KR101440521B1 - Dehumidifier - Google Patents

Abstract

The dehumidifier of the present invention comprises: a main body having an air inlet and an air outlet; An air blower installed to suck indoor air through the air suction unit and to be discharged to the air discharge unit after passing through the main body; A dehumidification rotor in which moisture in the room air sucked by the blower is adsorbed and regenerated at a low temperature; A regeneration fan installed to blow air into the dehumidification rotor; A heater installed to heat the air blown to the dehumidification rotor by the dehumidification fan; And a condensing heat exchanger having a condensing flow passage through which the air regenerated by the dehumidifying rotor passes and a heat absorbing flow passage through which the indoor air sucked by the blowing fan passes and moisture in the air passing through the condensing flow passage is condensed, The regenerated air is condensed by the room air flowing toward the dehumidification rotor, so that there is an advantage that the room can be efficiently dehumidified with low noise and low power consumption.

Dehumidifier, main body, dehumidification rotor, heater, regeneration fan, condensing heat exchanger

Description

Dehumidifier {Dehumidifier}

 The present invention relates to a dehumidifier for dehumidifying indoor air, comprising a dehumidification rotor that absorbs moisture in room air and is regenerated at a low temperature, and a condensation heat exchanger that condenses the air that has been regenerated from the dehumidification rotor by exchanging heat with room air flowing toward the dehumidification rotor The present invention relates to a dehumidifier.

  In general, the dehumidifier dehumidifies the humid air in the room. In the prior art, the room air is passed through a heat exchanger including a condenser and an evaporator through which the refrigerant flows, and the humidity is lowered. The dehumidified air is again discharged into the room, .

That is, the dehumidifier uses a method of taking heat from ambient air by evaporating refrigerant in a liquefied state in the evaporator. As the refrigerant evaporates, the temperature of the evaporator is lowered and the temperature of the air passing through the evaporator is also lowered.

Therefore, as the temperature around the evaporator drops, the moisture contained in the air condenses and forms dew on the surface of the evaporator, and the dew on the surface of the evaporator drops onto the bucket.

However, since the dehumidifier using the heat exchanger including the condenser and the evaporator requires the compressor for compressing the refrigerant as described above, the cost is increased, the noise due to driving the compressor is generated, and a space for installing the compressor is required. There is a problem in that it is not easy to move due to the weight of a compressor or the like.

On the other hand, in Patent Publication No. 10-0598214, moisture is taken away by the desiccant while air passes through the desiccant, and moisture adsorbed by the desiccant is evaporated by the heat of the heater to regenerate the desiccant, and a humidifying and dehumidifying device Lt; / RTI >

In the humidifying and dehumidifying device using the desiccant as described above, the indoor air heated by the heater passes through the desiccant and evaporates the moisture adsorbed by the desiccant by indirect heating or integrates the electric heater with the desiccant The moisture of the secant is evaporated by the direct heating method of the electric heater, and the regeneration air blower discharges the air (hot and humid) which has evaporated the desiccant water to the outside.

However, in the dehumidifying apparatus disclosed in Patent Publication No. 10-0598214, when the high-temperature and high-humidity air which evaporates the water of the desiccant is discharged into the room, the dehumidifying ability of the room is lowered, When the air is discharged outdoors, a separate duct for guiding hot and humid air, which has evaporated moisture of the desiccant, to the outside, is required, which complicates the structure and makes it difficult to move the dehumidifying device.

Disclosure of Invention Technical Problem [8] The present invention has been conceived to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a dehumidifying apparatus, And then the dehumidified air is circulated through the dehumidifying rotor to efficiently dehumidify the room.

It is another object of the present invention to provide a dehumidifier in which the condensing ability of the air recycled by the desiccant can be further improved, thereby improving the indoor dehumidification capability.

According to an aspect of the present invention, there is provided a dehumidifier comprising: a main body having an air suction unit and an air discharge unit; An air blower installed to suck indoor air through the air suction unit and to be discharged to the air discharge unit after passing through the main body; A dehumidification rotor in which moisture in the room air sucked by the blower is adsorbed and regenerated at a low temperature; A regeneration fan installed to blow air into the dehumidification rotor; A heater installed to heat the air blown to the dehumidification rotor by the dehumidification fan; And a condensing heat exchanger having a condensing flow passage through which the air regenerated by the dehumidifying rotor passes and a heat absorbing flow passage through which indoor air sucked by the blowing fan passes and moisture in the air passing through the condensing flow passage is condensed.

The dehumidification rotor includes a desiccant including meso silica and a secant wheel to which the desiccant is fixed.

The meso silica has a pore size of 2 to 50 nm.

The condensing heat exchanger is a synthetic resin material.

The air conditioner is disposed in the order of the condensing heat exchanger, the dehumidifying rotor, and the heater in the flow direction of the room air.

Further comprising: a rotor frame disposed between the blower and the condensing heat exchanger; and a rotor supporter installed on the rotor frame and rotatably supporting the dehumidifying rotor, wherein the rotor frame is connected to the condenser heat exchanger, A bypass portion for bypassing the dehumidification rotor is formed.

And a bucket mounted below the condensing heat exchanger and containing condensed water condensed and dropped in the condensing heat exchanger.

In the dehumidifier of the present invention configured as described above, the air regenerated by the dehumidification rotor is condensed by the room air flowing toward the dehumidification rotor and then circulated to the dehumidification rotor. Therefore, when the air regenerated by the dehumidification rotor is discharged to the room There is an advantage that the room can be dehumidified efficiently.

Further, the dehumidifier of the present invention is characterized in that the desiccant of the dehumidifying rotor includes meso silica which is excellent in moisture adsorbing ability and regenerated at a low temperature, so that it is possible to dehumidify the room quickly, and power consumption for regeneration can be minimized There is an advantage.

 Further, the dehumidifier of the present invention further includes a duct for guiding the air that has passed through the condensing duct of the condensing heat exchanger to the regenerating fan, so that the condensing duct of the condensing heat exchanger can be designed to maximize the condensing efficiency .

Further, the dehumidifier of the present invention is advantageous in that the condensation heat exchanger is made of a synthetic resin material, the condensation flow path of the condensing heat exchanger can be precisely molded, the cost is low, and the weight can be reduced.

In the dehumidifier of the present invention, a bypass section for bypassing the dehumidification rotor is provided in the rotor frame, through which the room air passed through the condensing heat exchanger is made larger than the dehumidification rotor, and the condensing efficiency of the condensing heat exchanger can be increased .

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

 FIG. 3 is a longitudinal sectional view of an embodiment of the dehumidifier according to the present invention, and FIG. 4 is a cross-sectional view of an embodiment of the dehumidifier according to the present invention FIG. 5 is a schematic view showing the dehumidifying and regenerating principle of an embodiment of the dehumidifier according to the present invention, FIG. 6 is a schematic view showing the temperature of air during dehumidification according to an embodiment of the present invention, Fig. 2 is a schematic diagram of absolute humidity.

As shown in FIG. 1, the dehumidifier according to the present embodiment discharges dehumidified room air after sucking indoor air and absorbing moisture. The dehumidifier includes a main body 2, an air suction unit 4, (6) is formed.

As shown in Figs. 1 and 2, the main body 2 includes a base 10, a rear case 20 which forms the rear outer surface of the dehumidifier and is disposed on the rear side of the base 10, A front case 30 coupled to the front of the front case 30 and a front panel 40 disposed forward of the front case 30. [

The base 10 is provided with a wheel assembly 11 composed of a wheel for supporting the movement of the dehumidifier and a wheel support for rotatably supporting the wheel

The wheel assembly 11 is mounted on the base 10 by a fastening member such as a screw.

The base 10 has a wheel assembly receiving portion 12 at four corners of which a part of the wheel assembly 11 is inserted and accommodated.

The base 10 can be formed in a plate shape or in a box shape and includes a bucket take-out portion 13 for drawing out a bucket 130 to be described later on one of front, back, left, And the upper surface 14 is opened so that the condensed water generated in the condensing heat exchanger 110 and dropped down to the bucket 130 can be opened.

The rear case 20 forms a rear outer appearance of the dehumidifier and includes a rear plate 21 and left and right side plates 22 and 23 formed in a bent shape at left and right ends of the rear plate 21, And an upper plate portion 24 formed in a bent shape at the upper end of the thick plate portion 21.

The rear case 20 is provided with an air discharging portion 6 in which the room air dehumidified in the main body 2 is discharged to the outside of the main body 2. [ The air discharge portion 6 is formed in the upper plate portion 24 of the rear case 20 so that air in the room dehumidified in the main body 2 is discharged to the upper side of the dehumidifier.

The rear case 20 is formed with a rear opening 25 for entering and exiting the bucket 130.

The front case 30 forms the front exterior of the dehumidifier and includes a front plate 31 and left and right side plates 32 and 33 formed in a bent shape at left and right ends of the front plate 31, And an upper plate portion 34 formed in a bent shape at the upper end of the front plate portion 31.

The front case (30) is formed with an air suction hole (35) through which indoor air is sucked into the main body (2). The air suction hole 35 is formed in the front plate portion 31 of the front case 30 so that the room air sucked into the main body 2 is sucked in the forward and backward direction from the front of the dehumidifier.

The front case 30, in particular, the top plate 34 is provided with a control unit 36 having a control unit for operating a dehumidifier and a display unit for displaying information of the dehumidifier.

The control unit 36 includes a control panel 37 exposed to the outside and a control PCB 38 disposed on the control panel 37 and equipped with various electric parts such as a control unit and a display unit.

The front case 30 is formed with a front opening 39 for the entrance and exit of the bucket 130.

The front panel 40 forms the front surface of the dehumidifier and is formed with an air suction portion 4 in which room air is sucked into the air suction hole 35 of the main body 2,

That is, the room air passes through the air suction portion 4 of the front panel 40 and the air suction hole 35 of the front case 30 in order to be sucked into the main body 2, And is discharged to the outside through the air discharge portion 6 of the rear case 20.

The front panel 40 is clogged to improve the appearance of the front surface of the dehumidifier and the air inlet 6 is formed on the front surface. The front panel 40 includes a plate-like front plate portion 41 having no openings , And the air suction part (4) is formed behind the front plate part (41). The air suction part 4 is formed to protrude from the back surface of the front plate part 41 of the front panel 40 and is formed into a grill shape.

A blower 50, a dehumidification rotor 60, a regeneration fan 90, a regenerative heater 100, and a condensing heat exchanger 110 are provided in the main body 2.

The blower 50 sucks indoor air I through the air suction unit 4 and then discharges the air to the air discharge unit 6 after passing through the main body 2 so that the indoor air I is supplied to the dehumidification rotor 60 A fan housing 53 having a rear surface opened to form an air flow passage with the rear case 20 and an air intake hole 51 formed on the front surface thereof and a discharge portion 52 formed on the upper surface thereof, A fan motor 54 installed in one of the fan housing 53 and the rear case 20 and a fan 54 connected to the rotary shaft of the fan motor 54 so as to be rotated between the fan housing 53 and the rear case 20, (55).

In the fan housing 53, a discharge grill 56 is provided in the discharge portion 52.

The fan 55 is rotatably supported by a fan support portion 26 formed in the rear case 21. [

The dehumidification rotor 60 is disposed between the blower 50 and the condensing heat exchanger 110 so that moisture in the room air I sucked by the blower 50 is adsorbed and can be regenerated at a low temperature.

The desiccant rotor 60 surrounds the desiccant 61 and the desiccant 61 surrounds the desiccant 61 so that moisture in the room air I can be adsorbed while the room air I passes, And includes a secant wheel 62 to be fixed.

The desiccant 61 is formed in a disc shape as a whole, and a fixing hole 63 for fixing the desiccant wheel 62 to the center is formed at the center.

The desiccant 61 alternately winds the ceramic fiber-like flat paper and the corrugated paper in a cylindrical shape, and meso-silica (SiO2) is formed by coating or the like.

Mesoporous silica is mesoporous silica having excellent pore structure and surface area, so that it is excellent in hygroscopic property and can be regenerated even at a low temperature of about 60 캜 or less.

The meso silica is obtained by reacting spherical silica particles and silica precursors having a particle diameter of 10 to 1000 nm with a surfactant in a solvent to grow a cell portion made of silica and a surfactant component on the surface of the spherical silica particles and then heat- When the surfactant component of the shell portion is removed, a silica shell portion having pores of a predetermined diameter formed in the place where the surfactant is removed is formed.

The above meso silica has a pore size of 2 nm to 50 nm.

[Table 1]

sample Hygroscopicity (mL / g) Regeneration temperature (℃) Surface area BET Zeolite 0.37 153 780 Alumina 0.47 80 327 Meso silica 0.63 48 609

Table 1 shows the results of a test of the regeneration zone of desiccant and the like. As a result of comparison of meso silica having a size of about 200 nm and a pore of 2 nm to 50 nm with zeolite and alumina, meso silica Is relatively higher in dehumidifying ability than the zeolite or alumina due to its high water absorption capacity per gram of the sample, and the regeneration temperature is relatively low, so that it can be regenerated by the relatively low hot wind.

When the desiccant 61 is rotated, a portion where moisture is adsorbed (hereinafter referred to as an adsorbing portion) through the room air I and a portion where moisture is evaporated as the regeneration air O passes The regenerating unit 110 is a regeneration unit in which the regeneration air O passes through a portion opposed to the regeneration heater 110. The regeneration unit 110 includes a regeneration unit 110 which is opposed to the regeneration heater 110, The dehumidifying portion is the portion through which the room air I passes.

The desiccant wheel 62 is a sort of desiccant case for protecting the desiccant 61. The desiccant wheel 62 has a rim portion 64 formed in a ring shape and surrounding the desiccant 61, And a connecting portion 66 formed radially between the rim portion 64 and the fixing portion 65 so as to connect the rim portion 64 and the fixing portion 65.

A rotor supporter 68 for rotatably supporting the dehumidification rotor 60 and a rotor frame 69 for mounting the rotor supporter 68 are disposed in the main body 2.

The rotor supporter 68 substantially supports the dehumidification rotor 60 and includes a rim portion 70 formed in a ring shape and surrounding the dehumidification rotor 60 and a rim portion 70 surrounding the dehumidification rotor 60 for rotatably supporting the dehumidification rotor 60 And a connecting portion 72 radially formed between the rim portion 70 and the supporting shaft 71 to connect the rim portion 71 and the supporting shaft 71 with each other.

The rim 70 is formed with a fastening portion 73 which is fastened to the rotor frame 69 by a fastening member such as a screw.

The rotor frame 69 is mounted with a rotor supporter 68, and the rotor supporter 68 is mounted with a fastening member such as a screw.

The rotor frame 69 is a kind of barrier that divides the inside of the main body 2 into a rear side space in which the blower 50 is disposed and a front side space in which the condensing heat exchanger 110 is disposed. A penetrating portion 75 through which the supporter 68 penetrates is formed in an opening in front of the air suction hole 51 of the blower 50. [

The rotor frame 69 has an opening 76 for communicating the regeneration fan 90 with the duct 120 that allows the air guided by the duct 120 to be introduced into the regeneration fan 90 to flow into the regeneration fan 90 .

The rotor frame 69 has an opening 76 for communicating the duct 120 and the regenerating fan 90 so that the air that has passed through the duct 120 is quickly sucked into the regenerating fan 90 and sucked into the regenerating heater 100, Is preferably formed as close as possible to the regenerative heater (100).

For example, when the regenerative heater 100 is provided so as to correspond to the upper portion of the dehumidification rotor 60, the rotor frame 69 preferably has an opening 76 formed thereon, When the rotor frame 69 is provided so as to correspond to the lower portion of the rotor 60, it is preferable that an opening 76 is formed in the lower portion of the rotor frame 69.

The rotor frame 69 is formed with a bypass portion 77 through which the room air passed through the condensing heat exchanger 110 bypasses the dehumidification rotor 60.

The bypass portion 77 is not limited to the portion where the heat exchange area of the condensing heat exchanger 110 is opposed to the dehumidification rotor 60 but is larger than the size of the dehumidification rotor 60, I of the condensing heat exchanger 110 condenses the air passing through the condensing heat exchanger 110 while passing through the portion of the condensing heat exchanger 110 opposed to the dehumidifying rotor 60 and the rest of the room air I is condensed by the condensing heat exchanger 110 to condense the air passing through the condensing heat exchanger (110) while passing through the portion not opposed to the dehumidification rotor (60).

That is, the total size of the condensing heat exchanger 110 is formed to be larger than that of the dehumidification rotor 60, and the portion not opposed to the dehumidification rotor 60 also condenses the regeneration air.

On the other hand, on the rotor frame 69, there is formed a control portion installing portion 79 in which a control portion 78 for controlling the dehumidifier is installed.

The control unit 78 is connected to the control box 82 which is made of a metal material and is provided with a PCB 80 in which various electric parts are installed, a PCB 80 in which a PCB 80 is installed and a synthetic resin material, .

The regeneration fan 90 is a device for causing the air for regeneration of the dehumidification rotor 60 to be blown to the dehumidification rotor 60 and is provided with a fan housing 91 and a fan housing 91, An orifice 93 provided in the fan housing 91 for guiding the air sucked by the fan 92 and an orifice 93 provided in the fan housing 91 to rotate the fan 92 Includes a fan motor (94).

The regeneration fan 90 is installed to be positioned behind the opening 76 of the rotor frame 69 and the orifice 93 is positioned so as to communicate with the opening 76 of the rotor frame 69.

The regenerative heater 100 heats the air blown into the dehumidification rotor 60 by the regenerative fan 90 and supplies the high temperature air to the dehumidification rotor 60 so that the dehumidification rotor 60 and the blower 50 As shown in FIG.

The regenerative heater 100 includes an electrothermal heater 101, a heater cover 102 covering the electrothermal heater 101 and communicating with the regeneration fan 90, and a heater cover 102 positioned between the heater cover 102 and the dehumidification rotor 60 And a blocking film 103 coupled with the heater cover 102.

The shielding film 103 is a kind of air guide for preventing the air heated by the heater 101 from moving toward the dehumidification rotor 60 between the heater 101 and the dehumidification rotor 60, Or semi-circular shape, and an opening is formed in the surface facing the dehumidification rotor 60. [

The condensing heat exchanger 110 is for condensing the regeneration air that has been regenerated from the dehumidification rotor 60 by heat exchange with the indoor air I sucked by the blower 50. The condenser heat exchanger 110 condenses the dehumidification rotor 60 and the rotor frame 69, As shown in FIG.

The condensing heat exchanger 110 is installed at the rear of the front plate portion 31 of the front case 30 with the front of the dehumidification rotor 60 and the rotor frame 69.

That is, the dehumidifier according to the present embodiment is disposed in the order of the condensing heat exchanger 110, the dehumidification rotor 60, the regenerative heater 100, and the blower 50 in the flow direction of the indoor air I.

The condensing heat exchanger 110 is provided with a condensing flow passage 112 through which the regeneration air O regenerated by the dehumidification rotor 60 passes and a room air I sucked by the blower 50 through a dehumidifying rotor 60 The heat absorbing channel 114 is formed to pass through the heat absorbing channel 114 before passing through the heat absorbing channel 114.

 A plurality of the condensing heat exchangers (110) are arranged back and forth in the air flow direction.

The condensing heat exchanger 110 has a condensing flow passage 112 formed therein and a heat absorbing flow passage 114 formed through the condensing heat exchanger 110.

The condensing heat exchanger 110 has a condensing flow path 112 formed between the front plate and the rear plate. The front plate and the rear plate are made of a synthetic resin material for easy molding and lightening of the condensing flow path 112 and the heat absorbing flow path 114.

A plurality of flow paths are connected in parallel within the condensing heat exchanger 110, and the plurality of flow paths are formed in the condensing heat exchanger 110 as a whole in the vertical direction as a whole.

The heat absorbing flow path (114) is formed in the part of the condensing heat exchanger (110) where the condensing flow path (112) is not formed in the front and rear direction.

The condensing heat exchanger 110 is provided with a regeneration air inflow portion through which the regeneration air having passed through the dehumidification rotor 60 flows into the condensing heat exchanger 110. The regeneration air having passed through the condensing flow passage 112 is discharged And a condensed water discharge port 118 through which the condensed water condensed in the condensing duct 112 is discharged is formed in the lower part.

The condensing heat exchanger (110) is formed in the size and shape of the regeneration section of the dehumidification rotor (60).

That is, when the regenerative heater 100 has a generally angular shape, the portion of the dehumidification rotor 60 opposed to the regenerative heater 100 is a regeneration portion, and the regeneration air inlet portion of the condensing heat exchanger 110 regenerates the regenerated heater 100, When the regenerative heater 100 has a semicircular shape, the portion of the dehumidification rotor 60 opposed to the regenerative heater 100 is a regenerative portion,

The reconditioning air inlet portion of the condensing heat exchanger 110 is formed in a semicircular shape like the regenerative heater 100.

The condensing heat exchanger 110 is formed such that the reconditioning air discharge portion 116 protrudes sideways on one side of the circumference of the condensing heat exchanger 110 so that the heat exchange area of the condensing heat exchanger 110 is maximized.

That is, when the reconditioning air discharge unit 116 is located on the front and rear surfaces of the condensing heat exchanger 110, that is, on the air flowing surface, the condensing heat exchanger 110 performs condensing heat exchange The heat exchange area of the condensing heat exchanger 110 is increased when the reconditioning air discharging part 116 is formed so as to protrude sideways on one side of the periphery of the condensing heat exchanger 110. [

On the other hand, the condensed water outlet 118 is formed to protrude from the lower part of the periphery of the condensing heat exchanger 100.

The condensing heat exchanger 110 is formed so that the flow paths of the condensing flow path 112 are spaced apart from each other in the left and right direction of the condensing heat exchanger 110, And the lower part of the periphery of the condensing heat exchanger 110 is formed to be downwardly directed toward the condensed water discharge port 118. In addition,

The dehumidifier according to the present embodiment includes a duct 120 for guiding the air that has passed through the condensing duct 112 of the condensing heat exchanger 110 to the regenerating fan 90 and a duct 120 for condensing in the condensing heat exchanger 110, And a bucket 130 in which condensed water is contained.

The duct 120 is connected to the regeneration air discharging portion 116 of the condensing heat exchanger 110 and the other end of which is connected to the rotor frame 69, As shown in Fig.

That is, the dehumidifier according to the present embodiment is arranged in the order of the regeneration fan 90, the regenerative heater 100, the dehumidification rotor 60, the condensing heat exchanger 110, and the duct 120 in the flow direction of the regeneration air I The regenerative heater 100 is disposed behind the dehumidification rotor 60 and the condensation heat exchanger 110 is disposed downstream of the dehumidification rotor 60 and the rotor frame 60. [ 69, and the duct 120 is arranged in front of the rotor frame 69. [

 In the above-described dehumidifier, the reconditioning air I passes through the regenerating heater 100 and the desiccant rotor 60 in order to flow the regeneration air I blown by the regenerating fan 90 to the front of the dehumidifying rotor 60 Flows downward from the front of the dehumidification rotor 60 along the condensing flow path 112 of the condensing heat exchanger 110 and is moved to the side of the condensing heat exchanger 110 and then flows along the duct 120 69 and passes through the rotor frame 69 in the front-rear direction, flows backward, and is sucked into the regeneration fan 90.

The bucket 130 is a box body whose top surface is opened, and is attached to and detached from the base 10.

 A drain pan 140 is disposed in the main body 2 for receiving the condensed water condensed in the condensing flow passage 112 of the condensing heat exchanger 110 and discharging the condensed water to the bucket 130.

7 is an enlarged cross-sectional view of the dehumidifying rotor and the heater shown in Fig.

The dehumidifier according to the present embodiment is assembled integrally with the regenerative heater 110 while the rotor supporter 68 supports the desiccant 61 and the desiccant wheel 62.

The fixed portion 65 of the desiccant wheel 62 is inserted into the fixing hole 63 formed in the desiccant 61 and fixed to the desiccant 61 and serves as the rotating shaft of the dehumidifying rotor 60, A support shaft through hole 67 through which the support shaft 71 of the supporter 68 passes is formed.

The support shaft 71 of the rotor supporter 68 is projected so as to penetrate through the support shaft through-hole 67 of the dehumidification rotor 60.

The supporting shaft 71 of the rotor supporter 68 is formed with a fastening hole 74 in which the fastening member 104 is fastened so that the regenerative heater 100 can be fixed to the supporting shaft 71.

The regenerative heater 100 is provided with a heater cover 102 through which the fastening member 104 is passed through the heater cover 102 so that the fastening member 104 passes through the heater cover 102 and the shielding film 103 and is coupled to the support shaft 71 And a shielding film penetration portion 106 through which the fastening member 104 penetrates is formed in the shielding film 103. [

That is, the fastening member 104 passes through the heater cover penetration portion 105 of the heater cover 102 and the shielding film penetration portion 106 of the shielding film 103 in order, and then passes through the support shaft 71 of the rotor supporter 68 And the rotor supporter 68 supports the regenerative heater 110 while the support shaft 71 supports the desiccant 61 and the desiccant wheel 62 in a rotatable manner.

8 is a front view of the dehumidification rotor and the rotor frame shown in Fig. 2;

The dehumidifier according to the present embodiment further includes a dehumidification rotor rotating mechanism 84 for rotating the dehumidification rotor 60, as shown in Fig.

The rotating mechanism 84 includes a driven gear 85 formed on the outer periphery of the rim portion 64 of the desiccant wheel 62, a drive gear 86 for rotating the driven gear 85, And a motor 87 for driving the motor.

The motor 87 is fastened to one of the rotor supporter 68 and the rotor frame 69 with a fastening member such as a screw.

   Hereinafter, the operation of the present invention will be described.

First, when an operation command of the dehumidifier is inputted through the control unit 36, the control unit 78 drives the dehumidification fan 50, the regeneration fan 90 and the dehumidification rotor rotation mechanism 84.

The indoor air I is sucked into the main body 2 through the air suction part 4 and then passes through the heat absorbing flow path 114 of the condensing heat exchanger 110. After that, And passes through the rotor 60. The indoor air I passing through the dehumidification rotor 60 is heated while being desorbed by the desiccant 61 and then discharged to the outside through the air discharge portion 6. (A-> B-> C-> D)

When the dehumidifying fan 50 is driven as described above, the dehumidifying rotor rotating mechanism 84 rotates the dehumidifying rotor 60 and the dehumidifying rotor 60 is rotated by the dehumidifying rotor 60, Is regenerated by being opposed to the additional regenerative heater (110), and then moved to a position not opposed to the regenerative heater (110) again to be dehumidified.

When the regeneration fan 90 is driven, the regeneration air O flows to the regeneration heater 110 by the regeneration fan 90 and is heated to a high temperature by the regeneration heater 110. The regeneration air heated by the regeneration heater 110 as described above passes through the regeneration section which is a part opposed to the regeneration heater 1100 in the downstream of the dehumidification rotor 60 and the moisture adsorbed to the regeneration section of the dehumidification rotor 60 at this time The regeneration air which has been changed into high temperature and high humidity by the dehumidification rotor 60 flows into the condensing flow path 112 of the condensing heat exchanger 110 and passes through the condensing flow path 112, (E - > F- > G- > H) while being cooled by the indoor air (I) passing through the condensing heat exchanger (110)

The regeneration air O passing through the condensing duct 112 is sucked into the regeneration fan 90 after passing through the duct 120. The regeneration air is supplied to the regeneration fan 90 and the regenerating heater 100, The dehumidification rotor 60, the condensing heat exchanger 110 and the duct 120 while continuously circulating the dehumidification rotor 60. [

During the regeneration of the dehumidification and dehumidification rotor 60, the condensation flow path 112 of the condensing heat exchanger 110 condenses moisture during the regeneration of the dehumidification rotor 60 to generate condensed water And the dropped condensed water is dropped into the drain pan 140 through the condensed water outlet 118 of the condensing heat exchanger 110. The dropped condensed water is drained to the bucket 130 by the drain pan 140, (130).

The desiccant 61 of the dehumidifying rotor 60 includes meso silica and can be regenerated at a low temperature so that it is not necessary to raise the regenerative heater 100 to a higher temperature than necessary, The power consumption of the desiccant 100 can be minimized, and the desiccant 61 can be regenerated quickly, so that the amount of dehumidification per hour becomes high.

1 is a perspective view of one embodiment of a dehumidifier according to the present invention,

2 is an exploded perspective view of a main portion of an embodiment of a dehumidifier according to the present invention,

3 is a longitudinal sectional view of one embodiment of the dehumidifier according to the present invention,

4 is a horizontal sectional view of one embodiment of a dehumidifier according to the present invention,

5 is a schematic view showing the dehumidification and regeneration principle of one embodiment of the dehumidifier according to the present invention,

FIG. 6 is a view schematically showing the temperature and absolute humidity of air during dehumidification according to an embodiment of the dehumidifier according to the present invention,

7 is an enlarged sectional view of the dehumidifying rotor and heater shown in Fig. 2,

8 is a front view of the dehumidification rotor and the rotor frame shown in Fig. 2;

DESCRIPTION OF THE REFERENCE NUMERALS

  2: Body 10: Base

20: rear case 30: front case

40; Front panel 50: blower

60: Dehumidification rotor 61: Desiccant

62: desicante wheel 68: rotor supporter

69: desiccant frame 90: regeneration fan

100: regenerating heater 110: condensing heat exchanger

120: duct 130: bucket

Claims (7)

A main body having an air suction part and an air discharge part; An air blower installed to suck indoor air through the air suction unit and to be discharged to the air discharge unit after passing through the main body; A dehumidification rotor in which moisture in the room air sucked by the blower is adsorbed and regenerated at a low temperature; A regeneration fan installed to blow air into the dehumidification rotor; A heater installed to heat the air blown by the regeneration fan to the dehumidification rotor; A condensing heat exchanger having a condensing flow passage through which the air regenerated by the dehumidifying rotor passes and a heat absorbing flow path through which indoor air sucked by the blowing fan passes and moisture in the air passing through the condensing flow passage is condensed; A dehumidifying rotor rotating mechanism; And a rotor frame positioned between the blower and the condensing heat exchanger, Further comprising a rotor supporter installed in the rotor frame and rotatably supporting the desiccant rotor, Wherein the condensing heat exchanger is formed to be larger in size than the dehumidification rotor, Wherein the rotor frame is provided with a bypass portion through which the room air passed through the condensing heat exchanger bypasses the dehumidification rotor. The method according to claim 1, Wherein the desiccant rotor includes a desiccant including meso silica, and a desiccant to which the desiccant is fixed. 3. The method of claim 2, Wherein the meso silica has a pore size of 2 to 50 nm. delete delete delete delete

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