KR20200034351A - Dehumidifying aparatus - Google Patents

Abstract

The present invention relates to a dehumidification apparatus including a cooling system circulating a refrigerant to a condenser, an expander, and an evaporator by using a compressor. More specifically, the dehumidification apparatus includes: a casing comprising inlets formed on at least two of the front and rear and left and right side surfaces, an outlet formed in the upper part and a water collection part formed in the lower part to collect moisture condensed in the air; an evaporator installed to be adjacent to each of the inlets in an inward direction of the casing; a condenser installed to be spaced from the evaporator; and an air blow fan installed in the lower part of the outlet to enable the air suctioned into the inlets to be discharged through the outlet after being dehumidified. Therefore, the condenser is installed adjacent to the evaporator to enable the air cooled by the evaporator to be heated by the condenser, while the condenser and the evaporator are combined with one single radiator. A plurality of radiators are installed to increase the temperature of the cooled air to a normal temperature through the condenser while dehumidifying the air. Since hot and cold conditions coexist in one radiator, the discharged air can be prevented from being heated at a high temperature.

Description

Dehumidifying device {Dehumidifying aparatus}

The present invention relates to a dehumidifying device including a cooling system circulating a refrigerant to a condenser, an expander, and an evaporator using a compressor. In particular, a condenser is installed adjacent to the evaporator so that air cooled in the evaporator is heated in the condenser, The condenser and the evaporator are coupled to one heat sink, and a plurality of heat sinks are provided, so that the cooled air can be directly heated to a normal temperature by the condenser by dehumidifying the intake air, and the cool state of one heat sink It relates to a dehumidifying device that can prevent the discharged air is heated to a high temperature because the and the hot state coexist.

In the summer of Korea, mercury stock rises high and is not only hot, but also has high humidity, making it difficult to withstand. When the humidity is high, the discomfort index that a person feels increases and is not good for health. If the indoor humidity is high, mold is easy to bloom, and harmful insects such as fleas and cockroaches also love the environment with high humidity.

Humidity includes absolute humidity and relative humidity. Humidity when determining an unpleasant index refers to relative humidity (RH). Absolute humidity literally refers to the amount of absolute water vapor contained in the air, and relative humidity refers to the amount of water vapor in the atmosphere relative to the relative humidity, i.e., saturated water vapor at the current temperature. The humidity in the weather forecast refers to the relative humidity. For a comfortable interior, it is good to maintain the relative humidity at 40-60%.

As the amount of saturated water vapor increases or the amount of water vapor in the atmosphere decreases, the relative humidity decreases, and the amount of saturated water vapor increases with temperature, so heating the air can increase the amount of saturated water vapor, thereby reducing the relative humidity.

Also, the relative humidity can be lowered by directly removing the moisture in the air. A dehumidifier is a machine that makes pleasant air by controlling the relative humidity in this way.

That is, as shown in FIG. 1, the refrigerant is circulated while sequentially passing through the evaporator 2, the compressor 4, and the condenser 6, but the air introduced into the main body 8 receives the evaporator 2 The temperature drops as it goes through, and accordingly, the dew point is lowered so that moisture in the air is condensed, heated while passing through the condenser 6, and then dried air is discharged by the blowing fan 10 to dehumidify.

However, the above-described conventional dehumidifier has a problem in that efficiency is lowered by sucking air in one direction and discharging dehumidified air in the other direction, in particular, cooling in the evaporator 2 as shown in FIG. 1. Since the heated air is discharged to the outside after being heated again in the condenser 6, hot air is discharged to the outside, thereby causing problems such as affecting indoor and outdoor temperatures.

The present invention is to solve this problem, the object of the present invention is to ensure that the temperature difference between the air flowing into the dehumidifying device and the air discharged after dehumidification is minimized to maintain the internal temperature of the dehumidifying space at a constant temperature. While providing a device, by inhaling air from various directions to dehumidify, the dehumidifying effect is maximized, and the anion generated from the anion generator is included in the air that is discharged to make it environmentally friendly, but also dehumidified air or water dehumidified in the air The purpose of this is to provide an environmentally friendly dehumidifying device by disinfecting by the far infrared ray and then draining.

The above object is a dehumidifying device including a cooling system that circulates refrigerant to a condenser 106, an expander 108, and an evaporator 110 using a compressor 104, wherein at least two or more sides of the front, rear, left, and right sides are intake ports ( 112) is formed, the outlet 114 is formed on the upper portion, the lower portion of the casing 118 is formed with a water collecting unit 116 to collect the water condensed in the air; In the inner direction of the casing 118, each evaporator 110 is installed to be adjacent to each inlet 112, and condensers 106 are installed to be spaced apart from the evaporator 110, and blown air is provided at the bottom of the outlet 114 It is achieved by a dehumidifying device characterized in that by installing the fan 120, the air sucked into the suction port 112 is dehumidified and then discharged to the discharge port (114).

In addition, the evaporator 110 and the condenser 106 are simultaneously coupled to one heat sink 122, and at least one through hole 122a is formed between the evaporator 110 and the condenser 106, and the evaporator ( 110) and the condenser 106, it is preferable that a plurality of heat sinks 122 are coupled.

In addition, the inside of the casing 118 further includes an anion generator 124 for generating negative ions, which is dehumidified in the evaporator 110, or is discharged after being dehumidified in the evaporator 110 or collected in the collecting unit 116 after dehumidification. It is preferable that the water is sterilized by the far infrared rays emitted from the far infrared ray generating unit 126 and then exhausted or drained.

The present invention intakes air from two or more of the front, rear, left, and right sides, but has an effect of maximizing the dehumidifying effect by installing an evaporator and a condenser in the inlet, respectively. In order to achieve a balance, in particular, a condenser is installed adjacent to the evaporator so that the air cooled in the evaporator is heated in the condenser, but the condenser and the evaporator are combined in one heat sink, and a plurality of heat sinks are provided. While dehumidifying the intake air, the cooled air can be heated up to the normal temperature by the condenser, and the cool and hot states coexist on one heat sink, so that the discharged air can be prevented from being heated to a high temperature. It has the effect.

1 is a conceptual view showing the structure of a conventional dehumidifying device.
2 is a conceptual view showing the structure of a dehumidifying device according to the present invention.

Referring to the configuration and operation of the present invention with reference to the accompanying Figure 2 as follows.

As illustrated in FIG. 2, a cooling system for circulating refrigerant through a compressor 104, a condenser 106, an expander 108, and an evaporator 110 is installed inside the casing 118, and the above-described compressor 104 , The cooling system by the condenser 106, the expander 108, and the evaporator 110 is due to the cooling cycle, and since it is a self-evident fact, it will be briefly described below, and its detailed description will be omitted.

The cooling cycle includes a compressor 104 for compressing a gas refrigerant such as Freon to a high temperature and high pressure gas refrigerant, and a condenser for condensing and liquefying the high temperature and high pressure gas refrigerant transferred from the compressor 104 by external air ( 106) (Condenser), the expander 108 for depressurizing the liquid refrigerant from the condenser 106, and the evaporator 110 for absorbing and cooling the surrounding heat while the depressurized refrigerant from the expander 108 is evaporated (Evaporator), and is provided with a blower fan 120 for cooling the refrigerant passing through the condenser 106 or circulating the air inside the casing 118.

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In the present invention, the intake port 112 is formed on at least two of the front, rear, left, and right sides of the casing 118 to allow external air to flow into the casing 118 through the intake port 112.

Here, the evaporator 110 is installed at the suction port 112 so that the inhaled air comes into contact with the evaporator 110 first, and the air cooled by the evaporator 110 or the dehumidified air is successively connected to the condenser 106. Let it meet, and the action of raising the temperature in the cooled air occurs.

As shown in the upper portion of the casing 118, an outlet 114 is formed to be sucked into the suction port 112 to allow dehumidified air to be discharged, and a blower fan 120 is provided below the discharge port 114. By installing the outside air is sucked into the intake port 112, it can be discharged to the outlet 114 through the blowing fan 120.

Meanwhile, as shown in FIG. 2, the evaporator 110 and the condenser 106 are coupled to one heat sink 122, but a plurality of heat sinks 122 are provided to cool the cooling effect by the evaporator 110 or The dehumidification effect is improved, and the heat dissipation effect or heat generation effect by the condenser 106 is improved.

However, since both the evaporator 110 and the condenser 106 are coupled to the heat sink 122 according to the present invention, cooling and exothermic actions occur at the same time. At this time, the evaporator is first sucked through the suction port 112 ( The air that meets 110) is condensed and dehumidified by the cooling action, and then continues to meet the condenser 106. As described above, the heat generation effect by the heat sink 122, which simultaneously generates cooling and exothermic actions, condensers 106 Since it is reduced compared to the capacity of the, the effect of raising the dried and cooled air that has passed through the condenser 106 is hardly expected, and accordingly, the air discharged to the discharge port 114 is not heated, that is, the suction port It is discharged to the temperature of the state before being sucked into (112).

Accordingly, it does not significantly affect the temperature change outside the casing 118.

On the other hand, since the evaporator 110 may reduce the ability of the evaporator 110, in the present invention, a plurality of through holes 122a are formed at a position between the evaporator 110 and the condenser 106 in the heat sink 122. You can also control the temperature transition.

That is, since the plurality of heat sinks 122 have a structure in which one heat sink 122 is coupled to the evaporator 110 and the condenser 106, the heat generated by the condenser 106 follows the heat sink 122. 110) may be conducted to the side, and thus, there may be a possibility that the dehumidifying effect of the evaporator 110 may decrease, thereby forming a through hole 122a between the evaporator 110 and the condenser 106 to reduce the conduction phenomenon. , Since the conduction phenomenon at an appropriate temperature is a means to prevent the cooled air from being heated to a temperature that is too high when it is heated again without reducing the dehumidifying effect of the evaporator 110, the dehumidifying capacity of the air and the dehumidified air It is possible to control the heating capacity.

In addition, it is preferable to install an anion generating unit 124 for generating anion inside the casing 118 so that anion is included in the air discharged to the outside, so that an environmentally friendly requirement can be added. It is preferable that the air discharged after being dehumidified at 110 or the water collected at the collecting part 116 after being dehumidified is sterilized by the far infrared rays generated at the far infrared generating unit 126 and then exhausted or drained.

104: compressor
106: condenser 108: expander
110: evaporator 112: inlet
114: outlet 116: water collecting part
118: casing 120: blowing fan
122: heat sink 122a: through
124: anion generator
126: far infrared ray generation unit

Claims (3)

In the dehumidifying device including a cooling system for circulating the refrigerant to the condenser 106, the expander 108, the evaporator 110 using the compressor 104,
A casing 118 in which at least two sides of at least two sides of the front, rear, left and right sides are formed, an outlet 114 is formed at an upper portion, and a collecting portion 116 is formed at the lower portion to collect moisture condensed in the air;
In the inner direction of the casing 118, each evaporator 110 is installed to be adjacent to each inlet 112, and condensers 106 are installed to be spaced apart from the evaporator 110, and blown air is provided at the bottom of the outlet 114 Dehumidifying device characterized in that by installing the fan 120, the air sucked into the suction port 112 is dehumidified and then discharged to the discharge port (114).
According to claim 1,
The evaporator 110 and the condenser 106 are simultaneously coupled to one heat sink 122, but at least one through hole 122a is formed between the evaporator 110 and the condenser 106, and the evaporator 110 Dehumidifying device characterized in that a plurality of heat sinks (122) are coupled to the condenser (106).
According to claim 1,
Dehumidifying device further comprises an anion generator 124 installed inside the casing 118 to generate anions.

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