KR20110112531A - Air conditioners system to processed vaporization and dehumidification - Google Patents

Abstract

The present invention relates to a vaporized dehumidifying air conditioner, and more particularly, is installed in a control box, a wardrobe, a shoe box, etc., which controls various industrial machines electronically, inhales the air therein, cools it, and condenses water vapor in the air. The evaporative dehumidification air conditioner is improved by dehumidifying performance is improved by evaporating the moisture stored in the heat radiation member having a latent heat storage means is discharged together with the air to facilitate cooling of the heat radiation member.
To this end, the present invention, in the dehumidifier using a thermoelectric element, the partition is provided inside the chamber divided into a suction part having a suction port and a discharge part having a discharge port, a first fan provided in the discharge part, and the chamber The cooling unit is provided on one side of the controller and the thermoelectric element is provided with a humidity sensor for sensing the humidity in the air sucked in the suction portion of the other side is provided with a heat radiation member, the heat radiation member is provided with a latent heat storage means Condensation tank is provided in the lower portion of the cooling member and the heat dissipation member is characterized in that it comprises a dehumidifying unit coupled to the partition.

Description

AIR CONDITIONERS SYSTEM TO PROCESSED VAPORIZATION AND DEHUMIDIFICATION}

The present invention relates to a vaporized dehumidifying air conditioner, and more particularly, is installed in a control box, a wardrobe, a shoe box, etc., which controls various industrial machines electronically, inhales the air therein, cools it, and condenses water vapor in the air. The evaporative dehumidification air conditioner is improved by dehumidifying performance is improved by evaporating the moisture stored in the heat radiation member having a latent heat storage means is discharged together with the air to facilitate cooling of the heat radiation member.

In general, the dehumidifier removes moisture by using a predetermined device or dehumidifying agent for sterilizing and cleaning in the living room, room, office, etc., rather than the local space, and protects the sensitive electronic equipment or is suitable for work in the manufacturing plant. It is used to control humidity.

This dehumidifier is mainly composed of a refrigeration cycle using a refrigerant gas has a very large power consumption problem. And dehumidifiers using dehumidifying agents, etc. are semipermanently impossible to use, causing another environmental pollution.

Recently, a dehumidifier using a thermoelectric element has been introduced.

The thermoelectric element uses a semiconductor element. When the two metals having different properties are bonded to each other and a voltage is applied, one side absorbs heat and the other side uses a Peltier effect that emits heat. Contact with the cooling plate cools the air and condenses water vapor to remove moisture from the air.

Such a thermoelectric element does not require a compressor, as compared to a dehumidifier using a conventional refrigerant gas, so that it is possible to reduce the weight and size, and to cool and heat the thermoelectric element. It can be used, and there is no mechanical driving, so it can be expected to have high reliability due to its long life. In addition, it has advantages such as low noise, local cooling and environmental friendliness.

However, a dehumidifier using a thermoelectric element absorbs heat on one side but emits heat on the other side, so dehumidification efficiency is lowered if the heat is not removed (cooled). The dehumidification efficiency cannot be provided separately. If installed in the dehumidifier is a problem due to the condensate water.

In addition, the heat dissipation plate and the cooling plate bonded to both sides of the passion element are made of an expensive metal material having high thermal conductivity, there is a problem that the manufacturing cost of the dehumidifier increases.

The present invention is provided with a latent heat storage means for vaporizing water in order to use the latent heat in the heat radiating member provided in the thermoelectric element is improved dehumidification performance by improving the efficiency of removing water stored in the condensate tank and the cooling capacity of the heat radiating member. The purpose is to provide a vaporized dehumidifying air conditioner.

Another object of the present invention, the discharge port for discharging the air dehumidified in the discharge portion of the chamber to the outside and the circulation port for circulating the air that does not need dehumidification is provided in the interior of the place where the vaporization dehumidification air conditioner according to the present invention is installed The present invention provides a vaporized dehumidifying air conditioner which circulates air and prevents unnecessary power consumption by stopping operation of the thermoelectric element as necessary.

Still another object of the present invention is to provide an evaporative dehumidifying air conditioner having an ozone generator for disinfecting the air sucked into the suction unit to purify the air in the room.

Still another object of the present invention is to provide a vaporized dehumidifying air conditioner having a condensate tank provided in the dehumidifying unit so that a dehumidifier can be installed even in a place where a separate condensate discharge means cannot be provided.

Still another aspect of the present invention is to provide a vaporized dehumidifying air conditioner having the cooling plate and the heat radiating plate to improve the cooling or heating efficiency as a radiator structure, to reduce the manufacturing cost and to be compact and lightweight.

Hereinafter, the present invention will be described.

Regarding the means for solving the problem,

The present invention provides a dehumidifier using a thermoelectric device, comprising: a chamber having a partition formed therein and divided into a suction part having a suction hole and a discharge part having a discharge hole; A first fan provided in the discharge part; A control unit provided at an intake unit of the chamber to sense humidity of inhaled air; And a cooling member is provided at one side of the thermoelectric element, and a heat dissipation member is provided at the other side, and the heat dissipation member is provided with a latent heat storage means, and a condensation tank is provided at the lower portion of the cooling member and the heat dissipation member. Characterized in that comprises a.

Another invention of the present invention is characterized in that the latent heat storage means is a capillary body having an upper end protruding to an upper portion of the heat dissipating member and having a lower end contacting the bottom surface of the condensation tank.

Another invention of the present invention, the discharge portion of the chamber partition wall provided across the central portion of the partition and the inside of the chamber in a direction perpendicular to the partition; A second fan provided at a place where the first fan is not included among the discharge parts partitioned by the partition wall; And a circulation port provided in a section provided with the second fan of the discharge unit to discharge the air sucked into the suction unit back to the room.

Another invention of the present invention, the cooling member is a first frame penetrated up / down; And a cooling plate which is bent in a zigzag and provided in the first frame to provide a passage of air sucked into the intake port, wherein the heat dissipation member is penetrated up and down; And a heat dissipation plate bent in a zigzag and provided in the second frame to partially pass the air sucked into the suction port, and part of the heat dissipation plate into which the capillary body is inserted.

Another invention of the present invention, the control unit includes a humidity sensor for sensing the humidity of the air sucked into the suction port provided in the suction unit; An ozone generator for purifying the air sucked into the suction port; And an optical sensor for stopping the operation of the ozone generator when sensing the light when the chamber is opened.

First, the present invention is provided with a latent heat storage means for vaporizing water in order to use the latent heat in the heat radiating member provided in the thermoelectric element to improve the efficiency of removing moisture stored in the condensate tank and the cabinet capacity of the heat radiating member to improve the dehumidification performance It is effective.

Second, the present invention is provided with a discharge port for discharging the air dehumidified in the discharge portion of the chamber to the outside and the circulation port for circulating the air that does not need dehumidification to the inside of the place where the vaporized dehumidification air conditioner according to the present invention is installed There is also an effect of preventing unnecessary power consumption by circulating and stopping the thermoelectric element as necessary.

Third, the present invention is provided with an ozone generator for disinfecting the air sucked into the suction unit has the effect of purifying the air in the room.

Fourth, the present invention, the condensate tank is provided in the dehumidification unit, because the condensed water is evaporated and discharged from the heat radiating member together with the air discharged to the outside by the latent heat storage means, even in a place where no separate condensate discharge means can be provided. It is also possible to install a dehumidifier.

Fifth, the present invention, the cooling plate and the heat radiation plate has a radiator structure to improve the cooling or heating efficiency, there is also an effect that can reduce the manufacturing cost.

1 is a perspective view showing a vaporization dehumidification air conditioner according to the present invention.
Figure 2 is a plan view showing a vaporization dehumidification air conditioner according to the present invention.
3 is a cross-sectional view taken along the line AA ′ of FIG. 2.
4 is a cross-sectional view showing a section taken along line BB ′ of FIG. 2.
5 is a perspective view showing a dehumidifying unit according to the present invention.
6 is a view showing a heat sink and a heating plate used in a conventional dehumidifier.

Hereinafter, with reference to the accompanying Figures 1 to 6 will be described the vaporized dehumidification air conditioner according to the present invention.

1 is a perspective view showing a vaporization dehumidification air conditioner according to the present invention, Figure 2 is a plan view showing a vaporization dehumidification air conditioner according to the present invention, Figure 3 is a cross-sectional view taken along the line AA 'of FIG. 4 is a cross-sectional view showing a cross-sectional view taken along line BB ′ of FIG. 2, FIG. 5 is a perspective view illustrating a dehumidifying unit according to the present invention, and FIG. 6 is a view showing a heat sink and a heating plate used in a conventional dehumidifier. to be.

1 to 4, the vaporized dehumidifying air conditioner 10 according to the present invention will be described. In the dehumidifier using the thermoelectric element 310, the suction port 121 is formed by a partition 110 provided therein. The chamber 100 is divided into a suction part 120 provided and a discharge part 130 provided with a discharge port 131, a first fan 132 and the suction part 120 provided in the discharge part 130. The control unit 200 and the cooling element 320 is provided on one side of the thermoelectric element 310 and the heat dissipation member 330 is provided on the other side, the latent heat storage means 400 in the heat dissipation member 330 Is provided is configured to include a dehumidifying unit 300 coupled to the partition (110).

The chamber 100 has a rectangular parallelepiped, the partition 110 of which crosses from one side to the other side of the chamber 100, and the front of the chamber 100 is the suction unit 120, and the chamber 100. The rear of the compartment is partitioned by the discharge unit 130.

The shape of the chamber 100 may be manufactured in various shapes according to the shape of the rectangular parallelepiped, which is easy to design, assemble and manage in the present invention, or the space in which the vaporized dehumidifying air conditioner 10 of the present invention is installed.

In the suction part 120, an inlet 121 through which external air is introduced into the suction part 120 is formed on an upper surface of the chamber 100.

1 and 2, the chamber 100 is provided perpendicular to the partition 110 at a central portion of the partition 110 so that the discharge part 130 is provided in the first chamber 130-1. ) And a partition wall 133 partitioned into a second chamber 130-2.

In the central portion of the partition 110 is formed a coupling hole to which the dehumidifying unit 300 according to the present invention is coupled. In addition, the front of the partition 133 is formed with a recessed groove corresponding to the heat radiation member 330 of the dehumidifying unit 300 coupled to the coupling hole so that the outside air sucked into the suction unit 120 is dehumidified It is preferable to allow the discharge unit 130 to flow into the discharge unit 130 only through the unit 300.

When the first chamber 130-1 of the discharge unit 130 is the other side portion of the partition wall 133, and the second chamber 130-2 is one side portion of the partition wall 133, the first fan 132 is provided on the other wall surface of the discharge unit 130 in the first chamber 130-1, and is disposed on an upper surface of the chamber 100 corresponding to the position where the first fan 132 is provided. A discharge port 131 for discharging the air drawn into the suction unit 120 due to the driving of the first fan 132 to the outside of the chamber 100 is provided.

The second fan 134 is provided on the rear wall surface of the discharge unit 130 in the second chamber 130-2, and the chamber 100 corresponds to the position where the second fan 134 is provided. One side of the circulating port 135 for discharging the air drawn into the suction unit 120 due to the drive of the second fan 134 to the outside of the chamber 100 is provided.

The first fan 132 and the second fan 134, a plurality of rotary blades are formed by the drive of the drive motor to rotate, which is already well known technology and will not be described in detail.

The control unit 200 is provided with the humidity sensor 210 for sensing humidity to sense the humidity in the air sucked into the suction unit 120 through the suction port 121, the interior of the chamber 100 Is provided.

The control unit 200 may be provided outside the chamber 100, but in the present invention, the humidity sensor 210 is provided at the suction unit 120 of the chamber 100 so that the humidity sensor 210 is provided at the suction port 121. It is preferable to prevent the malfunction of the humidity sensor 210 by better sensing the humidity in the air sucked into).

The controller 200 may further include an ozone generator 220 to sterilize and purify the air sucked into the suction port 121.

In addition, the control unit 200 further includes an optical sensor 230, when the chamber 100 is opened during the operation of the vaporization dehumidification air conditioner 10 according to the present invention, the optical sensor 230 detects light By sending a signal to the control unit 200 to stop the operation of the ozone generator 220, it is preferable to prevent the ozone generated from the ozone generator 220 to leak out of the chamber 100.

Since the humidity sensor 210, the ozone generator 220 and the optical sensor 230 are well known techniques, detailed description thereof will be omitted.

The dehumidifying unit 300 uses a so-called 'thermoelectric element 310' using a semiconductor element that generates heat or absorbs heat when current flows, and the thermoelectric element 310 is already well known. Detailed description thereof will be omitted.

The dehumidifying part 300 is provided with the cooling member 320 on one side of the thermoelectric element 310 that absorbs heat when current flows, and on the other side of the thermoelectric element 310 that generates heat when current flows. The heat dissipation member 330 is provided, and a condensation tank 340 is provided below.

The dehumidifying unit 300 will be described in more detail with reference to FIG. 5 as follows.

The cooling member 320 includes a first frame 321 penetrating up and down and a cooling plate 322 provided in the first frame 321 in a zigzag shape.

The first frame 321 is a metal having a high thermal conductivity and is provided in a rectangular pillar shape where the inside penetrates up and down.

The cooling plate 322 is also made of a metal having high thermal conductivity and is provided in the first frame 321 penetrating up and down.

The cooling plate 322 sequentially contacts a side surface and the other side of the first frame 321 and bends in a zigzag shape to penetrate a plurality of passages penetrating up and down inside the first frame 321. To form.

The heat dissipation member 330 is composed of a second frame 331 penetrating up and down and a heat dissipation plate 332 provided in the second frame 331 in a zigzag shape.

The second frame 331, like the first frame 321, is a metal having a high thermal conductivity is provided in a rectangular pillar shape that penetrates up and down inside.

The heat dissipation plate 332 is also made of a metal having high thermal conductivity and is provided in the second frame 331 penetrating up and down.

The heat dissipation plate 332, like the cooling plate 322, sequentially contacts one side surface and the other side surface of the second frame 331 and is bent in a zigzag shape to be in the second frame 331. A plurality of passages penetrating up and down will be formed.

The cooling member 320 and the heat dissipation member 330 is a metal having a high thermal conductivity, and a detailed description of the cooling member 320 and the heat dissipation member 330 is a metal material that is commonly used in the heat sink 500. However, the cooling member 320 and the heat dissipation member 330 is not limited to the metal material used for the heat sink 500, it is apparent that the material can be applied to any material having high thermal conductivity performance.

The condensation tank 340 is provided below the cooling member 320 and the heat dissipation member 330 to store moisture condensed by the cooling member 320.

The condensation tank 340 may be provided in the lower portion of the cooling member 320 in which moisture existing as a gas in the air is changed into a liquid, but in the present invention, the condensation tank 340 is stored in the condensation tank 340 to improve dehumidification performance. Since the moisture is also to be removed, the cooling member 320 and the heat dissipation member 330 is manufactured to a size that includes to cover the lower portion of the cooling member 320 and the heat dissipation member 330 integrally. Do.

The heat dissipation member 330 is further provided with a latent heat storage means 400 for removing water stored in the condensate tank 340 by using latent heat.

The latent heat storage means 400, the upper end is protruded to the upper portion of the heat dissipation member 330, the lower end is provided as a capillary body 410 is provided to contact the bottom surface of the condensate tank 340 is the second The inside of the frame 331 is inserted into the passage of the heat dissipation plate 332 provided in a zigzag shape.

In the present invention, the capillary body 410 is a commercially available gauze or capillary filter but is not limited to the above, and since the capillary body 410 is a well known technique, a detailed description thereof will be omitted.

Hereinafter, a driving process of the vaporization dehumidification air conditioner 10 according to the present invention to remove moisture in the air will be described.

The vaporization dehumidification air conditioner (10) is connected to the vaporization dehumidification air conditioner (10) installed in a control box, a wardrobe and a shoe box, and operates a switch connected to the control unit (200) to power the control unit (200). Applying the control unit 200 is to apply power to each part of the vaporization type air conditioner (10).

The controller 200 drives the first fan 132 to suck air into the suction port 121, and the humidity sensor 210 provided in the controller 200 is sucked into the suction port 121. Detect humidity in the air

If the humidity is not detected in the air sucked into the inlet 121 by the humidity sensor 210, the controller 200 stops driving of the first fan 132 and the user advances the controller 200. The second fan 134 is driven according to whether or not the ventilation function is set to allow the sucked air to flow into the second chamber 130-2 provided with the second fan 134.

When the ventilation function is not set in the control unit 200, the control unit 200 detects the humidity of air naturally sucked into the intake port 121 without driving the second fan 134 and the dehumidification unit 300. ) And whether the first fan 132 is driven.

When the ventilation function is set in the control unit 200, the control unit 200 drives the second fan 134 to forcibly suck the internal air of the control box, the wardrobe, the shoe box, and the like into the inlet 121, and forcibly Inhaled air flows into the passage formed in the cooling member 320 and passes through the passage formed in the heat dissipation member 330 through the condensation tank 340 and is controlled by the second fan 134 by the second fan 134. And it is discharged to the circulation port 135 connected to the interior of the shoe box or the like.

When humidity is detected in the air sucked into the suction port 121 by the humidity sensor 210, the controller 200 continuously drives the first fan 132 and simultaneously supplies power to the dehumidifying unit 300. To remove moisture from the air.

When power is applied to the dehumidifying unit 300, one side of the thermoelectric element 310 absorbs heat and the other side generates heat. Accordingly, the cooling member 320 provided at one side of the thermoelectric element 310. Is cold and the heat dissipation member 330 provided on the other side is heated.

The air forcedly sucked into the suction port 121 according to the driving of the first fan 132 is the cooling member 320 cooled by the thermoelectric element 310, that is, the first frame 321 and the inside thereof. Inflow into the passage of the air provided by the cooling plate 322 is provided bent in a zigzag and the forced suction air is cooled in contact with the cooling member 320 to reduce the amount of saturated water vapor of the forced suction air As a result, moisture in the air condenses and turns into liquid water.

The cooled air and the condensed water flow into the condensation tank 340 provided under the dehumidifying unit 300, and the cooled air flows back into the heat dissipation member 330, and the condensed water is the condensed water. Stored in bath 340.

The cooled air introduced into the heat dissipation member 330 is heated while contacting the heat dissipation plate 332 which is bent and zigzag inside the second frame 331, thereby increasing the amount of saturated steam.

The liquid water stored in the condensate tank 340 is the latent heat storage means 400, that is, the capillary body 410 provided in the zigzag heat dissipation plate 332, the lower end of the condensate tank 340. Touching the bottom surface and the upper end is provided to extend to the upper portion of the heat dissipation member 330 so that the water of the condensation tank 340 rides up through the lower end of the capillary body 410 by the capillary phenomenon.

That is, the water stored in the condensate tank 340 rises up the capillary body 410, and is heated by the heat dissipation member 330 to wet the capillary body 410, in which air with an increased amount of saturated steam is wet. The water on the surface of the capillary 410 is vaporized by the heat of the heat radiating member 330 and the heated air.

The air introduced into the heat dissipation member 330 flows into the first chamber 130-1 provided with the first fan 132 in a state containing a lot of moisture and is discharged to the outside through the discharge port 131.

The water stored in the condensation tank 340 is heated by the heat dissipation member 330 through the capillary body 410 and vaporized by the heated air, and the condensation tank together with the air discharged to the discharge port 131. The water stored in the 340 may be discharged together to prevent the water stored in the condensate tank 340 from overflowing or re-introducing into the control box, the wardrobe or the shoe closet due to the interruption of the air conditioner 10. Can be.

In addition, by preventing the condensate storage efficiency of the condensate tank 340 is lowered, it is possible to prevent the dehumidification performance of the dehumidification unit 300 is lowered, it is possible to maintain a steady dehumidification performance.

The ozone generator 220 provided in the control unit 200 may generate ozone to disinfect and purify the air sucked into the suction unit 120 to operate the dehumidifying unit 300 to dehumidify it. In addition, it is possible to purify the internal air of control boxes, wardrobes and shoe racks even during circulation.

For the safety of the user, when the chamber 100 is opened during the operation of the vaporization dehumidification air conditioner 10, the light sensor 230 provided in the control unit 200 is introduced into the chamber 100. By detecting the stop operation of the ozone generator 220 to prevent the ozone outflow to the outside of the chamber (100).

On the other hand, the control unit 200 adjusts the driving motor rotational speed of the first fan 132 and the second fan 134 according to the humidity in the air forcedly sucked into the suction port 121, or according to the user's setting The dehumidification performance may be controlled by controlling the thermoelectric element 310 of the dehumidifying part 300 by controlling the cooling temperature and the heating temperature of the cooling member 320 and the heat dissipation member 330.

As such, by using the vaporized dehumidifying air conditioner 10 according to the present invention, it is not necessary to separately provide a discharge pipe or a hose for discharging the condensed water stored in the condensate tank 340, it is possible to miniaturize the control box, closet and There is an advantage that can be installed so as to take up less space in the shoebox.

In addition, since the latent heat storage means 400 is provided in the dehumidifying part 300, the water stored in the condensation tank 340 can be removed more quickly, so that the dehumidifying performance of the vaporized dehumidifying air conditioner 10 according to the present invention is improved. It can improve and maintain the same dehumidification performance.

In addition, the circulation port 135 is provided in addition to the discharge port 131 to operate the dehumidifying unit 300 according to the humidity in the air to prevent unnecessary electricity consumption, and to circulate the air purified by the ozone generator 220. The internal air of the control box, wardrobe and shoe box can be cleaned.

In addition, as shown in FIG. 6, the heat dissipation member 500 and the heat dissipation member 330 and the cooling member 320, in which a large amount of expensive metal material having high thermal conductivity is used, are vertically coupled to the base plate to increase the surface area. ) And a plurality of cooling plates 600 are provided with a predetermined thickness, whereas the cooling member 320 and the heat dissipation member 330 according to the present invention are inside the first frame 321 and the second frame 331. In order to increase the thermal conductivity in the thin plate-like cooling plate 322 and the heat dissipation plate 332 is provided, and to increase the surface area by providing the cooling plate 322 and the heat dissipation plate 332 in a zigzag shape dehumidification efficiency There is an advantage to provide a high vaporization dehumidification air conditioner (10) capable of cost reduction.

The present invention is not limited to the specific preferred embodiments described above, and any person skilled in the art to which the present invention pertains can make various modifications without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

10: vaporization dehumidification air conditioner
100: chamber 110: partition
120: suction part 121: suction port
130: discharge part 130-1: first chamber
130-2: second chamber 131: discharge port
132: the first fan 133: partition wall
134: second fan 135: circulation port
200: control unit 210: humidity sensor
220: ozone generator 230: light sensor
300: dehumidifying unit 310: thermoelectric element
320: cooling member 321: cooling plate
330: heat dissipation member 331: heat dissipation plate
340: condensate tank 400: latent heat storage means
410 capillary body

Claims (5)

In the dehumidifier using a thermoelectric element,
A chamber having a partition therein and divided into a suction part having a suction hole and a discharge part having a discharge hole;
A first fan provided in the discharge part;
A control unit provided at an intake unit of the chamber to sense humidity of inhaled air; And
One side of the thermoelectric element is provided with a cooling member, the other side is provided with a heat dissipation member, the heat dissipation member is provided with a latent heat storage means and a condensation tank is provided at the lower portion of the cooling member and the heat dissipation member; Evaporative dehumidification air conditioner comprising a. The method of claim 1, wherein the latent heat storage means,
Evaporating and dehumidifying air conditioner, characterized in that the upper end is projected to the upper portion of the heat dissipation member, the lower end is a capillary body provided in contact with the bottom surface of the condensate tank. The method of claim 1, wherein the discharge portion of the chamber,
A partition provided across the central portion of the partition and the inside of the chamber in a direction perpendicular to the partition;
A second fan provided at a place where the first fan is not included among the discharge parts partitioned by the partition wall; And
And a circulation port provided in a section provided with the second fan of the discharge unit to discharge the air sucked into the suction unit back to the room. 4. The method according to any one of claims 1 to 3,
The cooling member,
A first frame penetrating up and down; And
And a cooling plate that is bent in a zigzag and provided in the first frame to provide a passage of air sucked into the intake port.
The heat dissipation member,
A second frame penetrating up and down; And
Evaporative and dehumidifying air conditioner comprising a; zigzag bent and provided in the second frame to provide a portion of the air intake to the suction port, a portion of the heat dissipation plate is inserted into the capillary body. The method of claim 1, wherein the control unit,
The control unit provided in the suction unit includes a humidity sensor for sensing the humidity of the air sucked into the suction port;
An ozone generator for purifying the air sucked into the suction port; And
And an optical sensor for stopping the operation of the ozone generator when the light is detected when the chamber is opened.

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