KR101339850B1 - Latent heat exchanger assembly method and the latent heat exchanger - Google Patents

Abstract

The present invention relates to a latent heat exchanger comprised in a condensing gas boiler, etc. and, more particularly, to a method for assembling a latent heat exchanger and a latent heat exchanger capable of being promptly assembled with the simple structure by minimizing the screw assembling process without the welding process. The method for assembling a latent heat exchanger comprises the housing preparation step of producing an upper housing and a lower housing produced in the rectangular parallelepiped shape by the drawing process and the punching process; the heat exchange structure production step of laminating a heat exchange member formed in the rectangle shape by a bellows type flexible pipe, forming a heat exchange structure in the rectangular parallelepiped shape and then combining a connection member for entering and discharging heating water with each of an inlet and an outlet of the heat exchange member; the hemming connection step of interposing the heat exchange structure between the upper housing and the lower housing to connect the side surface contacting the upper and lower housings by the hemming process; and the fixation step of fastening and fixating the connection member in the upper and lower housings. [Reference numerals] (S1) Housing preparation step;(S2) Heat exchange structure production step;(S3) Hemming connection step;(S4) Fixation step

Description

Latent heat exchanger assembly method and the latent heat exchanger

The present invention relates to a latent heat exchanger provided in a condensing gas boiler, and more particularly, there is no welding work, and the latent heat that allows assembly work to be performed quickly within a short time by minimizing screw assembly process and having a simple and simple structure. A method of assembling a heat exchanger and a latent heat exchanger thereof.

In general, condensing gas boilers are increasingly being used due to conditions that maximize thermal efficiency with minimal fuel consumption. Heat exchangers that maximize thermal efficiency in such condensing gas boilers are typically directly sensible by burners. The sensible heat exchanger in contact with the sensible heat exchanger and the latent heat exchanger for supplying the heating water to the sensible heat exchanger after preheating the heating water supplied by the latent heat of the exhaust gas passing through the sensible heat exchanger.

As such, the sensible heat exchanger or latent heat exchanger provided in the condensing gas boiler is provided with respective heat exchange structures through which exhaust gas passes through the interior of the housing. Had troublesome and uncomfortable problems.

The present invention relates to a latent heat exchanger among the above heat exchangers, and as described in Patent No. 10-0975104, filed and filed by the present applicant, to smoothly induce exhaust gas in a housing, thereby improving thermal effect pipe efficiency. In addition to improving the foreign matter has been registered to smoothly discharge without contact with the heat exchange structure.

However, in the case of the above-mentioned patent, the assembly process of the latent heat exchanger is quite cumbersome and inconvenient. In other words, an inlet for exhaust gas is formed on one surface thereof, and a drain hole is formed on the bottom surface of the latent heat exchanger. A main body housing in which an exhaust port to be connected is formed to integrally form a horizontal housing and a vertical housing in which front and rear sides are opened; A rear panel fixed to the rear of the main body housing by induction guides by screwing or the like and then being fixed by welding; The heat exchange structure corresponding to the main body is mounted to the front of the main body, and is configured to be assembled by a front panel which is fastened and fixed with several screws together with the packing.

Accordingly, due to the structural characteristics of the main body housing which is formed in the area of the Hangul consonant of the latent heat exchanger, the induction of exhaust gas is smoothly performed, which has the advantage of increasing heat exchange efficiency.

However, in the case of the latent heat exchanger as described above, the structure has a considerably complicated structure, that is, a main body housing composed of horizontal and vertical housings, a rear panel on which an induction guide is fastened, and a front panel on which a heat exchange structure is mounted. In addition to the considerable number and complexity of the elements, assembling through assembly of several screws together with welding, the assembly work is not only cumbersome and inconvenient, but also takes a long time.

In addition, the latent heat exchanger of the registered patent formed in the shape of the tracer has a disadvantage in that the installation area corresponding to it has a large volume due to its structural characteristics.

Korean Patent No. 10-0975104

The present invention has been made to solve the above-mentioned conventional problems, its main purpose is that there is no welding work and the assembly process can be made quickly in a short time according to the simple and simple structure as possible by minimizing the screw assembly process An assembly method of a latent heat bridge cooler and a latent heat exchanger are provided.

Another object of the present invention is to prevent condensate from leaking.

Still another object of the present invention is to facilitate the discharge of condensed water or foreign matter.

The present invention for solving the above technical problem, the housing preparation step of manufacturing the upper housing and the lower housing manufactured in the form of a rectangular parallelepiped by drawing and drilling work; A heat exchange structure manufacturing step of stacking heat exchange members formed in a rectangular shape by a bellows-type flexible tube to form a heat exchange structure in the form of a rectangular parallelepiped, and then coupling a connection member in which heating water is introduced and discharged into each inlet and outlet of the heat exchange member; A hemming joining step of joining a side of the upper and lower housings by a hemming operation through a heat exchange structure between the upper housing and the lower housing; A fixing step of fastening and fixing the connection member to the upper and lower housings; .

An upper housing having a rectangular parallelepiped having an exhaust hole formed on an upper surface thereof and a first insertion hole formed on one side thereof; An inlet for introducing exhaust gas is formed on one side of the bottom surface to correspond to the upper housing, a drain hole is formed on the bottom surface opposite to the inlet, and a second insertion hole is formed at a position corresponding to the first insertion hole. A lower housing having a side edge formed in contact with the upper housing by a joint part by a hemming joint; A heat exchange structure formed by interposing a heat exchange member formed in a rectangular shape by a bellows-type flexible tube in the upper and lower housings and formed in a rectangular parallelepiped shape; A connection member inserted into the first and second insertion holes and fastened to the upper and lower housings such that heating water is introduced into and discharged from each inlet and outlet of the heat exchange member; .

Bonding portion to which the upper and lower housings are bonded is formed on the upper side than the middle in the overall height of the upper and lower housings.

A guide guide plate inclined toward the drain hole formed in the lower housing may be further provided on the bottom surface of the upper housing through which the exhaust hole is formed.

The bottom surface of the lower housing, characterized in that the inclined surface is formed to be inclined toward the drain port side from the side in which the inlet is formed.

In the present invention, there is no welding operation and the assembly process can be performed quickly in a short time according to the simplest and simplest structure by minimizing the screw assembly process, thereby maximizing the assembly efficiency of the latent heat exchanger, thereby improving production efficiency. Of course, the volume is also minimized due to the simple and simple structure, thereby minimizing the installation area, thereby having an excellent space utilization.

In addition, the joint formed in the upper and lower housings is positioned above the middle of the upper and lower housings, thereby preventing condensate from leaking and improving reliability.

In addition, by allowing the discharge of condensed water or foreign matter to be made smoothly, it has an effect of ensuring a long use period and excellent economic efficiency and further increase the reliability.

1 is a block diagram schematically showing an assembly step of the present invention.
2a to 2d schematically illustrate the assembly process of the present invention,
Figure 2a is a main view schematically showing the upper and lower housings.
Figure 2b is a schematic diagram showing the heat exchange structure schematically.
Figure 2c is a schematic main view of the upper, lower housing hemming bonded state.
Figure 2d is a schematic main view of a state in which the connection member is fastened.

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

1 is a block diagram schematically showing an assembly step of the present invention.

In the method of assembling a latent heat exchanger provided in a conventional condensing gas boiler as shown in the drawing, preheating the heating water supplied using latent heat of exhaust gas, and then supplying the heating water to the sensible heat exchanger.

In the present invention, there is no welding work, and in order to minimize the assembly process of the screw to have a simple and simple structure as much as possible, so that the assembly work can be made quickly in a short time,

As shown in FIG. 2A, the plate is manufactured in a rectangular parallelepiped form by a general drawing operation and a drilling operation, that is, the upper housing and the four sides are blocked and the upper housing 10 is opened, and the bottom and the four sides are blocked. A housing preparation step (S1) of manufacturing a lower housing 20 having an upper portion open is performed.

In other words, an exhaust hole 12 connected to the exhaust pipe is formed on the upper surface of the upper housing 10 so as to exhaust the heat exchanged exhaust gas, and on one side thereof, a first insertion hole for inserting an upper portion of the connection member to be described later. 14 is formed, the lower housing 20 is formed with an inlet 22 through which exhaust gas is introduced into one side of the bottom surface corresponding to the upper housing 20, the bottom surface of the opposite side of the inlet 22 A drain hole 24 is formed to discharge foreign substances such as condensate generated during the heat exchange process or rainwater or dust introduced through the exhaust hole, and the connection member at a position corresponding to the first insertion hole 14. The upper and lower housings 10 and 20 having the second insertion hole 26 into which the lower part is inserted are manufactured.

In addition, a drain hole formed in the lower housing without being directly contacted with a heat exchange structure to be described later, rain or dust introduced through the exhaust hole 12 is formed on the bottom surface formed with the exhaust hole 12 of the upper housing 10. It is preferable that the guide guide plate 16, which is installed to be inclined from the exhaust hole 12 side to the drain port 24 side so as to be smoothly discharged through the spot welding, is further provided.

In addition, the bottom surface of the lower housing 20 is also formed as an inclined surface 20a inclined from the inlet 22 side to the drain opening 24 side, that is, in the inclined surface inclined parallel to the guide guide plate, in the heat exchange process It is preferable to allow the condensate generated or the foreign matter introduced through the exhaust hole to be smoothly guided to the drain port and discharged.

Then, a conventional bellows-type flexible tube having a large contact area as shown in FIG. 2B is bent to stack at least 2 to 5 layers of heat exchange members 32 formed in a rectangular shape so that heat exchange can be efficiently performed. Forming a heat exchange structure 30 in the form of a rectangular parallelepiped having a heat exchange structure manufacturing step of coupling the connection member 40, the heating water is introduced and discharged into each of the inlet (32a) and outlet (32b) of the heat exchange member (32) (S2) is performed.

That is, the heat exchange structure 30 may be laminated with a rectangular heat exchange member 32 to have a minimum volume to form a rectangular parallelepiped and have a minimum volume, thereby increasing heat exchange efficiency by a bellows-type flexible tube as much as possible. Has a condition.

Then, as shown in FIG. 2c, the heat exchange structure 30 is interposed between the upper housing 10 and the lower housing 20, and the sides of the upper and lower housings 10 and 20 contact by the conventional hemming operation. A hemming joining step S3 for forming and joining the joining portions 18 is performed.

That is, as the upper housing and the lower housing are joined by a normal hemming operation rather than by separate welding or screw fastening, the upper and lower housings can be quickly and simply joined together in a short time.

In addition, the joint portion 18 formed by the hemming operation on the side of the upper and lower housings 10 and 20 is formed to be located on the upper side than the middle of the overall height of the upper and lower housings 10 and 20. By doing so, it is preferable that the condensed water generated during the heat exchange process or the rain water introduced through the exhaust hole can be smoothly discharged through the drain hole without being leaked by the joint portion formed high from the bottom surface of the lower housing.

Next, as shown in FIG. 2d, the fixing step of fastening and fixing the connection member 40 connected to each inlet and outlet of the heat exchange member, which is the heat exchange structure 30, by screws or the like on the upper and lower housings 10 and 20. To (S4); As a result, the assembly work for assembling a series of latent heat exchangers is completed.

Thus, according to the present invention, the upper and lower housings are manufactured, and after the heat exchange structure is manufactured, the upper and lower housings are joined by a hemming operation instead of being fastened and fixed by welding or several screws. The assembly work of the has been made quickly in a short time without any hassles to improve the assembly efficiency.

In addition, as the joint portion formed by the hemming operation of the upper and lower housings is formed at a height at which the condensate or the like is not leaked, it has a condition to ensure high reliability.

In addition, the guide guide plate provided in the upper housing prevents foreign matter from directly contacting the heat exchanging structure, thereby increasing the heat exchanging efficiency without degrading the performance of the heat exchanging structure.

In addition, by forming the bottom surface of the lower housing to be inclined toward the drain, the discharge of condensate or foreign matter is immediately and smoothly discharged immediately, thereby causing additional heat exchange structure to further increase heat exchange efficiency.

10: upper housing 12: exhaust hole
14: first insertion hole 16: guide guide plate
18: junction 20: lower housing
20a: slope 22: inlet
24: drain hole 26: second insertion hole
30 heat exchange structure 32 heat exchange member
32a: inlet 32b: outlet
40:

Claims (5)

Housing preparation step (S1) for producing the upper housing 10 and the lower housing 20 produced in the form of a rectangular parallelepiped by a drawing operation and a drilling operation;
After stacking the heat exchange member 32 formed in the rectangular shape by the bellows-type flexible pipe to form the heat exchange structure 30 in the form of a rectangular parallelepiped, the heating water is supplied to each inlet 32a and the outlet 32b of the heat exchange member 32. A heat exchange structure manufacturing step (S2) for coupling the inflow and discharge connection members 40;
Hemming bonding step (S3) and the side of the upper and lower housings 10, 20 to contact the side of the upper housing 10 and the lower housing 20 through the heat exchange structure 30 through the hemming operation; ;
A fixing step (S4) of fastening and fixing the connection member 40 to the upper and lower housings 10 and 20; Assembly method of the latent heat exchanger, characterized in that made. An upper housing 10 having a rectangular parallelepiped having an exhaust hole 12 formed on an upper surface thereof and a first insertion hole 14 formed on one side thereof;
An inlet 22 through which exhaust gas is introduced is formed at one side of the bottom surface to correspond to the upper housing 10, and a drain hole 24 is formed at the bottom surface of the opposite side of the inlet 22. A lower housing 20 in which a second insertion hole 26 is formed at a position corresponding to the insertion hole 14 so that a side edge contacting the upper housing 10 is joined by a joint part 18 by a hemming joint;
A heat exchange structure (30) formed in a rectangular parallelepiped by stacking heat exchange members (32) formed in a rectangular shape by a bellows-type flexible tube in the upper and lower housings (10) and (20);
The upper and lower housings 10 and 20 are inserted into the first and second insertion holes 14 and 26 so that the heating water flows into and out of each of the inlet 32a and the outlet 32b of the heat exchange member 32. To the connecting member 40 is fastened to; A latent heat exchanger, characterized in that configured. 3. The method of claim 2,
A latent heat exchanger, characterized in that the junction portion (18) to which the upper and lower housings (10) (20) are joined is formed on the upper side than the middle in the overall height of the upper and lower housings (10) (20). The method of claim 3,
A latent heat exchanger, characterized in that the guide guide plate (16) further inclined toward the drain hole (24) formed in the lower housing 20, the bottom surface formed with the exhaust hole (12) of the upper housing (10). 5. The method according to any one of claims 2 to 4,
The bottom surface of the lower housing 20, the latent heat exchanger, characterized in that the inclined surface (20a) is formed to be inclined toward the drain port (24) from the side in which the inlet (22) is formed.

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