KR20090004796A - Heat exchanger, and making method thereof - Google Patents

Abstract

Total-heat exchanger and the manufacturing method thereof are provided that the manufacturing cost is low and the manufacture is facilitated. A total-heat exchanger(300) comprises an air supply guideline corrugated fibreboard(310) and a ventilation guideline corrugated fibreboard(320). The air supply guideline valley portion(311) forming the air supply stream passage is repeatedly formed in the air supply guideline corrugated fibreboard. The air supply guideline valley portion includes an air supply guide portion(313), an air supply outlet part(314) and an air supply influx unit(312). The ventilation guideline valley portion(321) forming the exhaust channel is repeatedly formed in the ventilation guideline corrugated fibreboard.

Description

Heat exchanger and manufacturing method of heat exchanger {HEAT EXCHANGER, AND MAKING METHOD THEREOF}

1 is a partially cutaway perspective view of a total heat exchanger according to the prior art,

Figure 2 is an exploded perspective view of a part of another prior art heat exchanger,

3 is a perspective view of a total heat exchanger according to the present invention;

4 is an exploded perspective view of a part of the total heat exchanger according to the present invention;

5 is a perspective view of a state in which a corrugated cardboard is inserted between the first and second rollers in the method of manufacturing a total heat exchanger according to the present invention;

6 is a perspective view of the first and second rollers used in the method for manufacturing a total heat exchanger according to the present invention;

Figure 7 is a perspective view of a state in which the heat transfer film is bonded to the corrugated cardboard in the method for manufacturing a heat exchanger according to the present invention,

8 is a plan view of a corrugated cardboard bonded with a heat-transfer film on the lower surface in the method of manufacturing a total heat exchanger according to the present invention;

9 is a plan view of the state in which the corrugated cardboard of FIG.

FIG. 10 is a plan view showing the laminated cardboard divided in FIG. 9;

FIG. 11 is a plan view showing a state in which the cardboards stacked in FIG. 10 are cut into hexagons. FIG.

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

300 Electric Heat Exchanger 310 Supply Air Corrugated Cardboard

320 Exhaust Guide Corrugated Board 330

The present invention relates to a total heat exchanger and a method for manufacturing the same, and more particularly, to a total heat exchanger and a method for producing the total heat exchange of the outdoor air to be supplied and the indoor air exhausted.

In general, ventilation is an important part of building construction, from houses to buildings, department stores, theaters, stores, schools, and hospitals. By the way, when the ventilation is made to warm or cool air escapes to the outside, the room becomes cold or hot and has a problem that the indoor cooling and heating effect is impaired. Therefore, a ventilator equipped with a total heat exchanger has been developed to improve this problem.

1 shows a total heat exchanger 100 according to the prior art.

The heat exchanger 100 of FIG. 1 is formed by alternately stacking the corrugated cardboard 110 in which the bones 111 are continuously repeated so that the bone formation directions are orthogonal to each other, and the heat-transfer film 130 is interposed therebetween.

The heat exchanger 100 is stacked so that the bone 111 formed on the corrugated cardboard 110 is orthogonal to each other so that the air supply (B) and the exhaust (A) cross each other to move the heat transfer.

The cross flow type heat exchanger (100) is inexpensive because it produces a large amount of corrugated paper and cuts it to a predetermined size, and thus the leakage rate is due to homogeneous bonding because both the corrugated paper and the heat-transfer film interposed therebetween are made of paper. At the same time, it is easy to manufacture and has the advantage that the heat exchange area can be variably adjusted according to design specifications.

However, the conventional cross flow type heat exchanger 100 has a disadvantage in that heat exchange efficiency decreases as indoor air and outdoor air move orthogonally.

Another prior art heat exchanger 200 is shown in FIG. The heat exchanger 200 alternately stacks the exhaust guide unit 210 for guiding indoor air to the outside and the air supply guide unit 220 for guiding the outdoor air to the interior, with an interlayer heat exchanger 230 interposed therebetween. It is a configuration. In addition, the exhaust guide 210 is formed with a plurality of exhaust guide protrusions 211 made of plastic material at regular intervals to guide the exhaust (A) to the outside, the air supply guide 220 ) Is provided with a plurality of air supply guide protrusion 221 having a bending point of two places to guide the air supply (B) indoors at regular intervals.

In the counterflow type heat exchanger 200, the heat exchange is performed by flowing the air supply and the exhaust gas at the center of the air supply guide part 220 and the air exhaust guide part 210. The counterflow type pre-heat exchanger 200 has the advantage that the heat exchange efficiency is higher than that of the cross-flow type pre-heat exchanger by supplying and exhausting the air flows to face each other, the injection of the exhaust guide protrusion 211 and the air supply protrusion 221 made of plastic Manufacturing process to change the heat exchange area due to the high price by the complicated process such as the process of inserting and forming the heat-transfer film between them, easy to leak due to the joining of the dissimilar materials of plastic and paper, and the plastic injection process. Since the mold must be changed, it is difficult to change the heat exchange area.

The present invention has been made to solve the problems of the prior art, and an object of the present invention is to provide a total heat exchanger having a low manufacturing cost and easy manufacturing and excellent heat exchange efficiency.

In the electrothermal heat exchanger according to the present invention, the air supply guide valleys forming the air supply passage are continuously formed repeatedly, and the air supply guide valleys are formed by being extended from the air supply guide portion, one end of the air supply guide portion, and the air supply. An air supply guide corrugated sheet which is formed from an air supply inlet portion which is bent and extended from the other end of the guide part and sequentially guides the air supply introduced into the indoors through the air supply inlet, air supply guide, air supply outlet of the air supply guide valley; And

An exhaust guide valley portion forming an exhaust flow path is continuously formed repeatedly, and the exhaust guide valley portion is bent from the other end of the exhaust guide portion, an exhaust inlet portion bent and extended from one end of the exhaust guide portion, and bent from the other end of the exhaust guide portion. It comprises an exhaust guide corrugated cardboard formed to guide the exhaust through the exhaust inlet, the exhaust guide portion, the exhaust outlet portion of the exhaust guide bone portion formed in the exhaust air from the interior to the outside;

A plurality of the air supply guide corrugated cardboard and the exhaust guide corrugated cardboard are alternately stacked, and a heat transfer film is interposed between the plurality of the air supply guide corrugated cardboard and the exhaust guide corrugated cardboard,

The air supply guide portion of the air supply guide cardboard and the exhaust guide portion of the exhaust guide cardboard is arranged in parallel so that the moving direction of the air supply passing through the air supply guide portion and the exhaust direction passing through the exhaust guide portion are reversed. .

In addition, the manufacturing method of the total heat exchanger according to the present invention,

Inserting the corrugated core between the first roller and the second roller to form a corrugated cardboard, wherein the first roller is formed on the outer circumferential surface in the rotational direction is repeatedly formed at regular intervals and the protrusion is formed on the left side in the longitudinal direction of the first roller A first inclined protrusion formed to be inclined in an axial direction, a first horizontal protrusion parallel to the axial direction, and a first protrusion in which the first horizontal protrusion and the inclined second inclined protrusion are sequentially formed; A third projection, a second horizontal projection, and a fourth projection, in which the first projection and the left and right symmetrical projections are sequentially formed, the second roller is formed so that the outer circumferential surface thereof meshes with the first roller. Corrugated cardboard forming step of forming a bone by the protrusion by inserting a bone core between the first and second rollers;

Adhering an electrothermal film to one surface of the cardboard formed in the cardboard forming step;

A first cutting step of dividing the corrugated cardboard to which the heat-transfer film is adhered by the bonding step between the bone formed by the second inclined protrusion and the bone formed by the third inclined protrusion to divide the cardboard into left and right cardboard;

A second cutting step of cutting the left and right corrugated cardboard cut by the first cutting step by a predetermined length;

Alternately stacking left and right corrugated cardboard cut in the second cutting step; And

A third cutting step of cutting the laminated cardboard into a predetermined planar shape;

Characterized in that comprises a.

First, a full heat exchanger according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a perspective view of the total heat exchanger according to the present invention, Figure 4 is a partially exploded perspective view of the total heat exchanger 300 according to the present invention.

The heat exchanger 300 according to the present invention is composed of a plurality of air supply guide corrugated cardboard 310, a plurality of exhaust guide corrugated cardboard 320, a plurality of heat transfer film 330, all planar shape is made of a hexagon.

The air supply guide corrugated cardboard 310 is for guiding the air supply B supplied from the outdoor to the indoor, and a plurality of air supply guide valleys 311 forming the air supply flow passage are continuously formed repeatedly, and the air supply guide bone 311 ) Is an air supply guide 313 for guiding the air supply with a predetermined length, the air supply outlet 314 is bent and extended upwardly at an angle from one end of the air supply guide 313, and the air supply It is composed of an air supply inlet portion 312 is bent and inclined downward at a predetermined angle from the other end of the guide portion 313.

The air supply air supplied from the outdoor to the indoor by the air supply guide cardboard 310 is sequentially flowed through the air supply inlet 312, air supply guide 313, air supply outlet 314.

The exhaust guide corrugated cardboard 320 is for guiding the exhaust (A) discharged from the indoor to the outdoor, a plurality of exhaust guide valleys 321 forming the exhaust flow path is continuously formed repeatedly, the exhaust guide bone 321 The exhaust guide portion 323 includes an exhaust inlet portion 324 and an exhaust outlet portion 322 formed at both ends of the exhaust guide portion 323.

The exhaust guide part 323 has a predetermined length to guide the exhaust gas and is disposed in parallel with the air supply guide part 313. The exhaust inlet part 324 is bent and inclined downward from an end of the exhaust guide part 323 at a predetermined angle, and is formed to cross the valley direction of the air supply outlet part 314. The exhaust outlet part 322 is bent upwardly inclined upward at a predetermined angle from the other end of the exhaust guide part 323, and is formed to cross the valley direction of the air supply inlet part 312.

The exhaust discharged from the indoor to the outdoor by the exhaust guide cardboard 320 is sequentially flowed through the exhaust inlet 324, the exhaust guide 323, the exhaust outlet 322.

The plurality of air supply guide corrugated cardboard 310 and the plurality of exhaust gas guide corrugated cardboard 320 are alternately stacked, and the air supply outlet portion 314, air supply guide portion 313 and the air supply guide bone of the air supply guide cardboard 310 The exhaust inlet portion 324, the exhaust guide portion 323, and the exhaust outlet portion 322 of the exhaust guide bone portion of the exhaust guide corrugated cardboard 320 are respectively disposed above (or below) the air supply inlet portion 312. .

The heat insulating film 330 is formed between the alternately stacked air supply guide corrugated cardboard and the exhaust guide corrugated cardboard to perform the role of heat transfer of the air supply and exhaust flow from the upper and lower sides.

Referring to the operation of the total heat exchanger 300 of the present invention having the above configuration is as follows.

The air supplied from the outdoor to the indoor flows sequentially through the air supply inlet 312, air supply guide 313, air supply outlet 314 of the air supply guide bone 310 by the air supply guide 310 The exhaust gas discharged from the indoor to the outdoor is sequentially flowed through the exhaust inlet 324, the exhaust guide 323, and the exhaust outlet 322 of the exhaust guide bone 321 by the exhaust guide corrugated cardboard 320. do. As described above, the exhaust outlet portion of the exhaust guide valley portion 321 above (or below) the air supply inlet portion 312, the air supply guide portion 313, and the air supply outlet portion 314 of the air supply guide valley portion 311 ( 322, the exhaust guide part 323, and the exhaust inlet part 324 are arranged, and the air supply guide part 313 and the exhaust guide part 323 are arranged in parallel so that the air supply guide part 313 and the exhaust guide part ( The air supply and the exhaust guided by 323 move oppositely. As such, the air supply and the exhaust move to face each other, thereby making the heat exchange effect excellent.

In addition, since the heat exchanger 300 of the present invention is made of corrugated cardboard having a predetermined pattern, it is possible to mass produce and at the same time low cost, and also the corrugated cardboard and the heat-transfer film 330 are made of the same paper material. The adhesion has a very low leakage rate.

Hereinafter, a method of manufacturing a total heat exchanger according to a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

5 is a perspective view of a state in which a corrugated cardboard is inserted between the first and second rollers in the method of manufacturing a total heat exchanger according to the present invention, and FIG. 6 is a view of the first and second rollers used in the method of manufacturing a total heat exchanger according to the present invention. 7 is a perspective view of a state in which the heat transfer film is bonded to the corrugated cardboard in the method of manufacturing a heat exchanger according to the present invention, Figure 8 is a plan view of the cardboard is bonded to the heat transfer film on the lower surface in the method of manufacturing a heat exchanger according to the present invention 9 is a plan view of the corrugated cardboard of FIG. 8 bisected, FIG. 10 is a plan view showing the laminated cardboard of bisected in FIG. 9, and FIG. 11 is a diagram of cutting the laminated cardboard of FIG. It is a plan view shown.

First, as shown in FIG. 5, a corrugated cardboard 401, which is a raw material of corrugated cardboard, is inserted into a goal getter 500 including a first roller 510 and a second roller 550 to form a cardboard having bone. The first roller 510 and the second roller 550 is for forming a bone in the core wick, the first roller 510 is a protrusion 511 is repeatedly formed in the rotational direction of the roller on the outer peripheral surface, the second roller 550 is formed so that its outer circumferential surface is engaged with the protrusion 511 of the first roller 510.

Referring to FIG. 6, the protrusion 511 repeatedly formed on the outer circumferential surface of the first roller 510 has a first protrusion 520 formed on the left side in the longitudinal direction (axial direction) of the roller, and a first protrusion 520 on the right side. A second protrusion 530 extending and symmetric with the 520 is formed.

In the first protrusion 520, the first inclined protrusion 521, the first horizontal protrusion 522, and the second inclined protrusion 523 are sequentially formed. The first inclined protrusion 521 is formed to be inclined at a predetermined angle with the axial direction of the first roller 510, and the first horizontal protrusion 522 is formed in parallel with the axial direction of the first roller 510, and the second inclined portion is inclined. The protrusion 523 is formed to be inclined at a predetermined angle with the first horizontal protrusion 522 and has the same inclination direction as the first inclined protrusion 521.

The second protrusion 530 is formed to be symmetrical with the first protrusion 520, and is formed to extend to the second inclined protrusion 523 of the first protrusion 520, and includes a third inclined protrusion 531 and a third protrusion. The two horizontal projections 532 and the fourth inclined projections 533 are sequentially formed.

The third inclined protrusion 531 is formed to be symmetric with the second inclined protrusion 523 and has an inclined direction opposite to the inclined direction of the second inclined protrusion 523.

The second horizontal protrusion 532 is symmetrical with the first horizontal protrusion 522, and is formed parallel to the axial direction of the first roller 510, and the fourth slope protrusion 533 is the first slope protrusion 521. ) Is formed to be symmetrical to the left and right and has the same inclination direction as the third inclined projection (531).

The second roller 550 is formed so that its outer circumferential surface is meshed with the first roller 510. That is, in the second roller 550, the groove 551 corresponding to the protrusion 511 of the first roller 510 is repeatedly formed in the rotation direction, and the first protrusion 520 and the first protrusion of the first roller 510 are formed. The first groove 560 and the second groove 570 corresponding to the second protrusion 530 are formed, and the first groove 560 is the first inclined protrusion 521 of the first protrusion 520 and the first horizontal portion. A first inclined groove 561, a first horizontal groove 562, and a second inclined groove 563 corresponding to the protrusion 522 and the second inclined protrusion 523 are formed, respectively, and the second groove 570 is A third inclined protrusion 531, a second horizontal protrusion 532, a fourth inclined protrusion 533 corresponding to the third inclined protrusion 531, a second horizontal protrusion 533, and a second horizontal groove 557, respectively. A fourth inclined groove portion 573 is formed.

Accordingly, as described above, the corrugated cardboard 410 having a predetermined pattern is formed by the protrusion of the first roller 510 and the second roller 550 engaged therewith (step a).

Then, after the corrugated cardboard is formed, the heat insulating film 470 is adhered to one surface of the corrugated cardboard formed as shown in FIG. 7. (B) Here, an adhesive is applied to one surface of the corrugated cardboard or the heat insulating film.

Thereafter, the cardboard to which the heat-transfer film is adhered is cut between the bone 433 formed by the second inclined protrusion 523 and the bone 451 formed by the third inclined protrusion 531, thereby making left and right corrugated cardboards 430 and 450 cut out. The first cutting step is performed by dividing into ().

Then, a second cutting step of cutting the cut left and right corrugated cardboards 430 and 450 to a predetermined length L is performed (step d, see FIG. 9).

Thereafter, the left and right cardboards 430 and 450 are alternately stacked, and the bone 432 and the right cardboard 450 formed by the first horizontal protrusion 522 of the first roller 510 in the left cardboard 430. The valleys 452 formed by the second horizontal projections 532 of the first roller 510 are stacked in parallel, and the left corrugated cardboard 430 is formed by the first inclined projections 521 of the first roller 510. In the formed bone 431 and the right corrugated cardboard 450, the bones 451 formed by the third inclined protrusions 531 of the first roller 510 are stacked to cross each other and bonded to each other (step e, see FIG. 10). 10, the portion indicated by the solid line is the left cardboard 430, and the portion indicated by the dotted line is the right cardboard 450)

Then, the laminated corrugated cardboard is cut into a predetermined planar shape, and the planar shape is cut to form a hexagon (X), and as shown in FIG. 11, the first horizontal protrusion 522 of the first roller 510 in the left corrugated cardboard. A third cutting step is performed in which a bone formed by the second horizontal protrusion 532 of the first roller 510 is cut parallel to two opposite parallel sides of the hexagon in the bone formed by the right cardboard (step f). , See FIG. 11). By this process, the same heat exchanger as the heat exchanger 300 of the present invention is manufactured.

In addition, in the method of manufacturing a total heat exchanger according to another embodiment of the present invention, step c) is a step of cutting the corrugated cardboard to which a heat-transfer film is bonded to a predetermined length (L), and step d) is performed in c). The left and right corrugated cardboards 430 and 450 are cut by cutting the corrugated cardboard to which the cut heat transfer film is adhered, between the bones 433 formed by the second inclined protrusion 523 and the bones 451 formed by the third inclined protrusion 531. The dividing step) is different from that of the preheat exchanger according to the first embodiment.

The above-described method for manufacturing a total heat exchanger of the present invention enables mass production, low cost, and easy manufacturing, and production of a total heat exchanger having excellent heat exchange efficiency is possible.

Although the present invention has been described with reference to preferred embodiments, it will be apparent to those skilled in the art that modifications and variations are possible without departing from the scope and spirit of the present invention.

According to the present invention, a total heat exchanger and a method for manufacturing the same have an advantage of providing a total heat exchanger having low heat production efficiency and excellent heat exchange efficiency.

Claims (5)

The air supply guide valleys forming the air supply flow passage are continuously formed repeatedly, the air supply guide valleys are bent from the other end of the air supply guide portion, the air supply outlet portion is formed to be bent and extended from one end of the air supply guide portion, An air supply guide corrugated paper configured to sequentially guide the air supply flowing into the air from the outside through the air supply inlet, the air supply guide, and the air outlet through the air supply inlet formed; And An exhaust guide valley portion forming an exhaust flow path is continuously formed repeatedly, and the exhaust guide valley portion is bent from the other end of the exhaust guide portion, an exhaust inlet portion bent and extended from one end of the exhaust guide portion, and bent from the other end of the exhaust guide portion. It comprises an exhaust guide corrugated cardboard which guides the exhaust through the exhaust inlet, the exhaust guide, the exhaust outlet portion of the exhaust guide bone portion formed in the exhaust air from the indoor to the outside formed; A plurality of the air supply guide corrugated cardboard and the exhaust guide corrugated cardboard are alternately stacked, and a heat transfer film is interposed between the plurality of the air supply guide corrugated cardboard and the exhaust guide corrugated cardboard, The air supply guide portion of the air supply guide corrugated cardboard and the air exhaust guide portion of the exhaust guide corrugated cardboard are formed in parallel so that the moving direction of the air supply passing through the air supply guide portion and the air flow direction passing through the air exhaust guide portion are reversed. The air supply outlet and the air supply inlet of the air supply guide valley of the air supply guide corrugated cardboard, respectively, the exhaust inlet and exhaust outlet of the exhaust guide bone of the exhaust guide corrugated body and the bone formation direction is formed to cross each other . The method of claim 1, And the air supply guide corrugated cardboard, the exhaust guide corrugated cardboard, and the heat transfer paper are hexagonal in planar shape. The method according to claim 1 or 2, The air supply guide corrugated cardboard and the exhaust guide corrugated cardboard are formed on the outer circumferential surface in a rotational direction at regular intervals, and the first projection is formed to be inclined with the axial direction on the left side in the longitudinal direction, and the first parallel to the axial direction. A horizontal protrusion, a first protrusion formed sequentially of the first horizontal protrusion and an inclined second inclined protrusion, and a third inclined protrusion, a second horizontal protrusion and a fourth symmetrical symmetry with the first protrusion on the right side; And a corrugated core is inserted between the first roller on which the second protrusion formed with the oblique protrusion is sequentially formed and the second roller formed to correspond to the outer circumference of the first roller. In the manufacturing apparatus of the total heat exchanger, The protrusion is repeatedly formed at regular intervals in the rotational direction on the outer circumferential surface, and the protrusion has a first inclined protrusion formed to be inclined in an axial direction and to the left in the longitudinal direction, a first horizontal protrusion parallel to the axial direction, and the first horizontal protrusion and A first roller having a first projection formed thereon, wherein the second inclined projection inclined is sequentially formed; An apparatus for manufacturing a total heat exchanger including a second roller having an outer circumferential surface formed to correspond with the first roller so as to form a channel by inserting a core core between the first roller and the second roller to form a flow path. . The method of claim 4, wherein The right side of the first roller is formed with a second inclined protrusion is formed in the third inclined protrusion, the second horizontal protrusion, the fourth inclined protrusion and the left and right symmetrical with the first protrusion, the outer peripheral surface of the second roller is the first Apparatus for manufacturing a total heat exchanger is formed to correspond to the roller.

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