KR102587597B1 - Dehumidification rotor and Assembly structure of blower and heat exchanger connected to the dehumidification rotor - Google Patents

Abstract

The present invention improves the durability of the motor by lowering the load on the motor by reducing friction when the rotor rotates, and at the same time reduces power consumption, and provides a dehumidifying rotor that allows the blower and heat exchanger to be easily assembled in the dehumidifying rotor while maintaining airtightness. The purpose is to provide an assembly structure for the blower and heat exchanger connected to this.
The dehumidifying rotor of the present invention includes a rotor portion rotatable across a first passage through which a first fluid passes and a second passage through which a second fluid passes, and a rotor housing coupled to the outer surface; a driving unit that rotates the rotor unit; a case that partitions the first flow path and the second flow path and accommodates the rotor unit; and a first band coupled to the front and rear surfaces of the case, in contact with the outer surface of the rotor housing, and having a lubricating layer formed on the surface in contact with the rotor housing.

Description

Dehumidification rotor and assembly structure of blower and heat exchanger connected to the dehumidification rotor}

The present invention relates to an assembly structure of a dehumidification rotor and a blower and heat exchanger connected thereto. More specifically, it relates to an assembly structure that reduces friction on the contact surface when the dehumidification rotor rotates and allows the blower and heat exchanger to be easily assembled in the dehumidification rotor while maintaining airtightness. It relates to the assembly structure of a dehumidifying rotor and a blower and heat exchanger connected to it.

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

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

When the air conditioner is operated in a dehumidifying mode, moisture contained in indoor air is adsorbed in the first area of the dehumidifying rotor, and the adsorbed moisture is transferred to the air passing through the second area in the second area as the dehumidifying rotor rotates. It is released.

Generally, a dehumidifying rotor includes a rotor unit containing an absorbent material, a rotor housing coupled to an outer surface of the rotor unit, a motor for rotationally driving the rotor unit, a case accommodating the rotor unit, and a space between the case and the rotor housing. It is composed of a sealing member to maintain airtightness.

The conventional dehumidifying rotor had a problem in that when the rotor unit rotated, a large friction force was generated at the contact surface between the rotor housing and the sealing member, thereby increasing the load on the motor and thus increasing power consumption.

In addition, the conventional air conditioner has a structure in which the blower and heat exchanger connected to one side of the dehumidification rotor are assembled using separate fastening means such as screws, so it is not easy to assemble the blower and heat exchanger to the dehumidification rotor, and it is not easy to assemble the blower and heat exchanger to the dehumidification rotor. There was a problem in that airtightness was not maintained at the fastened area and leakage occurred, deteriorating the dehumidification performance of the air conditioner.

As an example of a conventional air conditioner, “Air conditioner and its control method” is disclosed in Republic of Korea Patent No. 10-1782838.

The present invention was developed to solve the above-mentioned problems, and its purpose is to provide a dehumidifying rotor that improves the durability of the motor and reduces power consumption by reducing friction during rotation of the rotor unit and lowering the load on the motor. There is.

Another object of the present invention is to provide an assembly structure for a dehumidification rotor and a blower and heat exchanger connected thereto, which allows the dehumidification rotor to be easily assembled with a blower and a heat exchanger while maintaining airtightness.

The dehumidifying rotor of the present invention for realizing the above-described purpose is rotatably provided across a first passage through which the first fluid passes and a second passage through which the second fluid passes, and has a rotor housing on the outer surface. Combined rotor unit; a driving unit that rotates the rotor unit; a case that partitions the first flow path and the second flow path and accommodates the rotor unit; and a first band coupled to the front and rear surfaces of the case, in contact with the outer surface of the rotor housing, and having a lubricating layer formed on the surface in contact with the rotor housing.

The lubricating layer may be made of Teflon tape.

The first band is made of a rubber material, and a second band made of metal may be coupled to the outer surface of the first band located around the rotor housing.

The assembly structure of the blower and heat exchanger connected to the dehumidification rotor of the present invention includes the dehumidification rotor; a blower connected to the first flow path and provided on one side of the dehumidifying rotor; a heat exchanger connected to the second flow path and provided on one side of the dehumidification rotor; a first flow guide provided between the dehumidifying rotor and the blower to form a flow path for the first fluid; a second flow path guide provided between the dehumidification rotor and the heat exchanger to form a flow path for the second fluid; a first sealing member interposed between the first flow guide and the blower to maintain airtightness and to allow the first flow guide and the blower to be assembled together; and a second sealing member interposed between the second flow path guide and the heat exchanger to maintain airtightness and to allow the second flow path guide and the heat exchanger to be assembled together.

A first coupling groove and a second coupling groove are formed on both sides of the first sealing member, and the blower is provided with a first coupling part formed with a first protrusion that fits into the first coupling groove of the first sealing member. , The first flow path guide may be provided with a second coupling portion formed with a second protrusion that is fitted into the second coupling groove of the first sealing member.

A plurality of fixing pins are protruding from one side of the first sealing member along the circumferential direction, and a plurality of fixing pin coupling grooves into which the plurality of fixing pins are fitted may be formed in the first coupling part of the blower. .

A coupling groove may be formed on one side of the second sealing member, and the second passage guide may be provided with a third coupling portion formed with a third protrusion that fits into the coupling groove of the second sealing member.

The second sealing member may be formed with a frame-shaped body that is in close contact with the front of the heat exchanger and an extension part that is in close contact with the bottom of the heat exchanger.

According to the assembly structure of the dehumidifying rotor and the blower and heat exchanger connected thereto according to the present invention, a lubricating layer is formed on the contact surface of the first band in contact with the rotor housing, thereby reducing friction during rotation of the rotor unit and lowering the load on the motor. Power consumption can be reduced.

According to the assembly structure of the blower and the heat exchanger connected to the dehumidification rotor according to the present invention, airtightness is maintained between the first passage guide provided between the dehumidification rotor and the blower and the first coupling part of the blower by the first sealing member. It can be assembled easily.

In addition, it can be easily assembled while maintaining airtightness between the second flow path guide provided between the dehumidification rotor and the heat exchanger and the heat exchanger by the second sealing member.

1 is a view showing a portion of an air conditioner in which a dehumidifying rotor and a blower and heat exchanger connected thereto are installed according to an embodiment of the present invention;
Figure 2 is a perspective view of a dehumidifying rotor according to the present invention;
Figure 3 is an exploded perspective view of Figure 2;
Figure 4 is a perspective view showing the dehumidification rotor and the blower and heat exchanger connected thereto combined according to the present invention;
Figure 5 is an exploded perspective view of Figure 4;
Figure 6 is a plan view of Figure 4;
Figures 7 and 8 are a cross-sectional view and a cross-sectional perspective view along line AA in Figure 4;
Figure 9 is a view showing the first sealing member and the second coupling portion of the blower being coupled by a fixing pin and a fixing pin coupling groove.

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. 1, the configuration of an air conditioner (1) equipped with a dehumidifying rotor and a blower and heat exchanger connected thereto according to an embodiment of the present invention will be described.

The air conditioner 1 has a main body 10 with a diaphragm 20 in between, a first flow path 30 is provided on one side of the diaphragm 20, and a first flow path 30 is provided on the other side of the diaphragm 20. 2 Euros (40) will be provided. In one embodiment, the first flow path 30 may be a dehumidifying flow path that allows indoor air introduced through the indoor ventilation (RA) to flow toward the indoor air supply (SA), and the second flow path 40 may be a regeneration flow path that allows outdoor air introduced through the outdoor air (OA) to flow toward the outdoor exhaust (EA). The second flow passage 40 on the exhaust (EA) side is provided with a regenerative blower 50 for sucking outdoor air.

The air conditioner (1) includes a dehumidifying rotor (100) that rotates across the first flow path (30) and the second flow path (40).

Referring to Figure 2, there is a rotor inside the dehumidifying rotor 100 that alternately passes through the first flow path 30 and the second flow path 40 by rotation to adsorb moisture or release the adsorbed moisture. A unit 110 is provided. The rotor unit 110 is provided with an absorbent material to absorb moisture therein.

When the air conditioner (1) is in the dehumidifying mode, the adsorbent located in the first flow path (30) adsorbs moisture contained in the indoor air passing through the first flow path (30). When the absorbent material that has adsorbed the moisture rotates and is located in the second passage 40, moisture is released into the outdoor air passing through the second passage 40, thereby dehumidifying the indoor air.

A blower 200 is provided on the first flow path 30 side of the dehumidification rotor 100 to suck indoor air, and on the second flow path 40 side of the dehumidification rotor 100, air flowing in through outside air (OA) is provided. A heat exchanger 300 is provided to heat outdoor air.

The outdoor air heated by the heat exchanger 300 causes the moisture adsorbed on the adsorbent of the rotor unit 110 passing through the second flow path 40 to be evaporated and released by heat, and is regenerated by drying the adsorbent. .

A first flow path guide 400 is provided between the dehumidification rotor 100 and the blower 200 to form a first flow path 30, and a second flow path guide is provided between the dehumidification rotor 100 and the heat exchanger 300. A second flow path guide 500 is provided to form the flow path 40.

Referring to FIGS. 1 to 3, the dehumidifying rotor 100 of the present invention is rotatable across a first passage 30 through which the first fluid passes and a second passage 40 through which the second fluid passes. It is provided on the outer surface and includes a rotor unit 110 coupled with a rotor housing 114, a driving unit 120 that rotates the rotor unit 110, and the first flow passage 30 and the second flow passage 40. It is partitioned and includes cases 130, 140, and 150 that accommodate the rotor unit 110.

A rotating shaft 113 is coupled to the center of the rotor unit 110, and a rotor housing 114 is coupled to the outer surface of the rotor unit 110. A gear portion 115 meshed with a belt 122, which will be described later, is formed in the rotor housing 114.

The driving unit 120 includes a motor 121 and a belt 122 that rotates by receiving power from the motor 121 and engages the gear unit 115 of the rotor housing 120.

The cases 130, 140, and 150 include a side case 130 surrounding the side of the rotor unit 110, and a front case 140 and a rear case 150 respectively coupled to the front and rear of the side case 130. It comes true.

The front case 140 includes a first plate 141 with openings S1' and S2' formed in the center, a first frame 142 dividing the openings S1' and S2' into two sides, and A first rotation shaft coupling portion 143 formed at the center of the other side of the first frame 142 and connected to one end of the rotation shaft 113 in a rotatable state, and a first band 160, which will be described later, are in close contact with each other. It is configured to include a first seating portion 144 and a through hole 145 on which the motor 121 is mounted.

The rear case 150 includes a second plate 151 with openings S1" and S2" formed in the center, and a second frame 152 dividing the openings S1" and S2" into two sides, A second rotation shaft coupling portion 153 formed at the center of one side of the second frame 152 and connected to the other end of the rotation shaft 113 in a rotatable state, and a first band 180, which will be described later, are in close contact with each other. It is configured to include a second seating portion 154.

In addition, the dehumidifying rotor 100 is coupled between the edge of one side 111 of the rotor unit 110 and the first seating part 144 of the front case 140 to maintain airtightness. 1 band 160, a second band 170 coupled to the outer surface of the first band 160 located around the rotor housing 114, and the other side 112 of the rotor unit 110 ) and the first band 180 for maintaining airtightness by being coupled between the edge portion of the rear case 150 and the second seating portion 154 of the rear case 150, and the first band 180 located around the rotor housing 114. It further includes a second band 190 coupled to the outer surface of the band 180.

Lubricating layers 161 and 181 are formed on the contact surfaces of the first bands 160 and 180 in contact with the rotor housing 114. In one embodiment, the lubricating layers 161 and 181 may be made of Teflon tape.

By forming the lubricating layers 161 and 181 on the first bands 160 and 180, when the rotor unit 110 rotates by the driving unit 120, the rotor housing 114 and the lubricating layers 161 and 181 are formed. The rotational friction force between the contact surfaces of the bands 160 and 180 can be minimized to lower the load on the motor 121, thereby reducing the power consumption of the motor 121.

The second bands 170 and 190 are configured to reinforce the rigidity of the first bands 160 and 180 made of rubber, and may be made of metal, preferably stainless steel.

Hereinafter, with reference to FIGS. 4 to 9, the assembly structure of the blower and the heat exchanger connected to the dehumidifying rotor of the present invention will be described.

The assembly structure of the blower 200 and the heat exchanger 300 connected to the dehumidification rotor 100 of the present invention is in communication with the above-described dehumidification rotor 100 and the first flow path 30, and the dehumidification rotor 100 a blower (200; 200a, 200b) provided on one side of a heat exchanger (300) connected to the second flow path (40) and provided on one side of the dehumidifying rotor (100), the dehumidifying rotor (100) and the blower A first flow path guide 400 provided between (200) to form a flow path for the first fluid, and a first flow path guide 400 provided between the dehumidifying rotor 100 and the heat exchanger 300 to form a flow path for the second fluid. 2 Passage guide 500, a first seal that is interposed between the first passage guide 400 and the blower 200 to maintain airtightness and to allow the first passage guide 400 and the blower 200 to be assembled together. A member 600, and a second member interposed between the second flow path guide 500 and the heat exchanger 300 to maintain airtightness and to allow the second flow path guide 500 and the heat exchanger 300 to be assembled together. It is configured to include a sealing member 700.

The blower 200 may be composed of dual blowers 200a and 200b, and a first coupling portion 210 for coupling with the first sealing member 600 is provided on the front of the blower 200.

The first flow path guide 400 includes a body 410 having an open front surface, a through hole 420 formed at the rear of the body 410 and communicating with the blowing path of the blower 200, and the through hole 420. It is formed on the body 410 around the sphere 420 and includes a second coupling portion 430 for coupling with the first sealing member 600.

The second flow guide 500 includes a body 510 having openings 520 formed on the front and rear sides, and a second sealing member 700 formed around the rear surface of the body 510 for coupling to the second sealing member 700. It is composed of three coupling portions 530.

A first coupling groove 611 and a second coupling groove 612 are formed on both sides of the first sealing member 600. A first protrusion 211 that is fitted into the first coupling groove 611 of the first sealing member 600 is formed on the first coupling portion 210 of the blower 200. A second protrusion 431 that is fitted into the second coupling groove 612 of the first sealing member 600 is formed on the second coupling portion 430 of the first flow guide 400.

In addition, as shown in FIG. 9, a plurality of fixing pins 613 are formed to protrude along the circumferential direction on one side of the first sealing member 600, and the first coupling portion 210 of the blower 200 ) is formed with a plurality of fixing pin coupling grooves 212 into which the plurality of fixing pins 613 are fitted.

A coupling groove 711 is formed on one side of the second sealing member 700, and a third channel is fitted into the coupling groove 711 of the second sealing member 700 in the second flow path guide 500. A third coupling portion 530 in which a protrusion 531 is formed is provided.

The second sealing member 700 includes a frame-shaped body 710 in close contact with the front 310 of the heat exchanger 300, and an extension part in close contact with the bottom 320 of the heat exchanger 300 ( 730) is formed.

According to the assembly structure of the blower 200 and the heat exchanger 300 connected to the dehumidifying rotor 100 of the present invention configured as described above, as shown in FIGS. 7 and 8, the first sealing member 600 By this, the first coupling part 210 of the blower 200 and the second coupling part 430 of the first flow path guide 400 can be easily assembled in an airtight state by fitting, and the second sealing The front 310 and bottom 320 of the heat exchanger 300 and the third coupling portion 530 of the second flow path guide 500 are easily maintained in an airtight state by fitting together by the member 700. Can be assembled.

Therefore, compared to the prior art, the blower 200 and the heat exchanger 300 connected to the dehumidifying rotor 100 can be easily assembled by fitting and pressing without the need for separate fastening means such as screws, and the airtight state is firmly maintained. You can.

As described 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: air conditioner 10: main body
20: plate 30: first euro
40: Second flow path 50: Regenerative blower
100: dehumidifying rotor 110: rotor unit
111: Front of rotor unit 112: Rear of rotor unit
113: rotation axis 114: rotor housing
115: gear unit 120: driving unit
121: motor 122: belt
130: side case 140: front case
141: first plate 142: first frame
143: first rotation shaft coupling portion 144: first seating portion
145: Through hole 150: Rear case
151: second plate 152: second frame
153: Second rotation shaft coupling portion 154: Second seating portion
160,180: 1st band (rubber band) 170,190: 2nd band (stainless steel band)
171,191: Lubricating layer (Teflon tape) S1', S1": First opening
S2', S2": Second opening 200, 200a, 200b: Blower
210: first coupling portion 211: first protruding portion
212: fixing pin coupling groove 300: heat exchanger
310: Front of heat exchanger 320: Bottom of heat exchanger
400: 1st Euro Guide 410: Body
420: Through hole 430: Second coupling portion
431: second protrusion 500: second flow guide
510: body 520: opening
530: third coupling portion 531: third protrusion portion
600: first sealing member 610: body
611: first coupling groove 612: second coupling groove
613: fixing pin 700: second sealing member
710: Body 711: Coupling groove
720: opening 730: extension

Claims (8)

delete delete delete It is provided to be rotatable across a first passage through which the first fluid passes and a second passage through which the second fluid passes, a rotor unit coupled to a rotor housing on the outer surface, a drive unit for rotating the rotor unit, and A case that divides the first flow path and the second flow path and accommodates the rotor unit, is coupled to the front and back of the case, is in contact with the outer surface of the rotor housing, and has a lubricating layer on the surface in contact with the rotor housing. A dehumidifying rotor including a formed first band;
a blower connected to the first flow path and provided on one side of the dehumidifying rotor;
a heat exchanger connected to the second flow path and provided on one side of the dehumidification rotor;
a first flow guide provided between the dehumidifying rotor and the blower to form a flow path for the first fluid;
a second flow path guide provided between the dehumidification rotor and the heat exchanger to form a flow path for the second fluid;
a first sealing member interposed between the first flow guide and the blower to maintain airtightness and to allow the first flow guide and the blower to be assembled together; and
a second sealing member interposed between the second flow path guide and the heat exchanger to maintain airtightness and to allow the second flow path guide and the heat exchanger to be assembled together;
Including,
A first coupling groove and a second coupling groove are formed on both sides of the first sealing member,
The blower is provided with a first coupling portion formed with a first protrusion that fits into the first coupling groove of the first sealing member,
The first flow path guide is provided with a second coupling portion formed with a second protrusion that fits into the second coupling groove of the first sealing member,
A coupling groove is formed on one side of the second sealing member,
An assembly structure of a blower and a heat exchanger connected to a dehumidifying rotor, wherein the second flow path guide is provided with a third coupling portion formed with a third protrusion that is fitted into the coupling groove of the second sealing member. According to paragraph 4,
An assembly structure of a blower and a heat exchanger connected to a dehumidifying rotor, wherein the lubricating layer is made of Teflon tape. According to paragraph 4,
A plurality of fixing pins are protruding from one side of the first sealing member along the circumferential direction,
An assembly structure of a blower and a heat exchanger connected to a dehumidifying rotor, characterized in that a plurality of fixing pin coupling grooves into which the plurality of fixing pins are fitted are formed in the first coupling part of the blower. According to paragraph 4,
The first band is made of a rubber material,
An assembly structure of a blower and a heat exchanger connected to a dehumidifying rotor, characterized in that a second band made of metal is coupled to the outer surface of the first band located around the rotor housing. According to paragraph 4,
An assembly structure of a blower and a heat exchanger connected to a dehumidifying rotor, wherein the second sealing member is formed with a frame-shaped body that is in close contact with the front of the heat exchanger and an extension part that is in close contact with the bottom of the heat exchanger.

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