KR20190120195A - Desiccant device for dehumidification - Google Patents

Abstract

The present invention provides a desiccant device for dehumidification that can be miniaturized. The dehumidifying desiccant device 10 includes a first desiccant 14 and a second desiccant 16 which adsorb moisture in the air by flowing air. The first desiccant 14 contains a first micro dehumidifier. The second desiccant 16 contains a second microscopic dehumidifier. The first microscopic dehumidifying agent and the second microscopic dehumidifying agent are selected so that the adsorptivity of the moisture is different depending on the moisture contained in the air.

Description

Desiccant device for dehumidification

The present invention relates to a desiccant device for dehumidification.

The desiccant device for dehumidification is an air conditioner that produces air of low humidity with a moisture absorbent. By supplying air of low humidity to a room etc. with the dehumidification desiccant device, comfort can be acquired even if the temperature of a room etc. is not reduced very much. The dehumidification desiccant device includes a supply air fan, a desiccant part, a cooling part, a heating part, a regeneration fan, and the like.

The desiccant part adsorbs moisture in the air by flowing air introduced from the outside into the desiccant part by the air supply fan. Air flowing through the desiccant portion is dehumidified in the desiccant portion. The comfort of the room is obtained by cooling the dehumidified air in the cooling section and flowing the room.

On the other hand, when the moisture adsorbed on the desiccant portion is removed and regenerated, air dried in the heating portion flows into the desiccant portion. By flowing dry air, moisture adsorbed to the desiccant portion is included in the dry air and removed from the desiccant portion. The desiccant portion is regenerated by removing moisture from the desiccant portion. Air containing moisture is exhausted outside by a fan for regeneration (Patent Document 1).

However, in order to sufficiently adsorb moisture in the desiccant portion, it is necessary to secure the shape of the desiccant portion largely, and room for improvement is left in view of this.

Japanese Patent Publication No. 2009-240935

The present invention provides a desiccant device for dehumidification that can be miniaturized.

This invention has the following structures.

[1] A desiccant device for dehumidification, comprising a desiccant for adsorbing moisture in the air by flowing air, wherein the desiccant includes at least a first desiccant and a second desiccant, The desiccant device for dehumidification which makes the adsorption property of the dehumidifying agent included and the moisture of the dehumidifying agent contained in the said 2nd desiccant different according to the relative humidity in air. [2] The dehumidifying agent contained in the first desiccant has a larger adsorption amount of water in a region having a higher relative humidity than the dehumidifying agent contained in the second desiccant, and the dehumidifying agent contained in the second desiccant includes: Compared with the dehumidifying agent included in the first desiccant, the adsorption amount of water is larger in a region where the relative humidity is lower than the region where the relative humidity is higher, and the first desiccant is in a direction in which the air flows than the second desiccant. The desiccant device for dehumidification as described in [1] arrange | positioned upstream. [3] The dehumidifying agent contained in the first desiccant and the dehumidifying agent contained in the second desiccant are porous dehumidifying agents, and the pore diameter of the porous dehumidifying agent contained in the first desiccant is the second desiccant. The desiccant device for dehumidification according to [1] or [2], which is larger than the pore diameter of the porous dehumidifying agent contained in the kant. [4] The first desiccant and the second desiccant are each provided with a sheet in which the dehumidifying agent is held and wound in a spiral shape, and a spacer to secure the gap between the sheets. The desiccant device for dehumidification according to any one of [3]. [5] The desiccant device for dehumidification according to [4], wherein the spacer also serves as a dehumidifying agent. [6] The desiccant device for dehumidification according to [4] or [5], wherein the sheet is a nonwoven fabric. [7] The desiccant device for dehumidification according to [4] or [5], wherein the sheet is an adhesive sheet. [8] The desiccant device for dehumidification according to [6], wherein the dehumidifying agent is contained in the nonwoven fabric. [9] The desiccant device for dehumidification according to [7], in which the dehumidifying agent is attached to the adhesive sheet.

According to the dehumidification apparatus for dehumidification of this invention, the adsorption property of the dehumidifier contained in 1st desiccant and the dehumidifier contained in 2nd desiccant differed according to the relative humidity in air. Therefore, the dehumidifying agent (for example, 1st desiccant) which is excellent in adsorption property with respect to air of high relative humidity can be arrange | positioned upstream. Furthermore, a dehumidifying agent (for example, 2nd desiccant) which is excellent in adsorption property with respect to air with a certain degree of relative humidity can be arrange | positioned downstream.

That is, moisture contained in air of high relative humidity can be efficiently adsorbed to the first desiccant. In addition, moisture contained in air having a relatively low relative humidity can be efficiently adsorbed to the second desiccant. Thereby, the moisture contained in the air can be adsorbed efficiently by the dehumidifying desiccant apparatus, and the dehumidifying desiccant apparatus can be miniaturized.

BRIEF DESCRIPTION OF THE DRAWINGS It is sectional drawing which shows the desiccant device for dehumidification of embodiment of this invention.
FIG. 2 is a front view illustrating a first desiccant in the desiccant device for dehumidification of FIG. 1.
3 is a cross-sectional view taken along III-III of FIG. 2 in the dehumidifying desiccant device of the present invention.
It is a perspective view explaining the state which wound the 1st sheet | seat of the 1st desiccant of FIG.
(A) is a top view which shows the 1st microscopic dehumidifier of 1st desiccant, FIG. 5 (b) is the top view which shows the 2nd microscopic dehumidifier of 2nd desiccant, FIG. It is a top view which shows the 3rd desiccant 3rd minute dehumidifier.
It is a graph which shows the magnitude | size of the pore diameter of the 1st-3rd small dehumidifier of (a)-(c) of FIG. 5 by frequency distribution.
FIG. 7 is a graph showing the relationship between the adsorption amount of moisture of the first to third microdehumidifiers of FIGS. 5A to 5C and the relative humidity in the air.
8 (a) and 8 (b) are schematic diagrams illustrating a state in which the desiccant device for dehumidification of the present invention is subsequently installed in an integrated air conditioner.
9 (a) and 9 (b) are schematic diagrams illustrating a state in which the desiccant device for dehumidification of the present invention is subsequently installed in a split type air conditioner.

Next, embodiment of this invention is described based on drawing.

In addition, in FIG. 1, in order to facilitate understanding of the structure of the desiccant device 10 for dehumidification, the 1st micro-humidifier (dehumidifier) 24, the 2nd micro-humidifier (dehumidifier) 32, and the 3rd micro The dehumidifier (dehumidifier) 35 is omitted and shown.

As shown in FIG. 1, the desiccant device 10 for dehumidification is provided in the inside 13 of the flow path 12 through which air flows. The dehumidifying desiccant device 10 includes a first desiccant 14, a second desiccant 16, and a third desiccant 18 accommodated in the interior 13 of the flow passage 12.

Hereinafter, the upstream side and the side in which the 3rd desiccant 18 is arrange | positioned in the flow path 12 are demonstrated downstream.

The flow path 12 is formed in circular cross section, for example. The flow path 12 can flow air of high relative humidity toward the 1st desiccant 14 from the upstream of the 1st desiccant 14 like arrow A. FIG. Dry air which has passed through the first desiccant 14, the second desiccant 16, and the third desiccant 18 can flow in the downstream side of the flow path 12 as indicated by the arrow B.

Moreover, the air of low relative humidity can flow like arrow C toward the 3rd desiccant 18 from the downstream of the 3rd desiccant 18. FIG. High relative humidity air that has passed through the third desiccant 18, the second desiccant 16, and the first desiccant 14 may flow in an upstream side of the flow path 12, as indicated by the arrow D.

As shown in FIGS. 2 and 3, the first desiccant 14 includes a first sheet 21 wound in a vortex shape (wound) and a large number of numbers included in the first sheet 21. The dehumidifying agent 25 which secures the space | interval S1 between the 1st microscopic dehumidifier 24 and the 1st sheet 21 is provided.

By securing the space | interval S1 between the 1st sheet | seat 21 with the dehumidifier 25, the flow path of air can be ensured at the space | interval S1. That is, the dehumidifier 25 has a role as a spacer which secures the space | interval S1 between the 1st sheet 21, and serves as an auxiliary dehumidifier. Hereinafter, the auxiliary dehumidifier 25 is called the first spacer dehumidifier 25.

The 1st sheet 21 is formed in the width dimension T1 (refer FIG. 4), for example, and is a strip | belt-shaped nonwoven fabric containing the 1st micro-humidifier 24. As shown in FIG. The first minute dehumidifier 24 is a minute dehumidifier as compared to the first spacer dehumidifier 25. A plurality of first minute dehumidifiers 24 are included in the interior 22 of the first sheet 21, and the first spacer dehumidifier 25 is disposed at intervals between the first sheets 21.

The first microscopic dehumidifier 24 and the first spacer dehumidifier 25 are formed of, for example, a material such as silica gel excellent in adsorption of moisture (water vapor). By arrange | positioning the some 1st microscopic dehumidifier 24 in the inside 22 of the nonwoven fabric fiber of the 1st sheet | seat 21, the moisture which arrived through the nonwoven fabric is adsorbed by the 1st microscopic dehumidifier 24. As shown in FIG. Thereby, the adsorption property of the moisture of the 1st desiccant 14 can be improved.

Moreover, since the 1st spacer dehumidifier 25 is arrange | positioned, the space | interval S1 between the 1st sheet 21 will be set as the 1st spacer dehumidifier 25 in the state in which the 1st sheet 21 was wound in the vortex shape. It is secured. Since the first spacer dehumidifier 25 also serves as a spacer, it is not necessary to provide the spacers individually, and the configuration can be simplified.

In this way, by disposing the plurality of first spacer dehumidifiers 25 between the first sheets 21, the space S1 can be reliably secured between the first sheets 21 in a simple configuration.

In addition, the 1st spacer dehumidifier 25 is formed from materials, such as a silica gel which is excellent in the adsorption property of water, for example. By using the material excellent in the water adsorption property for the 1st spacer dehumidifier 25, in addition to the adsorption property of the water in the air by the 1st micro dehumidifier 24, the performance can be further improved.

In the embodiment, the first microscopic dehumidifier 24 and the first spacer dehumidifier 25 are formed in a spherical shape having different outer diameters, and many pores 26 on the surface and inside thereof (see also FIG. 5A). Is formed. A large number of pores 26 are formed in the first micro dehumidifier 24 and the first spacer dehumidifier 25, thereby securing a large surface area of the first micro dehumidifier 24 and the first spacer dehumidifier 25, Adsorption can be improved.

The first microscopic dehumidifier 24 and the first spacer dehumidifier 25 are not limited to a spherical shape, and mold release and powder may also be used.

The pores of the first spacer dehumidifier 25 are preferably the same size with respect to the pores 26 of the first microscopic dehumidifier 24, but even if the pore diameter sizes are different, they can be used as reinforcing adsorption of water.

3 and 4, a plurality of first microscopic dehumidifiers 24 are supported in the first sheet 21 (that is, nonwoven fabric). In addition, a plurality of first spacer dehumidifiers 25 are included between the first sheets 21. By forming the 1st sheet 21 by a nonwoven fabric, it can hold | maintain in the state which stabilized the some 1st microscopic dehumidifier 24 in the inside 22 of the 1st sheet 21. FIG.

The 1st sheet 21 in which the some 1st microscopic dehumidifier 24 is included is wound in a vortex shape around the one end 21a. The first desiccant 14 can be easily formed by the simple structure which only winds up the 1st sheet 21 in a vortex shape.

In addition, the first desiccant 14 is formed in a circular shape by looking at the front face by winding the first sheet 21 in a spiral shape. Therefore, the 1st desiccant 14 can be arrange | positioned easily in the flow path 12 of a circular cross section.

Returning to FIG. 1, the second desiccant 16, like the first desiccant 14, includes the second sheet 31, the second microscopic dehumidifier 32 (see FIG. 5B), The second spacer dehumidifier 37 is provided.

Similarly to the first sheet 21 (see also FIG. 2), the second sheet 31 is wound in a spiral shape. The second minute dehumidifier 32 is included in the second sheet 31 similarly to the first minute dehumidifier 24 (see FIG. 5A). The second spacer dehumidifier 37 is disposed between the second sheets 31 similarly to the first spacer dehumidifier 25.

The pores of the second spacer dehumidifier 37 are preferably the same size with respect to the pores 33 of the second microscopic dehumidifier 32, but can be used as reinforcing adsorption of water even if the pore diameter sizes are different.

Similar to the first desiccant 14, the third desiccant 18 includes a third sheet 34, a third micro dehumidifier 35 (see FIG. 5C), and a third spacer dehumidifier 38. ).

Similarly to the first sheet 21 (see also FIG. 2), the third sheet 34 is wound in a spiral shape. The third microscopic dehumidifier 35 is included in the third sheet 34 similarly to the first microdehumidifier 24 (see FIG. 5A). The third spacer dehumidifier 38 is disposed between the third sheets 34 similarly to the first spacer dehumidifier 25.

The pores of the third spacer dehumidifier 38 are preferably the same size with respect to the pores 36 of the third microscopic dehumidifier 35, but can be used as reinforcing the adsorption of water even if the pore diameter sizes are different.

The 2nd desiccant 16 and the 3rd desiccant 18 are the same structures as the 1st desiccant 14, and detailed description is abbreviate | omitted.

In embodiment, although the example in which the 1st sheet 21, the 2nd sheet 31, and the 3rd sheet 34 was formed with the nonwoven fabric is demonstrated, it is not limited to this. For example, the 1st sheet 21, the 2nd sheet 31, and the 3rd sheet 34 can also be made an adhesive sheet.

An adhesive sheet is a sheet | seat in which the adhesive agent was apply | coated to the surface of the sheet | seat. A plurality of micro dehumidifiers are attached to the adhesive of the adhesive sheet, and a plurality of spacer dehumidifiers are attached. In this state, by winding the adhesive sheet in a spiral shape, the first desiccant, the second desiccant, and the third desiccant are formed by having a dehumidification performance and securing an air flow path.

By making the 1st sheet | seat 21, the 2nd sheet | seat 31, and the 3rd sheet | seat 34 into an adhesive sheet, it can hold | maintain the micro-dehumidifier and some spacer dehumidifier in the state which stabilized the sheet | seat.

As shown to Fig.5 (a), the 1st micro-dehumidifier 24 is formed as spherical shape as an example, and is a porous raw material in which many pore 26 was formed in the surface and the inside. Examples of the material of the first microscopic dehumidifying agent 24 include silica gel, zeolite, polymer moisture absorbent, porous titania, and the like.

In the first microscopic dehumidifier 24, the pores 26 are formed to have a diameter D1. Hereinafter, diameter D1 of the pore 26 is called "1st pore diameter D1."

As shown in FIG. 5B, the second microscopic dehumidifier 32 is formed as a spherical shape as an example, and is a porous material having a large number of pores 33 formed on its surface and inside thereof. The second minute dehumidifier 32 is formed of the same material as the first minute dehumidifier 24. As for the 2nd microscopic dehumidifier 32, the pore 33 is formed in diameter D2. Hereinafter, the diameter D2 of the pore 33 is called "second pore diameter D2."

As shown in FIG.5 (c), the 3rd small dehumidifier 35 is formed as spherical shape as an example, and is a porous raw material in which the many pores 36 were formed in the surface and the inside. The third small dehumidifier 35 is formed of the same material as the first small dehumidifier 24. As for the 3rd fine dehumidifier 35, the pore 36 is formed in diameter D3. Hereinafter, diameter D3 of the pore 36 is called "third pore diameter D3."

As shown in FIGS. 5A to 5C, the first pore diameter D1 of the first microscopic dehumidifier 24 is the second pore diameter D2 of the second microdehumidifier 32. It is formed larger than). The second pore diameter D2 of the second microscopic dehumidifier 32 is formed larger than the third pore diameter D3 of the third microdehumidifier 35.

In FIGS. 5A to 5C and 6, the first micro dehumidifier 24, the second micro dehumidifier 32, and the third micro dehumidifier 35 will be described. The graph shown in FIG. 6 shows the frequency distribution on a vertical axis, and shows the pore diameters D1, D2, D3 of the first to third dehumidifiers 24, 32, 35 on the horizontal axis. The graph G1 shown by the broken line shows the frequency distribution of the first microdehumidifier 24 included in the first desiccant 14. The graph G2 shown by the solid line shows the frequency distribution of the second microscopic dehumidifier 32 included in the second desiccant 16. The graph G3 shown by a dashed-dotted line shows the frequency distribution of the third minute dehumidifier 35 contained in the third desiccant 18.

The first microscopic dehumidifier 24 having the pores 26 of the first pore diameter D1 is included in the first desiccant 14. The second microscopic dehumidifier 32 having the pores 33 with the second pore diameter D2 smaller than the first pore diameter D1 is included in the second desiccant 16. The third microscopic dehumidifier 35 having the pores 36 with the third pore diameter D3 smaller than the second pore diameter D2 is included in the third desiccant 18. In the present invention, the number of desiccant is not limited to 2 or 3, and may be 4 (first to fourth desiccant) or more as necessary.

5 (a) to 5 (c) and FIG. 7, the adsorption amount of water in the first micro dehumidifier 24, the second micro dehumidifier 32, and the third micro dehumidifier 35. Explain. The graph shown in FIG. 7 shows the moisture adsorption amount of a dehumidifier on a vertical axis | shaft, and shows the relative humidity dependence characteristic of the adsorption moisture amount of the dehumidifier which taken relative humidity on the horizontal axis. The graph G4 shown by a broken line shows the relationship between the adsorption amount of the water of the first minute dehumidifier 24 included in the first desiccant 14 and the relative humidity. The graph G5 shown by the solid line shows the relationship between the adsorption amount of water and the relative humidity of the second minute dehumidifier 32 included in the second desiccant 16. The graph G6 shown by a dashed-dotted line shows the relationship between the adsorption amount of the water of the third microdehumidifier 35 included in the third desiccant 18 and the relative humidity.

As shown in the graph G4, the first minute dehumidifier 24 has a large adsorption amount of water in the region E1 having a high relative humidity. As shown in the graph G5, the second minute dehumidifier 32 has a large adsorption amount of water in the region E2 where the relative humidity is medium. As shown in the graph G6, the third minute dehumidifier 35 exhibits adsorption performance even in the region E3 having a low relative humidity, but the adsorption amount of moisture is relatively small, and even in a region where the relative humidity is high. The amount of adsorption does not increase. Here, the region E1 having a high relative humidity is a region where the relative humidity is higher than the relative humidity at the intersection of the graph G4 and the graph G5. The region E3 having a low relative humidity is a region where the relative humidity is lower than the relative humidity at the intersection of the graph G5 and the graph G6, and the region E2 having a medium relative humidity is an area of E1 and E3. In between.

Therefore, in the region E1 where the relative humidity is high, the moisture in the air can be efficiently adsorbed by adsorbing the moisture in the air with the first minute dehumidifier 24. Further, in the region E2 where the relative humidity is medium, the moisture in the air can be efficiently adsorbed by adsorbing the moisture in the air with the second minute dehumidifier 32. In the region E3 having a low relative humidity, moisture in the air can be adsorbed efficiently by the third microdehumidifier 35.

Returning to FIG. 1, in the interior 13 of the flow path 12, the first desiccant 14 is disposed adjacent to the upstream side of the second desiccant 16. The second desiccant 16 is disposed adjacent to the upstream side of the third desiccant 18.

Therefore, by flowing air having a high relative humidity from the upstream side of the flow passage 12 as shown by arrow A, the first minute dehumidifier 24 of the first desiccant 14 can efficiently adsorb moisture in the air. have.

Moisture in the air is adsorbed by the first microscopic dehumidifier 24 of the first desiccant 14, so that the relative humidity of the air flowing out of the first desiccant 14 is moderately suppressed. Medium relative humidity air flows from the first desiccant 14 to the second desiccant 16. Therefore, the second minute dehumidifier 32 of the second desiccant 16 can efficiently adsorb moisture in the air.

Moisture in the air is adsorbed by the second microscopic dehumidifier 32 of the second desiccant 16, so that the air flowing out from the second desiccant 16 is suppressed to a certain degree with a relatively low humidity. Lowly controlled relative humidity air is flowed from the second desiccant 16 to the third desiccant 18. Therefore, the third minute dehumidifier 35 of the third desiccant 18 can efficiently adsorb moisture in the air.

Thereby, the air which flowed out from the 3rd desiccant 18 like arrow B can be made into dry air.

On the other hand, in the case of removing the water adsorbed to the first micro dehumidifier 24, the second micro dehumidifier 32, and the third micro dehumidifier 35, the low relative humidity for regeneration from the downstream side of the flow path 12 is removed. Air (dry air) flows as shown by the arrow (C). By flowing the low relative humidity air to the third desiccant 18, the moisture adsorbed to the third microdehumidifier 35 can be efficiently contained in the air. That is, the water adsorbed by the 3rd small dehumidifier 35 can be removed efficiently.

The air flowing out from the third desiccant 18 has a relatively high relative humidity. By flowing the air having a relatively high relative humidity to the second desiccant 16, the moisture adsorbed to the second microdehumidifier 32 can be efficiently contained in the air. That is, the water adsorbed by the 2nd small dehumidifier 32 can be removed efficiently.

The air which flowed out from the 2nd desiccant 16 is moderately high in relative humidity. By flowing the air with moderately high relative humidity to the first desiccant 14, the moisture adsorbed to the first microdehumidifier 24 can be efficiently contained in the air. That is, the water adsorbed to the first micro dehumidifier 24 can be efficiently removed.

Air having a high relative humidity flowing out of the first desiccant 14 flows upstream as shown by arrow D. FIG.

Thereby, the water adsorbed by the 1st micro-humidifier 24, the 2nd micro-humidifier 32, and the 3rd micro-humidifier 35 can be removed, and the 1st micro-humidifier 24 and the 2nd micro-humidifier 32 are removed. ), The third minute dehumidifier 35 can be recycled in a reuse state.

In this way, the first desiccant 14, the second desiccant 16, and the third desiccant 18 are arranged in order from the upstream side to the downstream side, whereby the region having a relatively high relative humidity and a region having a low relative humidity is present. In the whole region up to, moisture in the air can be adsorbed efficiently. That is, the adsorptivity of the moisture of each of the micro dehumidifiers 24, 32, and 35 included in the first desiccant 14, the second desiccant 16, and the third desiccant 18 differs depending on the relative humidity in the air. It can be done.

Thereby, the desiccant device 10 for dehumidification can be made small compared with the desiccant device for dehumidification using the dehumidifier with the same porous diameter.

Next, the use example of the desiccant device 10 for dehumidification in FIG. 8A and FIG. 8B, FIG. 9A, and FIG. 9B is demonstrated.

As shown in FIG. 8A, in order to dehumidify the interior 53 of the factory 52 in the integrated air conditioning apparatus 50, air having a high relative humidity inside the factory 53 is supplied to the factory 52. It discharges to the exterior 54, and introduces air from the exterior 54 like arrow E. FIG.

In order to suitably remove moisture from the air introduced from the outside 54 in the air conditioning apparatus 50, the electricity consumption of the air conditioning apparatus 50 increases.

As shown in FIG. 8 (b), the dehumidification desiccant device 10 is subsequently installed on the upper portion 51 of the integrated air conditioning device 50 so as to be external to the dehumidification desiccant device 10. To induce air. Therefore, the moisture in the induced air can be adsorbed to the desiccant device 10 for dehumidification to remove moisture from the air. Thereby, dry air with low relative humidity can be blown from the desiccant device 10 for dehumidification through the piping 56 of the air conditioning apparatus 50 to the inside 53 of the factory 52. Therefore, dehumidification of the inside 53 of the factory 52 can be performed favorably.

As described above, the dehumidification desiccant device 10 for dehumidification is subsequently provided to the air conditioner 50, whereby the dehumidification function can be enhanced in a state in which electricity consumption is suppressed.

As shown in FIG. 9A, the air conditioner 60 is divided into an outdoor unit 61 and an indoor unit 62. Similarly to the integrated air conditioner 50, the split air conditioner 60 introduces air from the outside 54 in the same manner as the arrow F in the air conditioner 60.

In order to suitably remove moisture from the air introduced from the outside 54 in the air conditioning apparatus 60, the electricity consumption of the air conditioning apparatus 60 increases.

As shown in FIG. 9B, by dividing the air conditioner 60 into the outdoor unit 61 and the indoor unit 62, the outdoor unit 61 and the indoor unit 62 are compared with the integrated air conditioner 50. Becomes smaller. Since the dehumidification desiccant device 10 is compactly suppressed, for example, an area for subsequently installing the dehumidification desiccant device 10 on the upper part 63 of the indoor unit 62 can be secured. Thereby, the use of the desiccant device 10 for dehumidification can be expanded.

By subsequently installing the dehumidifying desiccant device 10 on the upper part 63 of the split type air conditioner 60, piping of the air conditioning device 60 from the desiccant device 10 for dehumidification is carried out. It is possible to blow into the interior 53 of the factory 52 via the 65. Thereby, the dehumidification function can be improved in the state which suppressed electricity consumption similarly to the integrated air conditioning apparatus 50 only by providing the dehumidifying desiccant device 10 for dehumidification in the air conditioning apparatus 60.

In addition, the technical scope of this invention is not limited to embodiment mentioned above, A various change can be added in the range which does not deviate from the meaning of this invention.

In the said embodiment, although the example provided with the 1st desiccant 14, the 2nd desiccant 16, and the 3rd desiccant 18 as the dehumidification desiccant apparatus 10 was limited to this. It doesn't work. As another example, only the first desiccant 14 and the second desiccant 16 may be provided. In addition, three or more desiccants may be provided as the desiccant device 10 for dehumidification.

In addition, in the said embodiment, although the sheet | seat 21, 31, 34 of the 1st-3rd desiccant 14, 16, and 18 was rolled up in a vortex shape, the example formed in the front view and demonstrated circularly, It is not limited to this. As another example, the first to third desiccant may be formed in a cube shape (cubic shape).

In this case, desiccant is formed, for example, by sandwiching a dehumidifying agent between flat meshes (mesh) and laminating the flat meshes at intervals in which air flows in the vertical direction.

In addition, in the said embodiment, although the example which fixed the dehumidification desiccant device 10 to the inside 13 of the flow path 12 was demonstrated, it is not limited to this. As another example, the dehumidifying desiccant device 10 may be rotatably provided in the interior 13 of the flow path 12.

In addition, in the said embodiment, about the example which hold | maintains each micro dehumidifier 24, 32, 35 inside each sheet 21, 31, 34 of the 1st-3rd desiccant 14, 16, 18. As shown in FIG. Although it demonstrated, it is not limited to this. As another example, the dehumidifying agent may be contained in the case so as to be movable, and the case may be configured to communicate a flow path with the case. By flowing air from the flow path in the case, the dehumidifying agent in the case flows into the air, and the air in the case can be brought into contact with the air evenly to adsorb moisture in the air with the dehumidifying agent.

In addition, in the said embodiment, although the 1st-3rd spacer dehumidifier 25, 37, 38 demonstrated the example which serves as a spacer and a dehumidifier, it is not limited to this. As another example, it is also possible to replace the first to third spacer dehumidifiers 25, 37, 38 with a member of the spacer only. As a result, for example, the degree of freedom in designing the first to third desiccants 14, 16, and 18 can be increased.

Although this invention was detailed also demonstrated with reference to the specific embodiment, it is clear for those skilled in the art that various changes and correction can be added without deviating from the mind and range of this invention.

This application is based on the JP Patent application 2017-029020 of an application on February 20, 2017, The content is taken in here as a reference.

10... … Desiccant device for dehumidification
14... … First Desiccant
16... … Second Desiccant
18... … Third Desiccant
21... … First sheet
23... … First spacer
24... … First microdehumidifier (dehumidifier)
25... … First spacer dehumidifier (spacer)
26, 33, 36... … Handwork
31... … Second sheet
32... … Second microdehumidifier (dehumidifier)
34... … Third sheet
35... … Third microdehumidifier (dehumidifier)
37... … Second spacer dehumidifier (spacer)
38... … Third spacer dehumidifier (spacer)
D1 to D3... First to third pore diameter

Claims (9)

Desiccant device for dehumidification including desiccant for adsorbing moisture in the air by flowing air,
The desiccant has at least a first desiccant and a second desiccant,
To make the adsorptivity of the dehumidifying agent contained in the first desiccant and the moisture of the dehumidifying agent contained in the second desiccant different depending on the relative humidity in the air,
Desiccant device for dehumidification. The dehumidifying agent of claim 1, wherein the dehumidifying agent contained in the first desiccant has a larger adsorption amount of water in a region having a higher relative humidity than the dehumidifying agent contained in the second desiccant,
The dehumidifying agent contained in the second desiccant has a larger adsorption amount of water in a region having a lower relative humidity than a region having a higher relative humidity than the dehumidifying agent contained in the first desiccant,
The first desiccant is arranged on the upstream side of the air flow direction than the second desiccant,
Desiccant device for dehumidification. The dehumidifying agent included in the first desiccant and the dehumidifying agent included in the second desiccant are porous dehumidifying agents according to claim 1 or 2,
The pore diameter of the porous dehumidifying agent contained in the first desiccant is
Larger than the pore diameter of the porous dehumidifying agent contained in the second desiccant,
Desiccant device for dehumidification. The method of claim 1, wherein the first desiccant and the second desiccant are each
The dehumidifying agent is held and is also wound in a spiral spaced apart sheet;
With a spacer to secure the gap of the sheet,
Desiccant device for dehumidification. The method of claim 4, wherein the spacer serves as a dehumidifying agent,
Desiccant device for dehumidification. The method of claim 4 or 5, wherein the sheet is a nonwoven fabric,
Desiccant device for dehumidification. The method according to claim 4 or 5, wherein the sheet is an adhesive sheet,
Desiccant device for dehumidification. The method of claim 6, wherein the dehumidifying agent is included in the nonwoven fabric,
Desiccant device for dehumidification. The method of claim 7, wherein the dehumidifying agent is attached to the adhesive sheet,
Desiccant device for dehumidification.

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