KR20000013896U - Heat sink fins for auxiliary heat exchanger in condensation gas boiler - Google Patents

Abstract

The present invention prevents the heating tube from being corroded by the condensate of the exhaust gas by installing a fence around the guide hole into which the electrode is inserted, thereby preventing the heating tube from being corroded. It is about.

In the present invention, a pair of left and right heating tubes 38 and a piping hole 34 are formed, while the upper and lower directions are formed in multiple stages, and the tube fence 34a is formed on the circumferential surface of the hole 34. And a heat dissipation fin 30 in which a welding hole inserting guide hole 36 is formed in the fence panel 32, which is the upper portion of the tube fence 34a, on one side of the combustion chamber 21 having the main heat exchanger 22. In the condensation gas boiler installed in the heat exchanger (23), the guide hole fence (36a) is formed on the upper and left and right sides of the guide hole (36) to have the same height and the same direction as the tube fence (34a). In this way, it is possible to prevent condensate generated from the exhaust gas from flowing into the heating tube at the source, thereby preventing corrosion of the heating tube, while increasing the heat transfer area by the guide hole fence to improve thermal efficiency. There is also an effect.

Description

Heat sink fins for auxiliary heat exchanger in condensation gas boiler

The present invention relates to a heat radiation fin for an auxiliary heat exchanger of a condensation gas boiler, and in particular, by installing a fence around a guide hole into which a welding rod is inserted to block an interface with the heating tube, the heating tube is corroded by the condensate of the exhaust gas. It relates to a heat dissipation fin for an auxiliary heat exchanger of a condensation gas boiler so as to prevent it.

In general, when the gas boiler drives the air supply fan 11 in the main body 10 as shown in FIG. 1, gas is injected into the burner 13 through the gas valve 12, and the spark plug of the ignition trans 14 By the ignition of the burner 13, the heat to be burned is absorbed while passing through the heat exchanger 15, the exhaust gas is discharged to the atmosphere through a communication with the exhaust port (10a), the air required for combustion is in communication with the It flows in through the air supply port 10b.

In addition, the heating water is supplied to each room by the circulation pump 16, and the circulation path is the heat exchanger 15, the expansion tank 17, the circulation pump 16, the heating water main pipe, the distributor, the heating branch pipe, the distributor. , Circulating to the heating return pipe, the heat exchanger 15, the direct water supplied through the water supply pipe receives heat from the heating water supplied from the hot water heat exchanger 18 is supplied through the hot water pipe. Reference numeral 15a denotes a heat dissipation fin 15a for absorbing combustion heat and transferring heat to the heating tube of the heat exchanger 15 through which the fluid flows.

2 shows a condensation gas boiler, which includes an exhaust hood 24 having an auxiliary heat exchanger 23 on one side of the combustion chamber 21 in the main body 20, and an exhaust pipe 26 side by side. Is installed on the other hand, the heating water recovered from the heating pipe is heated by exhaust gas of high heat before flowing into the main heat exchanger 22, thereby maximizing thermal efficiency. In the accompanying drawings, reference numeral 21a denotes an exhaust passage, 22a denotes a heat dissipation fin, 25 denotes an under cover of the exhaust hood 24, and 27 denotes a burner.

In the conventional heat dissipation fin 30 used in the auxiliary heat exchanger 23 of the condensation gas boiler as described above, as shown in FIG. The tube fence 34a is formed concentrically on the circumferential surface thereof, and the side fence 32a is formed at left and right ends thereof, and a plurality of guide fences 32b are formed in the up and down directions of the hole 34. A guide hole 36 for welding is formed on the tube fence 34a.

However, when the heat dissipation fin 30 is installed in the heating tube 38 as shown in FIG. 3B, the heating tube 38 is exposed through the guide hole 36, thereby exhausting the exhaust gas from the top to the bottom of the heat dissipation fin 30. Condensate contained in the water flows into the guide hole 36, which causes a problem that the heating tube 38 is corroded and oxidized.

The present invention is to solve the above problems, the purpose is to install a fence around the guide hole in which the electrode is inserted to block the interface with the heating tube, preventing the heating tube from being corroded by the condensate of the exhaust gas It is to provide a heat sink fin for the auxiliary heat exchanger of the condensation gas boiler to enable.

In order to achieve the above object, the present invention provides a pair of left and right heating tube piping holes, and is formed in multiple stages in the up and down directions, and a tube fence is formed on the circumferential surface of the hole. In a condensing gas boiler in which a heat dissipation fin having a guide hole for inserting a welding rod is formed in a fence panel, the upper part of which is installed in an auxiliary heat exchanger on one side of a combustion chamber having a main heat exchanger, the same height as the tube fence on the upper and left and right sides of the guide hole. To provide a heat sink fin for the auxiliary heat exchanger of the condensation gas boiler by forming a guide hole fence having the same direction while having a.

1 is a schematic view showing the internal structure of a typical gas boiler,

2 is a schematic configuration diagram of a general condensation gas boiler,

Figure 3a is a side view of a heat sink fin for a conventional auxiliary heat exchanger,

Figure 3b is a partial cross-sectional view of a state in which the conventional heat radiation fins installed in the heating tube,

Figure 4a is a side view of the heat sink fin for the auxiliary heat exchanger according to the present invention,

Figure 4b is a perspective view of the main part of the heat dissipation fin according to the present invention,

5 is a partial cross-sectional view of a state in which the heat radiation fin according to the present invention installed in the heating tube,

6 is a side view of a heat dissipation fin of another embodiment according to the present invention.

* Explanation of symbols on the main parts of the drawings *

10,20 ... body 15 ... heat exchanger

22 ... main heat exchanger 23 ... auxiliary heat exchanger

34,300 ... heatsink fins 32 ... fence panels

32a ... side fence 32b ... guide fence

34 ... hole 34a ... tube fence

36 ... guide hole 36a ... guide hole fence

38 ... heating tube

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

4A and 6 illustrate heat dissipation fins for an auxiliary heat exchanger of the condensation gas boiler according to the present invention, and the heat dissipation fins 300 for the auxiliary heat exchanger of the condensation gas boiler have a narrow width with respect to the height of the fence panel 32. A pair of left and right heating tube piping holes 34 are formed at the same time, and the side fences 32a are formed in multiple stages in the up and down directions and bent at right angles to the left and right ends. A plurality of guide fences 32b are formed below the 34.

The guide fences 32b are provided in pairs in the lower portion of the hole 34, and are formed spaced apart from each other, and are formed in an arc shape having the same center as the hole 34, and have a circumference of the hole 34. The tube fence 34a in which the hole 34 is perpendicular to the surface is formed while forming the same center, and the guide hole fence 36a is integrally formed in the guide hole 36 formed in the upper portion of the tube fence 34a. Is formed.

Side fence 32a, guide fence 32b, tube fence 34a, and guide hole fence 36a formed on the fence panel 32 are formed at the same height while forming the same direction as shown in FIG. 4B.

The present invention, which is configured as shown in FIG. 5, when the heat dissipation fin 300 is assembled to the heating tube 38 as shown in FIG. 5, the heating tube 38 is covered by the guide hole fence 36a so that the condensate flows into the heating tube 38. On the other hand, the heat transfer area is increased by the guide hole fence 36a, thereby preventing corrosion of the heating tube 38 and improving thermal efficiency.

According to the present invention as described above, by forming the guide hole fence integrally on the circumferential surface of the guide hole for inserting the welding rod to be assembled to the heating tube, it is possible to prevent the condensate generated from the exhaust gas flowing into the heating tube at the source. The effect is to prevent corrosion of the heating tube.

In addition, the heat transfer area is increased by the guide hole fence, thereby improving the thermal efficiency.

Claims (1)

A pair of left and right heating tube 38 piping holes 34 are formed, while multi-stages are formed in the up and down directions, and a tube fence 34a is formed on the circumferential surface of the hole 34. Auxiliary heat exchanger 23 on one side of the combustion chamber 21 having the main heat exchanger 22 having a heat dissipation fin 30 in which a guide hole 36 for inserting a rod is formed in the fence panel 32 that is the upper portion of the tube fence 34a. In the condensation gas boiler installed in Heat dissipation fin for the auxiliary heat exchanger of the condensation gas boiler by forming a guide hole fence (36a) having the same height as the tube fence (34a) in the upper and left and right sides of the guide hole (36) to achieve the same direction.