KR200265304Y1 - Boiler Heat Exchanger - Google Patents

Abstract

The present invention relates to a heat exchanger for a boiler, in particular, the inner periphery of the upper end of the inner wall of the combustion chamber 10 drills a plurality of heating water discharge holes 13 and a plurality of heating water discharge holes 13 penetrated at regular intervals, and the heat exchanger ( On the outer circumferential edge of the heating water heat exchange part 31 of 30, several heating water inlet holes 35 having a shape and size corresponding to the heating water discharge hole 13 are drilled to heat exchange the upper portion of the combustion chamber 10. When the lower end of the machine 30 is inserted and fixed, the heating water discharge hole 13 of the combustion chamber 10 and the heating water inlet hole 35 of the heat exchanger 30 coincide with each other, but the inner wall of the combustion chamber 10 is fixed. By forming an embossing portion 14 having a wave shape, the heating water introduced into the heating return path of the combustion chamber can be smoothly transferred to the heating water heat exchanger of the heat exchanger. Vortex caused by congestion It is a very useful design that can prevent the noise in advance, and when the inner wall of the combustion chamber is not greatly deformed when heated and cooled by the combustion heat of oil, the internal pressure becomes very strong and the heat transfer area is large, so that the heat can be used efficiently. .

Description

Heat exchanger for boiler

The present invention relates to a heat exchanger for a boiler, and in particular, the water is directly connected between a heating return path of the combustion chamber and a heating water heat exchanger of the heat exchanger, so that water is deposited at a certain portion (that is, at the upper end of the rear part of the combustion chamber) on the heating return path of the combustion chamber. The present invention relates to a heat exchanger for a boiler that prevents eddy currents and noises due to intensive heating generated due to congestion.

An oil boiler is obtained by heating a heat exchanger with the combustion heat of a burner which uses oil as a fuel so that the heating water is obtained by primary heat exchange, and optionally by receiving a second heat exchange with external direct water to obtain hot water.

In most of the heat exchangers used in such oil boilers, a low-temperature heat exchanger is mainly applied in which heating water is heated by direct heat of a burner and hot water is indirectly heated by heating water.

However, such a low heat exchanger has a structure in which hot water is indirectly heated by heating water heated by combustion heat of a burner, and thus it is uneconomical because a large amount of time and fuel consumption are required to obtain hot water.

In addition, it is very difficult to minimize the size of the unit to achieve the heat exchange is a lot of obstacles to downsizing the boiler as a whole.

In addition, the structure is very complicated, which causes a decrease in productivity and unnecessary cost increase in the process line.

In addition, as the overall size of the boiler increases, a lot of inconveniences occur during transportation and transportation due to the increase in weight.

Therefore, in recent years, a heat exchanger such as a fourth degree has been developed, which includes a heating return path 110 around the inside of each of the structures installed therein and at the same time a combustion chamber for transmitting the heat of combustion emitted from the burner 200 to the heating water. 100; A burner (200) for dissipating thermal energy by combusting a fuel supplied to a side portion of the combustion chamber (100); A heat exchanger (300) installed at an upper portion of the combustion chamber (100) to selectively supply heating water and hot water by being heated by combustion heat of the burner (200); An exhaust port 120 installed at an upper portion of the heat exchanger 300 to discharge combustion gas to the outside; It is composed of a silencer 121 is installed below the exhaust port 120 to reduce the exhaust noise of the combustion gas.

In this case, the heat exchanger 300 sequentially stacks the heating water heat exchanger 310 and the hot water heat exchanger 320, and is discharged from the burner 200 through the exhaust gas induction furnace 330 provided therein. As the combustion gas passed through, the heat exchange was performed directly.

In addition, one "U" -shaped connecting pipe 340 is provided between the heating return path 110 of the combustion chamber 100 and the heating water heat exchanger 310 of the heat exchanger 300.

That is, a pipe 10A connected to the heating return path 110 is installed at the front upper portion of the combustion chamber 100, and the front bottom of the heating water heat exchanger 310 of the heat exchanger 300 penetrates through the inside thereof. By installing the pipe 31A and installing the "U" shaped connecting pipe 340 between these pipes 10A and 31A, the heating return path 110 and the heating water heat exchanger 310 of the combustion chamber 100 are provided. ) Is a closed circuit through the "U" -shaped connecting pipe 340.

Therefore, the heating water returned to the heating water heat exchange part 310 is primarily heated by passing through the heating return path 110 of the combustion chamber 100, and then the combustion chamber 100 and the heat exchanger 300. ) Is supplied to the heating water heat exchanger 310 of the heat exchanger 300 through one "U" -shaped connecting pipe 340.

However, as described above, since one “U” -shaped connecting pipe 340 is installed between the heating return path 110 of the combustion chamber 100 and the heating water heat exchanger 310 of the heat exchanger 300, the heating piping After the heat is deprived of heat and returned, the heating water is reheated in the heating return path 110 of the combustion chamber 100, and when the water is returned to the heating water heat exchanger 310 of the heat exchanger 300, one “U” -shaped connection is connected. Since only water is transmitted through the pipe 340, not only does not smoothly transfer the heating water from the combustion chamber 100 to the heat exchanger 300, but also the heating water enters the heating return path 110 of the combustion chamber 100 to provide a heating water heat exchanger ( Since only the heating water present around the heat pipe 340 is transmitted when the water is sent to the 340, the heating water existing in the rear of the combustion chamber 100 is maintained in a stagnant state.

In such a state, when the heat of combustion of the burner 200 is continuously applied, heating is applied to the stagnant heating water, so that the heating water (particularly, the combustion chamber 100) exists in a part of the heating channel 110 of the combustion chamber 100. The stagnant heating water in the upper part of the rear part of the vortex caused a vortex phenomenon and noise at the same time.

In addition, since the inner wall of the combustion chamber 100 is composed of a flat iron plate, when the heat due to the combustion of oil is applied and then digested, the deformation is greatly generated, and the internal pressure is very weak and the heat transfer area. There was also a problem that the heat itself can not be used efficiently.

The object of the present invention is to smoothly transfer the heating water introduced into the heating return path of the combustion chamber to the heating water heat exchange part of the heat exchanger, and thus, due to the intensive heating caused by the stagnation of water in a certain part on the heating return path of the combustion chamber. It is to provide a heat exchanger for a boiler that can prevent eddy current and noise in advance.

Another object of the present invention is to form an embossed portion on the inner wall of the combustion chamber, so that the deformation is less generated when heated with the combustion heat of oil and then cooled, as well as the internal pressure is high and the heat transfer area is also large, so that heat can be efficiently used. To provide a heat exchanger for a boiler.

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

As shown in FIG. 1, a heat exchanger for a boiler according to the present invention has a heat insulating material 12 installed at a bottom surface thereof, and a heating return path 11 formed at a periphery thereof. Combustion chamber 10 for transmitting the heat of combustion emitted from the heating to heating water; A burner (20) installed in the lateral part of the combustion chamber (10) for releasing thermal energy by burning the supplied fuel; The heating water heat exchanger 31 and the hot water heat exchanger 32 are sequentially stacked along the exhaust gas induction furnace 33 and are installed on the combustion chamber 10 to be heated by the heat of combustion of the burner 20. A heat exchanger 30 for selectively supplying heating water and hot water; In the heat exchanger consisting of an exhaust port 40 installed on the upper portion of the heat exchanger 30 to discharge the combustion gas to the outside,

In the upper periphery of the breakdown chamber 10, a plurality of heating water discharge holes 13 and a plurality of heating water discharge holes 13 penetrate at a predetermined interval, and the heating water heat exchange part 31 of the heat exchanger 30 is formed. In the lower outer periphery, a plurality of heating water inflow holes 35 having a shape and size corresponding to the heating water discharge holes 13 are drilled to fix the lower end of the heat exchanger 30 to the upper portion of the combustion chamber 10. When the heating water discharge hole 13 of the combustion chamber 10 and the heating water inlet 35 of the heat exchanger (30) is characterized in that the mutual match.

2 is a view showing an embodiment of the heating water discharge hole 13 and the heating water inlet hole 35, characterized in that formed in a circular shape having a predetermined diameter.

3 shows another embodiment of the heating water discharge hole 13 and the heating water inlet hole 35, and is characterized in that it is perforated to have a rectangular shape.

At this time, the heating water discharge hole 13 and the heating water inlet hole 35 is to be drilled at least two or more, in most cases four are drilled at a predetermined interval.

In addition, the inner wall of the combustion chamber 10 to form an embossing portion 14 having a wavy shape so that even if the heating and cooling is repeated, the deformation can be made less.

Here, reference numeral 15 denotes a heating water return port, 36 is a direct water inlet, 37 is a hot water outlet, and 38 is a heating water outlet.

Referring to the effect of the present invention configured as described above are as follows.

First, the combustion chamber 10 is formed in a cylindrical shape so as to maintain a constant interval of the two sheets of iron plate, the upper and lower portions between the two iron plate blocking the heating water return port 15 coupled to the heating return pipe at the bottom of the outer wall By providing a heating, the heating return path 11 is formed between the inner and outer walls of the combustion chamber (10).

In addition, by forming a burner coupler 16 at an approximately middle portion of the combustion chamber 10 in the longitudinal direction, the burner 20 can be detachably installed, thereby replacing or repairing the burner 20 when the burner 20 fails. You can do it.

At this time, by installing a heat insulator 12 at the bottom of the combustion chamber 10, it is possible to prevent the heat of combustion of the burner 20 from convection to the outside through the floor in advance to use the heat efficiently. .

In addition, the inner wall of the combustion chamber 10 forms an embossed portion 14 that is bent in a wave shape, and thus the overall shape of the inner plate is greatly expanded and contracted due to repeated heating and cooling. Is not greatly deformed, the internal pressure becomes very strong, and the heat transfer area itself becomes large, so that the heat of combustion of the burner 20 can be efficiently used.

Meanwhile, several heating water discharge holes 13 are provided at the upper edge portion of the inner wall of the combustion chamber 10 so that the heating water returned by the heating return passage 11 is transferred to the heating water heat exchanger 31 side of the heat exchanger 30. By puncturing at regular intervals, it is not necessary to weld pipes for drilling holes and joining "U" shaped pipes as in the prior art, and not only workability is improved, but also the heating water discharge hole 13 itself. Since there are several, the heating water returned in the heating return passage 11 can prevent itself from stagnation.

On the other hand, the heating water heat exchanger 31 and the hot water heat exchanger 32 has a configuration that is sequentially stacked along the exhaust gas induction path 33, the heating of the heat exchanger 30 is installed on the combustion chamber 10 On the outer circumferential edge of the water heat exchange part 31, several heating water inlet holes 35 having a shape and a size corresponding to the heating water discharge hole 13 are drilled.

Therefore, in the future, when the lower end of the heat exchanger 30 is inserted into the upper part of the combustion chamber 10 and fixed to each other by soldering or the like, the heating water discharge hole 13 of the combustion chamber 10 and the heating water of the heat exchanger 30 are Since the inner circumferential surface of the combustion chamber 10 and the lower outer circumferential surface of the heat exchanger 30 are tightly fixed by lead or the like in a state where the inflow holes 35 coincide with each other, the combustion chamber 10 may not be used at all without using a separate connection pipe as in the related art. The heating return path 11 and the inside of the heating water heat exchanger 31 of the heat exchanger 30 may be interconnected.

Thus, the inside of the heating return path 11 and the heating water heat exchange part 31 of the combustion chamber 10 are the heating water discharge holes 13 of the combustion chamber 10 and the heating water inlet hole 35 of the heating water heat exchange part 31. Because it is directly connected to each other through) through the heating pipe to perform the indoor heating and the heating water flowing into the heating return channel 11 of the combustion chamber 10 to smoothly send the water to the heating water heat exchanger 31 of the heat exchanger (30). It can be.

That is, the heating water introduced into the heating return passage 11 of the combustion chamber 10 is not stagnated in the heating return passage 11 of the combustion chamber 10 but drilled into the combustion chamber 10 and the heating water heat exchanger 31, respectively. Since the water is sent to the heating water heat exchange part 31 of the heat exchanger 30 through several heating water discharge holes 13 and the heating water inlet hole 35, vortices caused by water stagnation (that is, water As a result of the boiling, water swirling) and noise are not generated at all.

In this case, the heating water discharge hole 13 and the heating water inlet hole 35 may be formed in a circular shape having a predetermined diameter as in the second degree, or may be perforated to have a rectangular shape as in the third degree. This can be determined according to the size of the heat exchanger.

In addition, the heating water discharge hole 13 and the heating water inlet hole 35 can drill at least two, four, or eight or more, and if four or more are normally drilled, the heating return of the combustion chamber 10 may be reduced. The heating water introduced into the (11) can be smoothly sent to the heating water heat exchange part 31 of the heat exchanger (30).

As described above, according to the present invention, a plurality of heating water discharge holes and inlet holes are drilled at the same positions on the inner wall of the combustion chamber and the outer wall of the heating water heat exchanger of the heat exchanger, so that the heating and return of the combustion chamber are matched with each other. The heating water flowed into the furnace can be smoothly transferred to the heating water heat exchanger of the heat exchanger, which can prevent vortex phenomena and noise caused by the stagnation of water in a certain part on the heating return path of the combustion chamber. In addition, the inner wall of the combustion chamber is formed with an embossing part, so that when it is heated with oil combustion heat and cooled, less deformation occurs and the internal pressure becomes very strong, and the heat transfer area is large, which makes it possible to use heat efficiently. will be.

1 is an overall configuration diagram of the boiler to which the present invention is applied

2 is an exploded perspective view of an embodiment of a heat exchanger of the present invention.

3 is an exploded perspective view of another embodiment of a heat exchanger of the present invention.

4 is an overall configuration diagram of a conventional oil boiler.

Explanation of symbols used in the main part of the drawing

10: combustion chamber 11: heating return

12: heat insulating material 13: heating water discharge hole

14: Ambossing unit 15: Heating water return hole

16: burner coupler 20: burner

30: heat exchanger 31: heating water heat exchanger

32: hot water heat exchanger 33: exhaust gas induction furnace

35: heating water inlet hole 36: direct water inlet

37: hot water outlet 38: heating water outlet

Claims (4)

A combustion chamber 10 which transfers combustion heat emitted from the burner 20 to the heating water; A burner (20) installed in the lateral part of the combustion chamber (10) for releasing thermal energy by burning the supplied fuel; The heating water heat exchanger 31 and the hot water heat exchanger 32 are sequentially stacked along the exhaust gas induction furnace 33 and are installed on the combustion chamber 10 to be heated by the heat of combustion of the burner 20. A heat exchanger 30 for selectively supplying heating water and hot water; The inner periphery of the inner wall of the combustion chamber 10 is drilled with a heating interval 11 and several heating water discharge holes 13 penetrating at a predetermined interval, and the heating water heat exchanger 31 of the heat exchanger 30. The lower outer periphery of the heat exchanger for the boiler, characterized in that the perforated several heating water inlet hole (35) having a shape and size corresponding to the heating water discharge hole (13). The heating water inlet hole of the heating water discharge hole 13 and the heat exchanger 30 of the combustion chamber 10 when the lower end of the heat exchanger 30 is fixed to the upper portion of the combustion chamber 10. A heat exchanger for boiler, characterized in that (35) is mutually matched. The heat exchanger of claim 1, wherein the heating water discharge hole (13) and the heating water inlet hole (35) are perforated at least two in a circle having a predetermined diameter. The heat exchanger according to claim 1, wherein an inner wall of the combustion chamber (10) has an embossing portion (14) having a wave shape.