KR101406990B1 - Functional heat exchange film and heat exchange unit comprising the same - Google Patents

Abstract

The present invention relates to a functional heat transfer film and an electric heating element including the same. More specifically, disclosed is a functional heat transfer film capable of blocking air while increasing vapor permeability. For the same, the functional heat transfer film includes: a film-shaped heat transfer layer including a polymeric resin and a first filler formed on the heat transfer layer for enhancing the permeability. According to the present invention, the permeability of the polymer material can be improved, and the penetration of air can be reduced. Therefore, the electric heating element can efficiently transfer heat with latent heat as well as sensible heat and prevents the penetration of air. The electric heating element having an excellent heat transfer efficiency can be manufactured thereby.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a functional heat transfer film,

The present invention relates to a functional heat transfer membrane and a heat transfer element including the functional heat transfer membrane. More particularly, the present invention relates to a functional heat transfer membrane having a significantly improved moisture permeability and at the same time capable of effectively blocking air flow, And a heating element using the same.

In recent years, as the need for efficient use of energy has emerged worldwide, various technologies for recovering and reusing waste heat that are used and discarded have been developed.

For this purpose, it is essential to develop a material that efficiently transfers heat, and at the same time, such material must not only efficiently heat transfer, but also other physical properties required for each device, such as dirt suppression degree At the same time, it should be satisfied.

As a representative example of a device for recovering and reusing waste heat, there is a heat recovery type ventilation device. The heat recovery ventilating type total enthalpy heat exchanger is a heat exchange device that ventilates indoor air and simultaneously performs heat exchange between exhaust and air supply. This conveys the heat of the air exhausted to the outside to the air supplied to the room while ventilating indoor and outdoor air, thereby enabling efficient use of energy, thereby preventing sudden temperature changes in the room.

A general form of the heating element used in this total enthalpy heat exchanger is shown in Fig. 1 is a perspective view for explaining a structure of a heating element.

1, the heating element 13 includes a liner 24 provided in a flat plate shape, a corrugation spacer 23 formed in a sinusoidal shape to be coupled to one surface of the liner 24 through an adhesive or the like, Are sequentially stacked and formed. Each of the spacers 23 is disposed so as to be orthogonal to the adjacent spacers 23. One of the spacers 23 forms an exhaust layer 21 formed to communicate with the exhaust passage and the other has a supply layer 22 formed to communicate with the air- . Such a spacer also serves as a support for maintaining the shape of the heating element.

Here, the heat exchange between the exhaust and the supply period is performed through the liner 24. Therefore, the heat exchange performance of the heat recovery ventilating type total enthusiast exchanger depends on the properties of the selected liner, and attempts have been made to use various materials as liners.

Such a liner is required not only to efficiently perform heat transfer but also to discharge air and supply air around the liner so that the air and the air to be supplied are not mixed with each other so that air permeability is not good You must stop it). As the conventional heat transfer element or liner, paper, aluminum, or the like has been used. Recently, a polymer synthetic resin film or the like is also used.

Since paper has a property of absorbing moisture, it has an advantage that it can utilize not only sensible heat but also latent heat due to phase change of water for heat transfer. However, in the rainy season, water is supersaturated on paper, which is a limitation as a medium of water transmission. In addition, since moisture can not be passed quickly and the moisture is faded for a long period of time, there is a problem that the material of the paper is moldy due to the humid environment and is greatly proliferated. This can be attributed to the fundamental characteristic that paper material gradually absorbs moisture and gradually transfers moisture to the dry air stream.

Therefore, there is a problem that it is difficult to use the ventilator in the case where the fresh air is supplied to the room. In addition, the paper has a low durability and thus has a limited amount of ventilation that can pass through, so that it is difficult to use the paper in a large air conditioner.

On the other hand, in the case of metals such as aluminum (heat transfer coefficient of 20 Kcal / mh ° C), the heat transfer efficiency is superior to that of paper (heat transfer coefficient 0.15 to 0.18 Kcal / mh ° C), so the sensible heat can be swiftly and efficiently exchanged between the exhaust gas And durability is also superior to that of paper. However, since aluminum is relatively expensive, its economic efficiency is low, and when it is exposed to moisture, there is a fear of corrosion and the like. Moreover, since aluminum has little property of passing moisture, heat transfer using latent heat is difficult.

A method using polymeric synthetic resin has been proposed in consideration of the advantages and disadvantages of paper and aluminum. That is, polyethylene (PE) or the like is formed into a film and used as a liner or the like. The heat transfer coefficient (about 0.24 Kcal / mhr ° C in the case of PP) is relatively high compared to paper and air permeation can be effectively prevented, There is an advantage that it is not only inexpensive, but also does not cause problems such as corrosion.

For example, a Korean patent (Registration No. 10-0737695) discloses "an exhaust layer and a supply layer provided so as to mutually cross each other for heat exchange between exhaust and air supply, and an electrothermal treatment including a liner between the exhaust layer and the supply layer In the element, the liner is composed of a multilayer structure in which a fiber composite fabric layer having a superabsorbent property and a heat transfer property and a high moisture-permeable polymer resin layer are mutually adhered by a lamination processing method or a coating method, Quot; device "is disclosed.

In addition to this, the polymer synthetic resin is used, but the air permeation can be effectively suppressed, and the moisture permeability can be improved to increase the heat transfer efficiency. durability. It is required to develop a technology that satisfies the properties generally required for air conditioners such as light weight.

Patent registered in Korea (Registration No. 10-0737695) (Notice of July 9, 2007) Korean Patent Publication No. 10-2012-29873 (disclosed on Mar. 27, 2012) Korean Patent Publication No. 10-2005-36705 (published on April 20, 2005)

The first object of the present invention is to provide a method and a device for preventing the mixing of adjacent airflows efficiently, and also capable of efficiently absorbing and discharging moisture due to excellent moisture permeability and thus being highly hygienic as well as hygienic, And to provide the functional heat transfer film.

The second object of the present invention is to provide an air conditioner which is capable of efficiently absorbing and discharging moisture because of its excellent moisture permeability, and is highly hygienic as well as highly durable, And a heat transfer element using this excellent functional heat transfer film as a liner or a spacer.

In order to achieve the first object of the present invention, there is provided a heat transfer sheet comprising: a film-shaped heat transfer layer containing a polymer resin; And a first filler for improving the moisture permeability formed in the heat transfer layer.

In order to achieve the second object of the present invention, in another embodiment of the present invention, there is provided a heat transfer element comprising a liner mediating heat transfer between channels, and a spacer formed between the liner and forming a flow path, A liner, a spacer, or a film-like heat transfer layer in which the liner and the spacer each comprise a polymer resin; And a first heat transfer layer formed on the heat transfer layer to improve the moisture permeability.

The first filler may be calcium carbonate, silica, zeolite, bentonite, talc, molecular sieve, heavy carbon, clay or clay. The first filler may be applied to one or both surfaces of the heat transfer layer, May be included in the heat transfer layer. Also, the heat transfer layer may use a stretched film for forming voids which further improves the moisture permeability.

In addition, a dirt suppressing layer may be further formed on the heat transfer layer to improve dirt suppression. The dirt suppressing layer may include a hydrophilic resin and a second filler for improving moisture absorption. For the same purpose, The second filler can be selectively included.

According to the present invention, the moisture permeability of a polymer resin material used as a heat transfer medium such as a liner or a spacer can be remarkably improved. Therefore, not only the sensible heat due to the temperature difference but also the latent heat accompanying the phase change of the water is used together with the heat transfer, so that the heat transfer efficiency is remarkably improved as compared with the metal material such as aluminum.

In addition, since the organic polymer resin is used as a base, the transfer and permeation of water can be performed quickly, and therefore, the phenomenon of wetting by moisture is small and the growth of fungi is difficult. Further, since it can be reused by washing with water or the like, the convenience of management and economical efficiency that can not be expected in paper and the like can be achieved.

Furthermore, since the damping degree is superior to that of paper, it is possible to prevent the mixing of adjacent airflows, particularly when used as a liner, to ensure the reliability of the air conditioning apparatus, It can also be used in large-scale air conditioning equipment, etc., and the use range is greatly expanded.

1 is a perspective view for explaining the structure of a general heating element.
2 is a cross-sectional view illustrating one embodiment of a functional heat transfer film according to the present invention.
3 is a cross-sectional view illustrating another embodiment of the functional heat transfer film according to the present invention.

Hereinafter, a functional heat transfer film and a heat transfer element according to preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The heat transfer film according to the present invention can be used as a liner or a spacer of a heat recovery type ventilator composed of a spacer and a liner. In addition, it can be used as a heat transfer film for various devices requiring heat transfer by latent heat as well as sensible heat.

According to an embodiment of the functional heat transfer film of the present invention, a film heat transfer layer including a polymer resin and a first filler for improving the moisture permeability included in the heat transfer layer are included.

 2 is a cross-sectional view illustrating one embodiment of a functional heat transfer film according to the present invention. Referring to FIG. 2, a heat transfer layer 100 serving as a base is included in the present embodiment.

The heat transfer layer 100 is made of a polymer resin. Specifically, the polymer resin includes an acrylic, urethane, ester, sulfone, or olefin type high moisture permeable organic polymer resin, and may include polyethylene (PE), polypropylene (PP), polyvinyl chloride (PVC), polystyrene PS) resin is formed into a film shape.

Generally, these organic polymer resins usually have very high dirt repellency. Air permeability (also referred to as air permeability) refers to the degree to which a substance is prevented from permeating air, usually expressed as the time it takes for a given amount of air to pass through a specimen composed of the substance under certain conditions . Therefore, if the time required at this time is long, the damping degree becomes high.

For example, in the case of ordinary paper, the damping degree is less than 300 seconds, so that the air moves through the paper without difficulty. Therefore, when general paper is used as the liner of the heat recovery type electrothermal device, the discharged air and the supplied air are mixed with each other, so that the reliability of the air conditioner can not be ensured and the contaminated air flows back into the room.

However, in the case of a synthetic resin material commonly referred to as " vinyl ", the air permeability is hardly achieved even when the air flow is applied for a long period of time with a considerable pressure because the damping degree is very high. When the polymer resin is used as the heat transfer layer as in the present invention, the durability of the durability is very high. Therefore, when used as a liner or the like, it is possible to prevent mixing of the exhaust gas and the feed gas.

The polymer resin used as the heat transfer layer can be produced in the form of a film and can be adopted if it is an organic polymer resin having a certain damping degree and moisture permeability. In the polymer backbone or the side chain, It is more advantageous to add hydrophilic functional groups for enhancing the hydrophilicity which contributes to the improvement of the moisture permeability which is the degree of absorption (absorption and discharge).

When the polymer resin having high hygroscopicity is applied to a heat transfer medium such as a liner instead of paper, absorption and release of moisture can be accelerated to increase the efficiency of the device. Can be solved.

As described above, in the present invention, by using a polymer resin having a polymeric hydrophilic property as the heat transfer layer, the moisture permeability is higher than that of a general polymeric resin. However, even in this case, since the moisture permeability is still lower than that of paper and therefore the heat transfer effect using latent heat is not so great, a first filler for improving the moisture permeability described later is used in order to further improve the moisture permeability.

 On the other hand, the polymer resin can be applied to air conditioners such as large buildings that require less durability because they are not torn even by strong wind pressure and ventilation compared with paper, and thus the application range of the total heat exchanger is limited . Furthermore, it is possible to improve the characteristics of the heating element by transferring the moisture promptly as compared with the paper due to the phenomenon of wetting by moisture (phenomenon of fading moisture), and effectively preventing the growth of fungi even when used for a long period of time .

In addition, the polymer resin is cheaper than a metal heat transfer medium such as aluminum, and can be cleaned with water without causing corrosion due to moisture or the like. Therefore, it is economical because it can be reused, and the indoor influx of corrosive substances is fundamentally blocked, so that it is not only hygienic but also can be easily cleaned, thereby greatly improving the convenience of management.

The functional heat transfer membrane according to one embodiment of the present invention includes a first filler 200 for improving the moisture permeability included in the heat transfer layer 100.

 Referring to FIG. 2, the first filler is included in the heat transfer layer as the polymer resin. As the first filler, calcium carbonate (CaCO3), silica, zeolite, bentonite, heavy carbon, clay, talc, molecular sieve, clay or a mixture thereof can be used have. The materials used as the first filler are all inorganic compounds, which are heterogeneous materials from the heat transfer layer if the heat transfer layer is used as an organic polymer resin.

That is, since the heat transfer layer and the first filler are heterogeneous materials, the heat transfer layer and the first filler are not completely bonded to each other even if they are mixed and molded. As shown in FIG. 2, The pores 210 are formed at the interface with the polymer resin.

The voids thus formed are literally empty spaces, and voids are formed in the middle of the heat transfer layer, so that the voids serve as drainage passages in the heat transfer layer. Therefore, the moisture is smoothly transmitted, and the moisture permeability is remarkably improved.

The above-mentioned calcium carbonate is a carbonate of calcium and is produced as marble, calcite, mudstone, limestone, chalk, ginkgo stone, clamshell, egg shell, coral, and the like. The silica (SiO2) is also referred to as silicon dioxide or silicic anhydride, and refers to silicic acid as a component of various silicates existing in nature. It is produced as crystals or amorphous in natural quartz, quartz, agate, agate, flint, silica sand, scaly silica, and red lead.

In addition, zeolites are collectively referred to as minerals which are aluminum silicate hydrates of alkali and alkaline earth metals, and the color is colorless transparent or white translucent. It is also called zeolite, and it has many kinds, but it has commonality with many points such as water content, crystal properties, and acidity.

In particular, as the zeolite, it is preferable to use a synthetic zeolite represented by Nam (AlO2) m (SiO2) nxH2O (m? N). The synthetic zeolite having the above structure is a crystal in which a SiO4 tetrahedron and an AlO4 tetrahedron form a three-dimensional network structure, and the mesh forms a cavity, and sodium ions are present therein. The cavity has a uniform diameter, and the thin holes are connected in the vertical and horizontal directions. That is, since the compound itself has cavities formed therein, the effect of improving the moisture permeability is excellent.

The molecular sieve is a kind of synthetic zeolite, which is a sodium salt having a crystal structure similar to that of natural zeolites. There are various kinds depending on the size of a cavity in which sodium ions exist.

The talc is a hydrate of magnesium silicate having a composition of Mg3 (Si) 10 (OH) 2 and having a soft oily texture in a monoclinic system. The clay means fine soil particles having a diameter of 0.002 mm or less. When the rock is weathered and decomposed, clay minerals are formed mainly by combining silicon and aluminum and water.

The first filler is preferably processed to have a particle diameter of about 0.1 to 100 mu m. If the particle diameter of the first filler is less than 0.1 mu m, pores of sufficient size can not be formed. On the other hand, if the particle diameter is more than 100 mu m, the durability of the heat transfer layer may be deteriorated.

The first filler may be included in an amount of 1 to 80 parts by weight based on 100 parts by weight of the heat transfer layer. When the first filler is used in an amount of less than 1 part by weight, the effect of increasing the moisture permeability is not expected because the pores are small in number. On the other hand, when the first filler is used in an amount exceeding 80 parts by weight, the heat transfer layer used as a liner, Particularly, while the moisture permeability is increased, the damping degree is lowered and mixing between the adjacent air occurs.

On the other hand, the heat transfer layer may be a stretched polymer film for further improving the moisture permeability. When the heat transfer layer is elongated, newly generated pores are generated mainly by expanding existing pores or by strong stretching around the first pillar. When the void space is additionally formed as described above, the moisture permeability is further improved in accordance with the above-described principle.

Therefore, not only the sensible heat due to the temperature change but also the latent heat due to the phase change of the water can be sufficiently utilized for the heat transfer.

On the other hand, since the air is also allowed to pass through these gaps, the degree of dirt suppression is lowered, so that it is necessary to separate flows of different air such as liner, which may adversely affect the application.

The present invention also provides another embodiment of a functional heat transfer film. 3 is a cross-sectional view illustrating another embodiment of the functional heat transfer film according to the present invention.

Referring to FIG. 3, the functional heat transfer layer according to the present exemplary embodiment may further include a dirt suppressing layer 300 for improving dirt absorption and hygroscopicity in addition to the heat transfer layer and the first filler. Specifically, the dirt suppressing layer 300 may include a resin layer 310 and a second filler 320 for improving moisture absorption.

When the hydrophilic resin is used as the resin layer 310, the resin layer serves as a film for preventing the air from passing therethrough. As a result, as described above, The problem of deterioration of the moisture permeability of the heat transfer layer can be prevented.

On the other hand, as the second filler, lithium chloride (LiCl), phosphate or the like excellent in the water absorption function can be used. They have the property of absorbing water, absorbing and dissolving water, and becoming solid again when water is removed. That is, the second filler doubles the heat transfer effect of the heat transfer element.

The second filler is preferably used in an amount of 1 to 30 parts by weight based on 100 parts by weight of the heat transfer layer. If the second filler is used in an amount less than about 1 part by weight, improvement in the hygroscopic performance is not sufficient and it is difficult to contribute to improvement in heat transfer performance. When the second filler is used in an amount exceeding about 30 parts by weight, And the device may be oxidized. In the case of a high humidity environment in the summer, the heat transfer film may become excessively wetted with moisture for a long period of time (wetting) and may be supersaturated.

Meanwhile, the second filler may be selectively included in the heat transfer layer for the same purpose.

The present invention provides a heating element using the heat transfer film. That is, in a general heat transfer element including a liner for mediating heat transfer between channels and a spacer formed between the liner and forming a flow path, the liner, the spacer, or the liner and the spacer may be composed of the above- have.

Particularly, since the heat transfer membrane has a very excellent damping effect as well as moisture permeability, it can be expected that heat transfer efficiency, durability, and durability that can not be expected in conventional paper liner and aluminum liner .

The functional heat transfer film including the first filler may be manufactured by various methods. For example, the functional heat transfer film may be manufactured by the following method. Specifically, a polyethylene (PE) resin is used as the polymer synthetic resin, and calcium carbonate is used as the first filler.

The master batch (mixed PE chip) in which calcium carbonate is mixed with the PE chip for the PE film is uniformly mixed and then put into a hopper for producing the PE film to prepare a PE film. At this time, calcium carbonate is preferably 50 parts by weight or less based on 100 parts by weight of the PE chip.

Then, if necessary, a hydrophilic resin mixed with the second filler is further coated on the heat transfer layer to produce a functional heat transfer film.

The functional heat transfer membrane as described above can be used mainly in a heat recovery type heat exchanger, and can be applied to various fields requiring heat transfer as well. It can replace aluminum or paper material or simple synthetic resin film material that has been used previously, and its low price, light weight, and ease of manufacturing process will increase marketability. In addition, since it is overcome the disadvantages of the paper device which was not applied to the large air conditioning due to its weak durability, it can be applied positively to the residential space and the large air conditioning requiring large air volume.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined in the appended claims. It can be understood that it is possible.

13: heating element 21: exhaust layer
22: supply layer 23: spacer
24: liner 100: heat transfer layer
200: first filler 220: air gap
300: dirt suppressing layer 310: resin layer
320: second filler

Claims (14)

A heat transfer layer comprising an acrylic, urethane, ester, sulphone or olefin type high moisture permeable organic polymer resin and being a stretched film for forming voids to improve the moisture permeability;
A first filler composed of calcium carbonate, silica, zeolite, bentonite, talc, molecular sieve, heavy carbon, clay or clay, applied or introduced into the heat transfer layer to improve the moisture permeability; And
And a dirt suppressing layer provided on the heat transfer layer for improving the dirt suppression,
Wherein the speculative inhibiting layer is a speculative inhibiting layer formed of a hydrophilic resin and a second filler formed on the resin layer for improving the hygroscopicity and composed of lithium chloride, sodium chloride, calcium chloride or phosphate. . delete delete delete The method of claim 1, wherein the first filler
Having a particle diameter of 0.1 to 100 탆,
And 1 to 80 parts by weight based on 100 parts by weight of the heat transfer layer. delete delete delete delete The functional heat transfer film according to claim 1, wherein the second filler is contained in an amount of 1 to 30 parts by weight based on 100 parts by weight of the heat transfer layer. 1. A heat transfer element comprising a liner for mediating heat transfer between channels, and a spacer formed between the liner and forming a flow path,
The liner, spacer, or liner and spacer are
A heat transfer layer comprising an acrylic, urethane, ester, sulphone or olefin type high moisture permeable organic polymer resin and being a stretched film for forming voids to improve the moisture permeability;
A first filler composed of calcium carbonate, silica, zeolite, bentonite, talc, molecular sieve, heavy carbon, clay or clay, applied or introduced into the heat transfer layer to improve the moisture permeability; And
And a damping layer formed on the heat transfer layer and composed of a hydrophilic resin and a second filler formed on the resin layer for improving the hygroscopicity and composed of lithium chloride, sodium chloride, calcium chloride or phosphate. . delete delete delete

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