KR930002643Y1 - Heater - Google Patents

Abstract

No content.

Description

Heater with heat exchanger inside

1 is a cross-sectional view schematically showing an embodiment of the heater according to the present invention installed inside the heat exchanger.

2 is a cross-sectional view schematically showing a state in which the damper is laid down in the heater shown in FIG.

3 is a sectional view schematically showing a conventional heater having a heat exchanger installed therein.

* Explanation of symbols for main parts of the drawings

1: radiator body 2: port

3,20: lower combustion cylinder 4,21: intermediate combustion cylinder

5,22: upper combustion cylinder 8,25: cylinder

15, 35: heat exchanger 17, 30, 52: exhaust port

18,40 Damper 23: Longitudinal combustion cylinder

24: transverse combustion cylinder 26: bottom plate

27: exhaust plate 28: side plate

29: exhaust top plate 36: first flow passage

43: control panel 50: communication

53: lid 54: second flow passage

The present invention relates to a heater provided with a heat exchanger therein, and more particularly to a heater provided with a heat exchanger to enable the conversion of the heat exchange amount in the heater and the exhaust direction of the exhaust gas.

Recently, a heater provided with a heat exchanger therein is known as a heater using combustion of oil or gas. Such a heat exchanger is connected with a fluid circulation circuit which serves to return a heated fluid such as hot water or the like to the heat exchanger after being fed back to the heat exchanger.

In such a conventional heater, as shown in FIG. 3, the inside of the heater main body 1 is provided with the port 2 which accommodates oil in the lower part. Above the port 2, a lower combustion cylinder 3, an intermediate combustion cylinder 4 formed of a transparent body such as glass, and an upper combustion cylinder 5 are placed in this order. The upper combustion cylinder 5 has a cylinder portion 8 placed on the upper end of the intermediate combustion cylinder 4. The upper end of the cylinder part 8 is provided with the exhaust underplate 9 which extends outwardly of this cylinder part. At the edge around the exhaust lower plate 9 is provided a side plate 10 extending upwards. The open upper part of the side plate 10 is covered by the exhaust top plate 11.

In such a conventional heater, the heat exchanger 15 is provided on the upper surface of the exhaust lower plate 9 in the vicinity of the side plate 10 inside the upper combustion cylinder 5. An exhaust port 17 is formed in the exhaust top plate 11 above the heat exchanger 15. The heat exchanger 15 is provided with a damper 18 attached to it so that it can rotate freely. The damper 18 serves to open and close the exhaust passage formed between the heat exchanger 15 and the exhaust top plate 11. That is, the damper 15 serves to open and close the passage of the exhaust gas passing through the heat exchanger 15.

In such a conventional heater, when the oil contained in the port 2 is ignited and burned, the exhaust gas rises in the direction of the arrow shown in FIG. That is, the exhaust gas rises toward the upper combustion cylinder 5 and is guided between the exhaust top plate 11 and the exhaust bottom plate 9. As a result, the exhaust gas is discharged to the outside through the exhaust port 17 after passing through the heat exchanger 15. The heat exchanger 15 receives the heat of the exhaust gas and heats the fluid therein, and then sends the heated fluid to an ondol heating mechanism (not shown) or the like. Ondol heating can be obtained by repeating the circulation in such a manner that the heated fluid discharges heat from the ondol heating mechanism and then returns to the heat exchanger 15 again.

However, in the conventional heater provided with the heat exchanger in this way, since the heat exchanger 15 is located under the exhaust port 17, the flow path until exhaust gas reaches the heat exchanger 15 will become long. For this reason, the exhaust gas is supplied to the heat exchanger 15 in a state where the temperature is lowered, and thus there is a problem that sufficient heat exchange cannot be achieved. In particular, when the combustion amount is small, there is a problem that the heat exchange amount is insufficient.

Moreover, in such a conventional heater, since the exhaust port 17 is provided in the vicinity of the heat exchanger 15, a problem arises also in the installation place of a heat exchanger since the position of the communication which attaches to the exhaust_gas | emission 17 is also limited. .

Accordingly, an object of the present invention is to increase the heat exchange amount of a heat exchanger that absorbs heat from exhaust gas, and to freely select the position where the exhaust port is installed within the heater without limiting it to any one point. It is to provide a heater provided with a heat exchanger.

According to the present invention, a heater including a longitudinal combustion cylinder extending in a longitudinal direction and a transverse combustion cylinder connected to an upper end of the longitudinal combustion cylinder and positioned transversely to guide exhaust gas discharged from the longitudinal combustion cylinder toward the exhaust port. A heater comprising: a damper provided between a first flow passage and a second flow passage formed at a connection portion between a longitudinal combustion cylinder and a lateral combustion cylinder to open and close them, and a heat exchanger provided in the first flow passage. Is provided.

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

1 shows an embodiment of a heater in which a heat exchanger is installed in accordance with the present invention. The heater includes a lower combustion cylinder 20 which is a part that provides combustion of fuel such as oil or gas, an intermediate combustion cylinder 21 formed of a transparent body such as glass on the upper portion of the lower combustion cylinder, and an upper combustion cylinder 22. ) Are placed one after the other. The upper combustion cylinder 22 includes the cylinder part 25 provided concentrically in the upper end part of the intermediate combustion cylinder 21. Thus, the lower combustion cylinder 20, the intermediate combustion cylinder 21, and the cylinder part 25 comprise the longitudinal combustion cylinder 23 extended longitudinally as a whole. At the lower end of the cylinder part 25, the bottom plate 26 formed in ring shape toward the inside from this cylinder part 25 is provided. The bottom plate 26 is placed directly on the upper end of the intermediate combustion cylinder 21. At the upper end of the cylinder portion 25, an exhaust lower plate 27 extending outwardly from the cylinder portion 25 is provided. At the circumferential edge of the exhaust lower plate 27 is provided a side plate 28 extending upward. The upper space portion of the side plate 28 is closed by the exhaust top plate 29. Thus, the horizontal combustion cylinder 24 extended in the horizontal direction by the exhaust lower plate 27, the side plate 28, and the exhaust upper plate 29 is comprised. An exhaust port 30 is formed in a part of the exhaust top plate 29.

The heat exchanger 35 is provided inside the cylinder part 25 of the upper combustion cylinder 22 comprised as mentioned above. The heat exchanger 35 is provided in a cylindrical shape along the inner wall surface of the cylinder portion 25 of the upper combustion cylinder 22. Inside the heat exchanger 35, a damper 40 for converting the path of the exhaust gas is provided. As shown in FIG. 2, the damper 40 can be moved downwardly with the lower end of the cylindrical vertical portion 41 close to the bottom plate 26 of the barrel 25. When moved in this way, the lower end of the damper 40 is placed on the tip of the portion bent slightly upward from the inside of the bottom tube 26. The damper 40 is provided with a flat plate portion 42 extending in a flange shape outward from the upper end of the vertical portion 41. The flat plate portion 42 is provided with an operation portion 43 that penetrates the exhaust top plate 29 and extends upward. This operation part 43 is used to raise or lower the damper 40. FIG. In the state where the damper 40 is raised as shown in FIG. 1, after the high temperature exhaust gas passes through the first flow passage 36 in which the heat exchanger 35 is disposed, it rises along the cylinder portion 25, It is discharged from the exhaust port 30 through the lateral combustion cylinder 24.

The exhaust port 30 is provided with the communication 50, so that the exhaust gas is discharged out of the heater through the communication 50. For example, when the communication 50 is to be installed at another position, another exhaust port 52 may be provided at any place on the exhaust top plate 29. When this exhaust port 52 is not used, the exhaust port 52 may be closed by covering the lid 53 there.

On the other hand, when heat dissipation of the ondol heating mechanism (not shown) is not required, the damper 40 may be lowered by simply pushing down the operation portion 43. As described above, when the damper 40 is lowered to the vicinity of the bottom plate 26, the exhaust gas enters the damper 24 as shown by the arrow of FIG. Then, the exhaust gas is discharged from the exhaust port 30 toward the communication 50. In this case, the fluid inside the heat exchanger 35 has a lower heat exchange amount compared with the case where the exhaust gas rises along the outside of the damper 40 through the first flow passage 36. . Therefore, the amount of heat dissipation of the ondol heating mechanism can be increased or decreased by raising or lowering the damper 40.

As described above, in the heater according to the present invention, since the heat exchanger is provided at the portion where the temperature of the combustion gas is the highest, the heat exchange amount can be increased as compared with the conventional heater.

Further, according to the present invention, since the heat exchanger is installed at the connection portion between the longitudinal combustion cylinder and the lateral combustion cylinder, the position of the exhaust port of the lateral combustion cylinder can be freely selected, and the difference in the communication connected with the exhaust port is not restricted. The installation place of a heater can also be selected effectively.

Claims (1)

A longitudinal combustion cylinder 23 extending in the longitudinal direction and a transverse combustion cylinder connected to an upper end of the longitudinal combustion cylinder and extending laterally to guide exhaust gas discharged from the longitudinal combustion cylinder toward the exhaust port 30; In the heater including the 24, provided between the first flow passage 36 and the second flow passage 54 of the exhaust gas formed in the connecting portion of the longitudinal combustion cylinder 23 and the lateral combustion cylinder 24. And a damper (40) for opening and closing the first and second flow passages (36 and 54), and a heat exchanger (35) disposed in the first flow passage (36).