KR200261188Y1 - Firebox Structure of Horizontal Boiler - Google Patents

Abstract

The present invention relates to the firebox structure of the horizontal boiler, and the guide portion 31 to discharge the flame and combustion gas generated from the burner 10 to the inner surface of the receiving portion of the hard plate 20 forming the firebox of the horizontal boiler and After the flame and the combustion gas generated from the burner is diffused, a plurality of guide pins 30 having a diffusion portion 32 formed thereon to be inverted to the other side of the accommodating portion 21 are provided at predetermined intervals, and the guide pins 30 By the flame and the combustion gas generated by the burner 10 is introduced into the rear portion of the receiving portion of the hard plate 20 forming the firebox, and then hit the diffusion portion 32 of the guide pin 30 is reversed after the direction of travel is determined By spreading in each direction and discharging it along the guide part 31 as a flue, heat exchange is evenly applied to the heat transfer area of the accommodating part 21 of the hard plate 20 forming the firebox, so that condensation and low temperature corrosion do not occur at the lower part of the firebox. Not being Ron, it is possible to achieve high efficiency in the horizontal boiler structure of Korean Utility Model Publication No. 969 (Notice No. 88-3719), in which the applicant owns the technology. It spreads evenly to the rear, top, bottom, left and right to improve the performance of the breakthrough boiler to save fuel and extend the life of the boiler.

Description

Firebox Structure of Horizontal Boiler

The present invention relates to a firebox structure of a horizontal boiler, and more particularly, to a firebox structure of a horizontal boiler in which combustion gas from a burner is inverted as evenly as possible to the firebox circumferential surface and flows to the combustion gas discharge pipe, thereby improving heat exchange efficiency.

Conventional inverted combustion horizontal boilers are generally as shown in Figure 1, such a horizontal boiler is as described in Korean Utility Model Publication No. 88-3719.

According to Fig. 1, the firebox structure of a conventional horizontal boiler has a firebox 21 by a hard plate 20 made of a circular circumferential surface 20a and a diaphragm 20b for sealing one opening of the circumferential surface 20a. In this case, an opening opposite the diaphragm 20b communicates with the inversion chamber 60, and one end of the plurality of combustion gas discharge pipes 40 disposed at predetermined intervals along the circumferential surface 20a of the hard plate 20 is reversed. Combustion gas from the burner 10 communicated with the chamber 60 and injected laterally through the inverting chamber 60 hits the diaphragm 20b after being introduced into the central portion of the fire chamber 21 and primarily. After being inverted and guided to the inverting chamber 60 along the circumferential surface 20a of the hard plate 20, the inverting chamber 60 is secondarily inverted to guide the combustion gas discharge pipe 40.

However, in the firebox structure of the conventional horizontal boiler, the combustion gas flowing into the inverting chamber 60 along the circumferential surface 20a after being primarily inverted in the firebox 21 is circumferential surface 20a of the hard plate 20. Since it is not provided with a means to distribute evenly, the hot combustion gas flowing into the firebox 21 is inverted to the upper portion of the firebox 21 and flows to the inverting chamber 60 along the upper circumferential surface 20a. Although a large amount of high temperature combustion gas flows into the combustion gas discharge pipe 40 disposed above the circumferential surface 20a of the hard plate 20, the combustion gas discharge pipe disposed under the circumferential surface 20a of the hard plate 20 ( 40) a small amount of hot combustion gas is introduced. Therefore, the combustion gas flowing into the discharge chamber 70 through the combustion gas discharge pipe 40 disposed on the circumferential surface 20a of the hard plate 20 is discharged to the discharge chamber 70 without sufficient heat exchange. Therefore, the problem that the heat exchange efficiency of the boiler is lowered.

In addition, the heating water in the heating water chamber 50 is also not heated evenly (the upper portion is at a high temperature, the lower portion is at a low temperature), causing a problem that the heating efficiency is further lowered.

In order to solve such a problem, as shown in FIG. 2, a guide member 30 ′ disposed at equal intervals is provided on the circumferential surface 20 a of the hard plate 20, and thus, the central portion of the fire chamber 21 is provided. The high temperature combustion gas flowing into the gas is guided between the guide members 30 'after being primarily inverted in the fire chamber 21, so that the high temperature combustion gas flows between the guide members 30'. 20a) is distributed as evenly as possible, but since the high-temperature combustion gas inverted in the firebox 21 is mostly directed only to the upper part, this is also the combustion gas discharge pipe disposed on the upper circumferential surface 20a of the hard plate 20. A large amount of hot combustion gas flows into the 40, but a small amount of hot combustion gas flows into the combustion gas discharge pipe 40 disposed below the circumferential surface 20a of the hard plate 20.

The present invention has been devised to solve the above problems, the combustion gas from the burner is inverted as evenly as possible to the circumferential surface of the fire chamber to flow to the combustion gas discharge pipe, so that the heat exchange efficiency of the horizontal boiler to improve the heat exchange efficiency The purpose is to provide.

1 is a partial cross-sectional view schematically showing an example of a firebox structure according to the prior art;

2 is a partial cross-sectional view schematically showing another example of a firebox structure according to the prior art;

3 is a partial cross-sectional view schematically showing an example of a firebox structure according to the present invention;

4 is a cross-sectional view taken along the line A-A of FIG.

5 is a view showing another example of a firebox structure according to the present invention, corresponding to FIG.

FIG. 6 is a view showing another example of a firebox structure according to the present invention.

FIG. 7a is a partially cutaway perspective view of a hard plate having a guide member according to FIGS. 4 and 6;

FIG. 7B is a partially cutaway perspective view of the hard plate with guide member according to FIG. 5; FIG.

-Explanation of terms for the main parts of the accompanying drawings-

10; Burner, 20; Plate,

20a; Circumferential surface, 20b; Membrane,

21; Firebox, 30; Guide member,

31; Guide portion 32; Diffusion,

40; Flue gas discharge pipe, 50; Chamber for heating water,

60; Inverting chamber, 70; Exhaust chamber.

The present invention for achieving the above object has a structure.

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

The firebox structure of the horizontal boiler according to the present invention, as shown in Figs. 3 and 4, a hard plate consisting of a circumferential surface 20a and a diaphragm 20b for sealing one opening of the circumferential surface 20a. The firebox 21 having one side opened by the 20 is formed, and the guide member 30 for inducing combustion gas reversed in the circumferential surface 20a is disposed at predetermined intervals, and the guide member 30 is And a guide portion 31 attached to the inside of the circumferential surface 20a of the light plate 20 radially from the center of the firebox, and bent from one end of the guide portion 31 to be radial to the diaphragm 20b of the light plate 20. The diffusion portion 32 is attached to the structure is made.

In addition, an opening opposite the diaphragm 20b communicates with the inversion chamber 60, and one end of the plurality of combustion gas discharge pipes 40 arranged at predetermined intervals along the circumferential surface 20a of the hard plate 20 is an inversion chamber ( And the other end of the combustion gas discharge pipe 40 communicates with the exhaust chamber 70 communicated with the exhaust port, while these fire chambers 21, the inverting / exhaust chambers 60 and 70 and the combustion gas discharge pipe are communicated with each other. 40 is disposed in the chamber 50 for heating water.

Combustion gas from the burner 10 injected in the lateral direction through the inversion chamber 60 flows into the central portion of the fire chamber 21 and then firstly inverts while hitting the diaphragm 20b so that After being guided to the inverting chamber 60 along the circumferential surface 20a and the guide member 30, the inverting chamber 60 is secondarily inverted and guided to the combustion gas discharge pipe 40, and then the exhaust chamber 70. It is discharged through the exhaust port, according to the present invention, while the combustion gas introduced into the central portion of the fire chamber 21 hits the diaphragm (20b) while being uniformly dispersed in the space between the diffusion portion 32 of the guide member (30) After being guided to the inverting chamber 60 along the guide portion 31 of the guide member 30 and the circumferential surface 20a of the hard plate 20, the circumferential surface of the hard plate 20 as high as possible is the combustion gas ( It flows evenly distributed in 20a).

Therefore, since the combustion gas of high temperature flows into the combustion gas discharge pipe 40 arrange | positioned around the circumferential surface 20a of the hard board 20 relatively evenly, the combustion gas which flows along the combustion gas discharge pipe 40 is a chamber for heating water 50 After conducting the heat of a high enough temperature to the heating water in the inside) is introduced into the discharge chamber 70, thereby improving the heating efficiency of the boiler.

Meanwhile, as shown in FIG. 5, when the guide part 31 and the diffusion part 32 of the guide member 30 are bent to form an arc, the combustion gas primarily reversed in the fire chamber 21 is formed. Since the vortex is formed while flowing along the guide part 31 and the diffusion part 32, there is an effect that the thermal conductivity is further improved.

In addition, even if the high-temperature combustion gas flows after being inverted as uniformly as possible through the diffusion portion 32 and the guide portion 31 of the guide member 30, the combustion gas flow amount of the upper portion and the lower portion of the fire chamber 21 Since a difference occurs between the flow amount of the combustion gas, as shown in FIG. 6, the distance between the guide members 30 is lower than the circumferential surface 20a of the hard plate 20 from the top of the circumferential surface 20a of the hard plate 20. It is desirable to gradually expand toward.

FIG. 7A is a perspective view, partially cut away, of the hard plate 20 having the flat guide member 30 shown in FIGS. 4 and 6, and FIG. 7B is a hard plate having the guide member 30 constituting the circular arc shown in FIG. 20 is a perspective view partially cut away.

According to the present invention as described above, because the guide member which is radially attached to the inside of the circumferential surface of the hard plate constituting the firebox and the diffusion member is bent from one end of the guide portion to be radially attached to the diaphragm of the hard plate is provided After the combustion gas from the burner flows into the central part of the firebox and is inverted and flows evenly by the guide member, the heat exchange efficiency is increased and the heating efficiency of the boiler is greatly improved.

In addition, since this can reduce the volume of the heat exchanger, there is an advantage that the boiler can be made small, and the lower part of the circumferential surface of the hard plate forming the firebox is not damaged by low temperature corrosion, which is expected to extend the life of the product. .

Claims (3)

The firebox 21 which opened one surface is formed by the circular plate 20 which consists of a circular peripheral surface 20a and the diaphragm 20b which seals one opening part of the peripheral surface 20a, and the peripheral surface 20a is formed. The guide member 30 for inducing the reversed combustion gas is disposed at predetermined intervals, and the opening opposite to the diaphragm 20b communicates with the inversion chamber 60 and along the circumferential surface 20a of the hard plate 20. One end of the plurality of combustion gas discharge pipes 40 arranged at predetermined intervals is in communication with the inversion chamber 60, so that the combustion gas from the burner 10 injected in the lateral direction through the inversion chamber 60 is the fire chamber ( After flowing into the central portion of 21, the membrane 20b hits the diaphragm 20b and is primarily inverted to guide the inversion chamber 60 along the circumferential surface 20a and the guide member 30 of the light plate 20, and then invert the chamber. In the firebox structure of the horizontal boiler which is inverted secondary at (60) and led to the combustion gas discharge pipe (40), The guide member 30 is bent from one end of the guide portion 31 attached to the inner circumferential surface 20a of the hard plate 20 radially from the center of the fire chamber 20 and the hard plate 20. The firebox structure of the horizontal boiler, characterized in that consisting of a diffusion portion (32) attached radially to the diaphragm (20b). 2. The firebox structure according to claim 1, wherein the guide part (31) and the diffusion part (32) of the guide member (30) are bent to form an arc. The method of claim 1, wherein the distance between the guide member 30 is characterized in that the progressively enlarged toward the lower portion of the circumferential surface (20a) of the hard plate 20 from the upper surface of the circumferential surface (20a) of the hard plate 20 The firebox structure of the horizontal boiler.