KR102620428B1 - Dehumidification rotor - Google Patents

Abstract

The purpose of the present invention is to provide a dehumidifying rotor that improves assemblyability and minimizes manufacturing costs by simplifying the assembly structure by reducing the number of parts while maintaining the same function and performance by sharing the parts for rotating the rotor. there is.
The present invention to implement this is provided to be rotatable across spatially separated first and second spaces, and absorbs moisture contained in the fluid passing through one of the first and second spaces. , a rotor provided to rotate in the remaining one of the first space and the second space to release the absorbed moisture; It includes a pair of rotor housings that support and couple to both sides of the rotor, have the same circular structure, and are assembled to each other in symmetrical positions.

Description

Dehumidification rotor

The present invention relates to a dehumidifying rotor, and more specifically, to a dehumidifying rotor that has the same function and performance and can simplify the assembly structure by sharing the parts for driving the rotor.

In general, an air conditioner is a device that maintains a comfortable indoor environment by controlling indoor temperature and humidity or ventilating indoor air according to the user's needs.

Recently, technologies have been developed that add various functions such as dehumidification, humidification, air purification, and ventilation to air conditioners to maintain comfortable indoor air according to seasonal changes according to the user's choice.

Referring to FIG. 1, the dehumidifying rotor 1 provided in a conventional air conditioner is a rotary rotor that is spatially separated and rotatable across two spaces through which different fluids pass, and includes an absorbent material for adsorbing moisture. (10), a core 20 coupled to the center of the rotor 10, and a connector 30 and bearing 40 coupled to both sides of the core 20, respectively, coupled to both sides of the rotor 10. A pair of press frames 50 supporting the rotor 10 and having a semicircular structure, eight spokes 60 radially coupled to the upper and lower parts on the inside of the pair of press frames 50, A first support frame 70 coupled to the upper circumference of the pair of press frames 50 and having a gear portion 71 formed on the outer peripheral surface for transmitting the driving force of a motor (not shown), and the pair of presses It is configured to include a second support frame 80 coupled to the lower circumference of the frame 50.

The pair of press frames 50 are assembled by bolts 21 penetrating the flange portions 51 formed at each circumferential end, and nuts 22 coupled to the bolts 21, and the spokes (60) is assembled to the press frame (50) using fastening means such as rivets.

In the conventional dehumidifying rotor (1) configured in this way, a pair of press frames (50), a plurality of spokes (60), and a first support frame (70) and a second support frame (80) are manufactured as separate parts. It is configured to be mutually assembled using fastening means such as bolts, nuts, and rivets. According to this assembly structure, the number of parts for rotating the rotor 10 is excessive, which makes the assembly structure complex, assembly quality is low, the assembly cost of the dehumidification rotor 1 increases, and productivity decreases. As the weight of the rotor 1 becomes heavier, the rotational torque increases, causing a problem in that the durability of the rotor 10 and the parts that rotate together with it is reduced.

In addition, the pair of press frames 50 each have a semicircular structure and are assembled by fastening each circumferential end, so that the assembly of the pair of press frames 50 is subject to manufacturing tolerances and assembly. The accuracy of the roundness is reduced due to the tolerance, and in this case, noise, appearance deformation, and gap leakage occur when the rotor 10 rotates, causing a problem in that the performance of the dehumidifying rotor 1 is deteriorated.

On the other hand, in the case of products with specifications of a large diameter and thickness of the dehumidifying rotor that have been developed recently, the fluid passing through the dehumidifying space and the fluid passing through the regeneration space pass through the inside of the dehumidifying rotor (1), respectively. ) There is a problem in that heat exchange efficiency and ventilation capacity are reduced due to leakage occurring not only in the lateral direction but also in the circumferential direction. However, in the prior art, mixing between fluids due to leakage of fluid passing through the inside of the dehumidifying rotor is guaranteed. The structure to prevent this from happening is insufficient.

The prior art related to the conventional dehumidifying rotor is disclosed in Patent Registration No. 10-1170389.

The present invention was developed to solve the above-mentioned problems. By commonizing the parts for driving the rotor to rotate, the assembly structure is simplified by reducing the number of parts while maintaining the same function and performance, thereby improving assembling and minimizing manufacturing costs. The purpose is to provide a dehumidifying rotor that allows this.

The dehumidifying rotor of the present invention for realizing the above-described purpose is rotatable across a spatially separated first space and a second space, and passes through one of the first space and the second space. a rotor provided to absorb moisture contained in the fluid and rotate to the remaining one of the first space and the second space to release the absorbed moisture; It includes a pair of rotor housings that support and couple to both sides of the rotor, are made of an integrated structure of the same circular shape, and are assembled to each other in symmetrical positions, wherein the pair of rotor housings includes a circular rotor housing body, and It includes first fastening parts and second fastening parts formed alternately at regular intervals in the circumferential direction on one side of the rotor housing body, and a first fastening part formed on the first rotor housing located on one side of the pair of rotor housings; The second fastening part is characterized in that it is fastened to each other at positions corresponding to the second fastening part and the first fastening part formed in the second rotor housing located on the other side of the pair of rotor housings.

The pair of rotor housings may be configured to be assembled together in a fitting manner.

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One of the first fastening portion and the second fastening portion may be a hook portion, and the other one of the first fastening portion and the second fastening portion may be configured as a hook engaging portion that is fastened by engaging the hook portion.

On one side of the rotor housing body, first protrusions and second protrusions are formed alternately at regular intervals in the circumferential direction, and one of the first fastening portion and the second fastening portion is formed on the first protrusion, The remaining one of the first fastening part and the second fastening part may be formed on the second protrusion.

The first rotor housing and the second rotor housing include a first protrusion formed on the first rotor housing corresponding to a second protrusion formed on the second rotor housing, and a second protrusion formed on the first rotor housing corresponding to the second protrusion formed on the first rotor housing. It may be configured to be mutually assembled at a position corresponding to the first protrusion formed on the rotor housing.

On the outer peripheral surface of the rotor housing body, a gear portion coupled with a motor gear coupled to the rotation shaft of the motor that provides driving force for rotation of the rotor may be formed integrally.

A core is provided at the center of the rotor, inside which a rotation axis forming the rotation center of the rotor is accommodated, and a plurality of insertion grooves are formed at predetermined depths in the front and rear directions on both sides of the core at regular intervals in the circumferential direction, The pair of rotor housings includes a circular rotor housing body, a hub provided at the inner center of the rotor housing body, and both ends supported by the rotor housing body and the hub and inserted into the insertion groove of the core to couple them. It may be configured to include a plurality of spokes provided radially.

a housing in which the first space and the second space are formed, the housing having a frame dividing the first space and the second space, and accommodating the rotor; It may further include a first leak-prevention member to prevent leakage in the lateral direction between the rotor and the housing, and a second leak-prevention member to prevent leakage in the circumferential direction between the rotor and the housing. .

The pair of rotor housings includes a first rotor housing provided on one side of the rotor and a second rotor housing provided on the other side of the rotor and assembled to the first rotor housing, the housing comprising: It may be comprised of a first housing provided on one side of the first rotor housing, and a second housing provided on the other side of the second rotor housing and coupled to the first housing.

The first leak prevention member is spaced apart on both sides between a first frame provided in the first housing and one side of the rotor, and between a second frame provided in the second housing and the other side of the rotor. It is provided in a double position along the longitudinal direction, and the second leak prevention member may be provided in a circular shape between the first housing and the first rotor housing, and between the second housing and the second rotor housing. there is.

According to the dehumidifying rotor according to the present invention, a pair of rotor housings that support and couple with both sides of the rotor are manufactured in the same circular structure and are assembled together in symmetrical positions, thereby reducing the number of parts for rotating the rotor and achieving dehumidification. By simplifying the assembly structure of the rotor, assembly can be improved and manufacturing costs can be minimized, and the durability of the dehumidifying rotor can be extended by reducing the weight of the product and reducing rotational torque.

In addition, the rotor housing is manufactured in a circular, integrated structure to improve circularity, thereby preventing noise, appearance deformation, and gap leakage occurring during rotor rotation, contributing to improving the performance of the dehumidifying rotor.

In addition, by providing a leak prevention member to block leakage in the lateral and circumferential directions between the rotor and the housing, mixing between the first fluid and the second fluid that are exchanged by the rotating rotor is prevented, thereby improving heat exchange efficiency and dehumidification performance. can be improved.

1 is an exploded perspective view of a dehumidifying rotor according to the prior art;
Figure 2 is a cross-sectional view showing a portion of an air conditioner equipped with a dehumidifying rotor according to the present invention;
Figure 3 is a perspective view of a dehumidifying rotor according to the present invention;
Figure 4 is an exploded perspective view of Figure 3;
Figure 5 is an exploded perspective view of the rotor, first and second rotor housings, hub, and first and second bearings;
Figure 6 is a perspective view showing the first rotor housing and the second rotor housing assembled on the core;
7 is a view for explaining the assembly structure of the first rotor housing and the second rotor housing;
Figure 8 is a perspective view showing the first rotor housing and the second rotor housing assembled;
Figure 9 is a front view of the assembly in which the rotor, first and second rotor housings, hub, and first and second bearings are assembled;
Figure 10 is a cross-sectional view along line AA of Figure 9;
Figure 11 is a cross-sectional view along line BB in Figure 9;
Figure 12 is a front view of Figure 3;
Figure 13 is a cross-sectional view along line CC of Figure 12;
Figure 14 is a cross-sectional view taken along line DD in Figure 12.

Hereinafter, the structure and operation of a preferred embodiment of the present invention will be described in detail with reference to the attached drawings.

First, with reference to FIG. 2, some configurations of an air conditioner equipped with a dehumidifying rotor 100 according to the present invention will be described. The air conditioner has a main body 210 with a diaphragm 220 in between, a regeneration passage 230 is formed on one side of the diaphragm 220, and a dehumidification passage 240 is formed on the other side of the diaphragm 220. is formed.

In the regeneration passage 230, the first fluid flows into one side of the regeneration passage 230, passes through the first space S1 of the dehumidification rotor 100, and flows to the other side of the regeneration passage 230. A first blower 250 for pressure feeding, and a heater 260 for heating the first fluid flowing into one side of the regeneration passage 230 and supplying it to the first space (S1) of the dehumidification rotor 100. It can be provided.

In the dehumidification passage 240, the first fluid flows into the other side of the dehumidification passage 240, passes through the second space S2 of the dehumidification rotor 100, and flows to one side of the dehumidification passage 240. A second blower 270 may be provided to pump the air.

The dehumidifying rotor 100 of the present invention is a rotary rotor 110 that rotates across a first space (S1) communicating with the regeneration passage 230 and a second space (S2) communicating with the dehumidifying passage 240. ) includes. Total heat exchange occurs between the first fluid passing through the regeneration passage 230 and the second fluid passing through the dehumidification passage 240 by the dehumidification rotor 110.

As the first fluid and the second fluid pass through the rotating rotor 110, total heat exchange occurs between the two fluids due to the heat absorption and heat dissipation action of the rotor 110, and are included in the second fluid passing through the dehumidifying space 240. After the moisture is absorbed into the rotor 110 located in the second space (S2), when the rotor 110 rotates from the second space (S2) to the first space (S1), the rotor (110) The absorbed moisture is evaporated and released by the heated first fluid passing through the regeneration space 230, thereby dehumidifying the second fluid, and at the same time, the rotor 110 located in the first space S1 absorbs moisture again. It is regenerated in a state where it can be absorbed.

2 to 14, the dehumidifying rotor 100 of the present invention is rotatable across a spatially separated first space (S1) and a second space (S2), and the first space (S1) ) and the second space (S2) by absorbing the moisture contained in the fluid passing through one of the first space (S1) and the second space (S2) and rotating the absorbed moisture into the remaining one of the first space (S1) and the second space (S2). It includes a rotor 110 provided to emit light, a pair of rotor housings 140-1, 140-2 that are coupled to support both sides of the rotor 110, have the same circular structure, and are assembled to each other in symmetrical positions. It is composed by: In addition, the dehumidifying rotor 100 includes housings 150 and 160 that accommodate an assembly in which the rotor 110 and a pair of rotor housings 140-1 and 140-2 are combined, and the rotor 110 and the housings 150 and 160. It is configured to include leak prevention members 170 and 180 to prevent leakage in the lateral and circumferential directions.

The rotor 110 is configured to rotate by driving a motor 190 around rotating axes 153 and 163 provided in the center, and includes an adsorbent for adsorbing moisture contained in the air. A penetrating portion 111a is formed in the front and rear direction at the center of the rotor body 111 of the rotor 110, and a cylindrical core 120 is inserted and coupled to the penetrating portion 111a. On the front part of the rotor body 111, a first groove 112 of a predetermined depth is formed radially in the front-back direction, and on the rear part of the rotor body 111, there is a front-back direction corresponding to the first groove 112. A second groove 112 of a predetermined depth is formed. Spokes 144 provided in a pair of rotor housings 140-1 and 140-2 are inserted and coupled to the first groove 112 and the second groove 112.

Referring to FIG. 6, on both sides of the cylindrical core body 121 of the core 120, a plurality of first insertion grooves 122 and second insertion grooves 123 are provided in the front-back direction at regular intervals in the circumferential direction. It is formed to a predetermined depth, and the spoke 144 is inserted and coupled to the first insertion groove 122 and the second insertion groove 123.

The pair of rotor housings 140-1 and 140-2 have the same structure and are configured to be assembled together by a fitting method, and include a first rotor housing 140-1 coupled to one side of the rotor 110, and , It consists of a second rotor housing (140-2) coupled to the other side of the rotor (110). The first rotor housing 140-1 and the second rotor housing 140-2 support the rotor 110 and rotate together with the rotor 110 by driving the motor 190.

In one embodiment, the first rotor housing (140-1) and the second rotor housing (140-2) include a circular rotor housing body (141) and a circumferential direction on one side of the rotor housing body (141). It includes first fastening parts 146 and second fastening parts 147 formed alternately at regular intervals.

7 to 11, the first fastening part 146 and the second fastening part 147 formed in the first rotor housing 140-1 are formed in the second rotor housing 140-2. It is configured to be fastened to the second fastening part 147 and the first fastening part 146, respectively. In one embodiment, the first fastening portion 146 and the second fastening portion 147 may be formed alternately at 90° intervals on one side of the rotor housing body 141. One of the first fastening parts 146 and the second fastening parts 147 is a hook part 146, and the other one of the first fastening parts and the second fastening parts is fastened by being caught by the hook part 146. It may be composed of a hook engaging portion 147.

On one side of the rotor housing body 141, first protrusions 145-1 and second protrusions 145-2 are formed alternately at regular intervals in the circumferential direction, and the first protrusions 145-1 One of the first fastening part 146 and the second fastening part 147 is formed, and one of the first fastening part 146 and the second fastening part 147 is formed on the second protrusion 145-2. The remaining one is formed. The first protrusion 145-1 and the second protrusion 145-2 may be formed on one side of the rotor housing body 141 at 90° intervals in the circumferential direction.

In this case, the first rotor housing (140-1) and the second rotor housing (140-2) have a first protrusion (145-1) formed on the first rotor housing (140-1). It corresponds to the second protrusion 145-2 formed in (140-2), and the second protrusion 145-2 formed in the first rotor housing 140-1 is connected to the second rotor housing 140-2. It may be configured to be mutually assembled at a position corresponding to the first protrusion 145-1 formed in .

That is, as shown in FIGS. 7 and 8, the first rotor housing 140-1 and the second rotor housing 140-2 have the same structure, and when assembled to each other, the first rotor housing (140-1) The rotor housing body 141 of 140-1 is arranged to face rearward, the rotor housing body 141 of the second rotor housing 140-2 is arranged to face forward, and the first rotor housing ( The first protrusion 145-1 and the second protrusion 145-2 formed on the second rotor housing 140-1 are the second protrusion 145-2 and the first protrusion 145 formed on the second rotor housing 140-2. -1) are assembled in a mutually fitting manner at the positions where they are in contact with each other.

Meanwhile, on the outer peripheral surface of the rotor housing body 141, a gear portion 142 coupled with a motor gear 191 coupled to the rotation axis of the motor 190 that provides driving force for rotation of the rotor 110 is integrated. It is formed by

At the inner center of the rotor housing body 141, a hub 143 is provided with a through hole 143a through which the rotation axes 153 and 163 (see FIG. 13) pass, and the inner surface of the rotor housing body 141 and A plurality of spokes 144 arranged radially are provided between the outer surfaces of the hub 143.

As such, in the present invention, the pair of rotor housings (140-1, 140-2) have the same structure, and the rotor housing body (141), gear portion (142), hub (143), and spokes (144) are integrated into one body. Since it is formed, compared to the structure in the prior art in which the press frame 50, the spokes 60, the first support frame 70, and the second support frame 80 are separated and assembled together, the rotor 110 ) By reducing the number of parts to rotate and drive the dehumidification rotor (100), the assembly structure of the dehumidification rotor (100) can be simplified to improve assembly and minimize manufacturing costs, and the weight of the product can be reduced to reduce rotational torque, thereby reducing the dehumidification rotor (100). ) can extend its durability.

In addition, by manufacturing the rotor housing (140-1, 140-2) as a circular integrated structure to improve circularity, unlike the case in the prior art where the press frame 50 is manufactured as a pair of semi-circular structures and assembled together, the rotor housing (140-1, 140-2) is manufactured as a circular integrated structure to improve circularity. This can contribute to improving the performance of the dehumidifying rotor 100 by preventing noise, appearance deformation, and gap leakage occurring during operation.

Hereinafter, the configuration of the housings 150 and 160 and the leakage prevention members 170 and 180 will be described.

The housings 150 and 160 include a first housing 150 provided on one side of the first rotor housing 140-1 and a first housing 150 provided on the other side of the second rotor housing 140-2 ( It consists of a second housing 160 coupled to 150).

The first housing 150 includes a first body 151 with openings S1' and S2' formed in the center, a first frame 152 dividing the openings S1' and S2' into two sides, and , and includes a first shaft portion 153 extending from the center of the other side of the first frame 152 to the other side.

The second housing 160 includes a second body 161 with openings S1" and S2" formed in the center, a second frame 162 dividing the openings S1" and S2" into two sides, and , It includes a second shaft portion 163 that extends from the center of one side of the second frame 162 to one side and is coupled to the first shaft portion 153. A fastening protrusion 153a is formed at the end of the first shaft portion 153, and a fastening groove 163a into which the fastening protrusion 153a is inserted and coupled is formed at the end of the second shaft portion 163.

Referring to FIG. 13, the first shaft portion 153 and the second shaft portion 163 have a through hole 143a formed in the hub 143 of the first rotor housing 140-1 and the second rotor housing 140, respectively. -2) are mutually fitted inside the core 120 through the through hole 143a formed in the hub 143. As a configuration for smooth rotation of the first shaft portion 153 and the second shaft portion 163, a first bearing ( 130-1) is coupled, and a second bearing 130-2 is coupled between the second shaft portion 163 and the hub 143 of the second rotor housing 140-2. The first shaft portion 153 and the second shaft portion 163 form the rotation center of the rotor 110 and support the rotor 110 in a rotatable state.

Referring to Figures 4 and 14, the leakage prevention members 170 and 180 are first leakage prevention members 170;170-1,170- for preventing lateral leakage between the rotor 110 and the housings 150 and 160. 2,170-3, 170-4) and a second leak prevention member (180; 180-1, 180-2) to prevent leakage in the circumferential direction between the rotor 110 and the housing 150, 160.

The first leak prevention member (170; 170-1, 170-2, 170-3, 170-4) is between the first frame 152 provided in the first housing 150 and one side of the rotor 110, and the second housing. A first part 171 and a second part 172 respectively provided between the second frame 162 provided at 160 and the other side of the rotor 110 and separated in a straight line, and the first part 172 It consists of a third part 173 provided to partially overlap one side of the spaced portion between the first part 171 and the second part 172.

The first frame 152 and the second frame 162 have first leakage prevention member seating portions 154-1,154 for fixing and supporting the first leakage prevention member (170; 170-1,170-2, 170-3, 170-4). -2,164-1,164-2) is formed. The first leak prevention member seating portion (154-1, 154-2, 164-1, 164-2) is the first part (171) and the second part of the first leak prevention member (170; 170-1, 170-2, 170-3, 170-4). It consists of a first seating part (154a), a second seating part (154b), and a third seating part (154c) on which the (172) and third parts (173) are seated, respectively.

The first leak prevention members (170; 170-1, 170-2, 170-3, 170-4) may be provided in duplicate along the longitudinal direction at positions spaced apart from each other on both sides. In this way, when the first leak prevention members (170; 170-1, 170-2, 170-3, 170-4) are provided in duplicate, leakage of the first and second fluids in the lateral direction is double blocked, thereby forming the first space (S1). ) and the second space (S2) can be reliably prevented from being mixed with fluid.

The second leak prevention member (180; 180-1, 180-2) is between the first housing 150 and the first rotor housing (140-1), and between the second housing 160 and the second rotor. Each is provided in a circular shape between the housings 140-2.

In a configuration corresponding to this, the first housing 150 and the second housing 160 have second leakage prevention member seating portions 155 and 165 for fixing and supporting the second leakage prevention member (180; 180-1, 180-2). ) is formed.

Both ends of the first leak prevention member (170;170-1,170-2,170-3,170-4) are configured to be in close contact with the inner surface of the second leak prevention member (180;180-1,180-2). In this way, the first leak prevention member (170;170-1,170-2,170-3,170-4) and the second leak prevention member (180;180-1,180-2) are configured to be in close contact with each other, so that the first fluid and the second fluid Since it is possible to block leakage in the lateral and circumferential directions at the same time, the heat exchange efficiency and dehumidification performance of the dehumidification rotor 100 can be improved by preventing mixing of the first fluid and the second fluid.

In one embodiment, the leakage prevention members 170 and 180 may be made of a brush material. The brushes are provided at close intervals to prevent leakage. In this way, if the leak prevention members (170, 180) are made of a brush material, it is possible to prevent the generation of dust due to friction and wear that may occur when using a general sealing member made of a conventional synthetic resin material such as rubber, thereby preventing the dehumidification rotor (100 ) and thereby prevent indoor air pollution, as well as the first and second housings (150,160), the rotor (110), and the first and second rotor housings (140-1,140) that are in contact with the leakage prevention members (170,180). -2) Friction on the contact surface can be reduced, thereby lowering the load applied to the motor 190, which has the effect of reducing power consumption.

As explained above, the present invention is not limited to the above-described embodiments, and obvious modifications can be made by those skilled in the art without departing from the technical spirit of the present invention as claimed in the claims. It is possible, and such modifications fall within the scope of the present invention.

1: dehumidifying rotor 10: rotor
20: core 21: bolt
22: nut 30: connector
40: Bearing 50: Press frame
51: Flange portion 60: Spoke
70: first support frame 71: gear unit
80: second support frame 100: dehumidification rotor
110: rotor 111: rotor body
111a: Penetrating part 112: First groove
113: second groove 120: core
121: Core body 122: First insertion groove
123: Second insertion groove 130-1: First bearing
130-2: Second bearing 140-1: First rotor housing
140-2: Second rotor housing 141: Rotor housing body
142: gear unit 143: hub
143a: Through hole 144: Spoke
145-1: first protrusion 145-2: second protrusion
146: Hook portion (first fastening portion) 147: Hook engaging portion (second fastening portion)
150: first housing 151: first body
152: first frame 153: first axis part
153a: Fastening protrusion 154-1, 154-2: First leak prevention member seating portion
154a: Part 1 154b: Part 2
154c: Third part 155: Second leak prevention member seating part
160: second housing 161: second body
162: 2nd frame 163: 2nd axis part
163a: Fastening groove 164-1, 164-2: First leak prevention member seating portion
164a: Part 1 164b: Part 2
164c: Third part 165: Second leakage prevention member seating part
170,170-1,170-2,170-3,170-4: First leak prevention member
180,180-1,180-2: Second leak prevention member 190: Motor
191: motor gear 210: main body
220: plate 230: regeneration channel
240: Dehumidifying oil path 250: 1st blower
260: heater 270: second blower
S1: First space S2: Second space
S1',S2',S1",S2": Opening

Claims (11)

It is rotatably provided over a spatially separated first space and a second space, and absorbs moisture contained in a fluid passing through one of the first space and the second space. a rotor provided to rotate into the remaining space and release the absorbed moisture;
A pair of rotor housings that support and couple to both sides of the rotor, have the same circular integrated structure, and are assembled to each other in symmetrical positions;
Including,
The pair of rotor housings includes a circular rotor housing body, and first fastening parts and second fastening parts formed alternately at regular intervals in the circumferential direction on one side of the rotor housing body,
The first fastening part and the second fastening part formed in the first rotor housing located on one side of the pair of rotor housings are connected to the second fastening part formed in the second rotor housing located on the other side of the pair of rotor housings. A dehumidifying rotor characterized in that it is fastened to each other at positions corresponding to each part. According to paragraph 1,
A dehumidifying rotor, characterized in that the pair of rotor housings are assembled together by a fitting method. delete According to paragraph 1,
A dehumidifying rotor, characterized in that one of the first fastening portion and the second fastening portion is a hook portion, and the other one of the first fastening portion and the second fastening portion is a hook engaging portion that is fastened by engaging the hook portion. According to paragraph 1,
On one side of the rotor housing body, first protrusions and second protrusions are formed alternately at regular intervals in the circumferential direction,
A dehumidifying rotor, characterized in that one of the first fastening part and the second fastening part is formed on the first protrusion, and the other one of the first fastening part and the second fastening part is formed on the second protrusion. According to clause 5,
The first rotor housing and the second rotor housing include a first protrusion formed on the first rotor housing corresponding to a second protrusion formed on the second rotor housing, and a second protrusion formed on the first rotor housing corresponding to the second protrusion formed on the first rotor housing. A dehumidifying rotor characterized in that it is mutually assembled at a position corresponding to the first protrusion formed on the rotor housing. According to paragraph 1,
A dehumidifying rotor, characterized in that the outer peripheral surface of the rotor housing body is formed integrally with a gear part coupled with a motor gear coupled to the rotation axis of a motor that provides driving force for rotation of the rotor. According to paragraph 1,
A core is provided at the center of the rotor, in which a rotation axis forming the rotation center of the rotor is accommodated inside,
On both sides of the core, a plurality of insertion grooves are formed at predetermined depths in the front-back direction at regular intervals in the circumferential direction,
The pair of rotor housings includes a circular rotor housing body, a hub provided at the inner center of the rotor housing body, and both ends supported by the rotor housing body and the hub and inserted into the insertion groove of the core to couple them. A dehumidifying rotor comprising a plurality of radially provided spokes. According to paragraph 1,
a housing in which the first space and the second space are formed, the housing having a frame dividing the first space and the second space, and accommodating the rotor; and
A dehumidifying rotor further comprising a first leak-prevention member for preventing leakage in a lateral direction between the rotor and the housing, and a second leak-prevention member for preventing leakage in a circumferential direction between the rotor and the housing. According to clause 9,
The pair of rotor housings includes a first rotor housing provided on one side of the rotor, and a second rotor housing provided on the other side of the rotor and assembled to the first rotor housing,
The housing is a dehumidifying rotor, characterized in that it consists of a first housing provided on one side of the first rotor housing, and a second housing provided on the other side of the second rotor housing and coupled to the first housing. According to clause 10,
The first leak prevention member is spaced apart on both sides between a first frame provided in the first housing and one side of the rotor, and between a second frame provided in the second housing and the other side of the rotor. It is provided in duplicate along the longitudinal direction at the location,
The second leak prevention member is a dehumidifying rotor, characterized in that it is provided in a circular shape between the first housing and the first rotor housing, and between the second housing and the second rotor housing.

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