KR200153586Y1 - Hot water heat exchanger - Google Patents

Abstract

The present invention relates to a hot water heat exchanger of a gas boiler, and in particular, consisting of a plurality of cylindrical heating tubes each of which is blocked inside, by installing a coiled pipe inside each heating tube, the contact area is increased to increase the heat exchange efficiency The present invention relates to a hot water heat exchanger for a gas boiler, the volume of which is suitable for installation in a slim gas boiler.

The hot water heat exchanger for an instantaneous gas boiler of the present invention is separated into two pairs of heating tubes (42, 44) (46, 48) in which the movement of the heating water is blocked by the blocking plate (72). The 42 and 44 are separated by a blocking plate 68 having a moving passage formed at an upper portion and a lower portion thereof, and the heating tubes 46 and 48 are also separated by a blocking plate 70 having a moving passage formed at an upper portion and a lower portion thereof. And a connection pipe 58 connecting the lower portions of the heating tubes 42 and 44 and the lower portions of the heating tubes 46 and 48, and the heating water inflow pipe 50 is formed on the upper portion of the heating tube 42. A heating tube formed in the heating tube, wherein a heating water discharge pipe 52 is formed on the heating tube 46; Both ends of the coil pipes 60 and 62 installed inside the heating tubes 42 and 44 are connected to each other, and one end thereof is connected to the hot water discharge pipe 54 passing through the upper portion of the heating tube 44. Both ends of the coil pipes 64 and 66 installed inside the 48 are also connected to each other so that one end is connected to the direct inflow pipe 56 passing through the upper portion of the heating tube 48, and the remaining ends not connected to each other are connected to each other. A coil pipe to form a direct flow path; Characterized in that consists of.

Description

Hot water heat exchanger for dual parallel type instant gas boiler

1 is an external perspective view of a conventional plate heat exchanger.

2 is a cross-sectional view of FIG.

3 is an external perspective view of a conventional coil heat exchanger.

4 is a cutaway view of FIG.

5 is an external perspective view of a heat exchanger according to the present invention.

6 is a cutaway view of FIG.

* Explanation of symbols for main parts of the drawings

2: plate heat exchanger 4: brass forging

6: heating water inlet pipe 8: heating water discharge pipe

10: direct inflow pipe 12: hot water discharge pipe

20: coil type heat exchanger 22: heat exchanger body

24: heating water inlet pipe 26: heating water discharge pipe

28: direct inflow pipe 30: hot water discharge pipe

32: coil pipe 40: heat exchanger

42,44,46,48: Heating tube 50: Heating water inlet pipe

52: heating water discharge pipe 54: hot water discharge pipe

56: direct inflow pipe 58: connection pipe

60,62,64,66: coil pipe 68,70: blocking plate

72: blocking plate

The present invention relates to a hot water heat exchanger of a gas boiler, and in particular, consisting of a plurality of cylindrical heating tubes each of which is blocked inside, by installing a coiled pipe inside each heating tube, the contact area is increased to increase the heat exchange efficiency The present invention relates to a hot water heat exchanger for a gas boiler, the volume of which is suitable for installation in a slim gas boiler.

Conventionally, in a gas boiler, heat exchange between heating water and direct water forms a passage to move the heating water, and another passage is formed to move the direct water so as not to be mixed with the heating water, thereby moving between the heating water and the direct water. The effect of heat transfer by temperature difference was performed.

In this case, the heat transfer medium (in general, metal medium such as copper or stainless steel) in indirect contact with the heating water uses a medium with high heat transfer rate, and also increases the heat transfer efficiency by maximizing the area of the contact surface in indirect contact. . However, such a heat exchanger is bulky, and there is a problem that the price is high. 1 shows a plate type heat exchanger 2 that has been conventionally used, and has a structure in which stainless plates and rubbers are stacked from the top to the bottom, and are supported by brass forgings at the upper and lower ends. The external perspective view (FIG. 1) and the cutaway view (FIG. 2) of the heat exchanger 2 are shown.

At the top and bottom of the heat exchanger (2) is a brass forging (4) for supporting and fixing the entire structure in the upper and lower parts, the heating water inlet pipe (6) for the water in and out on the outer surface of the brass forging (4) ), The heating water discharge pipe 8, the direct water inflow pipe 10, and the hot water discharge pipe 12 protrude outward.

In general, the heating water inlet pipe 6 and the heating water discharge pipe 8 are integrally formed in each of the brass forgings 4, and the direct water inlet pipe 10 and the hot water outlet pipe 12 are separate pipes. It extends through the brass forging (4).

Stainless steel plates and rubbers are stacked between the brass forgings 4 located at the upper and lower ends to form passages of water.

That is, the main body of the heat exchanger 2 is composed of a plurality of stainless plates and rubbers, and the inside of the heat exchanger 2 is divided into a passage through which the heating water moves and a passage through which the direct water moves.

The dividing passage, referring to FIG. 2, includes a heating water moving passage consisting of a heating water inflow pipe 6 and a heating water discharge pipe 8, a direct water inflow pipe 10, and a hot water discharge pipe 12. The parts indicated by the arrows are moving passages of hot water and heating water, respectively.

Although not shown in detail, a space is formed between each moving passage so that the heating water and the direct water may move along each moving passage without mixing with each other.

Therefore, since the heating water has a higher temperature than the direct water when moving each passage, the heat moves from the heating water to the direct water, and the direct water increases in temperature.

The heat exchanger (2) has a good heat transfer by using a stainless plate having a good heat transfer rate, and also has a high heat transfer efficiency due to a good blocking effect of heat dissipated to the outside due to the use of a rubber.

However, the heat exchanger (2) is expensive compared to having a high heat transfer efficiency, and is manufactured by using a forging of brass, stainless steel, etc., which is heavy in weight and complicated in structure, and loses pressure of hot water compared to heating water. In this case, when used in an area where the water pressure of the water supplied to the heat exchanger is high, deformation of the stainless plate may occur, causing leakage.

Also shown in FIG. 3 is a coil type heat exchanger 20 that has been conventionally used, and its appearance is similar to that of a conventional stainless plate type, but the coil type heat exchanger 20 has a main body 22 of the same metal, that is, copper. It is integrated.

In addition, the inside of the main body 22 is empty, and in this empty space, referring to FIG. 4, a coiled pipe 32 in which the pipe is spirally wound is installed, and both ends of the coiled pipe are directly inlet pipe 28. ) And hot water discharge pipe 30.

On the outer surface of the heat exchanger body 22, a heating water inlet pipe 24 and a heating water discharge pipe 26 are also formed integrally with the body 22 on the upper and lower surfaces, respectively.

Therefore, when the heating water and the direct water moves in each passage, since the heating water has a higher temperature than the direct water, the heat moves from the heating water to the direct water, and the direct water increases in temperature.

However, the coil-type heat exchanger 20 as described above is bulky and has a problem in that the heat exchange efficiency is low and the price is high because the body 22 is made of copper and radiates a lot of heat to the outside.

In order to solve the above problems, the present inventors have high heat efficiency due to less heat dissipated to the outside, light weight by not using heavy metal such as copper or brass, and reduce the volume of the boiler as a slim type. It is early to devise a hot water heat exchanger for an instantaneous gas boiler.

It is an object of the present invention to provide a hot water heat exchanger for a gas boiler, which can be used in a small gas boiler due to its small volume.

Another object of the present invention is to provide a hot water heat exchanger for a gas boiler having an excellent thermal insulation effect by injection molding a plurality of heating tubes internally connected to each other by plastic.

Still another object of the present invention is to provide a hot water heat exchanger for a gas boiler which can be used in a place where volume is reduced, manufacturing cost is reduced, and a large amount of hot water is required.

Hot water heat exchanger for instantaneous gas boilers of the present invention for achieving the above object, to the two pairs of heating tubes (42, 44) (46, 48) in which the movement of the heating water is blocked internally by the blocking plate (72) The heating tubes 42 and 44 are separated by a blocking plate 68 having moving passages formed at upper and lower portions thereof, and the heating tubes 46 and 48 also have blocking passages having moving passages formed at upper and lower portions thereof. And a connecting pipe 58 connecting the lower portions of the heating tubes 42 and 44 to the lower portions of the heating tubes 46 and 48, and the heating water inflow pipe 50 is heated. A heating tube formed at an upper portion of the tube 42, and a heating water discharge pipe 52 formed at an upper portion of the heating tube 46; Both ends of the coil pipes 60 and 62 installed inside the heating tubes 42 and 44 are connected to each other, and one end thereof is connected to the hot water discharge pipe 54 passing through the upper portion of the heating tube 44. Both ends of the coil pipes 64 and 66 installed inside the 48 are also connected to each other so that one end is connected to the direct inflow pipe 56 passing through the upper portion of the heating tube 48, and the remaining ends not connected to each other are connected to each other. A coil pipe to form a direct flow path; Characterized in that consists of.

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

The present invention relates to a hot water heat exchanger of the improved gas boiler, the main body is composed of a plurality of cylindrical heating tube which is blocked by the blocking plate and the moving hole is formed in a portion of the blocking plate to form a moving passage of the heating water. By installing coiled pipes connected to each other inside each heating tube, the indirect contact area between the heating water and the direct water is increased to increase the heat exchange efficiency, and the volume is reduced compared to the conventional heat exchanger, which is suitable for installation in a slim gas boiler. Hot water heat exchanger for gas boiler.

5 is a perspective view of the overall appearance of the hot water heat exchanger for the instantaneous gas boiler according to the present invention.

As shown, the heat exchanger is composed of four heating tubes 42, 44, 46, 48, and the heating water inlet pipe 50, hot water on top of each heating tube 42, 44, 46, 48 The discharge pipe 54, the heating water discharge pipe 52, and the direct water inlet pipe 56 are shown.

Although not shown, the four heating tubes 42 and 44 and 46 and 48 are separated from each other so that the heating water does not move by a blocking plate installed therein.

The connection pipe 58 installed under the heating tube is for moving the heating water inside the separated heating tube.

One end of the connection pipe 58 is connected to the lower part of the heating tubes 42 and 44, and the other end thereof is connected to the lower part of the heating tubes 46 and 48, thereby enabling movement of the heating water.

In the present invention, the inlet and outlet pipes for supplying the heating water and hot water in particular are characterized in that the upper side of the heating tube is installed. This has the advantage that the assembly time is greatly shortened.

FIG. 6 is a cutaway view of FIG. 5 to show the structure of the heating tube and the installation structure of the coil pipes 60, 62, 64, 66. FIG.

The heating tubes 42, 44, 46, 48 are blocked by a centrally located blocking plate 72. Therefore, the heating water does not pass internally.

In addition, a blocking plate 68 is provided between the heating tubes 42 and 44. However, the blocking plate 68 is provided with a moving hole in the upper and lower portion can pass the heating water.

The blocking plate 68 allows the heating water flowing from the heating water inlet pipe 50 to be evenly distributed into the heating tubes 42 and 44, and supports the coil pipes 60 and 62.

The blocking plate 70 provided between the heating tubes 46 and 48 has the same effect.

A connecting pipe 58 is provided below the heating tubes 42 and 44.

The other end of the connecting pipe 58 is connected to the lower portions of the inner tubes 46 and 48 to become passages for heating water.

Both ends of the coil pipes 60 and 62 provided inside the heating tubes 42 and 44 are connected to each other.

One end of both ends is connected to the hot water discharge pipe 54, and the other end is connected to one end of the coil pipes 64 and 66 connected to the direct inflow pipe 56 to form a movement passage of the hot water.

Both ends of the coil pipes 64 and 66 also have one end connected to the direct inlet pipe 56 and the other end connected to the ends of the coil pipes 60 and 62.

The advantage of this structure is that the coil pipes are connected in parallel and the contact area with the heating water is large, so that a large amount of hot water with a high temperature is required.

In addition, the heat exchanger according to the present invention can be manufactured by plastic injection molding. Therefore, there is an advantage in that the weight is very light and easy to handle compared to the product using a conventional brass or copper.

Referring to the operation and effects of the instantaneous gas boiler hot water heat exchanger of the present invention as described above.

The heating water introduced through the heating water inflow pipe 50 passes through the heating tubes 42 and 44 simultaneously and is moved through the connection pipe 58 installed at the lower portion.

At the same time, the direct flow introduced through the direct inflow pipe 56 is bisected and moved to the coil pipes 64 and 66 installed in the heating tube 46.

During this movement, heat is transferred from the heating water, and the dividing water is transferred to the coil pipes 60 and 62 installed in the heating tubes 42 and 44 through one pipe at the end.

The heating water passing through the connecting pipe 58 is evenly separated by the blocking plate 70, and passes through the coil pipes 64 and 66 to be discharged through the heating water discharge pipe 52.

As described above, the present invention can be used in a gas boiler having a small thickness due to its own volume, and by injection molding the heating tube through which the heating water passes, the thermal insulation effect is improved and thermal efficiency is improved, and the volume of the conventional heat exchanger is improved. It is reduced, manufacturing costs are reduced, hot water heat exchanger for the gas boiler can be used where a large amount of hot water is needed.

Although the present invention has been described in detail only with respect to the embodiments described, it will be apparent to those skilled in the art that the present invention may be modified or changed within the spirit and scope of the present invention, and such modifications or changes are made by the appended utility model claims. Should be limited.

Claims (2)

In the hot water heat exchanger of the gas boiler, it is separated into two pairs of heating tubes (42, 44) (46, 48) in which the movement of the heating water is blocked internally by the blocking plate (72), and the heating tubes (42, 44) ) Is separated by a blocking plate 68 having a moving passage formed at an upper portion and a lower portion thereof, and the heating tubes 46 and 48 are also separated by a blocking plate 70 having a moving passage formed at an upper portion and a lower portion thereof. A connection pipe 58 is formed connecting lower portions of 42 and 44 to lower portions of the heating tubes 46 and 48, and a heating water inflow pipe 50 is formed on the upper portion of the heating tube 42. A heating tube having a heating water discharge pipe 52 formed on the heating tube 46; Both ends of the coil pipes 60 and 62 installed inside the heating tubes 42 and 44 are connected to each other, and one end thereof is connected to the hot water discharge pipe 54 passing through the upper portion of the heating tube 44. Both ends of the coil pipes 64 and 66 installed inside the 48 are also connected to each other so that one end is connected to the direct inflow pipe 56 passing through the upper portion of the heating tube 48, and the remaining ends not connected to each other are connected to each other. A coil pipe to form a direct flow path; Hot water heat exchanger for dual parallel type instantaneous gas boiler, characterized in that consisting of. 2. The hot water heat exchanger of claim 1, wherein the heating tubes (42, 44, 46, 48) are made by plastic injection molding.