KR200364770Y1 - Heat sensing bar of gas boiler - Google Patents

Abstract

The present invention relates to a heat sensing rod for a gas boiler, the insulating portion 21 is installed in parallel to the side of the burner body 10 in which a plurality of salt holes (10a) are formed, and extends from the insulating portion 21 to the salt holes In the heat detection rod for a gas boiler composed of a detection unit 22 for detecting a flame generated by the detection unit 22 is a flame detection unit 22a (22b) bent in close contact with the flame hole (10a) of the burner body A plurality of first and second detectors 22a formed at a position spaced apart from each other, extending from the insulation portion 21 to be bent closely to the salt hole formed at the upper end of the burner body 10, and the first detector The second sensing part 22b is formed to extend from 22a and bends closely with the salt hole formed at the lower end of the burner body 10 so that the ignition state may be maintained even if the flame is not uniformly generated in the plurality of salt holes formed in the burner. Detectable gas ignition It is possible to reduce the detection error of as much as possible to detect the accurate ignition of gas, even if one of the soot or bending occurs, even if the gas does not detect the ignition of the gas, the remaining detection unit detects Since the operation can be performed, there is an effect of exhibiting improved performance even when using a heat sensing rod for a long time.

Description

Heat sensing bar of gas boiler

The present invention relates to a heat detection rod for a gas boiler, and more particularly to a heat detection rod for a gas boiler to reduce the detection error and extend the life by forming a plurality of flame detection unit for detecting a flame generated from the flame hole of the burner. .

1 is a cross-sectional view showing the configuration of a general down-combustion gas boiler, in which a main heat exchanger (2) is provided inside the boiler casing (1), and a burner (3) is installed above the main heat exchanger (2). The upper part of the burner 3 is provided with a blower and a blower 4 so that the combustion gas generated by the burner 3 is moved downwards in the main heat exchanger 2 and then the blower and the blower 4. By moving upward again by the heat exchanger with the water passing through the hot water coil (not shown) wound on the main heat exchanger (2) is configured to be discharged to the outside of the boiler casing (1).

As described above, the burner generating the combustion gas is conventionally shown in FIG. 2, on one side of the burner body 10 in which the plurality of salt holes 10a are formed, an ignition rod 11 for igniting the mixed gas ejected through the salt holes. ) And a heat sensing rod 12 for judging whether the gas is ignited or not.

The heat sensing rod 12 is a flame (flame) generated through the flame hole (10a) of the burner body 10 and the heat sensing rod 12 forms a closed circuit to ignite the gas by the flow of the salt current flowing through the closed circuit It will be judged. Therefore, the heat sensing rod of the burner according to the prior art has an end portion of the sensing portion 12b extending from the insulation portion 12a of the heat sensing rod 12 so as to detect a flame generated in the flame hole 10a of the burner. It is formed to be inclined downward to the side and is installed adjacent to the main body 10 of the burner.

However, as the heat sensing rod of the burner according to the prior art increases the amount of use of the burner, a material such as soot, which impedes the flow of electric current, is coated on the surface of the sensing portion 12b of the heat sensing rod, thereby preventing the flow of salt current, thereby preventing the heat sensing rod. Since the heat sensing rod is exposed to the flame generated from the burner for a long time, the thickness of the heat sensing rod becomes thin and the sensing portion of the heat sensing rod is damaged or the deformation of the gas is generated. There is a problem that does not accurately detect whether or not.

In addition, it is difficult to accurately detect whether the gas is ignited by one sensing unit because a uniform flame is not generated in every flame hole formed in the burner body according to the site conditions or the pressure of the gas in which the gas boiler is conventionally installed. there is a problem.

The object of the present invention devised in view of the above problems is to increase the number of gas detection to prevent deformation due to breakage and bending of the heat sensing rod to improve the durability to extend the life of the gas boiler to provide a heat detection rod .

Another object of the present invention is to provide a heat sensing rod for a gas boiler to reduce the detection error by accurately detecting whether the gas is ignited by increasing the number of gas detection and detecting flame occurrence at a plurality of positions.

1 is a cross-sectional view of a general downward combustion gas boiler.

2 is a side view of a heat sensing rod for a gas boiler according to the prior art.

Figure 3 is a side view of one embodiment of a heat sensing rod for a gas boiler according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10; Burner body 10a; Flame

20; Thermal sensing rod 21; Insulation

22; Sensing unit 22a; First detector

22b; Second detector

The present invention for achieving the object as described above is composed of an insulating portion installed in parallel to the side of the burner body formed with a plurality of salt holes, and a sensing unit extending from the insulating portion for detecting the flame generated in the salt holes In the heat detection rod for the gas boiler, the sensing unit is configured to sense a ignition of the gas generated in the salt holes at different positions by forming a plurality of flame detection parts bent in close contact with the flame hole of the burner body spaced apart from each other It is done.

The sensing unit extends from the insulator and is formed to be bent closely to the salt holes formed at the upper end of the burner body, and the first sensing unit extends from the first sensing unit to be bent closely to the salt holes formed at the bottom of the burner body. It is preferable to include a formed second sensing unit.

Hereinafter, preferred embodiments of the present invention as described above will be described in more detail based on the accompanying drawings.

As shown in FIG. 3, the embodiment of the present invention is formed in parallel with the burner body 10 in which a plurality of salt holes 10a are formed, and a heat sensing rod 20 is installed. The heat sensing rod 20 has an insulation portion 21 formed in parallel with the burner body 10, and the sensing portion 22 is formed to extend from an end portion of the insulation portion 21.

The detection unit 22 of the heat detection rod is formed with a flame detection unit bent adjacent to the burner body 10, the flame detection unit is a first detection unit 22a bent to the burner body 10 side, and the first detection The second sensor part 22b extends in the direction in which the part 22a is bent apart from the burner main body 10 and then bent toward the burner main body 10.

The first sensing unit 22a is positioned at the upper end position where the flame hole of the burner starts to form, and the second sensing unit 22b is preferably positioned at the lower end position where the salt hole formed in the burner ends. The second sensing unit may be located at the lower end, or the second sensing unit may be located at the upper end, and the second sensing unit may be positioned at the middle. This may be in accordance with the intention of the present invention for detecting the flame generated from the flame holes formed in the burner body 10 at various positions.

In addition, the distance between the burner main body 10 and the burner main body 10 is about 4 mm, and the distance between the burner main body 10 and the burner main body 10 is 6 mm. Adjusting the separation distance between the flame detection unit (22a) (22b) and the burner body 10 can also be set in accordance with the intention of the present invention.

In the drawing, reference numeral 11 denotes an ignition rod.

As described above, a plurality of flame detection units 22a and 22b which are formed to be bent adjacent to the burner main body 10 in the sensing unit 22 are formed to improve the accuracy of detecting whether the gas is ignited. In the embodiment of the present invention, the flame detection unit is to be formed in two places, one each in the upper and lower sides.

The operation of detecting whether the gas is ignited by the heat sensing rod for the gas boiler according to the present invention configured as described above will be described.

When the burner is operated by the driving of the gas boiler, the mixed gas ejected through the plurality of salt holes 10a formed in the burner body 10 is ignited by the ignition rod 11 to generate a flame through the salt holes 10a.

This flame is a flame and a closed circuit is formed by the first sensing unit 22a and the second sensing unit 22b in the sensing unit 22 of the heat sensing rod 20 installed adjacent to the burner main body 10 so that the salt current As it flows, it detects the ignition of the gas.

At this time, even if the flame is generated slightly in the salt hole adjacent to the first detector 22a, the flame is detected by the second detector 22b, so that the burner can detect whether the gas is normally ignited. On the contrary, even if the flame is not generated quickly in the salt hole adjacent to the second detector 22b, the flame is detected by the first detector 22a to detect the ignition state of the gas.

In addition, even if the flame is not detected because the soot is generated on the surface of either the first sensing unit 22a or the second sensing unit 22b during the use of the burner for a long period of time, the flame is detected by the other sensing unit. Can be detected.

Although the embodiment of the present invention has been described as a combustion gas boiler as an embodiment, the present invention is not limited thereto, and is applicable to the gas boiler in general, and may be modified within the scope of the technical idea described in the utility model registration claims of the present invention. And it will be obvious that variations are possible.

As described above, the heat detection rod for the gas boiler according to the present invention can detect the ignition state even if the flame is not generated uniformly in a plurality of flame holes formed in the burner, so that the detection error of gas ignition can be reduced to the maximum. There is an effect that can detect whether or not.

In addition, since a plurality of sensing rods are formed, even if one sensing unit does not detect the ignition of gas due to sooting or bending deformation, the remaining sensing unit can perform the sensing operation. The performance of detecting whether the gas is ignited has an effect of remarkably improved in comparison with the prior art.

Claims (2)

Insulation part 21 installed in parallel to the side of the burner body 10 in which a plurality of flame holes 10a are formed, and a detector 22 extending from the insulation part 21 to detect a flame generated from the salt holes. In the heat detection rod for a gas boiler composed of, The sensing unit 22 forms a plurality of flame detection units 22a and 22b which are formed to be bent closely with the flame holes 10a of the burner body at positions spaced apart from each other to ignite the gas generated in the salt holes at different positions. Heat sensing rod for the gas boiler, characterized in that configured to sense. The method of claim 1, The flame detection unit extends from the insulation unit 21 and is formed to be bent in close contact with the salt hole formed at the upper end of the burner body 10, and extends from the first detection unit 22a. The heat sensing rod for the gas boiler, characterized in that it comprises a second sensing portion (22b) bent closely to the salt hole formed in the bottom of the burner body (10).