KR101457491B1 - High efficiency boiler - Google Patents

Abstract

The present invention relates to a high efficiency boiler (1). The high efficiency boiler (1) including a plurality of section parts (100) which is connected in a line and has a lower connector (110) formed at a lower portion of the section part (100) and an upper connector (120) formed at an upper portion of the section part (100), comprises: a combustion chamber (130) which has a through hole formed at the central portion of the section part (100) in such a way that combustion gas burnt by a burner moves; a first path (140) which is formed on the outer circumference of the combustion chamber (130) and has at least one first gas passage (141), such that the combustion gas passing through the combustion chamber (130) moves in reverse; second paths (150) which are formed at upper and lower parts of the first path (140) and each of which has a second gas passage (151), such that the combustion gas passing through the first gas passage (141) moves in reverse again; a first main pipe (160) which is formed inside the section part (100) and is formed in a ring shape between the combustion chamber (130) and the first path (140); a second main pipe (170) which is formed between the first path (140) and the second path (150); a third main pipe (180) which is formed inside the border of the section part (100) and connected with the second main pipe (170); and a connection water passage (190) which is communicated with the first main pipe (160) and the second main pipe (170) in such a way that supplied water is circulated through the lower connector (110).

Description

{High efficiency boiler}

The present invention relates to a high efficiency boiler, in which a plurality of section sections 100 are coupled in a row, a lower connection hole 110 is formed in a lower portion of the section section 100, In the high efficiency boiler (1) in which the connecting port (120) is formed,

A combustion chamber 130 formed in the central portion of the section 100 so as to allow the combustion gas combusted by the burner to pass therethrough; a combustion chamber 130 formed around the outer periphery of the combustion chamber 130, A first path portion 140 provided with a first gas passage 141 formed in one or more through holes so that a combustion gas is reversed and moved and a second path portion 140 formed on upper and lower portions of the first path portion 140, A second passage part 150 provided with a second gas passage 151 through which the combustion gas passing through the first gas passage 141 is reversed and moved, A first main pipe 160 formed in the annular shape between the combustion chamber 130 and the first path portion 140 and a second main path 160 formed between the first path portion 140 and the second path portion 150, A third main pipe 180 formed inside the rim of the section 100 and connected to the second main pipe 170 and a second main pipe 170 formed inside the edge of the first main pipe 160, Relates to a high efficiency boiler (1), characterized in that comprises a, a second host (190) to be connected in fluid communication such that the water supplied through the lower connector (110) circulating between 170.

Generally, a boiler having a section connection structure is formed by forming a combustion gas chamber in the section corresponding to the heating plate, and a combustion gas burned by the burner into the combustion gas chamber is introduced into the high-temperature furnace section The water in the water channel is heated to generate a hot water or a steam heat source and transmitted to the upper connector so that indoor heating and hot water can be used.

The heat transfer fin boiler (Korean Utility Model Registration No. 20-0432038) of the following Patent Document 1 is a boiler in which hot gas generated by a burner and a hot air device heats a heating plate to heat hot water and steam, A first combustion chamber formed at a lower end of one side of the heating plate to heat the heating plate with the combustion gas; a second combustion chamber formed adjacent to the first combustion chamber and partially inverted with a part of the combustion gas passing through the first combustion chamber, A second secondary combustion chamber connected to the inverting access road and heating the heating plate with a combustion gas entering through the inverting access road, a second secondary combustion chamber connected to the second secondary combustion chamber, A third combustion chamber in which the combustion gas enters and heats the heating plate, and a heat transfer fin formed in the heating plate by the combustion gas inverted in the inversion access road And heating the entire heating plate along the guide path of the heat transfer fin in a short time to increase the thermal efficiency.

However, in the "heat transfer fin boiler" of Patent Document 1, the water channel structure of the heating plate is formed as a simple water column, and the rising water and the descending water interfere with each other to prevent the water circulation from proceeding smoothly, There is a problem in that the life of the boiler is shortened because local overheating phenomenon occurs at a portion where the rising water and the falling water interfere with each other during long-term use.

Patent Document 1: Korean Utility Model Registration No. 20-0432038

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a fuel injection device for an internal combustion engine, comprising a combustion chamber, The first and second main pipes are formed in the first and second pass portions and the first and second pass portions are formed in the first and second pass portions so that the circulation of the water is smoothly maintained while the thermal efficiency is increased .

The present invention also provides a high efficiency boiler which is capable of increasing the heat efficiency by increasing the flow rate of the combustion gas by increasing the flow rate of the combustion gas by forming the heat transfer guide pin having a streamline shape in the combustion chamber and the periphery of the first and second pass portions.

In order to solve the above problems, the high-efficiency boiler 1 according to the present invention is characterized in that a plurality of section sections 100 are coupled in a row, a lower connection hole 110 is formed in a lower part of the section section 100, A high efficiency boiler (1) in which an upper connection (120) is formed at an upper portion of the section (100)

A combustion chamber 130 formed in the central portion of the section 100 so as to allow the combustion gas combusted by the burner to pass therethrough; a combustion chamber 130 formed around the outer periphery of the combustion chamber 130 and passing through the combustion chamber 130 A first path portion 140 provided with a first gas passage 141 formed in one or more through holes so that a combustion gas is reversed and moved and a second path portion 140 formed on upper and lower portions of the first path portion 140, A second passage part 150 provided with a second gas passage 151 through which the combustion gas passing through the first gas passage 141 is reversed and moved, A first main pipe 160 formed in the annular shape between the combustion chamber 130 and the first path portion 140 and a second main path 160 formed between the first path portion 140 and the second path portion 150, A third main pipe 180 formed inside the rim of the section 100 and connected to the second main pipe 170 and a second main pipe 170 formed inside the edge of the first main pipe 160, A second host (190) to be connected in fluid communication such that the water supplied through the lower connector (110) circulating between 170; including and being configured.

The connecting water channel 190 is connected to the water inlet port 110 through the lower connecting port 110 and the water connecting water through the second and third main pipes 170 and 180, And the high temperature water having a high density due to the heat transmitted from the first, second and third main pipes 160, 170 and 180 among the circulating water inside the section 100 flows into the upper connector 120 And a circulation connection passage 193 for allowing water having a low density to be moved into the first main pipe 160 to be transferred to the second main pipe 170, Is formed.

The inlet connection passage 191 and the discharge connection passage 192 are formed to have the same inner diameter and the circulation connection passage 193 is connected to the inlet connection passage 191 and the discharge connection passage 192 And the inner diameter of the circulation connecting water passage 193 formed in the upward direction from the lower portion of the section 100 is smaller than the inner diameter of the circulation connecting water passage 193.

One or more heat transfer guide pins P having a streamlined shape may be formed on the periphery of the combustion chamber 130 and the first and second pass portions 140 and 150.

The heat transfer guide pins P formed on the first and second pass portions 140 and 150 are disposed to be offset from each other on the inner peripheral edge of the first and second pass portions 140 and 150 do.

According to the present invention, the first and second pass portions are sequentially formed around the combustion chamber formed at the central portion of the section portion, and annular first and second main pipes through which water is moved between the combustion chamber and the first and second path portions are formed And the first and second path portions are formed with connection ducts having different cross-sectional areas, thereby improving the thermal efficiency while smoothly circulating the water.

Further, since the heat transfer guide pin having a streamlined shape is formed on the periphery of the combustion chamber and the first and second pass portions, the flow of the combustion gas is made turbulent and the heat conduction rate is increased to increase the thermal efficiency.

1 is a front view showing a front face of a section of a high-efficiency boiler according to a preferred embodiment of the present invention;
FIG. 2 is a partially enlarged view showing the inside of a connected water channel in the configuration of a high efficiency boiler according to a preferred embodiment of the present invention. FIG.
FIG. 3 is a moving state diagram showing the movement path of the combustion gas in the high-efficiency boiler according to the preferred embodiment of the present invention.
FIG. 4 is a side view showing the movement path of the combustion gas in the interior of the section of the high efficiency boiler according to the preferred embodiment of the present invention,
FIG. 5 is a moving state diagram showing a movement path of water inside a high-efficiency boiler according to a preferred embodiment of the present invention.

Hereinafter, a high-efficiency boiler 1 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that, in the drawings, the same components or parts are denoted by the same reference numerals whenever possible. In describing the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention.

1, the present invention is roughly divided into a combustion chamber 130, a first pass portion 140, a second pass portion 150, a first main pipe 160, a second main pipe 170, a third main pipe 180, and a connecting water channel 190. [

Prior to the description, the present invention is a high-efficiency boiler (1) having one or more section sections (100) functioning as a heat transfer plate joined in series, wherein a path of the combustion gas and water through the internal structure of the section It should be noted that the description is centered on the shape and arrangement.

First, the combustion chamber 130 will be described. 1 or 3, the combustion chamber 130 is a component formed at a central portion of the section 100, and the combustion chamber 130 is connected to each of the sections 100 through a through- So that the combustion gas burned by the burner 10 connected to the section 100 installed at the foremost stage is moved.

In this case, the internal temperature of the combustion chamber 130 is maintained at a high temperature of 1200 ° C or more. In this case, the internal temperature of the combustion chamber 130 is maintained at a high temperature of 1200 ° C or more.

Next, the first pass section 140 will be described. 1 or 3, the first path portion 140 is a combustion gas transfer passage formed around the outer peripheral side of the combustion chamber 130 concentrically with the center of the combustion chamber 130, The first pass part 140 allows the combustion gas entering through the combustion chamber 130 to move reversely so that the first and second main pipes 160 and 170 can be thermally conducted by the temperature of the combustion gas .

The first pass part 140 is formed in at least one through hole in the structure of the present invention so that the first gas passageway 141 in which the combustion gas is moved is spaced apart and between the first gas passageway 141, A connecting water channel 190 connecting the first main pipe 160 and the second main pipe 170 is formed.

Meanwhile, when the combustion gas passing through the combustion chamber 130 moves in the first path portion 140, the temperature of the first path portion 140 becomes 400 to 800 ° C.

Next, the second path unit 150 will be described. 1 and 3, the second path portion 150 is formed at the upper and lower portions of the first path portion 140, It is possible to conduct heat to the second main pipe 170 and the third main pipe 180, which will be described later.

The second path portion 150 includes a second gas path 151 formed on the left and right portions of the upper and lower portions of the first path portion 140, The second gas passageway 151 of the lower left and right portions is formed so that water introduced into the lower connection hole 110 and water circulated in the first, second, and third main pipes 160, 170, It is possible to improve the heat absorption rate according to the temperature drop of the combustion gas moving to the second gas passage 151 of the lower left and right portions of the first path portion 140 by reducing the temperature difference.

When the combustion gas passing through the first pass part 140 moves in the second pass part 150, the second gas passageway 151 formed at the left part and the right part of the upper part of the first pass part 140 The temperature of the second gas passage 151 formed in the left portion and the right portion of the lower portion of the first path portion 140 becomes 150 to 350 캜.

Next, the first main pipe 160 will be described. 1 or 3, the first main pipe 160 is an annular pipe formed between the combustion chamber 130 and the first pass 140. The first main pipe 160 is connected to the combustion chamber 130, It is possible to conduct heat from the first pass 130 and the first pass 140 and serve as an ascending pipe for raising the temperature of the water introduced through the lower connection 110.

Next, the second main pipe 170 will be described. 1 or 3, the second main pipe 170 is annularly formed between the first pass portion 140 and the second pass portion 150. The second main pipe 170 is a ring- Passes through the combustion chamber 130 and the first path portion 140 and is heated to increase the temperature of the water entering the first main pipe 160 due to low-density water flowing therein, To move back to the first main pipe 160 through the first passage 191.

As shown in FIG. 2 or FIG. 5, between the first main pipe 160 and the second main pipe 170, one or more connecting water passages (not shown) are provided so as to continuously circulate the water introduced through the lower connector 110 The connecting water passage 190 is composed of an inlet connecting water passage 191, a discharge connecting water passage 192 and a circulating connecting water passage 193.

The water inlet connection passage 191 is formed to allow water to be introduced through the lower connection hole 110 and low-density water to pass through the second main pipe 170 and a third main pipe 180 And the discharge connection water passage 192 is connected to the first and second main pipes 160, 170 and 180 among the circulating water in the section 100, To the upper connector (120).

The circulating connection water channel 193 allows low-density water to be transferred to the second main pipe 170 to be moved into the first main pipe 160.

2, each of the circulating connection passages 193 has different inner diameters d3, d4, and d5, and the circulating connection passages 193 are connected to the input / The circulation connection passage 193 formed in a lower portion of the section section 100 is formed to be smaller than the inner diameters d1 and d2 of the connection water passage 191 and the discharge connection water passage 192, (d3, d4, d5) are made small, it is possible to increase the heat absorption rate of water by increasing the circulation speed of the water moving in the section section 100 and circulating it.

Next, the third main pipe 180 will be described. As shown in FIG. 1 or 3, the third main pipe 180 is a water pipe formed inside the lower edge of the section 100 and connected to the second main pipe 170, and the third main pipe 180 Is higher in density than water traveling through the combustion chamber 130 and the first pass 140 and moving to the second pass 150 among the water moving through the first main pipe 160, It is possible to increase the temperature of the water which has been introduced and which is lower in density than the high temperature water which can pass through the connection port 120 and to move it again to the first main pipe 160 through the water supply connection passage 191 .

1 or 2, at least one stream guiding fin P having a streamlined shape is formed in the periphery of the combustion chamber 130 and the first and second pass portions 140 and 150, The heat transfer guide pins P are uniformly arranged on the inner periphery of the combustion chamber 130 and are arranged to be offset from each other on the inner peripheral edge of the first and second pass portions 140 and 150 facing each other, As such, when the combustion gas moves, the flow of the combustion gas is made turbulent to increase the heat conduction rate and thereby increase the thermal efficiency.

Hereinafter, referring to FIG. 3 and FIG. 4, a description will be made of a path through which combustion gas moves to a high efficiency boiler according to a preferred embodiment of the present invention.

3 and 4, the combustion gas discharged from the burner 10 installed at the tip end side of the section 100 first enters the combustion chamber 130 and moves in the discharge direction.

When the combustion gas reaches the end of the section 100, the movement of the combustion gas in the discharge direction is limited. Therefore, the combustion gas is supplied to the plurality of first gas passages (not shown) formed on the outer peripheral side of the combustion chamber 130 141, and moves in a reverse direction to discharge the heat to the first main pipe 160 uniformly.

When the combustion gas as described above reaches the tip of the section 100, the movement of the combustion gas toward the reverse direction of the discharge is restricted, so that the combustion gas is supplied to the second passage portion 140, Enters the second path portion 150 provided with the gas passage 151 and moves in the discharge direction again so that the heat is uniformly conducted to the second and third main tubes 170 and 180 and then exhausted.

Hereinafter, with reference to FIG. 5, a description will be made of a path through which water flows in the high-efficiency boiler according to the preferred embodiment of the present invention.

Referring to FIG. 5, the water used for heating passes through the inlet connection passage 191 through the first inlet 102 to the first main pipe 160.

The water moved to the first main pipe 160 is first supplied to the second and third main pipes 170 and 180 through the inlet connecting water passage 191 and the circulating connecting water passage 193 up to the set temperature for generating hot water. And continues to circulate to the first main pipe 160 again.

As described above, the water circulating inside the section 100 is convectively developed due to the temperature being increased to some extent due to the heat conduction of the combustion chamber 130 and the first and second passes 140 and 150, .

On the other hand, the high-temperature water having a high density due to the temperature difference of the water moving inside the first, second and third main pipes 160, 170 and 180 is discharged to the upper connection port 120 through the discharge connection channel 192 And low temperature water having a low density is circulated within the first, second and third main tubes 160, 170 and 180 to increase the temperature while gradually increasing the density.

The circulation connecting water passage 193 communicated from the first main pipe 160 to the second main pipe 170 is connected to the circulation connecting water passage 193 formed in the upward direction from the lower portion of the section 100, The inner diameters d3, d4 and d5 are made smaller as the water circulation rate 193 increases so that the water absorption rate of water can be increased by increasing the circulation speed of the water moving within the section section 100 and circulating it.

The hot water in the circulating water is moved to the heating pipe (not shown) through the air outlet 101 formed in the upper part of the section 100, so that the housing or the facility can be heated.

Optimal embodiments have been disclosed in the drawings and specification. Although specific terms have been employed herein, they are used for purposes of illustration only and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1: High efficiency boiler
10: Burner
100:
101: Delivery port 102: Receipt port
110: lower connector 120: upper connector
130: combustion chamber 140: first pass section
141: first gas passage 150: second pass part
151: second gas passage 160: first main pipe
170: second main body 180: third main body
190: Number of connections 191: Number of connections
192: discharge connection number 193: circulation connection number
P: Heat transfer guide pin

Claims (5)

A high efficiency boiler (100) having a plurality of section sections (100) coupled in a row, a lower connection section (110) formed below the section section (100), and an upper connection section (1)
A combustion chamber 130 formed at a central portion of the section 100 so as to pass through the combustion gas to be burned by the burner;
And a first gas passage 141 formed around the outer peripheral side of the combustion chamber 130 and having a first gas passage 141 through which the combustion gas passing through the combustion chamber 130 is reversed and formed, );
And a second gas passage (151) formed in the upper and lower portions of the first path portion (140) and formed to pass through the combustion gas passing through the first gas passage (141) A two-pass unit 150;
A first main pipe 160 formed inside the section 100 and formed annularly between the combustion chamber 130 and the first pass 140;
A second main pipe 170 formed between the first pass 140 and the second pass 150;
A third main pipe 180 formed inside the rim of the section 100 and connected to the second main pipe 170;
And a connection water passage 190 communicating between the first main pipe 160 and the second main pipe 170 so as to circulate water supplied through the lower connection pipe 110. [ (One). The method according to claim 1,
The connection water passage 190 is connected to the water-
An incoming water connection passage 191 is formed to allow water to be introduced through the lower connection port 110 and water having a low density to be moved through the second and third main pipes 170 and 180,
The high temperature water having a high density due to the heat transmitted from the first, second and third main pipes 160, 170 and 180 among the circulating water in the section section 100 is transferred to the upper connection port 120, A water channel 192 is formed,
And a circulation connecting water channel (193) is formed in such a way that low-density water in the water moved into the first main pipe (160) is transferred to the second main pipe (170). The method according to claim 2,
The inlet connection passage 191 and the discharge connection passage 192 have the same inner diameter,
The circulation connection passage 193 is formed to be smaller than the inner diameter of the inlet connection passage 191 and the discharge connection passage 192. The circulation connection passage 193, (193), the inner diameter is reduced. The method of claim 3,
Wherein one or more streamline guide pins (P) are formed on the periphery of the combustion chamber (130) and the first and second pass portions (140, 150). The method according to claim 4,
The heat transfer guide pins (P) formed on the first and second pass portions (140, 150)
Wherein the first and second pass portions (140, 150) are staggered from each other on the inner peripheral edge of the first and second pass portions (140, 150).

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