KR200414752Y1 - A parasitic fire boiler - Google Patents

Abstract

The present invention relates to a boiler (1) used for various industrial sites or home use, the diaphragm (2a) is installed so as to partition the inside of the main body (2) constituting the boiler (1) up and down, the lower part of the first heat exchange room A second heat exchange chamber 4 is formed at the upper portion of the upper portion 3, and a third heat exchange chamber 7 is integrally formed to have an outlet 7a on the main body 2, and the first heat exchange chamber 3 is formed. The heat medium chamber 5 is provided in the interior thereof, and the first heat gathering chamber 6 is formed in the lower portion by the heat medium chamber 5, and the first heat gathering chamber 6 and several heat exchange pipes 9 are formed. The 2nd heat | fever gathering chamber 8 is provided in the inside of the 3rd heat exchange chamber 7 so that it may communicate with.

The heat medium chamber 5 and the third heat exchange chamber 7 are configured to communicate with each other, and a plurality of heat pipe heat transfer pipes 10 each having a plurality of heat exchange pipes 9 surrounded from the outside are installed, and the heat medium chamber 5 The burner 11 is installed at one side of the first heat exchange chamber 3 so that the flame is directly sprayed on several heat transfer heat pipes 10 installed in the heat sink) and sprayed in the first heat exchange chamber 3. The first heat source supply means 12 is configured to vertically penetrate the heat medium chamber 5 so as to supply the heat source generated by the flame to the first heat collecting chamber 6 and the second heat collecting chamber 8 In order to supply the heat source to the second heat exchange chamber (4), the second heat source supply means (13) is installed, and the flue (14) is provided in communication so as to discharge the waste gas to one side of the second heat exchange chamber (4). The present invention having the above-described configuration maximizes the heat transfer area of the heat medium and at the same time eliminates a separate combustion chamber, thereby miniaturizing the boiler (1). High thermal efficiency due to even heat dissipation throughout the boiler 1 by forming a vortex by directly injecting the flame of the burner 11 into the heat transfer pipe 10 to increase the heat efficiency. Many effects can be expected, such as maximizing the life of (1).

Vortex, boiler, heat exchange chamber, heat source flow guide plate, heat medium chamber, hot chamber, heat exchange pipe, heat transfer pipe, heat source supply means

Description

A parasitic fire boiler

1 is a cross-sectional view showing a preferred example of the flame vortex boiler provided in the present invention

Figure 2 is a side cross-sectional view of the flame vortex boiler provided in the present invention

3 is a cross-sectional view taken along line A-A of the flame vortex boiler provided in the present invention

Figure 4 is a cross-sectional view showing a second example of the flame vortex boiler provided in the present invention

5 is a cross-sectional view taken along line B-B of the flame vortex boiler provided in the present invention

Figure 6 is a cross-sectional view showing a third example of the flame vortex boiler provided in the present invention

7 is a cross-sectional view taken along line C-C of the flame vortex boiler provided in the present invention

◀ Explanation of symbols used in the main part of the drawing ▶

1: (flame vortex type) boiler 2: body

2a: Plate 3: First heat exchange chamber

4: 2nd heat exchange room 4a: heat source residence guide plate

5: Thermal medium chamber 5a: Thermal medium supply pipe

6: 1st Opening Meeting Room 7: 3rd Heat Exchange Room

7a: Outlet 8: Second Opening Meeting Room

9: heat exchange pipe 10: heat medium heat transfer pipe

11: burner 12: first heat source supply means

13: second heat source supply means 14: year

15: Through Pipe 16: Through Hole

16a: fixed mouth 17: large diameter through-pipe

18: Communication District 19: Daegu Gyeongtong District

19a: Opening

The present invention relates to a boiler used for various industrial sites or homes, and in more detail, it is possible to remove the combustion chamber from the existing boiler to increase the heat transfer area of the boiler, greatly reduce its size, and the flame sprayed from the burner is a heat transfer pipe. The purpose of the present invention is to provide a flame vortex-type boiler which generates vortices to prevent the heat loss of the boiler due to heat dissipation, thereby extending the life of the boiler and obtaining high thermal efficiency.

In general, a boiler supplies the flame of a burner to a combustion chamber, heats the heat medium (water) by receiving the heat source generated from the combustion chamber, and generates a heat medium (steam to hot water) with heat deformation.

The structure of the conventional boiler is composed of a burner, a combustion chamber, several heat transfer pipes communicating with the combustion chamber, a heat medium chamber outside the combustion chamber, and a heat exchange chamber through which heat exchange is performed through the heat medium (= heat transfer medium). The heat transfer area is structurally small compared to the size, resulting in low thermal efficiency.The flames emitted from the burner are supplied to only one side of the combustion chamber, so that one side of the combustion chamber has heat concentrating phenomenon. Energy costs have been consumed a great deal, and the heat loss of the heat exchange pipe has a problem such that the life of the boiler is shortened. Therefore, it is urgently required to develop a device capable of improving and solving the above problems.

Therefore, the present invention is to provide a boiler having a new configuration that can improve and solve the problems of the conventional boiler as described above, the present invention is to remove the combustion chamber of the conventional boiler and the flame of the burner heat transfer pipe and heat medium Flame vortex that can be directly injected into the chamber to dissipate heat by causing the vortex to dissipate by the heat transfer pipe to increase the heat transfer area of the boiler, significantly reduce the size of the boiler itself, improve thermal efficiency, and extend the life of the boiler. The present invention has been completed with the technical problem of the design in providing a type boiler.

1 is a cross-sectional view showing a preferred example of the flame vortex boiler provided in the present invention, Figure 2 is a side cross-sectional view of the flame vortex boiler, Figure 3 is a cross-sectional view of the AA line of the flame vortex boiler as When the present invention is described in detail below.

The present invention is installed in a boiler (1) used for various industrial sites or home use, the diaphragm (2a) for partitioning the inside of the main body (2) constituting the boiler (1) up and down, the lower part of the first heat exchange chamber The heat exchanger penetrating from the outside of the main body 2 is supplied to the upper part of the main body 2, the second heat exchange chamber 4, and the lower part of the inner plate 2a, that is, the inside of the first heat exchange chamber 3. The heat medium chamber 5 provided with the pipe 5a in communication with each other is provided so that the first heat collecting chamber 6 is formed at the lower portion by the heat medium chamber 5.

The heat medium (= heat transfer medium) may be selected and used according to the user's preference or the installation environment of the boiler 1 among various heat transfer media such as gas such as water, fluid, and air.

The upper part of the main body 2 is provided with a third heat exchange chamber 7 having an outlet 7a of a heat medium in which heat deformation is caused by heating, and a second heat exchange chamber 8 inside the third heat exchange chamber 7. It is configured to communicate with the first heat collecting chamber 6 and the several heat exchange pipes (9) formed in the lower side of the main body 2, the heat medium chamber (5) and the third heat exchange chamber (7) Several pipes 9 are configured to communicate with each other in a heat transfer pipe 10 in the form of a double tube surrounding the outside.

The first heat exchange chamber 3 is provided with a burner 11 at one side such that a flame is directly injected onto several heat transfer pipes 10 installed in the heat medium chamber 5 installed therein. The flame sprayed in 11) is configured to vortex by several heat transfer heat pipes 10 so that heat dissipation occurs.

A first heat source supply penetrating the heat medium chamber 5 up and down to supply the heat source generated by the flame sprayed into the first heat exchange chamber 3 to the first heat collecting chamber 6 under the heat medium chamber 5. A means 12 is formed, and a second heat source supply means 13 is formed so that the second heat exchange chamber 8 and the second heat exchange chamber 4 communicate with each other, and to one side of the second heat exchange chamber 4; Installs a flue 14 which can be heat exchanged several times and discharge the remaining waste gas.

The first heat source supply means 12 may be composed of several through pipes 15 penetrated vertically through the edge of the heat medium chamber 5, as shown in Figures 1 to 3, as shown in Figures 4 to 5 Likewise, the outer diameter of the heat medium chamber 5 is formed at regular intervals from the inner diameter of the main body 2, and is fixed to several fasteners 16a for fixing the heat medium chamber 5 to the body 2 in the radial direction of the heat medium chamber 5. The through hole 16 may be formed by the through hole 16. The through hole is formed in the middle of the heat medium chamber 5 such that the first heat exchange chamber 3 and the first heat gathering chamber 6 communicate with each other as shown in FIGS. 6 to 7. The large diameter through-pipe (17) of about 10 to 12 times the diameter of the pipe (15) is configured to penetrate up and down to supply a heat source to the first heat collecting chamber (6).

And the second heat source supply means 13 is formed so as to communicate with the second heat exchange chamber (4) several communication ports 18 provided at the edge of the second heat gathering chamber (8) as shown in FIGS. On the second heat exchange chamber 4, one side of the heat source stay induction plate (4a) is opened up and down to keep the heat source continuously can be configured to improve the heat transfer efficiency, if necessary in Figure 6 or As shown in FIG. 7, the large-diameter communication port 19 communicating with the second heat gathering chamber 8 and the second heat exchange chamber 4 is configured to communicate with each other, and the large-diameter communication hole 19 is formed in the year 14. The opening 19a is formed so that the lower side of the opposite side is opened so that only the waste gas is discharged to the flue 14 after the heat source is sufficiently heated while remaining in the second heat exchange chamber 4.

In the drawings, reference numeral 20 denotes a safety valve mounting portion, 21 a pressure gauge mounting portion, 23 a viewing window, and 24 shows a burner installation hole in which the burner 11 is installed.

The present invention constituted as described above is a vortex by directly spraying the flame on the heat transfer pipe 10 of the first heat exchange chamber 3 from the burner 11 mounted on the burner installation hole 24 formed at one side of the main body 2. And dissipate heat by the vortex of the flame, eliminating the defects of the boiler (1) to prolong its life, and also by minimizing the size of the boiler (1) by reducing the volume of the boiler (1), To provide convenience in use and construction to be described in more detail below.

First, the circulation process of the heat source, when the flame is injected from the burner 11 to the first heat exchange chamber 3 below the main body 2, the flame is vortexed by the heat transfer pipe 10 installed in the heat medium chamber (5). 3, 5, and 7 are distributed and distributed evenly in the first heat exchange chamber 3 to generate a heat source, and through the first heat source supply means 12, the first heat gathering chamber 6 After the heat source is collected, the heat source is collected into the second heat collecting chamber 8 which is communicated by the first heat collecting chamber 6 and the heat exchange pipe 9, and then through the second heat source supply means 13, Only the waste gas remaining after being supplied to the second heat exchange chamber 4 and finally being transferred is discharged to the outside through the flue 14.

In addition to the circulation process of the heat medium to the circulation process of the heat source, the flame is injected from the burner 11 during the operation of the boiler 1 to the first heat exchange chamber (3) at the same time through the heat medium supply pipe (5a) heat medium chamber ( 5) As the heat medium is supplied into the heat medium, the heat medium rises through the heat transfer heat pipe 10, and the heat source passes through the first heat gathering chamber 6 through the first heat source supply means 12 in the first heat exchange chamber 3. The heat is heated by the heat source in the heat exchange pipe (9) inside the heat medium in the first heat exchange chamber (3) in the first heat exchange chamber (3) while rising in the heat exchange pipe (9), and the flame is injected from the burner (11) outside And it is heated by the heat source, wherein the heat medium chamber 5 is heated by the heat source through the heat source and the first heat source supply means 12 of the upper and lower first heat exchange chamber 3 and the first heat collecting chamber (6). Will be.

Secondly, in the second heat exchange chamber 4, the heat medium is also heated to the inside and the outside of the double bar. As a result, the heat medium rising through the heat transfer heat pipe 10 is continuously heated by the heat source in the heat exchange pipe 9 inside. Heated, the heat source collected in the second heat collection chamber (8) through the heat exchange pipe (9) descends to the second heat exchange chamber (4) through the second heat source supply means (13) and heat transfer pipe (10) from the outside ) To warm the heating medium.

In addition, when the heat medium is supplied to the third heat exchange chamber 7 through the heat transfer heat pipe 10, the heat deformation of the second heat exchange chamber 8 installed in the third heat exchange chamber 7 is heated. It is discharged through the outlet (7a) in the form (in the case of using the water as a heat medium is made of steam or hot water), it does not have a separate combustion chamber as in the conventional boiler (1) of the boiler (1) While reducing the total volume and heating the heat medium through the first, second, third heat exchange chamber (7) to increase the heat transfer area, the thermal efficiency is significantly increased, the flame of the burner 11 heat transfer pipe (10) It is possible to maximize the life of the boiler (1) by dissolving the heat loss of the pipe due to the heat condensation phenomenon as opposed to the conventional boiler (1) by direct spraying to the uniform distribution of heat throughout.

In addition, the first heat source supply means 12 forms a variety of heat medium chamber (5), several through pipes (15), several through holes (16) by the fastener (16a), large diameter through-pipes 17, etc. It is to be made, but it is only to cook and select a configuration that can obtain the optimal thermal efficiency, the second heat source supply means 13 is formed on the edge of the second heat collection chamber (8) as shown in the configuration description An opening 19a is formed at the lower portion of the communication port 18 formed in communication with the two heat exchange chambers 4 and the heat source stay guide plate 4a formed in the second heat exchange chamber 4 or on the lower side opposite to the flue 14. What is necessary is just to select and comprise the structure comprised by the large diameter communication hole 19 which has the 1st heat source supply means 12, The said heat source residence guide plate 4a is a plate which divides the 2nd heat exchange chamber 4 up and down by one side. (The part far from the year 14) is opened up and down and supplied from the second heat gathering chamber 8 If you would be so original can stay longer to heat by staying induction plate (4a).

As described in detail above, the flame vortex boiler 1 provided in the present invention has a heat source of flames of the burner 11, the heat medium chamber 5 and the heat transfer pipe 10 in the first heat exchange chamber 3. It is configured to warm, the heat transfer pipe (9) in which the heat source is moved inside the heat transfer heat pipe (10) and the outside, the first and second heat exchange chamber (4) is configured to surround, respectively, the third heat exchange chamber (7) In the), the heat medium is heated by the second heat gathering chamber 8 installed therein, which maximizes the heat transfer area of the heat medium and eliminates the separate combustion chamber to increase the heat transfer effect while miniaturizing the boiler 1. By greatly injecting the flame of the burner 11 directly into the heat transfer pipe 10 to form a vortex, it is possible to maximize the high thermal efficiency and even life of the boiler 1 due to the uniform heat dissipation throughout the boiler 1. The flag The effect that it is intended for.

Claims (6)

In constructing a boiler (1) used for various industrial sites or home use; The first heat exchange chamber 3 formed in the lower part and the 2nd heat exchange chamber 4 formed in the upper part by the diaphragm 2a which partitioned the inside of the main body 2 which comprises the boiler 1 up and down, A third heat exchange chamber 7 integrally formed with an outlet 7a on the main body 2; A heat medium chamber 5 in which the heat medium supply pipe 5a penetrated outside the main body 2 is communicated with the inside of the first heat exchange chamber 3; A first hot air chamber 6 partitioned at a lower portion by the heat medium chamber 5, A second heat exchange chamber 8 installed inside the third heat exchange chamber 7 so as to communicate with the first heat exchange chamber 6 by several heat exchange pipes 9; A heat transfer pipe 10 comprising several heat exchange pipes 9 and a plurality of heat transfer chambers 5 and a third heat exchange chamber 7 in a double tube form, each of which is surrounded by an outer side; A burner 11 installed at one side of the first heat exchange chamber 3 so that a flame is directly sprayed onto the several heat transfer pipes 10 installed in the heat medium chamber 5; A first heat source supply means 12 configured to penetrate the heat medium chamber 5 up and down to supply the heat source generated by the flame sprayed into the first heat exchange chamber 3 to the first heat collecting chamber 6; Second heat source supply means (13) provided for supplying a heat source of the second heat gathering chamber (8) to the second heat exchange chamber (4); A flame vortex boiler, characterized in that it comprises a flue (14) in communication with the exhaust gas to one side of the second heat exchange chamber (4). The method of claim 1; The first heat source supply means (12) is a flame vortex boiler, characterized in that composed of several through pipes (15) penetrating up and down the edge of the heat medium chamber (5). The method of claim 1; The first heat source supply means (12) is formed of a plurality of fasteners for forming the outer diameter of the heat medium chamber (5) at regular intervals from the inner diameter of the body (2), and fixed to the body (2) radially of the heat medium chamber (5). A flame vortex boiler, characterized in that the through-hole 16 is formed by (16a). The method of claim 1; The first heat source supply means 12 is a flame vortex boiler, characterized in that configured to pass through the large diameter through-pipe (17) in the middle of the heat medium chamber (5). The method of claim 1; The second heat source supply means 13 has several communication ports 18 formed to communicate with the second heat exchange chamber 4 at the edge of the second heat gathering chamber 8; A flame vortex boiler, characterized in that the one side formed on the second heat exchange chamber (4) comprises a heat source residence guide plate (4a) open up and down. The method of claim 1; The second heat source supply means 13 has an opening 19a formed at the lower side opposite to the flue 14, and a cod having the second heat gathering chamber 8 and the second heat exchange chamber 4 in communication with each other. Flame vortex boiler, characterized in that it comprises a light passage (19).

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