KR20190030166A - Total enthalpy exchange element and manufacturing method porous wick - Google Patents

Abstract

The present invention relates to a total heat exchange element and a method of producing a porous wick for a total heat exchange element, which are used in an air conditioning field. In particular, the present invention relates to a total heat exchange element having a wick of a latent heat or moisture exchange function and a method of producing a porous wick for a total heat exchange element, in which the total heat exchange element as a total heat exchanger for exchanging sensible heat and latent heat, in which thin plate liners and spacers forming flow paths between the liners are arranged in a laminated structure, includes: a wick passing through the liners so as to be coupled thereto so that both upper and lower ends of the wick are exposed to upper and lower flow paths to allow latent heat exchange between the flow paths, wherein the wick is formed as a porous wick having a plurality of pores for exchanging moisture by mixing a soluble binder with a metal powder or a ceramic powder, injection-molding a mixed product, and removing the binder from the injection-molded product with a solvent. Accordingly, both sensible heat exchange due to a temperature difference of fluids and latent heat exchange due to moisture exchange are performed, and thus heat exchange efficiency is improved.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an overall heat exchange element having a wick of a latent heat or a moisture exchange function and a method of manufacturing a porous wick for an electric heat exchanger,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a total heat exchanger for use in the field of air conditioning and a method for manufacturing a porous wick for an electric heat exchanger, and more particularly to a total heat exchanger for exchanging sensible heat and latent heat, And a wick for passing latent heat between the flow paths through the liner so that both ends of the upper and lower ends are exposed through the upper and lower flow paths, wherein the wick is soluble in a metal powder or a ceramic powder And a porous wick having a plurality of pores formed therein for removing moisture by exchanging sensible heat according to a temperature difference of the fluid and latent heat exchange according to moisture exchange, All of them are made so that the heat exchange efficiency is excellent. It relates to a total heat exchange element and a manufacturing method of the heat transfer clearinghouse Edition porous wick.

2. Description of the Related Art [0002] In general, an overall heat exchanger (or an overall heat exchanger) in the field of air conditioning is a device for exchanging heat between two fluids having different temperatures and humidity, and includes a heat exchanger in a laminated structure.

As shown in Fig. 1A, the total enthalpy heat exchanger of the laminated structure used in the air conditioning field has a wavy gap-maintaining member 3, The heat exchanging elements are stacked alternately with each other along the member 2 to form a flow path.

The above-mentioned patent discloses a structure in which two fluids having different temperatures and humidity pass each other in a crossed manner, and sensible heat exchange by temperature difference and latent heat exchange by moisture exchange are performed. The gap holding member forms a flow path while supporting the structure of each layer, The member separates the upper and lower flow paths between the layer and the layer so that the sensible heat or latent heat exchange between the layers is made.

The heat exchanger used for these air conditioning needs to perform either heat exchange or moisture exchange by temperature difference between two fluids with different temperature and humidity and air bleeding to prevent permeation of carbon dioxide or other contaminants You must have. In addition, high flame retardancy for fire and the like is required.

In the case of the sensible heat exchanging element using the metal sheet as the partitioning member, the sensible heat exchange efficiency due to the high thermal conductivity of the metal is excellent, but the moisture exchange is not performed due to the non-moisture permeability of the metal sheet, It can not be achieved.

In order to solve the above-mentioned problems, there is a technique of using a fibrous material made of paper sheet or pulp or the like as a raw material as a partitioning member including a fibrous material (cellulose) having a lower thermal conductivity than a metal but a high moisture permeability,

Such a partitioning member is problematic in that the efficiency of exchange of sensible heat due to the temperature difference is low because the heat conductivity of the fiber material itself is low when a moisture absorbent and a flame retardant are added or laminated to increase the moisture permeability and flame retardancy of the fiber.

In addition, when a partition member made of a fibrous material is used, the heat sensible heat exchange becomes smaller as the thickness of the partition member becomes larger. Therefore, the partition member must be produced in the form of a thin film. There is a problem that the durability is poor.

In addition, even if a flame retardant is added to the fiber, the flame retardant can not impart complete flame retardancy due to the characteristics of the material itself, and the resulting flame retardant lowers the moisture-permeability and lowers the heat exchange efficiency. And the heat exchange efficiency is lowered by increasing the heat resistance of the heat exchange surface.

Another prior art related to this is Patent No. 10-1174120. As shown in FIG. 1B, by coating or impregnating a pore of an aluminum thin film or a metal thin film with a moisture absorbent, air permeability is reduced and permeability is increased To a process for producing a thin metal film for heat exchange.

However, since the surface of the thin film is coated or impregnated on the both surfaces of the thin film so that the surface of the thin film is exposed to the upper and lower flow paths of the thin film, the efficiency of latent heat exchange using the moisture absorbent is deteriorated .

In addition, the above-mentioned patent requires an after-treatment process for removing the surface of the moisture absorbent after coating or impregnating the moisture absorbent through the anodizing process for forming the pore, through the sialing process, and the whole subdivided process is complicated There is a problem that productivity is low due to difficult fabrication.

Accordingly, the present invention has been made to solve the above-mentioned problems,

The latent heat exchange is performed simultaneously through sensible heat exchange using a thin metal plate having high thermal conductivity and a wick including a porous metal having a high moisture permeability or a ceramic material having a hydrophilic group or a hydrophilic group so that the heat exchange efficiency And is excellent in flame retardancy and durability, and also has an electrothermal exchange element and a porous wick for electric heat exchanger which can easily manufacture a porous wick by forming a plurality of micropores for exchanging latent heat in metal or ceramic injection molding at a higher density, And a method for producing the same.

In order to achieve the above object, the total enthalpy heat exchanging element according to the present invention comprises:

A total heat-exchanging element comprising a laminate structure of a thin plate liner and spacers forming a flow path between the liner,

The liner is made of a thin plate of thermally conductive metal so that the upper and lower flow paths are separated from each other and thermal energy of the high temperature fluid passing through any one of the flow paths is transferred to another adjacent flow path through which the low temperature fluid flows, ,

And the upper and lower ends of the liner protrude from both sides of the liner so as to be positioned in the upper and lower flow passages. Thus, the high-temperature and high-humidity fluid passing through one of the flow paths collides with the wick, Condensed on the surface of the wick, and moisture condensed on the surface of the wick is moved to the adjacent channel through the wick so as to allow latent heat exchange between the adjacent channels,

The wick is a porous wick having a plurality of pores formed therein by mixing a metal powder or a binder having a solubility in a ceramic powder, injection-molding the same, and removing the binder from the injection product with a solvent.

In the method of manufacturing a porous wick according to the present invention,

a) a raw material preparing step of mixing a binder having a solubility in a metal powder or a ceramic powder;

b) an injection molding step of molding an injection molded product to be used as a wick using the raw material;

c) a binder removing step of dipping the injection product in a solvent to dissolve and remove the binder in the injection product;

d) drying and pre-sintering step of drying the injected material from which the binder has been removed to remove the residual solvent.

Further, in the method of manufacturing a porous wick according to the present invention,

The metal powder may include at least one selected from the group consisting of stainless steel (SUS), iron (FE), tungsten (W), tungsten-copper alloy (WC), and titanium alloy (TiC).

In addition, in the method of manufacturing a porous wick according to the present invention,

The ceramic powder is alumina (Al ₂ O _3), zirconia (ZrO _2), alumina reinforced zirconia (ATZ, Alumina Toughned Zirconia), zirconia toughened alumina (ZTA, Zirconia Touchned Alumina), silica (SiO _2), stearyl dimethyl site ( Steatite, and MgSiO ₃ ).

The present invention provides a method of manufacturing a latent heat exchanging element and a porous wick,

And a wick for passing latent heat between the passages through the liner so that the upper and lower ends of the passages are exposed to the upper and lower passages, respectively. The sensible heat exchange using the thin metal plate and the latent heat The porous wick having the capillary phenomenon is provided so that the moisture permeability between the upper and lower flow passages is improved to improve the latent heat exchange efficiency and to improve the sensible heat exchange efficiency by the metallic wick having high thermal conductivity Lt; / RTI &

A binder having solubility in a metal powder or a ceramic powder is mixed and injected, and then the binder is removed from the injection product with a solvent to form a plurality of pores for moisture exchange in the wick, whereby heat exchange efficiency, flame retardancy and durability The porous wick can be manufactured more easily and quickly and can be easily bonded to the thin plate liner, thereby ensuring manufacturing easiness and improving productivity.

1A and 1B are perspective views showing a conventional heat exchange element.
2 is a perspective view of the total heat-exchanging element according to the present invention.
Fig. 3 is an enlarged side view of the main part of Fig. 1; Fig.
4 is a flowchart of a method of manufacturing a porous wick according to the present invention.
5 is a cross-sectional view schematically showing a departure prevention means according to the present invention.

While the present invention has been described in connection with certain embodiments, it is obvious that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

In the drawings, the same reference numerals are used for the same reference numerals, and in particular, the numerals of the tens and the digits of the digits, the digits of the tens, the digits of the digits and the alphabets are the same, Members referred to by reference numerals can be identified as members corresponding to these standards.

In the drawings, the components are expressed by exaggeratingly larger (or thicker) or smaller (or thinner) in size or thickness in consideration of the convenience of understanding, etc. However, It should not be.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise.

 In the present application, the term " comprising " or " consisting of ", or the like, refers to the presence of a feature, a number, a step, an operation, an element, a component, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

It is to be understood that the first to second aspects described in the present specification are merely referred to in order to distinguish between different components and are not limited to the order in which they are manufactured, It may not match.

In describing a total heat exchange element having a wick of a latent heat or moisture exchange function and a porous wick for an electric heat exchanger according to the present invention, And the directions are specified in accordance with these standards unless otherwise specified in the detailed description of the invention and claims related to other drawings.

Hereinafter, an entire heat exchanging element having a wick having a latent heat or moisture exchange function according to the present invention and a method for manufacturing a porous wick for an electric heat exchanger will be described with reference to the accompanying drawings.

As shown in FIG. 2, which is a perspective view of the present invention and FIG. 3, which is an enlarged cross-sectional view of the present invention,

The total enthalpy heat exchanging element according to the present invention has a laminated structure of a thin plate liner 10 and a spacer 20 forming a flow path 21 between the liner 10 and is formed by passing through both surfaces of the liner 10 And a combined wick (30).

The liner 10 may be made of a paper sheet including cellulose having moisture permeability,

As described later, since the latent heat is exchanged according to the moisture exchange using the wick 30, the liner 10 is preferably used as the thin metal plate to improve the sensible heat exchange efficiency. More specifically, And the like.

The liner 10 separates the upper and lower flow passages 21 formed by the spacer 20 from each other and sensible heat exchange is performed according to the temperature difference of the fluids passing through the respective flow paths 21 by using a thin metal plate material.

That is, the heat energy of the first flow path 21a through which the high temperature fluid flows is transferred to the second flow path 21b through which the low temperature fluid flows, using the high thermal conductivity of the metal thin plate, so that the sensible heat is exchanged.

The spacers 20 are provided between the upper and lower liners 10 to form a flow path 21 through which fluids pass while maintaining a laminated structure,

The shape of the flow path 21 formed by the spacer 20 may be various,

It is more preferable that a metal thin plate of corrugated shape is used so that the contact area of the fluid with respect to the liner 10 can be increased and heat can be transferred.

In order to sufficiently reduce the thickness of the total heat exchanging element and the volume of the flow path 21,

A plurality of inclined surface portions 22b which are inclined at a predetermined angle at both ends of the contact surface portion 22a are arranged in the horizontal direction to form a trapezoidal flow path 21, The individual shapes and numbers of the flow paths 21 can be changed.

The spacers 20 are stacked in such a manner that the spacers 20 are stacked alternately with the liner 10 interposed therebetween so that the first flow path 21a to be supplied and the second flow path 21b to be discharged intersect each other So that the liner 10 will be interviewed.

The present invention also includes a wick 30 penetratingly connected to the liner 10 so that upper and lower ends thereof are exposed to upper and lower flow paths 21 to allow latent heat or moisture exchange between the flow paths 21 .

The wick 30 is a kind of core material that transfers heat (including latent heat and sensible heat) contained in the moisture of the first flow path 21a to the second flow path,

It is preferable that the wick 30 is made of a porous metal material and further includes a cellulose having a hydrophilic group.

The wick 30 made of such a porous metal material is formed of a pellet or a honeycomb structure having a plurality of micropores,

Moisture is condensed on the surface of the wick 30 as the fluid of high temperature and high humidity passing through the first flow path 21a collides with the wick 30.

The moisture thus condensed is transferred to the second flow path 21b due to the capillary phenomenon of the wick 30. The transferred moisture permeates into the low temperature and low humidity fluid passing through the second flow path 21b, Latent heat exchange is performed between the second flow paths 21a and 21b.

At this time, due to high thermal conductivity of the metal material, sensible heat exchange can be performed in the wick 30 itself.

In this case, the porous structure of the metal wick 30 can be not only a plurality of pores formed in the horizontal direction as shown in the drawing, but also a plurality of pores formed in the vertical direction, and further, the directions of the pores may be irregularly formed.

The wick 30 including cellulose having a hydrophilic group includes a cellulose paper component containing vegetable fibers having OH < 2 > and the like, and imparts moisture permeability between the upper and lower flow paths of the liner having no moisture permeability.

The wick 30 having the moisture permeability including the cellulosic is separated from the moisture condensed in the plurality of micropores and the cellulose of the hydrophilic group contained in the wick 30 itself is separated from the fluid of the high temperature and high humidity passing through the first channel 21a After moisture is absorbed, moisture is transferred to the low-temperature and low-humidity fluid passing through the second flow path 21b to exchange latent heat between the first and second flow paths 21a and 21b.

Further, the porous wick 30 is formed by mixing a metal powder or a binder having a solubility in a ceramic powder, injection-molding the same, removing the binder from the injection product with a solvent, and forming a plurality of pores for moisture exchange And a detailed description thereof will be given later with a method for manufacturing a porous wick.

The operation principle of the total enthalpy heat exchanger according to the present invention having such a configuration will be described.

For example, in the summer season, hot and humid air out of the room is supplied to the first channel 21a to be supplied to the room, and the low-temperature and low-humidity air in the room is exhausted to the second channel 21b,

At this time, the liner 10 absorbs heat of high temperature and humidity in the high-temperature and high-humidity air passing through the first flow path 21a and discharges (sensible heat exchange) to low temperature and low humidity air passing through the second flow path 21b,

The porous wick 30 absorbs moisture from hot and humid air passing through the first flow path 21a and discharges (latent heat exchange) to the low temperature and low humidity air passing through the second flow path 21b,

Air to be supplied to the room is made low-temperature and low-humidity, and indoor air conditioning is performed.

Therefore, the present invention is characterized in that the sensible heat exchange through the liner 10 and the latent heat exchange using the wick 30 (the metallic wick 30 having a high thermal conductivity is performed together with the sensible heat exchange)

The heat exchange efficiency is improved as compared with the conventional metal liner (only sensible heat exchange is possible, latent heat exchange is not possible) or cellulose liner (only latent heat exchange is feasible and sensible heat exchange efficiency is weak)

The flame retardancy and durability are ensured through the liner 10 made of a thin metal plate and the wick 30 is supplemented with the moisture permeability falling due to the liner 10 of the thin metal plate and the effect of sensible heat and latent heat exchange is excellent.

That is, in the conventional heat exchanger used for air conditioning, the sensible heat and the latent heat exchange depend on the material characteristics of the liner 10 itself. In contrast, in the present invention, in addition to sensible heat exchange using the thin metal liner 10, It is possible to improve the total heat exchange efficiency.

Further, the porous wick (30) used for the exchange of latent heat (and sensible heat) can easily form fine pores with high density through injection molding of metallic powder or ceramic powder in the form of wick and then removing the binder, It is possible to manufacture the total heat-exchanging element merely by sandwiching it, so that the productivity can be improved.

Particularly, since the fine pores are provided in the form of irregularly densely arranged on the surface (and inside) of the wick 30, the latent heat exchange efficiency through the condensation of moisture is further improved.

1 to 4, a method of manufacturing a porous wick for use in the above-described total heat-exchanging element includes a) a raw material preparing step, b) an injection molding step, c) a binder removing step, d) And a sintering step.

The step a) is a step of preparing a raw material by mixing a metal powder or a binder having solubility in a ceramic powder.

That is, a binder powder capable of dissolving a specific solvent is prepared by mixing the metal powder or the ceramic powder at a predetermined ratio.

The metal powder used in step a) may include at least one selected from the group consisting of stainless steel (SUS), iron (FE), tungsten (W), tungsten-copper alloy (WC), and titanium alloy (TiC).

The ceramic powder used in step a) may be one selected from the group consisting of Al ₂ O ₃ , ZrO ₂ , AlZnA, Al ₂ O ₃ , ₂ ), and steatite (MgSiO ₃ ).

As the binder to be mixed with the metal powder or the ceramic powder, a binder (wax-base) is used.

The step a) includes a step of crushing the mixed raw material after crushing the mixed raw material using a pelletizer so as to be a pelletizing sized suitable for injection molding.

The step b) is a step of injection-molding an injection material used as the wick 30 by using the raw material.

The step b) is performed by a metal injection molding technique when the raw material of the raw material is a metal powder, and the ceramic injection molding technique is used when the raw material of the raw material is a ceramic powder.

At this time, it is preferable that the shape of the molded article formed in step b) is a cylindrical shape that can be used as the wick 30, and the fine binder powder is embedded in the surface (and inside) of the molded article at a predetermined density.

In the step c), the injection product is dipped in a solvent to dissolve and remove the binder from the injection product.

That is, when the injection material is immersed in a solvent capable of dissolving wax which is the main material of the binder for a predetermined time, the binder is removed from the injection material as the binder is melted and mixed by the solvent, The space occupied by the binder becomes empty, and a plurality of micropores for allowing the latent heat exchange through the moisture condensation to be formed on the molding are formed at an irregular shape.

The step d) is a degreasing and sintering step of drying the injection-molded article from which the binder has been removed to remove the residual solvent.

In the step d), the injected material is placed in an oven at a predetermined temperature for a predetermined period of time to remove the remaining solvent from the injection material (degrease).

In step d), the pre-sintering process and the sintering process are performed in order after the thermal deviations so that the finished wick 30 has a predetermined strength. At this time, 30 are not in conformity with the required dimensions (dimensions), the wicks 30 can be machined to the same standard through machining.

When the porous wick 30 is completed, it is possible to easily assemble the porous wick into the fitting hole after inserting the fitting hole having the size corresponding to the outer diameter of the wick into the liner 10.

Meanwhile, since the wick 30 formed in the step d) has a certain strength or more due to the characteristics of the material, the wick 30 is assembled and fixed to the fitting hole of the liner 10 in an interference fit manner. There is no departure preventing means, so that the wick 30 can be removed from the liner 10 during use.

As shown in FIG. 5, the present invention includes a release preventing means for fixing the wick 30 to the fitting hole 11 of the liner 10.

The departure-

A plurality of insertion grooves 11a recessed in the inner circumferential surface of the fitting hole 11 and spaced apart in a circumferential direction at predetermined intervals,

And a plurality of engaging pieces 31 protruding from the outer circumferential surface of the wick 30 in the circumferential direction so as to be spaced apart from the insertion grooves 11a by the same distance and fitted into the insertion grooves 11a,

Each engaging piece 31 is provided with a fitting end 31A having a smaller width than the insertion groove 11a at the center of the engaging piece 31 while being smaller than the width of each insertion groove 11a , And a rupture portion 31a formed in a groove shape and partially cut between the engaging piece 31 and the fitting end 31A is provided,

When the wick 30 is inserted into the fitting hole 11 so that the fitting end 31A is fixedly inserted into the insertion groove 11a and then the wick 30 is rotated in one direction, The inner end of each of the engaging pieces 31 is caught by both sides of the liner 10 and the wick 30 is fixed while the engaging piece 31 and the fitting end 31A are cut off.

The engaging piece 31 and the fitting end 31A are connected to each other in the longitudinal direction of the wick 30 so that the engaging piece 31 is formed to have a smaller thickness than the fitting end 31A, And is connected to the latching piece 31 so that the width of the end portion decreases toward the outer side and the rupture portion 31a is provided outside both end portions of the fitting end 31A.

The engaging piece 31, the fitting end 31A and the breaking portion 31a may be integrally formed with the wick 30 during the injection molding in the step b), or may be formed through the post-processing in the step d) It is possible.

In addition, the respective insertion grooves 11a and the corresponding insertion end 31A are formed to have different thicknesses (widths) and arrangement distances from each other (FIG. 5 shows the same thickness and spacing for ease of understanding). ).

When the wick 30 is inserted into the fitting hole 11 of the liner 10 so that the fitting end 31A corresponding to each insertion groove 11a is aligned with the fitting hole 31 of the liner 10, When the insertion end 31A enters the insertion groove 11a at this time, the wick 30 is pressed under a strong pressure so as to insert the finely thick insertion end 31A with a thickness corresponding to the insertion end 31A, So that the wick 30 is first fixed to the groove 11a.

When the wick 30 is rotated in one direction in this state, the breaking portion 31a is broken so that the both engagement pieces 31 and the fitting end 31A are separated from each other. The second fixing of the wick 30 is completed by being caught on both surfaces of the liner 10 to prevent the wick 30 from being detached and separated from the fitting hole 11 of the liner 10. [

At this time, the fitting end 31A is integrally connected to the outer circumferential surface of the wick 30, but the strength of the connection portion between the wick 30 and the fitting end 31A is weakened due to the fine pores through the removal of the binder, Only the fitting end 31A is cut at the outer peripheral surface of the wick 30 and remains in the insertion groove 11a.

The width of each insertion groove 11a and the gap between the insertion grooves 11a are different from each other so that even if the assembled wick 30 rotates on the insertion hole 11, It is practically impossible to arrange the engaging pieces 31 and the insertion grooves 11a in a position corresponding to the insertion grooves 11a in which they are first inserted one by one. Even if the engaging pieces 31 and the insertion grooves 11a of the same size are rearranged in the same line, The engaging piece 31A does not fall into the insertion groove 11a due to the interference of the fitting end 31A with the wick 30 and the wick 30 is fixed semi-permanently on the fitting hole 11.

While the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, Changes and substitutions are to be construed as falling within the scope of protection of the present invention.

10: Liner
20: Spacer 21, 21a, 21b:
22a: contact portion 22b: inclined face portion
30: Wick

Claims (4)

A total heat-exchanging element comprising a laminate structure of a thin plate liner and spacers forming a flow path between the liner,
The liner is made of a thin plate of thermally conductive metal so that the upper and lower flow paths are separated from each other and thermal energy of the high temperature fluid passing through any one of the flow paths is transferred to another adjacent flow path through which the low temperature fluid flows, ,
And the upper and lower ends of the liner protrude from both sides of the liner so as to be positioned in the upper and lower flow paths, thereby allowing the high-temperature and high-humidity fluid passing through one of the flow paths to collide with the wick, Condensed on the surface of the wick, and moisture condensed on the surface of the wick is moved to the adjacent channel through the wick so as to allow latent heat exchange between the adjacent channels,
Wherein the wick is a porous wick having a plurality of pores for moisture exchange by mixing a binder having a solubility in a metal powder or a ceramic powder, injection-molding the same, removing the binder from the injection product with a solvent, device.
A method of manufacturing a porous wick for an electric heat exchanger having a plurality of pores for moisture exchange,
a) a raw material preparing step of mixing a binder having a solubility in a metal powder or a ceramic powder;
b) an injection molding step of molding an injection molded product to be used as a wick using the raw material;
c) a binder removing step of dipping the injection product in a solvent to dissolve and remove the binder in the injection product;
and d) a degreasing and sintering step of drying the injected material from which the binder has been removed to remove the residual solvent.
3. The method of claim 2,
Wherein the metal powder comprises at least one selected from the group consisting of stainless steel (SUS), iron (FE), tungsten (W), tungsten-copper alloy (WC) and titanium alloy (TiC) .
The method according to claim 2 or 3,
The ceramic powder is alumina (Al ₂ O _3), zirconia (ZrO _2), alumina reinforced zirconia (ATZ, Alumina Toughned Zirconia), zirconia toughened alumina (ZTA, Zirconia Touchned Alumina), silica (SiO _2), stearyl dimethyl site ( Steatite, MgSiO ₃ ). The method for manufacturing the total heat exchange element according to claim 1,

Images