KR20010000526U - Down stream type gas boiller - Google Patents

Abstract

The present invention relates to a top-down gas boiler, a heat exchanger (40) formed through a combustion passage through which a flame flow generated in the burner (30) is primarily moved and heat exchange is made through the center, and the combustion flow passage (41). Collecting unit 60 for moving to the pipe 42 after the combustion gas heat exchange is collected while moving to, and the combustion gas heat exchanged in the pipe 42 to the outside of the boiler body (10) Composed of an exhaust hood 50 to be discharged, the flame generated in the burner 30 is moved downward through the combustion flow path 41 formed in the center of the heat exchanger 40, the heat exchange with the water chamber is primarily made Combustion gas, which is primarily heat exchanged in the combustion flow passage 41, is first collected in the collecting unit 60 and then moved upward through the pipe 42 formed in the heat exchanger 40. Heat exchange The combustion gas moving to the upper side by exchanging heat with the water chamber through the tube 42 has a small volume of the exhaust hood 50 far from the fan 20 side, and the fan 20 Since the volume of the exhaust hood installed on the c) side is large, the exhaust pressure is maintained uniformly, so that the exhaust pressure of the combustion gas of the heat exchanger 40 is stably formed so that the combustion efficiency is increased.

Description

DOWN STREAM TYPE GAS BOILLER}

The present invention relates to a top-down gas boiler, and more particularly, the flame generated from the burner is moved to the bottom of the heat exchanger and then moved back to the top of the heat exchanger, thereby improving the combustion efficiency and improving the combustion efficiency. The combustion gas heat-exchanged in the air is to be discharged to the outside of the boiler while maintaining a uniform discharge pressure, and relates to a top-down gas boiler to prevent the internal temperature of the boiler is increased by the waste heat of high heat.

As shown in FIG. 1, a conventional top-down gas boiler is provided with a heat exchanger 40 through which water is circulated inside the boiler body 10, and a burner 30 is installed above the heat exchanger 40. The exhaust hood 50 is installed at the lower portion of the heat exchanger 40 to collect combustion gas, and one side of the exhaust hood 50 is configured to supply combustion gas to the outside of the boiler body 10 by a fan 20. One end of the exhaust flue 70 discharged to the furnace is connected.

In the conventional top-down gas boiler, when the boiler is operated, the flame generated from the burner 30 is moved through the tube 42 formed in the heat exchanger 40, and heat exchange is performed, and the heat exchange is performed through the tube 42. This combustion gas is collected in the exhaust hood 50, the combustion gas collected in the exhaust hood 50 to the outside of the boiler body 10 through the exhaust flue 70 by the operation of the fan 20. Emissions are taking place.

However, in the conventional top-down gas boiler, since the heat generated only by the flame generated in the burner 30 is moved downward through the inlet 42 of the heat exchanger 40, the combustion efficiency is lowered, and the heat exchanger ( Since the combustion gas heat-exchanged at 40) is collected in the exhaust hood 50, a separate exhaust flue 70 for discharging to the outside of the boiler body 10 should be installed to be connected to the exhaust hood 50, so that the boiler In addition, the size of the main body 10 is unnecessarily large, as well as the life of each component installed in the boiler main body 10 is shortened by the heat of the combustion gas discharged to the exhaust flue 70. .

The present invention is a heat exchanger formed by passing a combustion flow passage through which a flame generated in a burner is primarily moved to heat exchange while solving the same problem as in the prior art, and a combustion gas that is heat exchanged while moving to the combustion flow passage. Is composed of a collecting part for moving the tube after the gas is collected and an exhaust hood for discharging the combustion gas heat-exchanged in the tube to be discharged to the outside of the boiler body, so that the flame generated in the burner is located at the center of the heat exchanger. The heat exchange with the chamber is primarily performed while moving downwardly through the formed combustion flow path, and the combustion gas primarily heat exchanged in the combustion flow passage is first collected in the collecting part and then moved upward through the association formed in the heat exchanger. While secondary heat exchange is made, and heat exchange with the chamber through the association In the combustion gas moving upward, the volume of the exhaust hood is far from the fan side, and the volume of the exhaust hood formed on the fan side is large, so that the exhaust pressure is maintained uniformly, thereby burning the heat exchanger. It is to provide a top-down gas boiler that the discharge pressure of the gas is formed to be stable to increase the combustion efficiency.

1 is a cross-sectional view showing a conventional top-down boiler structure.

2 is a cross-sectional view showing a top-down boiler structure of the present invention

3 is a cross-sectional view showing the main portion of the present invention.

Explanation of symbols on the main parts of the drawings

10: boiler body 20: fan

30 burner 40 heat exchanger

41: combustion passage 42: association

50: exhaust hood 51: inclined surface

60: collecting part

Hereinafter, the technical configuration of the present invention by the accompanying drawings in detail.

As shown in FIG. 2, the top-down gas boiler according to the present invention has a heat exchanger 40 formed by passing a combustion passage 41 through the center thereof so that the heat generated by the flame generated by the burner 30 is primarily moved. ), The collecting unit 60 to be moved to the combustion passage 41 and the heat exchanged combustion gas is collected and then moved to the association 42, and the combustion gas heat exchanged in the association 42 is collected. After the boiler body 10 is characterized in that it is composed of an exhaust hood 50 to be discharged to the outside.

On the other hand, the exhaust hood 50, as shown in Figure 3, the volume of one side and the other side is formed with an upper surface having an inclined surface 51, the one side where the volume of one side and the other side is different from the inclined surface The fan 20 for forcibly discharging the combustion gas trapped in the exhaust hood 50 to the outside of the boiler body 10 is installed.

In addition, the fan 20 is found to be installed on one side of the exhaust hood 50 having a large internal volume.

The present invention configured as described above, when the boiler is operated, the flame generated from the burner 30 is moved to the lower part of the heat exchanger 40 through the combustion flow passage 41 formed in the heat exchanger 40, and primarily heat exchanges with the water chamber. Combustion gas is primarily collected in the collecting unit 60 while the combustion gas primarily collected in the collecting unit 60 is secondly connected to the upper portion of the heat exchanger 40 through the association 42. As it moves, secondary heat exchange occurs with the chamber.

The combustion gas which has undergone secondary heat exchange in the assortment 42 is introduced into the exhaust hood 50 secondarily.

At this time, the combustion gas flowing into the exhaust hood 50 is moved through the tube 42 while maintaining the suction pressure uniformly by the inclined surface 51 formed so that the volume inside the exhaust hood 50 changes, and heat exchange is made. Combustion gas heat exchanged while moving through the pipe 42 is collected in the exhaust hood 50, and the combustion gas collected in the exhaust hood 50 is exhaust flue 70 by operating the fan 20. Through) is discharged to the outside of the boiler body (10).

Therefore, the present invention, the flame generated in the burner 30 is moved downward through the combustion flow path 41 formed in the center of the heat exchanger 40 is primarily made of heat exchange with the water chamber, the combustion flow path 41 The combustion gas that is primarily heat-exchanged at) is first collected in the collecting unit 60 and then moved upwardly through the associated pipe 42 formed in the heat exchanger 40 so that the heat exchange is secondarily performed. The thermal efficiency of the is improved.

In addition, the combustion gas which is heat-exchanging with the water chamber through the tube 42 and moves upward is formed with a smaller volume of the exhaust hood 50 away from the fan 20 side, and the fan 20 side. Since the volume of the formed exhaust hood 50 is largely maintained, the exhaust pressure is maintained uniformly, so that the discharge pressure of the combustion gas of the heat exchanger 40 is stably formed, thereby increasing the combustion efficiency.

As described above, in the present invention, a combustion passage 41 is formed at the center of the heat exchanger 40 so that the heat generated by the flame generated by the burner 30 is primarily moved, and the combustion passage 41 is formed. After the heat exchanged through the combustion gas is collected in the collecting unit 60 and moved to the associated 42, the exhaust gas 50 to be discharged to the outside of the boiler body 10 after the heat-exchanged combustion gas is collected. The volume is composed of a volume corresponding to the wind pressure of the heat exchanger to maintain a uniform discharge pressure, it is a very useful design to improve the combustion efficiency.

Claims (3)

The heat exchanger 40 formed through the center of the combustion flow path through which the heat generated by the flame generated by the burner 30 is primarily moved, and the combustion gas heat-exchanged while moving to the combustion flow passage 41 are collected. And a collecting unit 60 for moving to the associated pipe 42 and an exhaust hood 50 for discharging the combustion gas heat-exchanged in the associated pipe 42 to be discharged to the outside of the boiler body 10. Top down gas boiler characterized in that. According to claim 1, wherein the exhaust hood 50 is formed with an inclined surface 51 in the upper portion is different from the volume of one side and the other side, the exhaust hood on one side where the volume of one side and the other side is different from the inclined surface 51 Top-down gas boiler characterized in that the fan 20 for forcibly discharging the combustion gas collected in the 50 to the outside of the boiler body (10). The gas boiler of claim 2, wherein the fan (20) is installed at one side of the exhaust hood (50) having a large internal volume.