KR100688351B1 - Device for heat exchanger be used evaporation latent heat of water - Google Patents

Abstract

A heat exchange device using evaporation latent heat of water is provided to exchange heat between room air and atmospheric air after lowering a temperature of room air with water discharged from a heat exchanger. A heat exchange device using evaporation latent heat of water includes a humidifying part(100) for spraying water to room air discharged through an outlet path(12) of a housing(11) by rotation of a discharge fan(12'), so that a temperature of atmospheric air introduced through an inlet path(13) by a suction fan becomes lowered by evaporation latent heat of the water. The humidification part has a humidifying element(120) for spraying water, a supply pipe(110) for guiding water from a water service pipe to the humidifying element, and a valve(130) for controlling a water supply amount under the control of a control part(200).

Description

Heat exchanger using latent heat of water {device for heat exchanger be used evaporation latent heat of water}

1 is a flow chart of a general heat exchanger

Figure 2 shows a conventional heat exchanger,

a is schematic,

b is a perspective view of the heat exchange unit;

3 is a block diagram of the present invention.

Figure 4 is a schematic diagram of a heat exchanger device to which the present invention is applied

5 is a use state diagram of the present invention

6 is a flow chart of the present invention.

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

100: humidifier 110: supply pipe

120: humidifying member 130: valve

140: guideman 200: control unit

300: anion generating unit

The present invention relates to a heat exchanger, and more particularly, it is possible to reduce heat loss of indoor air by heat-exchanging with outdoor air in a state in which water is sprayed into the indoor air discharged into the discharge passage of the heat exchanger and dropped further by the latent heat of evaporation of water. It relates to a heat exchanger using latent heat of evaporation of water.

In general, buildings such as apartments and houses are not equipped with a separate device for ventilating the polluted air in the room. Therefore, when ventilating the polluted air in the room, most people use windows such as the living room. The situation is to ventilate the polluted air.

The ventilation means only the effects of deodorization, dehumidification, and room temperature control to discharge contaminated air in the room.

As described above, when the indoor polluted air is ventilated using the window, the outdoor air is rapidly introduced into the room, and the heat efficiency decreases as it is discharged as it is through the window while easily losing the cooled and heated indoor air. .

As a means to solve this problem, a heat exchanger is used, which uses the principle of moving heat and moisture from a high place to a low place, as shown in FIG. 1, that is, fresh and hot air in the summer outdoors. Is introduced into the room, it is a device that can reduce the heat loss of the air conditioner because it is introduced into the room by reducing the temperature of the fresh outdoor air to the temperature of the indoor air by heat exchange with the contaminated cold air in the room.

The heat exchange device 10, as shown in Figure 2, is divided into the housing 11 of the rectangular housing is equipped with a discharge passage 12 and the inlet fan 13 'equipped with a discharge fan (12'). And a heat exchange unit 14 that is stacked in multiple stages while maintaining a phase difference of 90 ° such that the discharge passage 12 and the inflow passage 13 intersect each other.

Here, the process of heat-exchanging the indoor / outdoor air through the heat exchange unit 14 will be described as an example in summer when the outdoor temperature is 35 ° C and the cooled indoor temperature is 30 ° C.

In summer, when the outdoor temperature is maintained at 35 ° C., when the exhaust fan 12 ′ and the inlet fan 13 ′ are rotated by the operation of the heat exchanger 10 while the air conditioner is operated to maintain an indoor temperature of 30 ° C., Polluted and cool air in the room maintained at 30 ° C by the rotation of the discharge fan 12 'is discharged to the discharge passage 12 and at the same time, fresh and hot air in the outdoor area maintained at 35 ° C by the rotation of the inlet fan 13'. Is introduced into the inflow passage 13 to be introduced into the room in the state of filtering the foreign matter through the filter (15).

The cold and hot outdoor air at 30 ° C discharged to the discharge passage 12 and the hot and cold outdoor air at 35 ° C flowing into the inflow passage 13 pass through the heat exchange unit 14. Hot air exchanges heat, and outdoor hot air exchanges with indoor cold air to enter the room at a temperature of 31 ° C, while indoor cold air heats up with outdoor air to heat up to 34 ° C. Are discharged to the outdoors.

으로 ,Here, the formula of the temperature exchange efficiency in which indoor air and outdoor air heat exchange is

to ,

n _t : Temperature exchange efficiency (%)

t _OA : outside dry bulb temperature (℃) = 35 ℃,

t _SA : Air supply dry bulb temperature (℃) = 31 ℃,

t _RA : Ventilation dry temperature (° C.) = 30 ° C. The above equation shows that the temperature exchange efficiency of 80% is obtained.

으로 구할 수 있으며, 이는 34℃로 변환되어 배출됨을 알 수 있다.In addition, the temperature of the indoor air discharged to the outdoor through the discharge passage 12 of the heat exchanger 10 by the temperature exchange efficiency of 80%,

It can be obtained, which is converted to 34 ℃ can be seen that the discharge.

However, the temperature exchange efficiency may change according to the pollution degree of the indoor air. Here, the pollution rate of the indoor air does not matter, and only the exchange efficiency according to the indoor and outdoor temperature changes will be described.

However, while the heat of the heat exchanger is configured as described above, the temperature of the indoor air changes to a high temperature and is discharged to the outside, and the temperature of the outdoor air changes to a low temperature, so that the heat loss of the indoor air can be reduced. Not only can the temperature of the fresh outdoor air flowing into the room be lowered to the temperature of the indoor air, but also the indoor air is brought into the room when the temperature of the outdoor air is higher than the temperature of the indoor air. The air conditioner must be operated, which causes a problem of energy loss.

The present invention is made in view of the above-mentioned conventional defects, and an object thereof is that the outdoor air is dropped by the latent heat of evaporation while the indoor air evaporates the water sprayed into the indoor air discharged into the discharge passage of the heat exchanger. And to provide a heat exchanger using the latent heat of evaporation of water to heat exchange in the heat exchange unit to reduce the heat loss of the indoor air.

In addition, another object of the present invention, the evaporation of water that can be introduced into the room by the small water droplets and fine anions are added to the outdoor air introduced by heat exchange in the heat exchange unit of the heat exchanger is introduced into the room to maintain a comfortable indoor environment It is to provide a heat exchanger using latent heat.

The present invention for achieving this object,

By rotating the inlet fan of the heat exchanger, the indoor air discharged to the exhaust passage of the housing by the rotation of the exhaust fan is allowed to lower the temperature of the outdoor air introduced into the inlet passage through the filter of the housing by the latent heat of evaporation of water from the heat exchange unit. It is characterized by comprising a humidifying unit for spraying water.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 3 is a block diagram of the present invention.

According to the present invention, the temperature of the outdoor air introduced into the inflow passage 13 through the filter 15 of the housing 11 by the rotation of the inflow fan 13 ′ of the heat exchanger 10 is evaporated from the heat exchange unit 14. To configure the humidifying part 100 to spray water to the indoor air discharged to the discharge passage 12 of the housing 11 by the rotation of the discharge fan 12 'so as to be further dropped by the latent heat, more specifically Explained as follows.

The humidifying part 100 is connected to the water pipe is provided with a supply pipe 110 to guide the water supplied from the water pipe to the humidifying member 120, spraying the water supplied to the supply pipe 110 The humidifying member 120 is provided, and the valve 130 is provided to adjust the amount of water supplied under the control of the controller 200 while controlling the amount of water sprayed by the humidifying member 120.

In addition, anion generation that generates negative ions to add the negative ions to the indoor air heat exchanged in the heat exchange unit 14 and the indoor air that is further separated by the latent heat of evaporation of water sprayed from the humidifying part 100 to introduce the negative ions into the room It further comprises a unit 300.

Next, referring to the installation process of the present invention configured as described above, first, as shown in FIG. 4, a discharge passage penetrating inside the housing 11 in which the heat exchange unit 14 of the heat exchanger 10 is installed ( 12) That is, the humidifying member 120 of the humidifying part 100 is mounted on the other discharge passage 12 of the discharge fan 12 ', and the inflow passage 13 penetrates inside the housing 11, The heat exchanger 10 is installed at the rear of the inlet fan 13 ′ in a state where the interior of the building communicates with the interior of the building while the anion generator 300 is mounted, for example, on the upper portion of the balcony or the kitchen where the window is installed. After fixing the, connecting the supply pipes 110 and 310 so that water can be supplied from the water pipe to the humidifying unit 100 and the negative ion generating unit 300, respectively.

In this state, when the outdoor temperature in summer becomes 35 ° C. and the room is cooled to maintain 30 ° C. as an example, as illustrated in FIGS. 5 and 6, the discharge fan 12 is controlled by the control unit 200. ') And the inlet fan 13' rotate and at the same time open the valve 130 so that the water supplied from the water pipe is sprayed from the humidifying member 120 via the supply pipe 110 is operated. .

Here, the humidifying member 120 may spray the water supplied to the supply pipe 110 through a spray nozzle, or may spray the water supplied to the supply pipe 110 with a humidifier.

The discharge fan 12 'of the heat exchanger 10 rotates to discharge the polluted and cold air in the room maintaining 30 ° C to the discharge passage 12 to discharge the air to the outside and at the same time the inlet fan 13'. The fresh and hot air of the outdoor maintaining 35 ° C by the rotation of the inlet flows into the inflow passage 13 so that the foreign matter is introduced into the room through the filter (15).

At this time, the water from the humidifying member 120 to the inside of the discharge passage 12 in the contaminated and cool air to maintain the 30 ° C indoor air discharged to the discharge passage 12 by the rotation of the discharge fan 12 '. As the indoor air evaporates the sprayed water and absorbs the heat of the indoor air as much as the latent heat of evaporation of the water, the temperature of the indoor air absorbs about 540kcal per 1kg of water, the latent heat of evaporation of water. Falling, the water sprayed from the humidifying member 120 is not heat-exchanged with the indoor air is moved to the bottom of the discharge passage 12 is stored in the negative ion generating unit 300 via the guide hole (140).

In addition, by absorbing the heat amount of the indoor air as the latent heat of evaporation of water is discharged to the heat exchange unit 14 in a state in which the temperature of the indoor air is converted to 27.5 ℃ apart 2.5 ℃ is made of heat exchange with the outdoor air flowing into 35 ℃, The outdoor air heat-heated in the heat exchange unit 14 is converted into 29 ° C. and introduced into the inflow passage 13.

으로 ,Here, the formula of the temperature exchange efficiency in which indoor air and outdoor air heat exchange is

to ,

n _t : Temperature exchange efficiency (%)

t _OA : outside dry bulb temperature (℃) = 35 ℃

t _SA : Air supply dry bulb temperature (℃) = 29 ℃

t _RA : Ventilation drying temperature (° C.) = 27.5 ° C., which indicates that the temperature exchange efficiency of 120% can be obtained by the above formula.

으로 구할 수 있으며, 이는 33.5℃로 변환되어 배출됨을 알 수 있다.In addition, the temperature of the indoor air discharged to the outside by the temperature exchange efficiency of 120%,

It can be obtained, which is converted to 33.5 ℃ can be seen that the discharge.

However, the heat exchange efficiency may change according to the pollution degree of the indoor air. Here, the pollution degree of the indoor air does not matter, and only the temperature exchange efficiency according to the indoor and outdoor temperature changes is described.

On the other hand, the heat is exchanged to 29 ℃ in the heat exchange unit 14 and the indoor air flows into the inflow passage 13 and at the same time the water supplied from the water pipe by opening the valve 310 under the control of the control unit 200 is anion generating unit The heat exchanger 10 is operated to be supplied to the 300.

At this time, the water supplied to the valve 310 is stored to maintain a constant level at all times through the upper and lower water level sensors 321, 321 'located inside the water storage member 320, the water storage member ( The water stored in 320 is supplied to at least one anion generator 340 by a pumping operation of the pump 330 and at the same time an anion is generated in the anion generator 340. The process of generating the anion is applied by the applicant of the present application. Reference is made to a 2004 Patent No. 20121.

When the water supplied to the anion generator 340 by the pumping operation of the pump 330 is moved to the spray nozzle through the nozzle ribs and sprayed with the spray cap, it collides with the impact hole to form a fine water droplet of water droplets At the same time, the water splashes again and collides with the plate, and the water collided with the plate is scattered horizontally at the end of the plate and is instantaneously diffused to generate anions of fine droplets.

The negative ions generated by the above process and positioned in the inflow passage 13 are heat-exchanged in the heat exchange unit 14 according to the rotation of the inflow fan 13 ′ and are introduced into the room together with outdoor air maintaining 29 ° C. The negative ions can maintain a comfortable indoor environment.

Meanwhile, the humidifier 100 and the negative ion generating unit 300 may operate simultaneously under the control of the control unit 200 by changing the temperature of the season or the weather, and the humidifying unit 100 and the negative ion generating unit 300 may be operated. Each of them may be selected and operated, and the exhaust fan 12 'and the inflow fan 13' may be rotated at a constant speed under the control of the controller 200 to continuously vent indoor and outdoor air as well as discharge the air. While operating the rotation of the fan 12 'and the inlet fan 13' at regular intervals, it is also possible to ventilate indoor and outdoor air.

As described above, the present invention, by spraying the water in the humidifier to the indoor air discharged to the discharge passage of the heat exchanger to be discharged to the outdoor to heat exchange with the outdoor air in a state in which the temperature of the indoor air is further reduced by the latent heat of water evaporation Not only can the heat loss of indoor air be reduced, but the energy consumed for cooling operation can be saved, thereby improving economics.

In addition, the present invention, by adding negative ions generated by the collision of water to the outdoor air heat exchanged in the heat exchange unit to be introduced into the room, has the advantage of maintaining a comfortable indoor environment.

Claims (5)

By rotating the inlet fan 13 ′ of the heat exchanger 10, the temperature of the outdoor air introduced into the inlet passage 13 through the filter 15 of the housing 11 is further reduced by the latent heat of evaporation of water from the heat exchange unit 14. By using the latent heat of evaporation of water, the humidifying part 100 is configured to spray water into the indoor air discharged into the discharge passage 12 of the housing 11 by rotating the discharge fan 12 '. Heat exchanger. The humidifier 100 of claim 1, A supply pipe 110 connected to the water pipe to guide the water supplied from the water pipe to the humidifying member 120; A humidifying member 120 for spraying water supplied to the supply pipe 110; Heat exchanger using the latent heat of evaporation of water, characterized in that provided with a valve 130 for adjusting the amount of water under the control of the control unit 200 while controlling the amount of water sprayed to the humidifying member (120). The method of claim 2, wherein the humidifying member 120, Heat exchanger using latent heat of evaporation of water, characterized in that the spray nozzle for spraying water. The method of claim 1, Anion generating unit for generating negative ions to add the negative ions to the indoor air heat exchanged in the heat exchange unit 14 and the indoor air which is further separated by the latent heat of evaporation of water sprayed from the humidifying unit 100 to introduce the negative ions into the room ( Heat exchanger using latent heat of evaporation of water, characterized in that further comprises a 300). The method according to claim 1 or 4, Guide hole 140 that is communicated to the discharge passage 12 and the inlet passage 13 to drain the water stored in the lower portion of the discharge passage 12 to the negative ion generating unit 300 sprayed to the humidification unit 100 Heat exchanger using latent heat of evaporation of water, characterized in that the configuration further comprising.

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