KR20060091375A - Heat exchanger of a dehumidifier - Google Patents

Abstract

The present invention relates to a heat exchanger of the dehumidifier, and absorbs air from the air conditioning space to absorb and remove moisture with the desiccant, and supplies desiccant air to the air conditioning space and removes moisture from the desiccant. In one dehumidifier, it has an air inlet for introducing hot and humid air passing through the regeneration unit of the desiccant regeneration mechanism, and passes the air introduced into the air intake inwards and contacts the air flowing from the air conditioning space to the outside surface. And a condensation passage for generating condensate therein, and having a condensate outlet for discharging the condensate generated inside the condensation passage, and having an air outlet for discharging air passing through the condensation passage to supply the regeneration unit. Doing.

According to the present invention, it is possible to improve the heat exchange performance by increasing the contact area with the outside air while smoothly discharging the condensate generated inside the heat exchanger, it is possible to miniaturize the heat exchanger with the same performance.

Air Conditioners, Dehumidifiers, Desiccants, Heat Exchangers, Condensate

Description

Heat exchanger of a dehumidifier

1 is an exploded perspective view showing a dehumidifier using a refrigeration cycle according to the prior art,

Figure 2 is a schematic side cross-sectional view showing a dehumidifier using a refrigeration cycle according to the prior art,

3 is a block diagram showing a dehumidifying principle of the dehumidifier using the desiccant according to the prior art,

4 is a conceptual diagram showing a dehumidifier using desiccant according to the prior art;

5 is an exploded photograph showing a dehumidifier using desiccant according to the prior art;

Figure 6 is a side view showing a heat exchanger of the dehumidifier using the desiccant according to the prior art,

Figure 7 is a side view showing a heat exchanger of the dehumidifier according to the present invention.

Explanation of symbols on the main parts of the drawings

130: heat exchanger 131: air intake

132: condensation passage 132a: inclined channel

132b: cross inclined channel 133: condensate outlet

134: air outlet

The present invention relates to a heat exchanger of a dehumidifier, and more particularly, to a heat exchanger for generating regenerated air in a dehumidifier performing a dehumidification function using desiccant.

In general, an air conditioner is used as a device for cooling or heating air in an air conditioning space by using a refrigeration cycle or removing moisture from the air. In this way, a dehumidifier is widely used but a desiccant (drying agent) has recently been used. The method of using is also developed.

The dehumidifier using the refrigeration cycle condenses moisture on the surface of the evaporator by passing the humid air in the air conditioning space through the heat exchanger in the refrigeration cycle to lower the humidity, and then discharges the dehumidified air back into the air conditioning space to lower the humidity in the room.

As shown in FIGS. 1 and 2, the dehumidifier according to the prior art dehumidifies from the cabinet 3 having the inlet 1 and the outlet 1 formed therein, and the air introduced into the inlet 1 of the cabinet 3. A heat exchanger 6 composed of an evaporator 4 and a condenser 5 acting, and a blower 7 for forcibly blowing air introduced into the inlet 1 of the cabinet 3 to the heat exchanger 6. And a compressor (8) connected to the evaporator (4) and the condenser (5) and compressing the refrigerant, and installed at a lower portion of the heat exchanger (6) during the dehumidification of the heat exchanger (6). It includes a water tank (9) for collecting condensate flowing down and condensed on the surface.

The evaporator 4 lowers the temperature of the refrigerant by evaporating the refrigerant in the liquefied state and thus lowers the surface temperature of the evaporator 4, thereby lowering the temperature of the air in contact with the surface.

As such, as the temperature around the evaporator 4 decreases, moisture contained in the air condenses and condenses with dew on the surface of the evaporator 4, and the condensed water is provided below the heat exchanger 6. Fall into fresh water tank.

Referring to the operation principle of the dehumidifier using a refrigeration cycle, when the compressor 8 is operated, the refrigerant circulates through the compressor 8, the condenser 5, the expansion valve (not shown), and the evaporator 4 sequentially. In addition, the blower 7 is operated to force air to the condenser 5 and the evaporator 4 to pass the evaporator 4 and the condenser 5.

At this time, when the moisture contained in the air comes into contact with the surface of the evaporator 4, the condensed water is formed, and the condensed water flows along the surface of the evaporator 4 so as to fall into the water tank 9 to remove the moisture in the air.

3 to 6, the dehumidifier using desiccant sucks air from the air conditioning space, absorbs and removes moisture to the desiccant (D), and supplies the air from which moisture is removed to the air conditioning space, and desiccates the desiccant. By removing the moisture from the desiccant (D) through the Kant regeneration mechanism it is possible to remove the moisture in the air conditioning space by regenerating the absorption performance of the desiccant.

Desiccant is a material that has a strong affinity for moisture and can absorb water vapor directly from the surrounding air, which can be regenerated repeatedly by applying heat to the desiccant to evaporate the collected water vapor. In other words, the desiccant regeneration mechanism performs such a regeneration function. The steam exchange between the wet air and the desiccant depends on the steam partial pressure in the wet air and the vapor pressure difference on the desiccant surface, respectively.

The desiccant regeneration mechanism is provided by heating and supplying regeneration air to the desiccant rotor 10 for rotating the desiccant D containing moisture and the desiccant D rotated by the desiccant rotor 10. The regeneration unit 20 removes water from the desiccant (D), and a heat exchanger (30) which flows in air passing through the regeneration unit (20) to condense and remove water.

At the surface of desiccant (D) through which ambient air passes, its vapor pressure is lower than that of ambient air, so it absorbs moisture, and the absorbed water vapor is absorbed when the regeneration unit (20) heats the desiccant (D). The vapor pressure is higher than that of air to release moisture, and the discharged water vapor condenses and is discharged to the outside while passing through a heat exchanger.

The heat exchanger 30 has an air suction port 31 for introducing high temperature and high humidity air passing through the regeneration unit 20, and a condensation passage 32 for passing the air introduced into the air suction port 31. And contacting the outer surface of the condensation flow passage 32 with air introduced from the air conditioning space to generate condensed water in the condensation flow passage 32, and to generate the condensation water generated in the condensation flow passage 32. It is provided with a discharge condensate discharge port 33, and is provided with an air discharge port 34 for discharging the air passing through the condensation passage 32 to supply to the regeneration unit (20).

The air inlet 31 is connected to the air outlet 21 of the regeneration unit 20 to introduce the hot and humid air of the regeneration unit 20 into the condensation passage 32, the air outlet 34 is regeneration By being connected to the air inlet 22 of the part 20, the air from which moisture is removed by the condensed water in the condensation passage 32 is supplied to the regeneration unit 20. The air supplied to the regeneration unit 20 is heated by the heater H to repeat the cycle supplied to the desiccant (D).

As shown in FIG. 6, the conventional heat exchanger 30 arranges the condensing passage 32 perpendicular to the direction of gravity in order to allow the generated condensate to smoothly flow on the surface. Although it can smoothly discharge, there is a problem in that the heat exchange efficiency is reduced in terms of heat transfer because it is not designed to maximize the contact area with air.

Therefore, the present invention has been made to solve the above problems, heat exchange of the dehumidifier can improve the heat exchange performance by increasing the contact area with the outside air while smoothly discharging the condensate generated inside the heat exchanger The purpose is to provide a flag.

The present invention for achieving the above object, the desiccant to suck the air from the air conditioning space to absorb and remove the moisture to the desiccant, supply the air from which the moisture is removed to the air conditioning space, to remove the moisture from the desiccant A kant regeneration mechanism is provided, and the desiccant regeneration mechanism is configured to supply moisture from the desiccant by heating and supplying regeneration air to the desiccant rotor for rotating the desiccant containing water and the desiccant rotated by the desiccant rotor. In the dehumidifier composed of a regeneration unit for removing and a heat exchanger for introducing water passing through the regeneration unit to condense and remove moisture through the condensation passage, the condensation passage is inclined with respect to the direction of gravity.

The air introduced into the air inlet is exchanged with the outside air of the condensation passage while passing through the inside of the condensation passage and then discharged to the air outlet. At this time, condensate is generated inside the condensation passage and discharged to the outside through the condensate outlet. Since the inclined channel and the cross inclined channel are formed to be inclined with respect to the gravity direction, the length of the flow path per unit area becomes longer than that in the vertical direction on the premise of forming the flow paths having the same interval, thereby increasing the contact area with air. This improves heat transfer performance.

The condensation passage may be formed in a double space at a predetermined interval along the inflow direction of the external air. At this time, the pair of condensing flow passages are provided to face each other, and the air inlet and the air outlet are formed in communication with each condensing flow passage, respectively, and the pair of condensing flow passages are communicated with each other by the connection flow passage at the lower end, The condensate collected downward is preferably moved to one condensate outlet through the connecting passage, and the external air exchanges heat with the condensate passage by continuously passing through the pair of condensate passages.

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

Referring to FIG. 7, the heat exchanger according to the present invention includes an air inlet 131 for introducing high temperature and high humidity air passing through the regeneration unit 20 of the desiccant regeneration mechanism, and to the air intake 131. It has a condensation passage 132 for passing the introduced air to the inside and the condensate in the interior contact with the air flowing from the air conditioning space to generate condensate therein, and discharges the condensate generated in the condensation passage 132 A condensate outlet 133 is provided, and an air outlet 134 is provided to discharge the air passing through the condensation passage 132 to the regeneration unit 20.

The condensation passage 132 is composed of a plurality of inclined channels 132a and cross inclined channels 132b which are formed to be inclined with respect to the gravity direction.

The inclined channels 132a are formed in communication with each other, and a plurality of the inclined channels are formed in parallel with a predetermined interval therebetween, and the cross inclined channels 132b are formed in communication with the inclined channels 132a, and the inclined channels 132a are formed. It is formed in a direction crossing the and is formed parallel to each other at a predetermined interval.

The plurality of inclined channels 132a and the cross inclined channels 132b are formed by forming a plurality of inclined channels 132a and the cross inclined channels 132b in a rectangular frame as a whole, and the inclined channels 132a and the cross inclined channels 132b. The part of) is formed on the diagonal of the square frame.

The air introduced into the air inlet 131 passes through the inside of the condensation passage 132 to exchange heat with the outside air of the condensation passage 132, and then is discharged to the air outlet 134. Inside, condensate is generated and discharged to the outside through the condensate outlet 133.

Here, the inclined channel 132a and the cross inclined channel 132b are formed to be inclined with respect to the direction of gravity, so that the condensed water generated inside the condensation flow passage 132 falls on the inner wall of the condensation flow passage 132 to condense water outlet 133. Can be easily discharged, the length of the flow path per unit area becomes longer than the flow path in the vertical direction on the premise that the condensation flow path 132 forming a rectangular frame is inclined along the diagonal direction to form the flow paths of the same interval. Therefore, the heat transfer performance is improved by increasing the contact area with air.

On the other hand, the moisture in the air passing through the condensation passage 132 is in contact with the inner wall of the flow path is quickly exchanged heat is generated smoothly, condensed water is generated smoothly, the inclined channel 132a or cross inclined channel 132b Since gravity acts on the moisture, the probability of contact with the inner wall of the adjacent flow path increases, and the moisture is easily converted into condensed water, thereby improving water removal performance.

In addition, when the condensate formed in the inclined channel 132a or the cross inclined channel 132b moves along the inclined direction of the rectangular frame, the condensed water drops and moves stepwise on the inner wall of the flow path by gravity to move on the moving path. The resulting droplets are easily coalesced and dropped to facilitate the discharge of condensate.

Therefore, the size of the heat exchanger can be reduced based on the same heat exchange performance.

As described above, according to the heat exchanger of the dehumidifier according to the present invention, the heat exchange performance can be improved by increasing the contact area with external air while smoothly discharging the condensate generated inside the heat exchanger, and miniaturizing the heat exchanger with the same performance. It can work.

Claims (4)

A desiccant regeneration mechanism for sucking air from the air conditioning space to absorb and remove moisture with the desiccant, supplying the air from which the moisture has been removed, to remove the moisture from the desiccant, and The desiccant regeneration mechanism, A desiccant rotor for rotating the desiccant containing water; A regeneration unit for removing moisture from the desiccant by heating and supplying regeneration air to the desiccant rotated by the desiccant rotor; An air inlet for introducing hot and humid air passing through the regeneration unit, and a condensation passage for passing air introduced into the air inlet, and contacting an outer surface of the condensation passage with air introduced from an air conditioning space. A heat exchanger having a condensate outlet for generating condensate in the condensate passage and discharging condensate generated in the condensate passage, and having an air outlet for discharging air passing through the condensation passage and supplying it to the regeneration unit In the dehumidifier comprising a; The condensation passage is a heat exchanger of the dehumidifier, characterized in that formed inclined with respect to the direction of gravity. The method of claim 1, wherein the condensation passage, And a plurality of inclined channels formed in communication with each other and formed in parallel with a plurality of predetermined intervals. The method of claim 2, wherein the condensation passage, And a cross inclined channel formed in communication with the inclined channel and formed in a direction crossing the inclined channel, the cross inclined channels being formed to be parallel to each other with a predetermined interval therebetween. The method of claim 2 or 3, wherein the condensation passage is formed of a plurality of inclined channels and cross inclined channels as a whole a rectangular frame, a portion of the inclined channel and the cross inclined channel is formed on a diagonal of the rectangular frame Heat exchanger of dehumidifier.

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