control module (20b) to the room (3) and releasing the air that has passed through the first humidity control module (20a) to the outside. And are configured to be switched.

  The humidity control apparatus (1) is specifically configured as shown in FIGS. This humidity control device (1) has an integrated configuration in which two humidity control modules (20a, 20b) and two fans (30a, 30b) are housed in one casing (10), and is installed behind the ceiling. ing. FIG. 14 shows a first operation operation in which the first humidity control module (20a) is set to the moisture release side and the second humidity control module (20b) is set to the moisture absorption side. FIG. 15 shows the second humidity control module (20b). ) Is the moisture release side, and the second operation operation is shown in which the first humidity control module (20a) is the moisture absorption side. 14 and 15, (A) is a plan view (showing the internal structure when the apparatus is viewed from above), (B) is a left side view, and (C) is a right side. FIG.

  The casing (10) of the humidity control device (1) is formed in a square box shape. A first suction port (11) for taking outdoor air (OA) into the casing (10) and a second air port for taking indoor air (RA) into the casing (10) are formed on one side wall surface of the casing (10). A suction port (12) is provided. Moreover, the 1st blower outlet (13) which supplies supply air (SA) to room | chamber (3), and exhaust air are in the side wall surface on either side of the side wall surface in which each said inlet (11,12) is provided. A second outlet (14) for discharging (EA) to the outside is provided. These first inlet (11), second inlet (12), first outlet (13) and second outlet (14) are respectively provided with ducts (4a, 4b, 4c, 4d) are connected.

  The casing (10) is provided with a humidity control chamber (C1, C2) in which the humidity control module (20) is disposed and a fan chamber (C3, C4) in which the fans (30a, 30b) are disposed. Yes. The humidity control chambers (C1, C2) are composed of a first humidity control chamber (C1) and a second humidity control chamber (C2) located adjacent to each other in the casing (10) in FIGS. ing. The fan chambers (C3, C4) are composed of a first fan chamber (C3) and a second fan chamber (C4) that are also adjacent to the left and right of the casing (10). An air supply fan (30a) is disposed in the first fan chamber (C3), and an exhaust fan (30b) is disposed in the second fan chamber (C4).

  An inlet-side ventilation chamber (C5, C6) is formed between each of the suction ports (11, 12) and the humidity control chamber (C1, C2). The inlet-side ventilation chambers (C5, C6) are composed of a first inlet-side ventilation chamber (C5) and a second inlet-side ventilation chamber (C6) arranged in two upper and lower stages of the casing (10). The first inlet side ventilation chamber (C5) is provided with a first suction port (11), and the second inlet side ventilation chamber (C6) is provided with a second suction port (12). There are four dampers (D1, D2, D3, D4) that can be opened and closed between each inlet-side ventilation chamber (C5, C6) and each humidity control chamber (C1, C2). Yes.

  Outlet ventilation chambers (C7, C8) are formed between the humidity control chambers (C1, C2) and the fan chambers (C3, C4). The outlet side ventilating chambers (C7, C8) are composed of a first outlet side ventilating chamber (C7) and a second outlet side ventilating chamber (C8) arranged in two upper and lower stages of the casing (10). A total of four dampers (D5, D6, D7, D8) that can be opened and closed are provided between each humidity control chamber (C1, C2) and each outlet-side ventilation chamber (C7, C8). Yes.

  The outlet side ventilation chambers (C7, C8) communicate with the fan chambers (C3, C4). The first air outlet (13) is provided on the first fan chamber (C3) side of the casing (10), and the second air outlet (14) is provided on the second fan chamber (C4) side of the casing (10). It has been.

  In the above configuration, during the first driving operation, the first damper (D1), the fourth damper (D4), the fifth damper (D5), and the eighth damper (D8) are opened, and the second damper (D2 ), The third damper (D3), the sixth damper (D6) and the seventh damper (D7) are closed. In the second driving operation, the second damper (D2), the third damper (D3), the sixth damper (D6), and the seventh damper (D7) are opened, and the first damper (D1), the fourth damper are opened. The damper (D4), the fifth damper (D5) and the eighth damper (D8) are closed.

  By controlling the open / close state of the dampers (D1 to D8) in this way, in the first driving operation, as shown in FIG. 14, the damper (D1 to D8) was introduced into the casing (10) from the first suction port (11). Outdoor air (OA) is supplied to the room (3) from the first outlet (13) through the first damper (D1), the first humidity control module (20a) and the fifth damper (D5), The room air (RA) introduced into the casing (10) from the second inlet (12) passes through the fourth damper (D4), the second humidity control module (20b), and the eighth damper (D8). It is discharged outside through the two outlets (14). In the second driving operation, as shown in FIG. 15, the outdoor air (OA) introduced into the casing (10) from the first suction port (11) is converted into the third damper (D 3), the second The air is supplied from the first air outlet (13) to the room (3) through the humidity control module (20b) and the seventh damper (D7), and is introduced into the casing (10) from the second air outlet (14). The indoor air (RA) that has passed through the second damper (D2), the first humidity control module (20a), and the sixth damper (D6) is discharged from the second outlet (14) to the outside.

  And in the modification 3 of this Embodiment 2, the 1st driving | running operation | movement of FIG. 14 and the 2nd driving | running operation | movement of FIG. 15 are repeated alternately by switching the open / close state of a damper.

  Since this humidity control device (1) is configured as a dedicated humidifier, the humidity control module (20) through which air supplied to the room (3) passes is the first humidity control module (20a) and the second humidity control module. It is the humidity control module (20) on which the moisture releasing operation is performed regardless of which one of the humidity modules (20b) is switched to. Therefore, humidified air is continuously supplied to the room (3). In addition, the humidity control module (20) through which the air exhausted to the outside passes is the one where the moisture absorption operation is performed regardless of whether the humidity control module (20b) or the first humidity control module (20a) is switched. Humidity control module (20). Therefore, the humidity control module (20) through which the air discharged to the outside passes is always on the adsorption side.

  Thus, according to the third modification of the second embodiment, when one of the humidity control modules (20a, 20b) humidifies the air and supplies the air to the room (3), the other conditioning In the humidity module (20b, 20a), the humidification operation can be continuously performed by alternately switching between the operation of FIG. 14 and the operation of FIG. 15 in which moisture in the air is adsorbed by the adsorption layer (23).

(Modification 4)
Modification 4 of Embodiment 2 shown in FIG. 16 relates to a humidity control device (1) using a rotor type humidity control module (20). This humidity control apparatus (1) is also configured as a humidification-only machine, similar to the second embodiment and the first to third modifications thereof.

  An air supply side passage (P1) and an exhaust side passage (P2) are provided in the casing (10) of the humidity control apparatus (1). An air supply fan (30a) is provided in the air supply side passage (P1), and an exhaust fan (30b) is provided in the exhaust side passage (P2). The humidity control module (20) is formed in a disc shape, and is disposed across the air supply side passage (P1) and the exhaust side passage (P2) in the casing (10). The humidity control module (20) rotates around the rotation axis, so that the part located in the air supply side passage (P1) moves into the exhaust side passage (P2), and the exhaust side passage The portion located in (P2) can be moved into the supply side passage (P1).

  In the humidity control apparatus (1) of the fourth modification, the moisture release operation is performed in the air supply side passage (P1), and the moisture absorption operation is performed in the exhaust side passage (P2). Specifically, an electric field is applied to the portion where the humidity control module (20) is located in the supply side passage (P1), the electrocaloric cooling material (21) dissipates heat, and the adsorbent is heated. Water that is regenerated and contained in the adsorbent is given to the air. Also, the electric caloric cooling material (21) absorbs heat and cools the adsorbent without applying an electric field to the part where the humidity control module (20) is located in the exhaust side passage (P2), and moisture in the air is adsorbed. Adsorbed to the agent.

  In this embodiment, the moisture releasing operation and the moisture absorbing operation are performed while rotating the humidity control module (20) continuously or intermittently. Therefore, the humidity control module (20) can be dehumidified in the air supply side passage (P1) while simultaneously performing the moisture absorption treatment in the exhaust side passage (P2). ).

<< Embodiment 3 of the Invention >>
Embodiment 3 of the present invention will be described.

  The third embodiment shown in FIG. 17 is an example in which the humidity control apparatus (1) according to the second modification of the first embodiment shown in FIG. is there. This humidity control device (1) also has two indoor units (U1, U2) as in the example of FIG. 5, and both the first indoor unit (U1) and the second indoor unit (U2) are on one wall surface in the figure. It is installed on the right wall.

  In the humidity control apparatus (1), in addition to the humidity control module (20), the first indoor unit (U1) and the second indoor unit (U2) have an adsorption layer (23) in the humidity control module (20). There is provided a cooling and heating module (24) configured to cool and heat the air without providing. That is, the cooling and heating module (24) includes an electrocaloric cooling material (21) and an electrocaloric cooling material (21) applied to the electrocaloric cooling material (21) from the power source (25) in FIGS. It is comprised only from a pair of electrode (22) provided in the cooling material (21). In the cooling and heating module (24), the air can be heated when an electric field is applied, and the air can be cooled when the application of the electric field is canceled.

  In the third embodiment, air passes through the humidity control module (20) and the cooling and heating module (24) in both the first indoor unit (U1) and the second indoor unit (U2). Therefore, in the humidity control apparatus (1), in addition to performing the moisture absorption process and the moisture release process, the air cooling process and the heating process can be performed.

  The humidity control module (20) and the cooling / heating module (24) are located on the upstream side of the cooling / heating module (24) when the humidity control module (20) performs a moisture absorption operation. ) Is disposed so that the humidity control module (20) is positioned downstream of the cooling and heating module (24).

  FIG. 17A shows a state in which the cooling and moisture absorption operation is performed in the first indoor unit (U1) and the heating and moisture releasing operation is performed in the second indoor unit (U2). In the first indoor unit (U1), the application of the electric field to the electrocaloric cooling material (21) of the humidity control module (20) is released. Therefore, the humidity control module (20) of the first indoor unit (U1) absorbs heat, and moisture of outdoor air (OA) flowing from the outdoor to the indoor (3) is adsorbed. In the first indoor unit (U1), the application of the electric field to the cooling / heating module (24) is also released. Therefore, the air flowing from the outdoor to the indoor (3) is cooled. The dehumidified and cooled air is supplied to the room (3) as supply air (SA).

  On the other hand, in the second indoor unit (U2), the fan (30) rotates in the direction in which the indoor air (RA) is discharged outside, and at the same time, an electric field is applied to the electrocaloric cooling material (21) of the cooling and heating module (24). The electric field is also applied to the electrocaloric cooling material (21) of the humidity control module (20). Therefore, the air traveling from the room (3) to the outside is heated by the cooling and heating module (24) and then passes through the humidity control module (20). At that time, the humidity control module (20) also generates heat. Moisture contained in the adsorption layer (23) of the moisture module (20) is given to the air, and the air is discharged out of the room as exhaust air (EA). Thereby, the adsorption layer (23) of the humidity control module (20) is regenerated.

  FIG. 17B shows a state in which the cooling and moisture absorption operation is performed in the second indoor unit (U2) and the heating and moisture releasing operation is performed in the first indoor unit (U1). In the second indoor unit (U2), the application of the electric field to the electrocaloric cooling material (21) of the humidity control module (20) is released. Therefore, the humidity control module (20) of the second indoor unit (U2) absorbs heat, and moisture of outdoor air (OA) flowing from the outdoor to the indoor (3) is adsorbed. In the second indoor unit (U2), the application of the electric field to the cooling / heating module (24) is also released. Therefore, the air flowing from the outdoor to the indoor (3) is cooled. The dehumidified and cooled air is supplied to the room (3) as supply air (SA).

  On the other hand, in the first indoor unit (U1), the fan (30) rotates in the direction in which room air (RA) is discharged to the outside, and at the same time, an electric field is applied to the electrocaloric cooling material (21) of the cooling and heating module (24). The electric field is also applied to the electrocaloric cooling material (21) of the humidity control module (20). Therefore, the air traveling from the room (3) to the outside is heated by the cooling and heating module (24) and then passes through the humidity control module (20). At that time, the humidity control module (20) also generates heat. Moisture contained in the adsorption layer (23) of the moisture module (20) is given to the air, and the air is discharged out of the room as exhaust air (EA). Thereby, the adsorption layer (23) of the humidity control module (20) is regenerated.

  Thus, according to Embodiment 3, when one of the indoor units (U1, U2) dehumidifies and cools the air and supplies the air to the room (3), the other indoor unit In (U2, U1), the dehumidifying and cooling operation is continuously performed by alternately switching between the operation in FIG. 17A and the operation in FIG. 17B in which the air is heated and the adsorption layer (23) is regenerated. Can do.

  In this embodiment, the humidity control module (20) and the cooling and heating module (24) are arranged in series with respect to the air flow so that the outdoor air subjected to the latent heat treatment is further subjected to the sensible heat treatment and supplied to the room. However, the humidity control module (20) and the cooling and heating module (24) are arranged in parallel so that the outdoor air subjected to the latent heat treatment and the outdoor air subjected to the sensible heat treatment are mixed and supplied to the room. Good. This configuration may be the same in the following modifications.

-Modification of Embodiment 3-
(Modification 1)
Modification 1 of Embodiment 3 shown in FIG. 18 relates to a humidity control device (1) using a rotor type humidity control module (20). The humidity control device (1) includes a rotor type cooling and heating module (24) in addition to the rotor type humidity control module (20), and is configured to perform dehumidification cooling.

  An air supply side passage (P1) and an exhaust side passage (P2) are provided in the casing (10) of the humidity control apparatus (1). An air supply fan (30a) is provided in the air supply side passage (P1), and an exhaust fan (30b) is provided in the exhaust side passage (P2). The humidity control module (20) is formed in a disc shape, and is disposed across the air supply side passage (P1) and the exhaust side passage (P2) in the casing (10). The humidity control module (20) rotates around the rotation axis, so that the part located in the air supply side passage (P1) moves into the exhaust side passage (P2), and the exhaust side passage The portion located in (P2) can be moved into the supply side passage (P1).

  Further, the cooling and heating module (24) is also formed in a disk shape, and is disposed across the supply side passage (P1) and the exhaust side passage (P2) in the casing (10). This cooling and heating module (24) rotates about the rotation axis, so that the part located in the supply side passage (P1) moves into the exhaust side passage (P2), and the exhaust side passage The portion located in (P2) can be moved into the supply side passage (P1).

  In the humidity control apparatus (1) of the first modification of the third embodiment, the cooling and moisture absorption operation is performed in the supply side passage (P1), and the heating and dehumidifying operation is performed in the exhaust side passage (P2). Specifically, the electric caloric cooling material (21) absorbs heat and the adsorbent is cooled without applying an electric field to the portion where the humidity control module (20) is located in the supply side passage (P1), and the outdoor air Water in (OA) is adsorbed by the adsorbent. In addition, an electric field is not applied to a portion where the cooling and heating module (24) is positioned in the supply side passage (P1), and the electrocaloric cooling material (21) absorbs heat, thereby cooling the air. The dehumidified and cooled air is supplied to the room (3) as supply air (SA).

  On the other hand, an electric field is applied to the part where the cooling and heating module (24) is located in the exhaust side passage (P2), the electrocaloric cooling material (21) dissipates heat, and the indoor air (RA) that goes from the room (3) to the outside Is heated. In addition, an electric field is applied to the portion where the humidity control module (20) is located in the exhaust side passage (P2), the electrocaloric cooling material (21) dissipates heat, and the adsorbent is heated and contained in the adsorbent. Moisture is released into the room air (RA) to regenerate the adsorbent. Then, the moisture-supplied air is discharged out of the room as exhaust air (EA).

  In this modified example, the cooling moisture absorption operation and the heating moisture releasing operation are performed while rotating the humidity control module (20) and the cooling heating module (24) continuously or intermittently. Therefore, since the humidity control module (20) can be regenerated in the exhaust side passage (P2) and at the same time moisture absorption cooling can be performed in the air supply side passage (P1). (3) can be supplied.

(Modification 2)
The second modification of the third embodiment shown in FIG. 19 is an example configured as a humidifying heater while the humidity control apparatus (1) according to the third embodiment shown in FIG. 17 is a dehumidifying cooler. Also in this modification, both the first indoor unit (U1) and the second indoor unit (U2) are installed on the right wall surface in the figure.

  In the humidity control apparatus (1), in addition to the humidity control module (20), the first indoor unit (U1) and the second indoor unit (U2) have an adsorption layer (23 Is provided with a cooling and heating module (24) configured to cool and heat the air without being provided. That is, the cooling and heating module (24) includes an electrocaloric cooling material (21) and an electrocaloric cooling material (21) applied to the electrocaloric cooling material (21) from the power source (25) in FIGS. It is comprised only from a pair of electrode (22) provided in the cooling material (21). In the cooling and heating module (24), the air can be heated when an electric field is applied, and the air can be cooled when the application of the electric field is canceled.

  The first indoor unit (U1) and the second indoor unit (U2) are configured in the same manner as in the third embodiment of FIG.

  FIG. 19A shows a state where the heat and moisture releasing operation is performed in the first indoor unit (U1) and the cooling and moisture absorbing operation is performed in the second indoor unit (U2). In the first indoor unit (U1), an electric field is applied to the electrocaloric cooling material (21) of the humidity control module (20). Therefore, the humidity control module (20) of the first indoor unit (U1) dissipates heat, and moisture is given to the outdoor air (OA) flowing from the outdoor to the indoor (3). In the first indoor unit (U1), an electric field is also applied to the cooling and heating module (24). Accordingly, outdoor air (OA) flowing from the outdoor to the indoor (3) is heated. Then, humidified and heated air is supplied to the room (3) as supply air (SA).

  On the other hand, in the second indoor unit (U2), the fan (30) rotates in the direction in which the indoor air (RA) is discharged outside the room, and at the same time, the electric field applied to the electrocaloric cooling material (21) of the cooling and heating module (24). The application is released, and the application of an electric field to the electrocaloric cooling material (21) of the humidity control module (20) is also released. Therefore, indoor air (RA) heading from the room (3) to the outside is cooled by the cooling and heating module (24) and then passes through the humidity control module (20). At that time, since the humidity control module (20) also absorbs heat, moisture in the room air (RA) is adsorbed to the adsorption layer (23) of the humidity control module (20), and the air is discharged into the exhaust air (EA ) Is released to the outdoors.

  FIG. 19B shows a state where the heat and moisture release operation is performed in the second indoor unit (U2) and the cooling and moisture absorption operation is performed in the first indoor unit (U1). In the second indoor unit (U2), an electric field is applied to the electrocaloric cooling material (21) of the humidity control module (20). Therefore, the humidity control module (20) of the second indoor unit (U2) generates heat, and moisture is given to the outdoor air (OA) flowing from the outdoor to the indoor (3). In the second indoor unit (U2), an electric field is also applied to the cooling and heating module (24). Accordingly, outdoor air (OA) flowing from the outdoor to the indoor (3) is heated. Then, humidified and heated air is supplied to the room (3) as supply air (SA).

  On the other hand, in the first indoor unit (U1), the fan (30) rotates in the direction in which the indoor air (RA) is discharged outside, and at the same time, the electric field applied to the electrocaloric cooling material (21) of the cooling and heating module (24). The application is released, and the application of an electric field to the electrocaloric cooling material (21) of the humidity control module (20) is also released. Therefore, indoor air (RA) heading from the room (3) to the outside is cooled by the cooling and heating module (24) and then passes through the humidity control module (20). At that time, since the humidity control module (20) also absorbs heat, moisture in the room air (RA) is adsorbed to the adsorption layer (23) of the humidity control module (20), and the air is discharged into the exhaust air (EA ) Is released to the outdoors.

  According to Modification 2 of Embodiment 3, when one of the indoor units (U1, U2) performs humidification and heating of the air and supplies the air to the room (3), the other indoor unit In (U2, U1), the humidification heating operation is continuously performed by alternately switching the operation of FIG. 19A and the operation of FIG. 19B which cools the air and absorbs moisture in the adsorption layer (23). be able to.

(Modification 3)
Modification 3 of Embodiment 3 shown in FIG. 20 is an example configured as a humidifying heater while the humidity control apparatus (1) according to Modification 1 shown in FIG. 18 is a dehumidifying cooler. Also in this modification, a rotor type cooling and heating module (24) is used in addition to the rotor type humidity control module (20).

  The casing (10), humidity control module (20), and cooling / heating module (24) of the humidity control apparatus (1) are configured in the same manner as in FIG.

  Specifically, an air supply side passage (P1) and an exhaust side passage (P2) are provided in the casing (10) of the humidity control apparatus (1). An air supply fan (30a) is provided in the air supply side passage (P1), and an exhaust fan (30b) is provided in the exhaust side passage (P2). The humidity control module (20) is formed in a disc shape, and is disposed across the air supply side passage (P1) and the exhaust side passage (P2) in the casing (10). The humidity control module (20) rotates around the rotation axis, so that the part located in the air supply side passage (P1) moves into the exhaust side passage (P2), and the exhaust side passage The portion located in (P2) can be moved into the supply side passage (P1). Further, the cooling and heating module (24) is also formed in a disk shape, and is disposed across the supply side passage (P1) and the exhaust side passage (P2) in the casing (10). This cooling and heating module (24) rotates about the rotation axis, so that the part located in the supply side passage (P1) moves into the exhaust side passage (P2), and the exhaust side passage The portion located in (P2) can be moved into the supply side passage (P1).

  In the humidity control apparatus (1) of the third modification, the heat and moisture releasing operation is performed in the supply side passage (P1), and the cooling and moisture absorption operation is performed in the exhaust side passage (P2). Specifically, in the portion where the humidity control module (20) is located in the air supply side passage (P1), the electrocaloric cooling material (21) generates heat when the electric field is applied, and the adsorbent is heated, Moisture adsorbed by the adsorbent is given to the air. Further, an electric field is applied to a portion where the cooling and heating module (24) is located in the supply side passage (P1), whereby the electrocaloric cooling material (21) generates heat and the air is heated.

  On the other hand, in the part where the cooling and heating module (24) is located in the exhaust side passage (P2), the application of the electric field is canceled and the electrocaloric cooling material (21) absorbs heat, and the air that goes from the room (3) to the outside Is cooled. In addition, in the part where the humidity control module (20) is located in the exhaust side passage (P2), the application of the electric field is released, the electrocaloric cooling material (21) absorbs heat, the adsorbent is cooled, and the moisture in the air Is adsorbed by the adsorbent.

  In the third modification of the third embodiment, the heat moisture release operation and the cooling moisture absorption operation are performed while rotating the humidity control module (20) continuously or intermittently. Therefore, moisture can be given to the humidity control module (20) through the exhaust side passage (P2) and at the same time moisture release heat treatment can be performed in the air supply side passage (P1). Humidification heating operation to supply to (3) can be performed.

<< Embodiment 4 of the Invention >>
Embodiment 4 of the present invention will be described.

  The humidity control apparatus (1) of Embodiment 4 includes a dehumidifying operation for introducing the air that has been subjected to moisture absorption by the humidity control module (20) into the room (3) in the humidity control apparatus (1) shown in FIGS. The humidifying operation for introducing the air dehumidified by the humidity control module (20) into the room (3) is switchable.

  For example, in the humidity control apparatus (1) of FIG. 1, when supplying air from the outside to the room (3), as shown in FIG. 1 (A), the electrocaloric cooling material (21) of the humidity control module (20) A power supply circuit is configured to be able to switch between an operation for canceling the application of an electric field to and an operation for applying an electric field to the electrocaloric cooling material (21) of the humidity control module (20) as shown in FIG. When releasing air from the room (3) to the outside, an operation of applying an electric field to the humidity control module (20) as shown in FIG. 1 (B), and a humidity control module ( 20) The power supply circuit is configured to be switchable between the operation for canceling the application of the electric field to.

  If comprised in this way, in the humidity control apparatus (1) which has an indoor unit (U) provided with one humidity control module (20), the operation | movement which dehumidifies indoor (3) intermittently, and indoor (3) It is possible to switch between the operation of intermittently humidifying the operation.

(Modification 1)
In the first modification of the fourth embodiment, the operation of FIG. 4A and the operation of FIG. 11A are switched by switching the application state of the electric field in the humidity control apparatus (1) of FIGS. In addition to being configured, the operation of FIG. 4B and the operation of FIG. 11B can be switched. Since the basic configuration of the apparatus is the same as that shown in FIGS. 4 and 11, a detailed description thereof will be omitted.

  In the humidity control apparatus (1), in the operation of FIGS. 4 (A) and 4 (B), the application of the electric field to the humidity control module (20) through which air supplied from the outside to the room (3) passes is released. The electric field is applied to the humidity control module (20) through which the air discharged from the room (3) to the outside passes. 11A and 11B, an electric field is applied to the humidity control module (20) through which air supplied from the outside to the room (3) passes and is discharged from the room (3) to the outside. The electric field applied to the humidity control module (20) through which the air passes is released.

  If comprised in this way, in the humidity control apparatus (1) which installed two indoor units (U1, U2) in the wall surface which opposes a room, the operation | movement which dehumidifies a room (3) continuously, and a room (3) It is possible to switch between the operation of continuously humidifying the operation.

(Modification 2)
In Modification 2 of Embodiment 4, the operation of FIG. 5A and the operation of FIG. 12A are switched by switching the application state of the electric field in the humidity control apparatus (1) of FIGS. In addition to being configured, the operation of FIG. 5B and the operation of FIG. 12B can be switched. Since the basic configuration of the apparatus is the same as that shown in FIGS. 5 and 12, a detailed description thereof will be omitted.

  In the humidity control apparatus (1), in the operation of FIGS. 5A and 5B, the application of the electric field to the humidity control module (20) through which the air supplied from the outside to the room (3) passes is released. The electric field is applied to the humidity control module (20) through which the air discharged from the room (3) to the outside passes. 12A and 12B, an electric field is applied to the humidity control module (20) through which air supplied from the outside to the room (3) passes and is discharged from the room (3) to the outside. The electric field applied to the humidity control module (20) through which the air passes is released.

  If comprised in this way, in the humidity control apparatus (1) which installed two indoor units (U1, U2) on the one wall surface of a room, the operation | movement which dehumidifies a room (3) continuously, and a room (3) It is possible to switch between the operation of continuously humidifying the operation.

(Modification 3)
In the third modification of the fourth embodiment, the operation of FIG. 7 and the operation of FIG. 14 are switched by switching the application state of the electric field in the humidity control apparatus (1) of FIG. 6 to FIG. 8 and FIG. In addition to being configured, the operation of FIG. 8 and the operation of FIG. 15 can be switched. Since the basic configuration of the apparatus is the same as that shown in FIGS. 6 to 8 and FIGS.

  In the humidity control apparatus (1), in the operation of FIGS. 7 and 8, the application of the electric field to the humidity control module (20) through which the air supplied from the outside to the room (3) passes is released, and the room (3) An electric field is applied to the humidity control module (20) through which air exhausted from the room passes. 14 and 15, an electric field is applied to the humidity control module (20) through which air supplied from the outside to the room (3) passes, and air discharged from the room (3) to the outside passes through. The application of the electric field to the humidity control module (20) is released.

  If comprised in this way, in the humidity control apparatus (1) using the unit which can switch the distribution | circulation path | route of air within the casing (10) provided with two humidity control modules (20), indoor (3) is continued. Thus, it is possible to switch between the operation of dehumidifying automatically and the operation of continuously humidifying the room (3).

(Modification 4)
In the fourth modification of the fourth embodiment, the humidity control device (1) of FIG. 9 and the humidity control device (1) of FIG. 16 are configured as one device, and the operation of FIG. The operation of FIG. 16 is configured to be switchable. Since the basic configuration of the apparatus is the same as that shown in FIGS. 9 and 16, a detailed description thereof will be omitted.

  In the humidity control apparatus (1), in the operation of FIG. 9, the application of the electric field to the humidity control module (20) is canceled at the portion where the air supplied from the outside to the room (3) passes, and the room (3) An electric field is applied to the humidity control module (20) in a portion through which air exhausted from the room passes. In the operation of FIG. 16, an electric field is applied to the humidity control module (20) at a portion where air supplied from the outside to the room (3) passes, and air discharged from the room (3) to the outside passes. In the portion, the application of the electric field to the humidity control module (20) is released.

  If comprised in this way, in the humidity control apparatus (1) provided with the rotor-type humidity control module (20), the operation | movement which dehumidifies indoor (3) continuously, and humidifies indoor (3) continuously It becomes possible to switch between operation.

(Modification 5)
Modification 5 of Embodiment 4 switches between the operation of FIG. 17A and the operation of FIG. 19A by switching the application state of the electric field in the humidity control apparatus (1) of FIGS. In addition to being configured, the operation of FIG. 17B and the operation of FIG. 19B can be switched. Since the basic configuration of the apparatus is the same as that shown in FIGS. 17 and 19, a detailed description thereof will be omitted.

  In the humidity control apparatus (1), in the operation of FIGS. 17 (A) and 17 (B), to the humidity control module (20) and the cooling and heating module (24) through which air supplied from the outside to the room (3) passes. The application of the electric field is canceled and the electric field is applied to the humidity control module (20) and the cooling / heating module (24) through which the air discharged from the room (3) to the outside passes. 19 (A) and 19 (B), an electric field is applied to the humidity control module (20) and the cooling / heating module (24) through which air supplied from the outside to the room (3) passes, and the room ( The application of the electric field to the humidity control module (20) and the cooling / heating module (24) through which the air discharged from 3) passes is released.

  With this configuration, in the humidity control device (1) in which the humidity control module (20) and the cooling / heating module (24) are provided in each of the two indoor units (U1, U2), the room (3) is continuously connected. It is possible to switch between the operation of dehumidifying and cooling the air and the operation of continuously humidifying and heating the room (3).

(Modification 6)
In the sixth modification of the fourth embodiment, the humidity control device (1) of FIG. 18 and the humidity control device (1) of FIG. 20 are configured as one device, and the operation of FIG. The operation of the apparatus of FIG. 20 is configured to be switchable. Since the basic configuration of the apparatus is the same as that shown in FIGS. 18 and 20, a detailed description thereof will be omitted.

  In the humidity control apparatus (1), in the operation of FIG. 18, an electric field is applied to the humidity control module (20) and the cooling / heating module (24) in a portion through which air supplied from the outside to the room (3) passes. The electric field is applied to the humidity control module (20) and the cooling / heating module (24) at a portion where the air discharged from the room (3) to the outside passes through. Further, in the operation of FIG. 20, an electric field is applied to the humidity control module (20) and the cooling / heating module (24) in a portion through which air supplied from the outdoor to the indoor (3) passes, and the indoor (3) to the outdoor The application of the electric field to the humidity control module (20) and the cooling / heating module (24) is canceled at the portion through which the discharged air passes.

  If comprised in this way, in the humidity control apparatus (1) provided with the rotor-type humidity control module (20) and the cooling heating module (24), the operation | movement which dehumidifies and cools a room (3) continuously, 3) can be switched between continuous humidification and heating.

<< Embodiment 5 of the Invention >>
Embodiment 5 of the present invention will be described.

  Embodiment 5 shown in FIGS. 21 and 22 relates to a specific configuration of the humidity control module (20). The humidity control module (20) of the fifth embodiment and the humidity control modules (20) of the following modifications 1 to 3 (FIGS. 23 to 25) are the above-mentioned electrocaloric cooling material formed in a tube shape or a plate shape A base module having the electrode (22) provided on the front and back surfaces of (21) is provided, and an adsorbent layer is formed around the base module.

  First, in FIG. 21, the humidity control module (20) includes a plurality of humidity control tubes (41) and two electrode plates (42). The humidity control tubes (41) are arranged in a plurality of rows and stages so as to be parallel to each other, and electrode plates (42) are connected to both ends thereof. Further, the positive electrode of the power source (25) is connected to one of the electrode plates (42), and the negative electrode of the power source (25) is connected to the other of the electrode plates (42). The humidity control module (20) is arranged so that the axial direction of the humidity control tube (41) is perpendicular to the air flow direction.

  FIG. 22A is a partially enlarged cross-sectional view showing a cross-sectional structure of the humidity control tube (41). The humidity control tube (41) was provided in contact with the inner peripheral surface of the electric heating tube (43) and the electric heating tube (43) formed in the shape of a thin cylindrical film by the electrocaloric cooling material (21). A rod-shaped electrode (44) and a cylindrical electrode (45) provided so as to be in contact with the outer peripheral surface of the electric heating tube (43) are provided. Moreover, the adsorption surface (46) which made adsorbent the film form is formed in the outer peripheral surface of a cylindrical electrode (45). The rod-shaped electrode (44) and the cylindrical electrode (45) correspond to the electrode (22) in FIGS. 2 and 3, and the adsorption surface (46) corresponds to the adsorption layer (23). The electric heating tube (43), the rod electrode (44), and the cylindrical electrode (45) constitute a base module (47) of the humidity control module (20).

  The rod electrode (44) is electrically connected to one of the electrode plates (42), and the cylindrical electrode (45) is electrically connected to the other of the electrode plates (42). In this configuration, when an electric field is applied to the electric heating tube (43), the adsorption surface (46) generates heat to the surrounding air, and when the application of the electric field is canceled, the adsorption surface (46) absorbs heat from the surrounding air.

  In the humidity control module (20) of the fifth embodiment, when the adsorption surface (46) generates heat by applying an electric field, moisture contained in the adsorbent on the adsorption surface (46) is released to the surrounding air. The air is humidified. When the adsorption surface (46) is cooled by releasing the application of the electric field to the humidity control module (20), moisture is adsorbed from the surrounding air to the adsorbent on the adsorption surface (46), and the air is reduced. Moistened.

  Since the humidity control module (20) of the fifth embodiment can be put into practical use with a simple configuration and the module itself can be miniaturized, for example, by applying it to the humidity control device (1) of the first embodiment shown in FIG. In addition, the configuration of the humidity control device (1) can be suppressed from being complicated, and at the same time, the device (1) can be downsized. Moreover, this humidity control module (20) can be easily applied also to the humidity control apparatus (1) of FIGS. 4-8, FIGS. 10-15, 17 and 19. FIG.

  In addition, you may comprise a humidity control tube (41) as shown in FIG.22 (B). The humidity control tube (41) shown in FIG. 22 (B) has an adsorbing fin (a ring-shaped adsorbent applied around the cylindrical electrode (45) instead of the adsorbing surface (46)). This is an example of providing 48).

  When configured in this manner, the contact area with air can be increased as compared with the example of FIG.

(Modification 1)
The humidity control module (20) according to the first modification of the fifth embodiment shown in FIG. 23 is different in shape from the examples of FIGS.

  The humidity control module (20) includes an electric heating plate (51) formed in a thin flat plate shape by an electrocaloric cooling material (21), and a first plate provided so as to be in contact with the surface of the electric heating plate (51). And a second plate electrode (53) provided so as to be in contact with the back surface of the electric heating plate (51). The electric heating plate (51) and the two plate-like electrodes (52, 53) constitute a base module (54).

  A plurality of plate fins (55) are fixed to the upper surface of the first plate electrode (52) and the lower surface of the second plate electrode (53) in FIG. Each plate fin (55) is arranged in parallel with each other. An adsorption surface (56) is formed on the surface of each plate fin (55) by applying an adsorbent. The humidity control module (20) is installed in the humidity control device (1) so that the surface direction of the plate fin (55) is parallel to the air flow direction.

  The positive electrode of the power source (25) is connected to the first plate electrode (52), and the negative electrode of the power source (25) is connected to the second plate electrode (53). In this configuration, when an electric field is applied to the electric heating plate (51), the electric heating plate (51) generates heat, and the heat is transmitted to the plate fin (55) to heat the adsorption surface (56). Therefore, the adsorption surface (56) generates heat to the surrounding air. On the other hand, when the electric field application to the electric heating plate (51) is released, the electric heating plate (51) absorbs heat and the plate fin (55) is also cooled. Therefore, the adsorption surface (56) absorbs heat from the surrounding air.

  When the adsorption surface (56) generates heat by applying an electric field, the moisture contained in the adsorbent on the adsorption surface (56) is released to the surrounding air, and the air is humidified. When the adsorption surface (56) is cooled by releasing the application of the electric field to the humidity control module (20), moisture is adsorbed from the surrounding air to the adsorbent on the adsorption surface (56), and the air is reduced. Moistened.

  The humidity control module (20) according to the first modification of the fifth embodiment can be reduced in size while suppressing the complexity of the configuration as in the case of FIG. 21 and FIG. By applying to the humidity control apparatus (1) of Embodiment 1, the configuration of the humidity control apparatus (1) can be simplified and downsized.

(Modification 2)
The humidity control module (20) according to the second modification of the fifth embodiment shown in FIG. 24 has a different shape from the examples shown in FIGS.

  The humidity control module (20) includes a flexible electric heating plate (61) and a first flexible electrode plate (62) provided in contact with one surface of the flexible electric heating plate (61). And a second flexible electrode plate (63) provided in contact with the other surface of the flexible electric heating plate (61). The flexible electric heating plate (61) and the two flexible electrode plates (62, 63) constitute a base module (64).

  The base module (64) is formed in a block shape by folding a strip-like member formed by laminating the flexible electrode plates (62, 63) on the flexible electric heating plate (61) several times. In addition, the portion where the flexible electrode plates (62, 63) face each other is folded back with a slight gap, and the space formed in that portion is filled with the electrical insulating material (66).

  On the surface of the first flexible electrode plate (62), an adsorbent is applied to at least a portion exposed on the surface of the base module (64). Thus, the adsorption surface (65) is formed by applying the adsorbent to the surface of the first flexible electrode plate (62).

  In the second modification of the fifth embodiment, when an electric field is applied to the flexible electric heating plate (61) with air flowing around the adsorption surface (65), the entire humidity control module (20) is heated. The adsorption surface (65) is also heated, and the moisture contained in the adsorbent is released into the air flowing around it to humidify the air. Further, when the application of the electric field to the flexible electric heating plate (61) is released while air flows around the adsorption surface (65), the entire humidity control module (20) is cooled and the adsorption surface (65) The water in the air flowing around is adsorbed by the adsorbent and the air is dehumidified.

  The humidity control module (20) according to the second modified example of the fifth embodiment has a simple configuration similar to that of FIGS. 21 to 23 and can reduce the size of the module itself. For example, the embodiment shown in FIG. By applying to the humidity control apparatus (1), the configuration of the humidity control apparatus (1) can be simplified and downsized.

  In the configuration of FIG. 24, a space may be formed in the portion without filling the electric insulating material (66) between the flexible electrode plates (62, 63). In this case, in order to give an electrical insulating function to the space, it is preferable to provide a member for holding the space at a predetermined pitch between the flexible electrode plates (62, 63). Moreover, when comprised in this way, it is good to apply | coat an adsorption agent to the whole surface of both electrode plates (62, 63), and to form an adsorption | suction surface (65). If comprised in this way, since the area of an adsorption | suction surface (65) can be enlarged, it becomes possible to improve humidity control performance further.

(Modification 3)
The humidity control module (20) according to the third modification of the fifth embodiment shown in FIG. 25 is an example in which the shape is different from that of FIGS.

  The humidity control module (20) includes a plurality of electric heating plates (71), a first electrode plate (72) provided in contact with one surface of each electric heating plate (71), and an electric heating plate (71). And a second electrode plate (73) provided in contact with the other surface. The electric heating plate (71) and the two electrode plates (72, 73) constitute a base module (74).

  In the base module (74), a plurality of electric heating plates (71) are arranged in parallel to each other, and suction plates (75) are fixed to both end faces thereof. An adsorption surface (76) is formed on the surface of the adsorption plate (75) by applying an adsorbent.

  In the third modification of the fifth embodiment, when an electric charge is applied to the electric heating plate (71) with air flowing around the adsorption surface (76), the entire humidity control module (20) is heated and the adsorption surface (76) is also heated, and the moisture contained in the adsorbent is released into the air flowing around it to humidify the air. In addition, when the application of the electric field to the heating plate (71) is canceled while flowing around the adsorption surface (76), the entire humidity control module (20) is cooled and the adsorption surface (76) is also cooled. Moisture in the air flowing through is adsorbed by the adsorbent, and the air is dehumidified.

  The humidity control module (20) according to the third modification of the fifth embodiment has a simple configuration similar to that shown in FIGS. 21 to 24 and can reduce the size of the module itself. For example, the embodiment shown in FIG. By applying to the humidity control apparatus (1), the configuration of the humidity control apparatus (1) can be simplified and downsized.

Embodiment 6 of the Invention
Embodiment 6 of the present invention relates to the cooling and heating module (24).

  As shown in FIG. 26, the cooling and heating module (24) includes electrodes (22) (82, 83) on the inner and outer peripheral surfaces of the electrocaloric cooling material (21) (81) formed in a cylindrical shape. Is provided with a base module (85).

  Specifically, the cooling and heating module (24) includes a heat transfer tube (81), an outer peripheral electrode (82), and an inner peripheral electrode (83). The outer peripheral electrode (82) includes a cylindrical outer peripheral body (82a), an annular plate-shaped outer peripheral heat transfer section (82b) formed on the inner peripheral surface of the outer peripheral body (82a), An annular outer fin (82c) formed on the outer peripheral surface of the side main body (82a) is integrally formed. The inner peripheral side electrode (83) includes a cylindrical inner peripheral side main body (83a) and an annular plate-shaped inner peripheral side heat transfer section (83b) formed on the outer peripheral surface of the inner peripheral side main body (83a). And the inner peripheral side fin (83c) formed in the inner peripheral surface of the inner peripheral side main-body part (83a) is integrally formed.

  The outer peripheral heat transfer section (82b) and the inner peripheral heat transfer section (83b) are alternately positioned in the axial direction of the cooling heating module (24). Further, a slight gap is formed between the inner peripheral side end of the outer peripheral heat transfer section (82b) and the outer peripheral surface of the inner peripheral main body section (83a). A slight gap is formed between the outer peripheral end of the inner peripheral heat transfer section (83b) and the inner peripheral surface of the outer peripheral body section (82a). With the above configuration, a labyrinth-like space is formed between the outer peripheral electrode (82) and the inner peripheral electrode (83).

  The heat transfer tube (81) is formed by the electrocaloric cooling material (21) into a shape that matches the labyrinth space, and the outer peripheral electrode (82) is mounted on the outer peripheral side of the heat transfer tube (81). The inner peripheral side electrode (83) is mounted on the inner peripheral side. The heat transfer tube (81), the outer peripheral side electrode (82) and the inner peripheral side electrode (83), for example, are divided into two parts in the circumferential direction, and are configured to be cylindrical by combining the divided parts. Can do.

  For example, as shown in FIG. 17, the cooling and heating module (24) of this embodiment can be configured such that two are provided in the humidity control apparatus (1), while the cooling operation is performed on one side and the heating operation is performed on the other side. . Specifically, when an electric field is applied to one cooling / heating module (24), the entire cooling / heating module (24) generates heat, and at that time, the exhaust air (EA) is transferred to the outer peripheral surface of the cooling / heating module (24). By flowing, heat can be released to the outside. At this time, supply air (SA) is not supplied indoors.

  When the application of the electric field to the other cooling and heating module (24) is released, the entire cooling and heating module (24) absorbs heat, and at that time, the supply air (SA) is flowed in the direction of the solid line to cool it. Air can be supplied indoors. At this time, the flow of exhaust air (EA) is stopped.

  When the above cooling operation and heating operation are performed on one of the two cooling heating modules (24), the heating operation is performed on the other, and the heating operation is performed on one of the two adsorption modules. On the other hand, the room can be continuously cooled by alternately switching to perform the cooling operation.

  Also, supply air (SA) is supplied to the room when an electric field is applied to the cooling and heating module (24), and exhaust air (EA) is cooled and heated when the application of the electric field to the cooling and heating module (24) is released. When the heating operation and the cooling operation are alternately repeated by the two cooling and heating modules (24) so as to flow around the module (24), the room can be continuously heated.

  As described above, when the cooling and heating module (24) of the present embodiment is used, it is possible to easily realize a configuration that performs cooling and heating in the humidity control apparatus (1).

  In addition, this cooling and heating module (24) can be used to reduce or humidify air by forming an adsorption layer (84) on the surface of the inner fin (83c) that serves as a passage for the supply air (SA). It can also be used as a module (20).

<< Embodiment 7 of the Invention >>
Embodiment 7 of the present invention relates to the cooling and heating module (24).

  As shown in FIG. 27, this cooling and heating module (24) is provided with electrodes (92, 93) on both sides of a heat transfer body (91) made of an electrocaloric cooling material (21) formed in a block shape. Provided base module (95). The cooling and heating module (24) is installed in a casing (15) attached to a building wall (2a) or a window. In the casing (15), an air supply fan (30a) is provided on the indoor side, and an exhaust fan (30b) is provided on the outdoor side. In addition, although not shown in figure, the humidity control module (20) is also provided in the casing (15).

  The cooling and heating module (24) includes a heat transfer body (91), a first electrode (92), and a second electrode (93). The first electrode (92) includes an indoor body portion (92a), an indoor heat transfer portion (92b) on the outer end surface of the indoor body portion (92a), and a chamber on the inner end surface of the indoor body portion (92a). The inner fin (92c) is integrally formed. The second electrode (93) includes an outdoor body portion (93a), an outdoor heat transfer portion (93b) on the inner end surface of the outdoor body portion (93a), and a chamber on the outer end surface of the outdoor body portion (93a). The outer fin (93c) is integrally formed.

  The indoor heat transfer section (92b) and the outdoor heat transfer section (93b) are alternately positioned in the vertical direction of the cooling / heating module (24) in the figure. The indoor heat transfer section (92b) and the outdoor heat transfer section (93b) are arranged so as to mesh with each other, while the first electrode (92) and the second electrode (93) are formed so as not to contact each other. Yes. In addition, a space is formed in a portion where the indoor heat transfer section (92b) and the outdoor heat transfer section (93b) mesh with each other.

  And the said heat exchanger (91) is formed in the shape corresponding to the space shape between an indoor side heat-transfer part (92b) and an outdoor side heat-transfer part (93b) with an electrocaloric cooling material (21), The first electrode (92) is mounted on the indoor side of the heat transfer body (91), and the second electrode (92) is mounted on the outdoor side.

  For example, as shown in FIG. 17, the cooling and heating module (24) of this embodiment can be configured such that two are provided in the humidity control apparatus (1), while the cooling operation is performed on one side and the heating operation is performed on the other side. . Specifically, when an electric field is applied to one cooling / heating module (24), the entire cooling / heating module (24) generates heat, and at that time, the exhaust air (EA) is moved to the outside of the cooling / heating module (24). By flowing, heat can be released to the outside. At this time, supply air (SA) is not supplied indoors.

  When the application of the electric field to the other cooling / heating module (24) is released, the entire cooling / heating module (24) absorbs heat, and then the supplied air (SA) flows in the direction of the arrow, thereby cooling the air. Can be supplied indoors. At this time, the flow of exhaust air (EA) is stopped.

  By alternately performing the above cooling operation and heating operation by the two cooling heating modules (24), the room can be continuously cooled.

  Also, supply air (SA) is supplied to the room when an electric field is applied to the cooling and heating module (24), and exhaust air (EA) is cooled and heated when the application of the electric field to the cooling and heating module (24) is released. When the heating operation and the cooling operation are alternately repeated by the two cooling and heating modules (24) so as to flow around the module (24), the room can be continuously heated.

  As described above, when the cooling and heating module (24) of the present embodiment is used, it is possible to easily realize a configuration that performs cooling and heating in the humidity control apparatus (1).

  The cooling and heating module (24) has, for example, an adsorption layer (94) formed on both the indoor fin (92c) and the outdoor fin (93c), and the first electrode (92) is located on the indoor side. The second electrode (93) is located on the outdoor side (the state shown in FIG. 27), the second electrode (93) is located on the indoor side, and the first electrode (92) is located on the outdoor side. When the state can be changed to the second state (not shown), moisture adsorbed on the indoor side is discharged on the outdoor side, or moisture absorbed on the outdoor side is supplied to the indoor side. Therefore, it can also be used as a humidity control module (20) for reducing or humidifying air.

<< Embodiment 8 of the Invention >>
Embodiment 8 of this invention shown in FIGS. 28-31 is related with a humidity control module (20).

  The humidity control module (20) includes a plurality of fins (102) formed of an electrocaloric cooling material (21) and a drive member (101) that conveys the fins (102). This is an example in which the application and release of the electric field to the caloric cooling material (21) are switched. 28 is a cross-sectional structural diagram of the humidity control module (20), FIG. 29 is a vertical cross-sectional structural diagram, and FIG. 30 is a plan structural diagram. FIG. 31 is a structural diagram of the fin (102).

  In the figure, the humidity control module (20) passes through a hole (2b) formed in the wall (2a) of the building, with one end located on the indoor side and the other end located on the outdoor side. An air supply fan (30a) is disposed at the indoor end, and an exhaust fan (30b) is disposed at the outdoor end.

  The humidity control module (20) is continuously disposed on the surface of the belt (101) as a driving member that is hung on a pulley (not shown) provided on the indoor side and the outdoor side. And a large number of fins (102). The fin (102) is formed in a plate shape by a self-heating element (electrocaloric cooling material (21)). Specifically, as shown in FIG. 31, the fin (102) has a shape in which the tip end is curved when viewed from the front, and the base end (102a) is bent. An adsorption layer is formed on the surface of the fin (102).

  The fin (102) is connected to the belt (101) on the side of the base end (102a) serving as a support portion. As shown in FIG. 28, the plurality of fins (102) overlap with each other in the linear portion of the belt (101), while they are unfolded in the curved portions at both ends of the belt (101). In the state where the fin (102) overlaps at the straight line portion, the outer edge has an arc shape along the hole (2b) as shown in FIG.

  A cooling electrode (103) and a heating electrode (104) are provided along the belt (101). The cooling electrode (103) and the heating electrode (104) are separated from each other at the lower right portion on the outdoor side and the upper left portion on the indoor side in FIG. In addition, the fin (102) is electrically connected to the cooling electrode (103) or the heating electrode (104) on the left and right one end surfaces of the base end portion in FIG. It is comprised so that it may contact. Accordingly, when an electric field is applied to the fin (102) from the heating electrode (104) and the cooling electrode (103), the fin (102) generates heat, and the adsorption layer also generates heat.

During the dehumidifying operation, an electric field is applied from the cooling electrode (103) to the fin (102), and the application of the electric field from the heating electrode (104) is released. Since the belt (101) is rotating in the direction of the arrow in FIG. 28, the fin (102) is cooled at the portion where the fin (102) is deployed on the left side of the figure, and the indoor air flows into the fin (102). Moisture is adsorbed by the adsorption layer, and the fin (102) is heated at the portion where the fin (102) is developed on the right side of the figure, and the moisture in the fin (102) is released to the outdoor air. By continuously rotating the belt (101) in this state, the dehumidifying operation can be performed continuously.

  Further, during the humidifying operation, electric charges are applied from the heating electrode (104) to the fin (102), and the application of the electric field from the cooling electrode (103) is released. At this time, the moisture in the outdoor air is adsorbed by the adsorption layer in the portion where the cooled fin (102) on the right side of the figure is developed, and the fin ( 102) is supplied to room air. By continuously rotating the belt (101) in this state, the humidification operation can be performed continuously.

  In addition, it is easy to make this humidity-control module (20) into a cooling heating module (24) by not having an adsorption layer on the surface of the fin (102) but only cooling and heating the air. . In this way, by using the belt (101) type humidity control module (20) and the cooling and heating module (24) together, an apparatus (1) for switching between dehumidifying cooling and humidifying heating in the room can be easily configured. Is possible.

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

  For example, in each of the embodiments described above, a ventilation method is adopted in which outdoor air is dehumidified and humidified and supplied indoors, and the indoor air is used for adsorption regeneration processing of the humidity control module (20) and discharged to the outside of the room. In the configuration in which indoor air is circulated, moisture may be adsorbed or desorbed by the humidity control module (20).

  In addition, the specific configurations of the humidity control module (20) and the cooling and heating module (24) described in the above embodiments may be appropriately changed according to the device configuration of the humidity control device (1).

  Furthermore, the configuration of the humidity control apparatus (1) may be changed as appropriate as long as the dehumidifying operation, the humidifying operation, the dehumidifying cooling operation, and the humidifying heating operation can be performed.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a humidity control module that adsorbs and desorbs moisture, and a humidity control apparatus for adjusting the humidity in the room using the humidity control module.

1 Humidity control device
5 Humidity control unit
20 Humidity control module
21 Electrocaloric cooling material
22 electrodes
23 Adsorption layer
24 Cooling and heating module
25 Power supply
35 Voltage controller
47 Base module
54 Base module
64 base module
74 Base module
85 Base module
95 Base module
101 Drive member
102 fins
P Air passage

Claims (19)

A humidity control module that adsorbs and desorbs moisture in the air,
An electrocaloric cooling material (21) and a pair of electrodes (22) provided on the electrocaloric cooling material (21) so as to apply an electric field to the electrocaloric cooling material (21) from a power source (25) ,
A humidity control module characterized in that an adsorption layer (23) capable of adsorbing and desorbing moisture in the air is provided on the surface. An electrocaloric cooling material (21) and a pair of electrodes (22) provided on the electrocaloric cooling material (21) so as to apply an electric field to the electrocaloric cooling material (21) from a power source (25) A humidity control module (20) having an adsorption layer (23) capable of adsorbing and desorbing moisture in the air on its surface;
A voltage controller (35) for setting the application and release of an electric field to the electrocaloric cooling material (21);
A humidity control unit comprising: In claim 2,
The voltage controller (35) is configured to apply an electric field from the power source (25) to the electrocaloric cooling material (21) when moisture is desorbed from the adsorption layer (23). Humidity control unit characterized by In claim 2,
The voltage controller (35) is configured to cancel the application of an electric field from the power source (25) to the electrocaloric cooling material (21) when moisture is absorbed by the adsorption layer (23). Humidity control unit characterized by In claim 2,
The voltage controller (35) includes a moisture release operation for applying an electric field from the power source (25) to the electrocaloric cooling material (21) when moisture is released from the adsorption layer (23), and the adsorption layer. Humidity adjustment characterized by being configured to alternately perform a moisture absorption operation to cancel the application of an electric field from the power source (25) to the electrocaloric cooling material (21) during moisture absorption to adsorb moisture in (23) unit. In claim 5,
The voltage controller (35) adjusts the heat generation amount of the electrocaloric cooling material (21) by changing the magnitude of the electric field applied to the electrocaloric cooling material (21), and adjusts the moisture absorption / release capacity. A humidity control unit configured to perform In claim 5,
The voltage controller (35) adjusts the calorific value of the electrocaloric cooling material (21) by changing the ratio of applying an electric field to the whole electrocaloric cooling material (21), and absorbs and releases moisture. A humidity control unit configured to adjust the humidity. In claim 5,
The voltage controller (35) is configured to adjust the heat generation amount of the electrocaloric cooling material (21) by changing the time interval for repeating the moisture release operation and the moisture absorption operation, thereby adjusting the moisture absorption / release capability. Humidity control unit characterized by being. An electrocaloric cooling material (21) and a pair of electrodes (22) provided on the electrocaloric cooling material (21) so as to apply an electric field to the electrocaloric cooling material (21) from a power source (25) A humidity control module (20) having an adsorption layer (23) capable of adsorbing and desorbing moisture in the air on its surface;
A voltage controller (35) for setting the application and release of an electric field to the electrocaloric cooling material (21);
A humidity control apparatus comprising: an air passage (P) that supplies air that has passed through the humidity control module (20) to a room. In claim 9,
The humidity control apparatus, wherein the air passage (P) is configured to introduce into the room the air that has been subjected to moisture absorption by the humidity control module (20). In claim 9,
The humidity control apparatus, wherein the air passage (P) is configured to introduce into the room the air that has been subjected to moisture release treatment by the humidity control module (20). In claim 9,
It is configured to be able to switch between a dehumidifying operation for introducing the air absorbed by the humidity control module (20) into the room and a humidifying operation for introducing the air released by the humidity control module (20) into the room. A humidity control apparatus characterized by that. In claim 9,
In addition to the humidity control module (20), the humidity control module (20) includes a cooling and heating module (24) configured to cool and heat air without providing an adsorption layer (23),
The air passage (P) is configured to introduce the air absorbed by the humidity control module (20) into the room and introduce the air cooled by the cooling and heating module (24) into the room. Humidity control device characterized by. In claim 9,
In addition to the humidity control module (20), the humidity control module (20) includes a cooling and heating module (24) configured to cool and heat air without providing an adsorption layer (23),
The air passage (P) is configured to introduce the air dehumidified by the humidity control module (20) into the room and introduce the air heated by the cooling and heating module (24) into the room. A humidity control apparatus characterized by that. In claim 9,
In addition to the humidity control module (20), the humidity control module (20) includes a cooling and heating module (24) configured to cool and heat air without providing an adsorption layer (23),
Dehumidifying and cooling operation for introducing the air adsorbed by the humidity control module (20) and the air cooled by the cooling and heating module (24) into the room, and the air and cooling heating module dehumidified by the humidity control module (20) A humidity control apparatus configured to be switchable between a humidifying and heating operation of introducing the air heated in (24) into a room. In any one of claims 9 to 15,
The humidity control module (20) includes a base module (47, 54, 64, 74) in which the electrode (22) is provided on the front and back surfaces of the electrocaloric cooling material (21) formed in a tube shape or a plate shape. ), And the adsorbent is provided around the base module (47, 54, 64, 74). In any one of claims 9 to 15,
The humidity control module (20) includes a base module (85) in which the electrode (22) is provided on an inner peripheral surface and an outer peripheral surface of the cylindrical electrocaloric cooling material (21), and the electrode A humidity control apparatus, wherein the adsorbent is provided on a surface of (22). In any one of claims 9 to 15,
The humidity control module (20) includes a base module (95) provided with the electrodes (22) on both sides of the electrocaloric cooling material (21) formed in a block shape, and the electrodes (22) A humidity control device, wherein the adsorbent is provided on the surface of the humidity control device. In any one of claims 9 to 15,
The humidity control module (20) includes a drive member (101) that conveys a plurality of fins (102) formed of an electrocaloric cooling material (21), and the electrocaloric cooling material in the air passage (P). A humidity control device configured to switch between application and release of an electric field to (21).

Images