KR101191716B1 - Rotary type heat exchanging apparatus - Google Patents

Abstract

PURPOSE: A rotary electric heat exchange device is provided to create an intermediate layer by dividing an electric heat exchange device into a plurality of layers. CONSTITUTION: A first external layer(411) includes one area corresponding to a first flow path and another area corresponding to a second flow path. A second external layer(412) corresponds to the first external layer. An intermediate layer(413) includes an activated carbon filter layer. The intermediate layer is formed between the first external layer and the second external layer. The intermediate layer filters air which passes through the second external layer.

Description

ROTARY TYPE HEAT EXCHANGING APPARATUS}

The present invention relates to a rotary total heat exchange element, and more particularly, to a rotary total heat exchange element that performs a total heat exchange function and an air filtration function.

Modern life is inevitably accompanied by living in a room that is blocked from the outside air, and thus a ventilation device for exchanging indoor air with external air is essential. In general, the indoor ventilation device uses a blower to exhaust the indoor air. However, when the indoor air is discharged in this manner, the indoor air or heat is discharged to the outside without filtration, and the outdoor air is introduced through the gaps of the windows or doors, thereby losing the heat and cooling of the room, thus unnecessary consumption of cooling and heating costs. Will result.

Waste heat recovery ventilator has been proposed to solve this problem, waste heat recovery ventilator is a two-way ventilation system for releasing the indoor polluted air and at the same time to supply the outdoor air through the filtration, purification, heat exchange. At this time, the total heat exchange element may serve as a heat exchanger to conserve the heat energy of the indoor air during ventilation during the heating and cooling to give the heat energy to the outdoor air introduced. That is, the heat energy (sensible and latent heat) included in the air to be ventilated is absorbed by the total heat exchange element and serves to transfer the heat energy to the air supplied.

The heat recovery ventilator is a two-way ventilation system that discharges indoor contaminated air and supplies fresh external air to the interior at the same time. In general, the waste heat recovery electrothermal exchange element uses an air supply passage and indoor air to guide outdoor air to the interior. It may be arranged at the point where the exhaust flow passage leading to the outdoors cross. The waste heat recovery ventilator may include a total heat exchange element for performing heat exchange of the air to be supplied and exhausted, and a blower installed at the air supply path and the exhaust path. Through the total heat exchange element, the sensible and latent heat of the indoor air may be preserved and discharged so that heat energy may be exchanged during supply and exhaust.

However, most of the conventional heat exchange elements are configured to minimize heat loss by increasing the recovery rate of waste heat during heat exchange, and these heat exchange elements do not have a practical and effective filtration function of the outside air supplied to the room. have.

In order to solve the above problems, an object of the present invention is to provide a total heat exchange element that performs heat exchange and air filtration by dividing the total heat exchange element through which air passes into a plurality of layers and forming an intermediate layer.

According to an aspect of the present invention, in the rotary electrothermal heat exchange element having a first flow path through which indoor air passes outdoors and a second flow path through which outdoor air passes indoors, one region and a second corresponding to the first flow path are formed. A first outer layer having another area corresponding to the flow path, one region corresponding to the first flow path and another area corresponding to the second flow path, and having a second outer layer facing the first outer layer, and activated carbon Including an activated carbon filter layer formed between the first outer layer and the second outer layer, the outdoor air passing through the second outer layer is filtered and delivered to the first outer layer, the indoor air passing through the first outer layer And an intermediate layer which is filtered and transferred to the second outer layer, absorbs sensible heat and latent heat of indoor air introduced into one region of the first outer layer, and absorbs the absorbed sensible and latent heat. 2 to other areas of the outer layer It provides a rotary electrothermal heat exchange element that delivers the incoming outdoor air.

According to the present invention, it is possible to obtain a total heat exchange element for performing a heat exchange and an air filtration function.

1 is a view for explaining the operation of the total heat exchanger to which the total heat exchange element according to an embodiment of the present invention.
2 is a view schematically showing a total heat exchange element according to an embodiment of the present invention.
3 is a structural diagram of a total heat exchange element according to another embodiment of the present invention.
4 is a structural diagram of a total heat exchange element according to another embodiment of the present invention.
5 is a structural diagram of a total heat exchange element according to another embodiment of the present invention.

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

1 is a view for explaining the structure of a total heat exchanger using a total heat exchange element according to an embodiment of the present invention.

Referring to FIG. 1, the heat exchanger 100 according to the present embodiment includes a main body housing 101 having an inlet and an exhaust port, a plurality of blowing fans 141 and 142 disposed inside the main body housing 101, and heat transfer. Exchange element 110 may be included.

Air inlets 122 and 132 for sucking air and outlets 121 and 131 for discharging sucked air may be formed on the front and rear surfaces of the main body housing 101, respectively. That is, the front of the main body housing 101 may be formed with an indoor air inlet 122 for sucking indoor air and an indoor air outlet 121 for discharging the air sucked from the outside into the room. An outdoor air inlet 132 for sucking outdoor air and an outdoor air outlet 131 for discharging air sucked indoors to the outside may be formed at a rear surface of the main body housing 101. Inside the body housing 101, a flow path through which air flows may be formed between the outdoor air inlet 132 and the indoor air outlet 121, and between the indoor air inlet 122 and the outdoor air outlet 131. . In this embodiment, the flow path formed between the outdoor air inlet 132 and the indoor air outlet 121 and the flow path formed between the indoor air intake 122 and the outdoor air outlet 131 are formed to pass through the heat exchange element 110. Can be.

Blowing fans 141 and 142 may be disposed in the body housing 101 to suck air through the inlets 122 and 132 and to discharge the air through the outlets 121 and 131. The first blowing fan 141 may be formed between the outdoor air inlet 132 and the indoor air outlet 121 to inhale the outdoor air and discharge the outdoor air into the room. The second blower fan 142 may be formed between the indoor air inlet 122 and the outdoor air outlet 131 to suck the indoor air and discharge the indoor air to the outside.

The total heat exchange element 110 may be formed at a point where the flow path formed between the outdoor air inlet 132 and the indoor air outlet 121 and the flow path formed between the indoor air intake 122 and the outdoor air outlet 131 intersect with each other. have. The total heat exchange element 110 may preserve the sensible and latent heat contained in the indoor air sucked through the indoor air inlet 122, and transfer the stored sensible and latent heat to the outdoor air sucked through the outdoor air inlet 132. have. Since the sensible heat and latent heat of the indoor air is transmitted to the air sucked from the outside by the heat exchange element 110, the air discharged through the indoor air outlet 121 is more sensitive to the sensible and latent heat of the indoor air than the sensible and latent heat of the outdoor air. It can have a close nature.

In the present embodiment, the total heat exchange element 110 may have a flat cylindrical shape. Inhaled outdoor air and indoor air may pass through the heat exchange element through the upper and lower surfaces of the cylindrical heat exchange element. At this time, when the cylindrical heat transfer element is rotated about the central axis of the cylinder, sensible and latent heat of indoor air passing through the heat exchange element 110 may be transmitted to outdoor air passing through the heat exchange element.

On the other hand, the flat cylindrical heat exchange element 110 may have a multi-part form. FIG. 2 schematically shows an electrothermal exchange element according to an embodiment of the present invention. As shown in FIG. 2 (a), the electrothermal exchange element 110 itself has a flat cylindrical shape. As shown in (e) to (e), the heat exchange element 110 may have a multi-division form, and in particular, the heat exchange element 110 may be multi-divided into a plurality of fan-shaped shapes about a central axis of a cylindrical shape. On the other hand, in the total heat exchange element 110, the plurality of fan shape may be the same.

When the heat exchange element 110 has a multi-part form, when the total heat exchange element is replaced due to the end of the service life (for example, the limit of life) of the heat exchange element, the respective parts are separated from the main body housing to thereby be integrated. It is possible to more easily remove / replace the total heat exchange element than the total heat exchange element. In addition, when a part of the total heat exchange element is defective, only the defective part may be replaced, thereby reducing the maintenance cost of the total heat exchanger.

Meanwhile, in the example of FIG. 2, the electrothermal exchange elements are shown to be divided into the same fan shape, but the present invention is not limited thereto, and the shapes of the divided pieces may be different from each other, and only some of them may be the same. In addition, the electrothermal exchange element is shown in the figure divided into 2, 4, 6 and 8, the present invention is not limited to this, the number is not limited.

3 is a structural diagram of a total heat exchange element according to an embodiment of the present invention. Referring to FIG. 3, the electrothermal heat exchange element 310 according to the present exemplary embodiment may include a first outer layer 311, an intermediate layer 313, and a second outer layer 312.

In the present exemplary embodiment, the first outer layer 311 may pass indoor air to one region 311a and outdoor air to the other region 311b. One region 311a of the first outer layer 311 may be connected to the first passage 351, and the other region 311b may be connected to the second passage 352. The air sucked in the room may pass through the one area 311a through the first passage 351. Air that is sucked outdoors and passed through other regions of the second outer layer 312, the middle layer 313, and the first outer layer 311 may be discharged to the interior through the second passage 352.

The second outer layer 312 may face the first outer layer 311, and allow indoor air to pass through one area and outdoor air to another area. One region of the second outer layer 312 may be connected to the third passage 353, and the other region may be connected to the fourth passage 354. Air sucked in the room through the first passage 351 may be discharged to the outside through the third passage 353 through the first outer layer 311, the middle layer 313, and the second outer layer 312. Can be. The air sucked from the outside may be discharged through the fourth passage 354 through the other areas of the second outer layer 312, the middle layer 313, and the first outer layer 311 and be discharged into the room. Although one region and the other region of the second outer layer 312 are not shown in FIG. 3, one region of the second outer layer 312 is a region corresponding to the region 311a of the first outer layer 311. The other area of the second outer layer 312 is an area corresponding to the other station 311b of the first outer layer 311.

The intermediate layer 313 may be stacked between the first outer layer 311 and the second outer layer 312. The intermediate layer 313 may pass air passing through the first outer layer and air passing through the second outer layer. In the present exemplary embodiment, the intermediate layer 313 may filter outdoor air that has passed through the second outer layer 312 and pass it through the first outer layer 311. That is, the intermediate layer 313 may perform antibacterial and deodorizing functions on outdoor air introduced into the room. Details of the intermediate layer 313 are described in more detail with reference to FIGS. 4 and 5.

The heat exchange element 310 according to the present embodiment may rotate about the central axis 310a of the cylinder. Indoor air may be sucked through the first passage 351, and outdoor air may be sucked through the fourth passage 354. The sucked air may pass through the first outer layer 311, the intermediate layer 313, and the second outer layer 312 of the total heat exchange element 310, respectively. That is, sensible and latent heat included in the indoor air may be preserved in the total heat exchange element when the indoor air sucked through the first passage 351 passes through the total heat exchange element. As the heat exchange element 310 rotates, the sensible heat and latent heat of the indoor air stored in the heat exchange element 310 may be transmitted to the outdoor air sucked through the fourth passage 354. Therefore, the outdoor air discharged through the second passage 352 may be in a state of receiving sensible and latent heat included in the indoor air. Accordingly, there is an effect that can reduce the energy use by preventing heat loss caused by indoor and outdoor air circulation.

Meanwhile, in FIG. 3, the heat exchange element 310 is integrally illustrated as having a cylindrical shape, but the present invention is not limited thereto, and the heat exchange element 310 may be divided into multiple parts as described above with reference to FIG. 2. It may have a form.

4 schematically shows a structural diagram of the total heat exchange element according to the present embodiment. Referring to FIG. 4, the electrothermal heat exchange element 410 according to the present exemplary embodiment may include a form in which the first outer layer 411, the intermediate layer 413, and the second outer layer 412 are sequentially stacked. .

In the present exemplary embodiment, the first outer layer 411 and the second outer layer 412 facing the first outer layer 411 may pass indoor air to one area and pass outdoor air to another area. have. In the present exemplary embodiment, the first outer layer 411 and the second outer layer 412 may be fibers including polyester and polypropylene, and the content and weight of the polyester and polypropylene may be different from the first outer layer ( 411 and second outer layer 412 can be defined to facilitate air permeation.

The intermediate layer 413 may be stacked between the first outer layer 411 and the second outer layer 412. The intermediate layer 413 may pass air passed through the first outer layer and the second outer layer. In the present exemplary embodiment, the intermediate layer 413 may filter the outdoor air passing through the second outer layer 412 and pass it to the first outer layer 411.

In this embodiment, the intermediate layer 413 may include an activated carbon filter layer on which activated carbon is deposited. 4 shows an example in which all of the intermediate layers 413 are formed of activated carbon filter layers. The activated carbon filter layer 413 may be, for example, a polyester nonwoven fabric on which activated carbon is deposited. Activated carbon is a carbon aggregate composed of well-developed micropores. The micropores are interconnected passageways and have a very large surface area. This surface area shows the adsorption effect which is the biggest characteristic of activated carbon, and the adsorption capacity may vary depending on the size and area of the pores.

Micropores are exposed on the surface of the activated carbon filter layer, and the activated carbon filter layer exhibits excellent characteristics in terms of adsorption rate and amount of adsorption to air pollutants. For example, when foreign matter such as dust, foreign matter in the air, organic solvent, or odor molecules moves to the outer surface of the activated carbon filter layer, it diffuses through the micropores. The diffused foreign matter is bonded to or filled with the inner surface of the micropores, so that the foreign matter cannot pass through the activated carbon filter layer. Accordingly, the total heat exchange element 410 including the activated carbon filter layer 413 has improved adsorption and deodorization by the activated carbon filter layer 413, and also has an antibacterial effect and humidity control due to adsorption, dust removal, harmful substances in the air and Excellent characteristic for removing odor.

In addition, activated carbon can selectively adsorb moisture in the air, thereby adsorbing / discharging moisture in the air, thereby improving the latent heat characteristic (latent heat exchange) of the total heat exchange element, and also controlling the humidity of the room appropriately. have.

Meanwhile, in FIG. 4, the heat exchange element 410 is illustrated as integrally having a cylindrical shape, but the present invention is not limited thereto, and the heat exchange element 410 is multi-divided as described above with reference to FIG. 2. It may have a form.

5 is a structural diagram of a total heat exchange element according to still another embodiment of the present invention. Referring to FIG. 5, the electrothermal heat exchange element according to the present exemplary embodiment may have a form in which the first outer layer 511, the intermediate layer, and the second outer layer 512 are sequentially stacked. This embodiment is the same as the embodiment of FIG. 4 except that the intermediate layer includes at least one activated carbon filter layer 513 and at least one polyester filter layer 514. Hereinafter, description is omitted except for differences.

As described above, the intermediate layer includes at least one activated carbon filter layer 513 and at least one polyester filter layer 514. In the intermediate layer, the activated carbon filter layer 513 and the polyester filter layer 514 are preferably stacked alternately with each other. Also, although two activated carbon filter layers 513 and three polyester filter layers 514 are shown in the figures, this is illustrative and may include different numbers of activated carbon filter layers 513 and polyester filter layers 514.

The activated carbon filter layer 513 may be a nonwoven fabric in which activated carbon is deposited as described in the embodiment of FIG. 4. Meanwhile, the polyester filter layer 514 may be a polyester nonwoven fabric. Polyester nonwoven fabric has the same strength as woven fabrics, and its physical properties have high strength both in light and above. In addition, the polyester nonwoven fabric is excellent in heat resistance, weather resistance, oil resistance, chemical resistance and breathability, and is composed of fine fibers, so that the cut surface is clean during cutting processing. On the other hand, by including the polyester filter layer in the total heat exchange element 510, pressure loss is reduced because the density gradient of polyester is given to the total heat exchange element.

The invention is not limited by the embodiments described above and the accompanying drawings, which are intended to be limited by the appended claims. It will be apparent to those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. something to do.

110, 310, 410, 510: electrothermal exchange elements
311, 411, 511: first outer layer
312, 412, 512: second outer layer
313, 413: mezzanine
513: activated carbon filter layer
514: polyester filter layer

Claims (9)

A rotary electrothermal heat exchange element having a first flow path for passing indoor air outside and a second flow path for passing outdoor air indoors,
A first outer layer having one region corresponding to the first passage and another region corresponding to the second passage;
A second outer layer having one area corresponding to the first flow path and another area corresponding to the second flow path and facing the first outer layer; And
Activated carbon is formed between the first outer layer and the second outer layer including an activated carbon filter layer, and the outdoor air passing through the second outer layer is filtered and delivered to the first outer layer, and the first outer layer An intermediate layer that filters the indoor air passing through the bed and delivers it to the second outer layer,
Absorbs sensible heat and latent heat of indoor air introduced into one region of the first outer layer, and absorbs the absorbed sensible and latent heat to outdoor air introduced into another region of the second outer layer. In passing,
The intermediate layer includes at least one polyester filter layer and at least one activated carbon filter layer, wherein the polyester filter layer and the activated carbon filter layer are alternately stacked with each other,
The polyester filter layer is a polyester nonwoven fabric, the activated carbon filter layer is a polyester nonwoven fabric having activated carbon deposited thereon,
The first outer layer, the intermediate layer and the second covering layer has a flat cylindrical shape sequentially stacked,
The cylindrical shape has a multi-divided form into a plurality of fan-shaped shape around the central axis of the cylindrical shape, the fan-shaped rotatable heat exchange element that can be separated separately.
delete delete delete The method of claim 1,
And wherein said first outer layer and said second outer layer comprise polyester and polypropylene.
delete delete delete The method of claim 1, wherein
And said plurality of fan-shaped shapes are identical to each other.

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