KR100958391B1 - Dehumidifier - Google Patents

Abstract

The dehumidifier of the present invention includes a dehumidifying rotor including a main body having a dehumidifying flow path through which indoor air is inhaled and dehumidified and a regenerating flow path through which regenerated air flows, a dehumidifying part dehumidifying the indoor air, and a regenerating part regenerated using the regenerated air; And a condensation heat exchanger in which a plurality of heat exchange plates formed with a plurality of condensation passages through which the regenerated air passing through the regeneration unit is sucked upward and discharged downward are disposed in parallel. Therefore, according to the present invention, the flow in the condensation heat exchanger is uniform, the heat exchange area is widened, so that the dehumidification performance of the dehumidifier is improved, and the noise when driving the dehumidifier is reduced.

Dehumidifier, condensation heat exchanger, heat exchange plate, regenerated air inlet, regenerated air outlet

Description

Dehumidifier {Dehumidifier}

The present invention relates to a dehumidifier, and more particularly, to a dehumidifier that improves a heat exchange efficiency by improving a flow path of a condensation heat exchanger that cools regenerated air, and improves a flow of a flow inside the condensation heat exchanger.

In general, the dehumidifier may be classified into a dehumidifier using a cooling cycle and a dehumidifier using a desiccant rotor according to an operation method.

In the case of a dehumidifier using a cooling cycle, a compressor must be provided, and the noise of the compressor and the problem of securing a space in which the compressor is located, etc., and a dehumidifier using a desiccant rotor has been widely used in recent years.

Desiccant rotor has the property of adsorbing moisture in the air, dehumidifying while passing the room air through the desiccant rotor, and is based on the principle of regenerating desiccant adsorbed with moisture using high temperature air.

Here, the air regenerated by the desiccant rotor becomes hot and humid, and the hot and humid air is discharged to the outside. However, when the high temperature and high humidity air is discharged to the outside, even if the dehumidifier is located on the exterior of the building or indoors, there is a problem that a separate exhaust duct should be provided.

Therefore, when circulating the hot and humid air in which the desiccant is regenerated inside the dehumidifier, it is not necessary to provide a separate exhaust duct. In addition, the location of the dehumidifier has the advantage that the user can be placed in the desired position.

In order to circulate the high temperature and high humidity air, it is necessary to remove the moisture of the high temperature and high humidity air, and thus condensation heat exchange that can generally remove the high temperature and high humidity moisture in the space between the indoor air inlet and the desiccant rotor. A group is provided. That is, the humidity is reduced by the principle of condensing moisture inside the hot humid air by exchanging the hot humid air with the normal temperature air.

Therefore, in order to increase the heat exchange efficiency of the condensation heat exchanger, the shape of the flow path inside the condensation heat exchanger is very important. Therefore, the heat exchange area is increased by using a plurality of heat exchange plates in order to increase the heat exchange area.

However, the conventional condensation heat exchanger has a problem that the flow of the flow inside the condensation heat exchanger is not uniform even though the heat exchange area is increased by using a plurality of heat exchange plates.

An object of the present invention for solving the above problems is to provide a dehumidifier capable of uniformly flowing the flow while increasing the heat exchange area of the condensation heat exchanger by connecting a plurality of heat exchange plates in parallel.

Another object of the present invention is to provide a heat exchanger which makes the flow of air inside the condensation heat exchanger uniform by varying the area of regenerated air inlets of the plurality of heat exchange plates.

Still another object of the present invention is to provide a dehumidifier for forming a regenerated air flow path of the condensation heat exchanger differently according to the position of the regenerated air discharge part to make the flow inside the condensation heat exchanger uniform.

The dehumidifier according to the present invention for solving the above problems is a main body having a dehumidification passage in which indoor air is sucked and dehumidified and a regeneration passage through which regenerated air flows, a dehumidifying unit for dehumidifying the indoor air, and regeneration using the regeneration air. And a dehumidification rotor including a regeneration unit, and a plurality of heat exchange plates formed with a plurality of heat exchange plates formed with a plurality of condensation passages through which the regeneration air passing through the regeneration unit is sucked upward and discharged downward.

Regeneration air inflow portions through which the regeneration air passing through the dehumidification rotor flows are formed on the plurality of heat exchange plates, and the plurality of regeneration air inflow portions communicate with each other.

On the other hand, the regeneration air inlet is formed in a shape that is wider in proportion to the distance to the center 222a of the condensation heat exchanger facing the position of the regeneration unit and corresponding to the center of the dehumidification rotor.

The regeneration air inlet may be formed in a fan shape. In addition, the regeneration unit may be located in the upper center of the dehumidification rotor.

The regeneration air inlet may be formed in a shape in which the lower end of the point spaced apart from the center 222a of the condensation heat exchanger is shielded. Furthermore, the dehumidification rotor may include a rotating part for rotating the dehumidifying rotor at the center, and the shielded shape may be shielded against the shape of the rotating part.

The area of the regeneration air inlet may be formed to become smaller along the regeneration air inlet direction.

The regeneration air inlet of the second or more heat exchanger plate in a direction in which regeneration air is introduced among the plurality of heat exchanger plates has a streamline shape that is long in the left and right direction on the upper surface of the condensation heat exchanger.

On the other hand, the lower left and right surfaces of the plurality of heat exchange plates, respectively, the regeneration air discharge portion through which the regeneration air passing through the dehumidification rotor is formed.

The regeneration unit may be formed at a position rotated at an angle toward the far side from the regeneration air discharge unit.

In addition, the regeneration air inlet of the second or more heat exchanger plates in a direction in which the regeneration air is introduced among the plurality of heat exchanger plates is formed in a streamline shape that is long in the left and right direction on an upper surface of the condensation heat exchanger, and the regeneration air inlet portion of the streamline is As the distance from the regeneration air outlet increases, the area becomes wider.

Finishing module according to the present invention having the above configuration has the following effects.

First, each regeneration air inlet of the heat exchanger plates connected in parallel is connected to make the flow of air inside each heat exchanger plate uniform, thereby making the flow of air inside the condensation heat exchanger uniform. Therefore, there is an advantage that can improve the dehumidification performance, and reduce the noise caused by the flow of regeneration air.

Second, there is an advantage that the position of the regenerated air discharge portion of the condensation heat exchanger is formed at the periphery of the condensation heat exchanger to maximize the heat exchange area and to slim down the size of the dehumidifier.

Third, by varying the area of the lower space according to the position of the regeneration air outlet, or by forming a variety of positions of the regeneration air inlet, it is possible to maintain a uniform flow in the condensation heat exchanger.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the embodiments, the same name and the same reference numerals are used for the same configuration, and additional description thereof will be omitted.

First embodiment

1 is a perspective view of a dehumidifier according to a first embodiment of the present invention, Figure 2 is an exploded perspective view of the main part of the dehumidifier of FIG.

1 and 2, the overall configuration of the dehumidifier according to the first embodiment of the present invention will be described.

As shown in FIG. 1, the dehumidifier according to the present embodiment sucks indoor air, absorbs moisture, and then discharges dehumidified indoor air, and the air suction unit 4 and the air discharge unit are disposed on the main body 2. (6) is formed.

As shown in FIG. 2, the main body 2 includes a base 10, a rear case 20 coupled to a rear portion of the base 10, and a front case 30 disposed in front of the rear case 20. ) And a front panel 40 coupled to the front case 30.

The base 10 forms a bottom surface of the main body, and is provided with a wheel assembly 11 including a wheel and a wheel support rotatably supported by the wheel so as to assist the movement of the dehumidifier. The wheel assembly is mounted on the base 10 with a fastening member such as a screw.

The rear case 20 forms the rear appearance of the dehumidifier. The rear case 20 is provided with an air discharge part 6 through which the indoor air dehumidified in the main body 2 is discharged to the outside of the main body 2.

The front case 30 forms the front side of the dehumidifier. The front case 30 has an air suction hole 35 through which indoor air is sucked into the body 2. In addition, a control unit 36 having a control unit for driving and operating a dehumidifier and a display unit for displaying information of the dehumidifier is provided in the upper plate part of the front case 30.

The front panel 40 forms a front appearance of the dehumidifier, and an air intake unit 4 through which indoor air is sucked into the air intake hole 35 of the front case 30, in particular, is formed.

That is, the indoor air passes through the air suction part 4 of the front panel 40 and the air suction hole 35 of the front case 30, and is sucked into the main body 2, and dehumidified within the main body 2. After that, it is discharged to the outside through the air discharge portion 6 of the rear case 20.

The front panel 40 is clogged in front to improve the appearance of the dehumidifier front, and the air intake 6 is formed outside the front.

Inside the main body 2, a blower 50, a dehumidification rotor 60, a regeneration fan 90, a regeneration heater 100, and a condensation heat exchanger 200 are provided.

The blower 50 is a type of dehumidifying fan that sucks indoor air through the air suction unit 4 and passes through the main body 2 to be discharged to the air discharge unit 6. A fan housing 53 having an open rear surface, an air suction hole formed at a front surface thereof, and a discharge portion opening at an upper portion thereof, a fan motor 54 installed at one of the fan housing 53 and the rear case 20, and a fan. And a fan 55 (hereinafter, referred to as a dehumidifying fan) that is connected to the rotating shaft of the motor 54 and rotates between the fan housing 53 and the rear case 20. The fan housing 53 may be provided with a discharge grille in the discharge portion.

The dehumidifying rotor 60 is absorbed in the indoor air sucked by the blower 50 and is capable of low temperature regeneration. The dehumidifying rotor 60 is installed between the blower 50 and the condensation heat exchanger 200.

The dehumidification rotor 60 has a desiccant 61 which is capable of adsorbing moisture in the indoor air while allowing indoor air to pass through, and a low temperature regeneration, and a desiccant wheel which surrounds the desiccant 61 and fixes the desiccant 61. 62).

The desiccant 61 is wound to be formed in a disk shape as a whole, and a fixing hole 63 for fixing is formed at the center.

The desiccant 61 is wound in a cylindrical shape alternately between flat and corrugated paper made of ceramic fibers, and meso silica (Meso-Silica (SiO2)) has a very developed pore and surface area, so it has excellent hygroscopic properties and a low temperature of about 60 ° C. or less. Also included is a nano carbon ball (NCB: Nano caboon ball) that can be regenerated, that is, moisture removal.

The nano carbon ball (NCB) is composed of a spherical hollow core part and a mesoporous carbon cell part, and is a spherical carbon structure having a diameter of 200 nm to 500 nm, having a pore of 2 nm to 50 nm, and a surface area of BET and Mesopore than that of conventional activated carbon. There is no pore blockage because of the large area.

On the other hand, the desiccant 61 is a portion (hereinafter referred to as the 'adsorption unit') where the water is adsorbed while passing the indoor air when rotated, and a portion where the moisture is evaporated while the regeneration air passes (hereinafter referred to as 'regeneration unit') Is alternately changed to absorb / evaporate moisture. The regeneration portion is generally formed in a fan shape.

The desiccant 61 may be a regeneration unit through which regeneration air passes through a portion facing the regeneration heater 100, and may be an adsorption unit through which indoor air passes, except for a portion facing the regeneration heater 100.

The desiccant wheel 62 is formed in a ring shape to surround the circumference of the desiccant 61, a fixing part to which the desiccant 61 is fixed, and an edge part and a fixing part to connect the edge part and the fixing part. And a radially formed connection therebetween.

Inside the main body 2, a rotor supporter 68 rotatably supporting the dehumidifying rotor 60 and a rotor frame 69 on which the rotor supporter 68 is mounted are arranged.

The rotor frame 69 is a kind of barrier that divides the inside of the main body 2 into the rear space where the blower 50 is disposed and the front space where the condensation heat exchanger 200 is disposed, and the rotor frame 69 is a rotor. A through portion 75 through which the supporter 68 penetrates is formed in front of the air suction hole of the blower 50.

The rotor frame 69 has an opening in front of the regeneration fan 90 that communicates the regeneration fan 90 with the duct 280 that allows air to flow into the regeneration fan 90. And the rotor frame 69 is formed with a control unit installation unit 79 is provided with a control unit 78 for controlling the dehumidifier.

On the other hand, the dehumidifier according to the present embodiment further includes a dehumidification rotor motor 87 for rotating the dehumidification rotor (60).

The regeneration fan 90 allows air for regeneration of the dehumidification rotor 60 (hereinafter referred to as regeneration air) to be blown to the dehumidification rotor 60, and rotates in the fan housing 91 and the fan housing 91. A fan 92 possibly arranged, an orifice 93 installed in the fan housing 91 to guide the air sucked by the fan 92, and a fan 92 installed in the fan housing 91 to rotate the fan 92. The fan motor 94 is included.

The regeneration heater 100 heats the air blown to the dehumidification rotor 60 by the regeneration fan 90 so that high temperature air is supplied to the dehumidification rotor 60, and the heat transfer heater 101 and the heat transfer heater 101. ) And a heater cover 102 in communication with the regeneration fan 90, and a blocking film 103 coupled to the heater cover 102 so as to be positioned between the heater cover 102 and the dehumidifying rotor 60.

The blocking film 103 is a kind of air guide that prevents air heated by the heater 101 from being moved between the heater 101 and the dehumidifying rotor 60 toward the dehumidifying rotor 60 without leaking around. Or it is formed in semi-circle shape, and the opening part is formed in the surface which faces the dehumidification rotor 60.

The condensation heat exchanger 200 is to allow the regenerated air that has regenerated the dehumidifying rotor 60 to be condensed by heat exchange with the indoor air sucked by the blower 50, and a plurality of heat exchange plates 220, 240, 260 It is arranged back and forth in the indoor air suction direction.

The condensation heat exchanger 200 is a heat absorption passage 232 through which the condensation passages 226, 246 and 266 through which the regenerated air regenerated the dehumidifying rotor 60 passes and the indoor air sucked by the blower 50 pass. 252 and 272 are formed. And the condensation heat exchanger 200 is made of a synthetic resin material for the ease of molding of the condensation passage 226, 246, 266.

The detailed configuration of each condensation heat exchanger 200 will be described in detail below.

3 is a perspective view of the condensation heat exchanger 200 of the present invention, FIG. 4 is a rear view of FIG. 3, FIG. 5 is a sectional plan view of FIG. 3, and FIG. 6 is an exploded perspective view of FIG. 3.

3 and 6, the structure of the condensation heat exchanger 200 of the first embodiment will be described.

The dehumidifier of the present invention includes a condensation heat exchanger 200 for removing moisture from the regenerated air. And the condensation heat exchanger 200 of the present embodiment includes a plurality of heat exchange plates 220, 240, 260 and the duct 280.

Hereinafter, the structures of the heat exchange plates 220, 240, 260 and the duct 280 will be described, and the coupling of the entire condensation heat exchanger 200 and the flow of air will be described.

In the present embodiment, the plurality of heat exchange plates 220, 240, 260 serves to remove moisture in the regenerated air by condensing the regenerated air that has passed through the regeneration part of the dehumidification rotor. The heat exchange plates 220, 240, and 260 include a first heat exchange plate 220, a second heat exchange plate 240, and a third heat exchange plate 260. However, the number of heat exchange plates may be variously provided according to the state of the regenerated air.

The first heat exchange plate 220 includes a first regeneration air inlet 222, a first regeneration air communication unit 234, a plurality of first condensation passages 226, a plurality of first endothermic passages 232, and a first The lower space 230a, the first condensed water discharge unit 230, and the first regeneration air discharge unit 224.

The first regenerated air inlet 222 has an opening formed at a surface on which the regenerated air flows from the first heat exchange plate 220 so that regenerated air passing through the regenerated part of the dehumidification rotor 60 flows into the condensation heat exchanger 200. It serves as an inlet.

Specifically, the first regeneration air inlet 222 is formed to face the position of the regeneration unit of the dehumidification rotor 61 and is widened in proportion to the distance from the center 222a of the condensation heat exchanger. Here, the center 222a of the condensation heat exchanger refers to a position on the condensation heat exchanger 200 corresponding to the center of the desiccant 61.

In general, the dehumidification rotor 60 is made of a circular shape and dehumidify the indoor air while rotating, made of a structure that is regenerated by regenerated air. Therefore, the regeneration unit in which the regeneration air regenerates the desiccant 61 is generally formed in a fan shape. As a result, when the first regenerated air inlet 222 of the first heat exchange plate 220 is formed to correspond to the shape of the regenerated part, suction of the regenerated air is facilitated. Therefore, the flow of the regeneration air in the condensation heat exchanger 200 becomes uniform, and the condensation efficiency of the regeneration air can be increased.

Meanwhile, the regeneration unit of the desiccant 61 may be formed at various positions on the circular desiccant 61. However, in this embodiment, the regeneration unit is located at the upper center of the desiccant 61. In addition, the first regeneration air inlet 222 is located at the upper center of the first heat exchange plate 220 correspondingly. Therefore, the regenerated air introduced through the first regenerated air inlet 222 may be uniformly distributed and flow into the plurality of first condensation passages 226 described later.

The first regenerated air communication unit 234 is formed in the first heat exchange plate 220 on the opposite side of the surface on which the first regenerated air inlet 222 is formed. And it communicates with the second regeneration air inlet 242 to be described later. A part of the regenerated air introduced through the first regenerated air inlet 222 is discharged to the second regenerated air inlet 242 of the second heat exchange plate 240 which will be described later.

The first regenerated air communication unit 234 may be formed in the same shape to face the first regenerated air inlet 222. As a result, the flow of the regenerated air can be guided in a straight line, so that the flow of the regenerated air is made uniform. In this case, at least one of the shapes of the second regeneration air inlet 242, the second regeneration air communication unit 254, and the third regeneration air inlet 262, which will be described later, may be used as the first regeneration air inlet 222. It may be formed in the same shape as opposed to. In addition, the first, second and third regenerated air inlets 222, 242 and 262 and the first and second regenerated air communication units 234 and 254 may be formed to decrease in area according to the advancing direction of the regenerated air. Can be. Therefore, it is possible to increase the heat exchange area between the regenerated air and the indoor air while smoothly flowing the regenerated air.

However, in the present exemplary embodiment, the first regenerated air communication unit 234 is formed in a streamline shape that is long in the left and right directions corresponding to the shape of the upper edge portion of the first heat exchanger plate 220. That is, since the shape and position of the second regeneration air inlet 242 to be described later are opposed to each other, the regeneration air may flow from the first heat exchange plate 220 to the second heat exchange plate 240 well.

The plurality of first condensation passages 226 may have a tubular shape that is long in the longitudinal direction. In addition, an inlet 226a into which regenerated air is introduced and an outlet 226b discharged are formed.

The plurality of first condensation passages 226 serves to heat-exchange the air excluding the air flowed to the second heat exchange plate 240 among the regenerated air introduced through the first regenerated air inlet 222.

The position of the inlet portion 226a of each first condensation passage may be variously formed according to the position of the first regeneration air inlet portion 222. However, in the present embodiment, the first regeneration air inlet 222 has a fan shape. Thus, the inlet 226a is located on the line extending from the line of the radial radius 222b. Therefore, the air introduced through the first regeneration air inlet 222 may be well flowed down along the first condensation passage 226.

In addition, the first condensation flow passages 226 formed at both ends of the first condensation flow passage 226 may have a radius because the regeneration air may not be easily introduced when the position of the inlet portion 226a is on the radial radius 222b line. 222b is positioned on the line bent downward on the line. As a result, the line where the inlets 226a are positioned is formed to be similar to 'M' as a whole.

Meanwhile, a baffle flow path 228 may be formed between the first condensation flow paths 226. In the first condensation passage 226, a plurality of rows in the vertical direction are located in parallel on the plane.

When the first regeneration air outlet 224, which will be described later, is located at the lower left and right sides of the circumference of the condenser, a difference in distance between the plurality of first condensation passages 226 and the first regeneration air discharge unit 224 may vary. Occurs. Therefore, a difference in flow distance occurs until the regenerated air introduced into the first regenerated air inlet 222 passes through the plurality of first condensation passages 226 and is discharged to the first regenerated air discharged part 224. Therefore, an imbalance in the flow of the entire regeneration air flowing through the first heat exchange plate 220 occurs.

Therefore, when the baffle flow path 228 is formed to communicate between the first condensation flow paths formed at a position close to the first regeneration air discharge portion 224, the first regeneration air discharge portion 224 is formed at a position close to the first regeneration air discharge portion 224. The regeneration air flowing through the condensation passage can be slowed down. Therefore, the overall flow of the regenerated air flowing through the first heat exchanger plate can be made uniform.

Meanwhile, although the baffle flow path 228 may be formed in various ways, in this embodiment, the baffle flow path and the baffle flow path connecting the entire first condensation flow path 226 while passing through the center 222a of the first heat exchange plate A pair of baffle flow paths connecting only the first condensation flow path of a portion corresponding to the upper and lower portions is formed.

An outlet portion 226b is formed at the lower end of the first condensation passage 226, respectively. Then, the air passing through the first condensation passage 226 is discharged through the plurality of outlets 226b. The outlets 226b may be arranged in various shapes. That is, it may be disposed in a straight line, or may be disposed on a line inclined upward based on the first condensed water discharge unit 230 to be described later.

The plurality of first heat absorbing passages 232 are formed between the plurality of first condensing passages 226.

The plurality of first heat absorbing passages 232 are formed between the plurality of first condensing passages 226 in the front and rear directions. The regenerated air of high temperature and high humidity flows from the top to the bottom of the first condensation passage 226. In addition, indoor air flows through the plurality of first endothermic passages 232. Therefore, moisture in the regenerated air is condensed by heat exchange between regenerated air of high temperature and high humidity and indoor air period at room temperature.

The first lower space 230a is formed between the plurality of outlet parts 226b and the first regeneration air discharge part 224 and forms a lower end of the first heat exchanger plate. And it receives the air passing through the plurality of outlets 226b serves to discharge to the first regeneration air outlet (224).

Meanwhile, a first condensed water discharge part 230 is formed in the first lower space 230a to discharge moisture condensed in the first condensed flow path 226 to the first lower space 230a and then discharged to the outside.

The lower surface of the first lower space 230a is inclined upwardly from the first condensate discharge part in order to discharge the condensed water to the first condensate discharge part 230 well.

The first regeneration air discharge unit 224 serves as an outlet through which the air passing through the first lower space 230a is discharged to the outside. And it is formed on one side of the peripheral portion of the first heat exchange plate (220). Therefore, the overall thickness of the condensation heat exchanger 200 can be reduced, and the appearance of the dehumidifier can be reduced.

In detail, in the present exemplary embodiment, the first regeneration air discharge part 224 is formed at the lower left and right circumferences of the first heat exchange plate 220.

The second heat exchange plate 240 is positioned on the rear surface of the first heat exchange plate 220 in the regeneration air inflow direction so that the regenerated air passing through the first heat exchange plate 220 can pass therethrough. And the overall configuration and function is similar to the first heat exchange plate 220. Hereinafter, the difference from the first heat exchange plate 220 will be described. Unexplained symbols, the second condensate outlet 250 and the third condensate outlet 270 has the same structure and function as the first condensate outlet 230. In addition, since the second lower space 250a and the third lower space 270a have the same structure and function as the first lower space 230a, detailed description thereof will be omitted.

The second heat exchange plate 240 has the same structure and configuration as that of the first heat exchange plate 220, but the second regeneration air inlet 242 and the second condensation passage 246 are configured differently.

The second regeneration air inlet 242 has an opening formed at a surface on which the regeneration air flows into the second heat exchange plate 240. And it communicates with a 1st regeneration air communication part. Therefore, a part of the regeneration air introduced into the first heat exchange plate 220 serves as an inlet.

As described above, the plurality of condensate flow passages are composed of the lower portion of the area occupied by the regeneration air inlet to guide the flow of the regeneration air in the vertical direction. Therefore, when the area of the regeneration air inlet is large, the area of the condensation passage is inevitably reduced, and thus the heat exchange efficiency of the entire condensation heat exchanger is reduced.

Therefore, unlike the first regenerated air inlet 222, the second regenerated air inlet 242 of the present embodiment is formed in a streamline shape that is long in the left and right directions along the shape of the upper periphery of the second heat exchanger plate. That is, they are formed in the same shape as the first regenerated air communication unit and communicate with each other. As a result, the area of the second condensation passage, which will be described later, increases, thereby increasing the heat exchange area between the indoor air and the regenerated air.

And when the second regeneration air outlet 244 to be described later is located at the bottom left and right of the circumference of the second heat exchange plate 240, the imbalance of the flow of regeneration air flowing through the second heat exchange plate 240 described above Therefore, the area formed by the second regeneration air inlet 242 may be wider as the distance from the second regeneration air outlet 244 is farther. Therefore, the flow of the regeneration air flowing through the second heat exchange plate 240 can be induced uniformly.

The plurality of second condensation passages 246 have a tubular shape that is long in the longitudinal direction. In addition, an inlet 246a into which regenerated air is introduced and an outlet 246b discharged are formed.

The plurality of second condensation passages 246 serve to heat-exchange the air excluding the air flowed to the third heat exchange plate 260 of the regenerated air introduced through the second regenerated air inlet 242.

The position of the inlet portion 246a of each second condensation passage may be variously formed corresponding to the position of the second regeneration air inlet portion 242. However, in the present embodiment, the second regeneration air inlet 242 is formed in a streamline shape that is long in the left and right directions as described above. The inlet portion 246a is positioned on the streamlined lower end line and has a gentle curved shape with the middle portion raised as a whole.

Therefore, the area formed by the second condensation passage 246 is larger than the area formed by the first condensation passage 226. Therefore, the heat exchange area of the second heat exchange plate 240 is larger than the heat exchange area of the first heat exchange plate 220.

Meanwhile, the baffle flow path 228 may be formed in the second condensation flow path 246 like the first condensation flow path 226, and the structure and the position of the outlet portion 246b are also configured in the same way.

The third heat exchange plate 260 is located on the rear surface of the second heat exchange plate 240 in the regeneration air inflow direction so that a part of the regeneration air passing through the second regeneration air inlet 242 may be introduced. And the overall configuration and function is similar to the second heat exchange plate 240.

In detail, the third heat exchange plate 260 is the same as the second heat exchange plate 240 except that the second regeneration air communication unit 254 is not formed. Specifically, all of the regenerated air introduced into the third heat exchange plate 260 through the second regenerated air communication unit 254 without heat exchange in the second heat exchange plate 240 is heat exchanged in the third heat exchange plate 260. Therefore, the third regenerated air communication unit is not formed in the third heat exchange plate 260 at a position corresponding to the third regenerated air inlet 262. The regenerated air introduced through the third regenerated air inlet 262 is all introduced into the plurality of third condensed flow paths 266.

And other components are formed in the same manner as the second heat exchange plate 240 below. Specifically, since the inlet part 266a and the outlet part 266b have the same structure and function as the inlet part 246a and the outlet part 246b of a 2nd heat exchange board, detailed description is abbreviate | omitted.

The duct 280 serves to flow the air discharged through the regeneration air discharge unit 224, 244, 264 to the regeneration fan 90. Therefore, the regeneration air discharge unit 224, 244, 264 and the regeneration fan 90 may be made in the form of a tube. The regeneration air discharge unit 224, 244, 264 and the regeneration fan 90 may be formed in various shapes and configurations.

Specifically, the present embodiment has an inlet portion having a size that can accommodate all of the regenerated air discharge portions 224, 244 and 264, and the inlet portion is fitted with each of the regenerated air discharge portions 224, 244 and 264. Are combined into a bond. And it is formed long in the vertical direction in parallel with the left or right peripheral portion of the condensation heat exchanger.

And it may be formed while contacting the left or right peripheral portion of the condensation heat exchanger (200). However, in the present embodiment, it is formed spaced apart by a predetermined interval. Accordingly, endothermic flow passages 232, 252, and 272 are formed between the outermost condensation passages forming the periphery of the condensation heat exchanger 200 among the plurality of condensation passages 226, 246, and 266.

Looking at the condensation process and the indoor air dehumidification process of the regeneration air of the first embodiment of the present invention configured as described above are as follows.

First, the regeneration air circulates through the regeneration path by the rotation of the regeneration fan 90. That is, the regenerated air passing through the regeneration fan 90 is heated in the regenerated heater 100 to increase the temperature. The high temperature regenerated air regenerates the regenerated portion of the dehumidifying rotor 60 and flows into the first regenerated air inlet 222 of the condensation heat exchanger 200.

Part of the air introduced into the first recycled air inlet 222 flows into the first condensed flow path 226, and the rest of the air flows into the second recycled air inlet 242 through the first recycled air communication unit 234. Inflow. Part of the air introduced into the second recycled air inlet 242 flows into the second condensed flow path 246, and the remaining portion of the air is introduced into the third recycled air inlet 262 through the second recycled air communication unit 254. It flows into the third condensation passage 266 through.

The regenerated air flowing into the first condensing passage 226, the second condensing passage 246, and the third condensing passage 266 flows downward along each condensing passage 226, 246, 266, and each condensation passage. Heat exchange with the indoor air of the endothermic passages 232, 252, and 272 intersecting the passages 226, 246, 266 is performed.

In the heat exchange process, moisture in the regenerated air is condensed, and the condensed water passes through each condensation passage 226, 246, 266 through the condensed water outlets 230, 250, 270 formed in the lower space. It flows into the drain pan 140.

The regenerated air that has passed through the condensation passages 226, 246, and 266 passes through the regenerated air outlets 224, 244, and 264 through the lower spaces 230a, 250a, and 270a, respectively. 280). Then, it is introduced into the regeneration fan 90 connected with the duct 280, passes through the regeneration heater 100, and circulates while regenerating the regeneration unit of the dehumidification rotor 60 again.

The indoor air is sucked into the air intake unit 4 of the main body 2 by the rotation of the blower 50. The heat exchanger is exchanged with the regeneration air while passing through the endothermic passages 232, 252 and 272 of the condensation heat exchanger 200.

The moisture contained in the indoor air is adsorbed while passing through the adsorption unit of the desiccant 61. The indoor air from which moisture is removed is passed through the blower 50 and discharged into the room through the air discharge unit 6.

Second embodiment

7 is a perspective view of a second embodiment of the present invention.

7, the overall configuration of a second embodiment of the present invention will be described. The second embodiment of the present invention is similar in overall construction to the first embodiment. Hereinafter, a description will be given focusing on the differences of the second embodiment.

The first regeneration air inlet 322 of the second embodiment of the present invention is shielded a portion spaced apart from the center 322a of the condensation heat exchanger by a predetermined distance. The dehumidifying rotor 60 has a rotating part in the center, and thus, regenerated air does not flow into the first regenerated air inlet 322 through the part where the rotating part is located. Therefore, the part of the first regeneration air inlet 322 in which the rotating part of the dehumidification rotor is located. In addition, the height of the first condensation passages 326 of the shielded portion may be increased to increase the area where the regenerated air exchanges with the indoor air. Specifically, the inlet portion 326a of the first condensation passage is located on the shielding line 322c of the shielded portion.

On the other hand, the lower portion of each condensation passage 332 is located in a straight line. The lower space 330a is formed at the lower end of the condensation passage 332 and each of the heat exchange plates 320, 340, 360. In this embodiment, the lower space 330a on the side where the regenerated air discharge unit 224 is located is increased to smoothly flow the regenerated air. Specifically, the wider the lower space 330a, the lower the pressure, so that the speed of the regenerated air on the condensation passage is relatively reduced. And the narrower the lower space (330a) the higher the pressure, the faster the speed of regeneration air on the condensation passage. As a result, the flow of the regenerated air is smoothly induced by uniformly inducing the flow of speed according to the distance from the regenerated air outlet 224.
The outlet 326b, which is not described, has the same structure and function as the outlet 226b of the first embodiment, the radius 322b is the same as the radius 222b of the first embodiment, and the lower space ( Since 330 has the same structure and function as the lower space 230 of the first embodiment, detailed description thereof will be omitted.

Third embodiment

Fig. 8 is a plan sectional view of a third embodiment of the present invention.

Referring to Fig. 8, the overall configuration of the third embodiment of the present invention will be described. The first embodiment of the present invention is similar in overall construction to the first embodiment. Hereinafter, a description will be given focusing on the differences of the third embodiment.

On the other hand, when the regeneration air outlets 224, 244, 264 are located on the left and right sides of the condensation heat exchanger, an imbalance may occur in the flow of air flowing through the condensation passage. Specifically, the regenerated air that has passed through the condensation passages 426, 446, and 466 located near the regenerated air outlets 224, 244, and 264 is quickly regenerated air outlets (224, 244). Discharged to 264. The regenerated air passing through the condensed flow passages 426, 446, and 466 located at a location far from the regenerated air discharge parts 224, 244, and 264 is relatively late. 264). As a result, an imbalance in flow between the condensation passages 426, 446, and 466 occurs.

Therefore, the cross-sectional areas of the condensation passages 426, 446, 466 in the present embodiment may be large in proportion to the distance from the regeneration air outlets 224, 244, 264. Therefore, a large amount of air flows to the regeneration air outlets 224, 244, 264 and the distant condensation flow passages 426, 446, 466, and the regeneration air outlets 224, 244, 264. A small amount of air flows over the nearby condensation flow paths 426, 446, and 466 to balance the overall flow.
Reference numerals that are not described refer to the first exchange plate 420, the second heat exchange plate 440, and the third heat exchange plate 460, respectively.

Fourth embodiment

9 is a perspective view of a fourth embodiment of the present invention.

9, the overall configuration of the third embodiment of the present invention will be described. The fourth embodiment of the present invention is similar in overall configuration to the first embodiment. The following description will focus on the differences of the fourth embodiment.

The first regeneration air inlet 522 of the fourth exemplary embodiment of the present invention is formed by rotating at a predetermined angle in a direction opposite to the first regenerated air outlet 224. Therefore, as described above, the flow imbalance when the first regenerated air discharge part 224 is located on one side of the left and right sides of the first heat exchange plate 520 can be eliminated.

Specifically, according to the present embodiment, it is possible to reduce the difference in distance between the plurality of inlets 526a of the condensation passage 526 and the first regeneration air discharge unit 224. Therefore, the regenerated air introduced into each condensation flow path through the regenerated air inlet 522 is moved a substantially constant distance until passing through the regenerated air outlet 224. Therefore, it is possible to smoothly flow the regenerated air of the first heat exchange plate 520.
Unexplained reference numeral 540 denotes "second heat exchange plate", "560" denotes "third heat exchange plate", "522b" denotes "radius", and "522a" denotes "center of condensation heat exchanger". "526b" points to "outlet".

Fifth Embodiment

10 is a rear view of the condensation heat exchanger of the fifth embodiment of the dehumidifier according to the present invention, and FIG. 11 is an exploded perspective view of the condensation heat exchanger of the embodiment.

Dehumidifier according to the present embodiment, as shown in Figure 10 to 11,

The first, second, and third heat exchange plates 620, 640, 660 of the first, second, and third heat exchange plates 622, 642, and 662 are the first, second, and third heat exchange plates 620 ( 640, 660 is formed on the upper, the first, second, third heat exchange plate 620, 640, 660 of the regeneration air discharge portion 624, 644, 664 of the first, second, third row An opening is formed in the lower part of the exchange plates 620, 640, 660, in particular in the air flow direction.

That is, the first, second, and third heat exchange plates 620, 640, 660 are provided with first, second, and third regenerated air discharge parts 624, 644, 664 under the respective rear surfaces thereof.

In addition, a first regeneration air discharge communication unit 634 and a second regeneration air discharge communication unit 654 are provided on the front surfaces of the first heat exchange plate 620 and the second heat exchange plate 640. 644) and 664 are formed to face the opening.

The first regeneration air discharge communication unit 634 communicates with the second regeneration air discharge unit 644, and the second regeneration air discharge communication unit 654 communicates with the third regeneration air discharge unit 664.

That is, the regenerated air passing through the third condensation passage 266 is the third regeneration air discharge unit 664, the second regeneration air discharge communication unit 654, the second regeneration air discharge unit 644, the first regeneration air It is introduced into the duct 680 through the discharge communication unit 634 and the first regeneration air discharge unit 624.

The regenerated air that has passed through the second condensation passage 246 is connected to the duct 680 through the second regenerated air discharge part 644, the first regenerated air discharge communication part 634, and the first regenerated air discharge part 624. Flows into).

The regenerated air that has passed through the first condensation passage 226 is introduced into the duct 680 through the first regenerated air discharge part 624.

On the other hand, the duct 680 is disposed in communication with the first regeneration air discharge. Specifically, the first regeneration air outlet 624 is coupled to the front and rear insertion. The first heat exchange plate 620 is bent and formed along the left and right circumferences.

The scope of the present invention is not limited to the above embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

1 is a perspective view of a first embodiment of the dehumidifier according to the present invention;

2 is an exploded perspective view of main parts of a first embodiment of the dehumidifier according to the present invention;

3 is a perspective view of a condensation heat exchanger of the first embodiment;

4 is a rear view of the condensation heat exchanger of FIG. 3;

5 is a plan sectional view of the condensation heat exchanger of FIG. 3;

6 is an exploded perspective view of the condensation heat exchanger of FIG. 3;

7 is a perspective view of a condensation heat exchanger of a second embodiment of the present invention;

8 is a plan sectional view of a condensation heat exchanger of a third embodiment of the present invention;

9 is a perspective view of a condensation heat exchanger of a fourth embodiment of the present invention;

10 is a rear view of the condensation heat exchanger of the fifth embodiment of the present invention;

11 is an exploded perspective view of a fifth embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

2: main body 200: condensation heat exchanger

10: base 20: rear case

30: front case 40: front panel

50: blower 60: dehumidification rotor

90: regeneration fan 100: regeneration heater

220: first heat exchange plate 222: first regeneration air inlet

224: first regeneration air discharge unit 226: the first condensation flow path

230: first condensate discharge portion 232: first endothermic flow path

240: second heat exchange plate 242: second regeneration air inlet

244: second regeneration air discharge unit 246: second condensation flow path

250: second condensate discharge portion 252: second endothermic flow path

260: third heat exchange plate 262: third regeneration air inlet

264: third recycled air discharge unit 266: the third condensing euro

270: third condensate discharge portion 272: third endothermic flow path

    280: duct

Claims (14)

A main body including a dehumidifying flow path through which indoor air is sucked and dehumidified and a regeneration flow path through which regenerated air flows; A dehumidifying rotor including a dehumidifying unit for dehumidifying the indoor air and a regenerating unit which is regenerated using the regenerated air; And A condensation heat exchanger in which a plurality of heat exchange plates formed with a plurality of condensation passages through which the regenerated air passing through the regeneration unit is sucked upward and discharged downward are disposed in parallel; Including, Regenerated air inflow parts are respectively formed on the plurality of heat exchange plates to receive regenerated air that has passed through the dehumidification rotor. The area of the regeneration air inlet is a dehumidifier is gradually smaller along the regeneration air inlet direction. The method according to claim 1, The plurality of regeneration air inlet is in communication with each other dehumidifier. delete The method according to claim 1, The dehumidifier is in the form of fan-shaped regeneration air inlet. The method according to claim 1, The regeneration unit is located in the upper center of the dehumidification rotor. The method according to claim 1, Regeneration air discharge portions through which the regeneration air passing through the dehumidification rotor is discharged are formed on the rear surfaces of the plurality of heat exchange plates, The dehumidifier is in communication with each of the plurality of regeneration air discharge. delete delete delete The method according to claim 1, Regeneration air inlet of the second or more heat exchange plate in the direction of the regeneration air of the plurality of heat exchange plate, Dehumidifier having a streamlined shape long in the horizontal direction on the upper surface of the condensation heat exchanger. The method according to claim 1, A dehumidifier having a regenerated air discharge portion through which the regenerated air passing through the dehumidification rotor is discharged on the lower left or right side of the plurality of heat exchange plates. delete The method according to claim 11, The regeneration air inlet of the second or more heat exchanger plate in the reflow air flow direction of the plurality of heat exchanger plates is formed in a long linear shape on the upper surface of the condensation heat exchanger in a horizontal direction, The dehumidifier of which the streamlined regeneration air inlet is wider as the distance from the regenerated air discharge is farther away. The method according to claim 11, And a cross-sectional area of the plurality of condensation passages increases in area in proportion to being farther from the regeneration air outlet.

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