KR200196318Y1 - Initial ignition device of annealing furnace - Google Patents

Abstract

The present invention improves the internal ignition function during the initial ignition in the combustion control process of the annealing furnace, prevents the deterioration due to the deformation of the conductors installed in the ignition device, and makes it possible to supply the combustion gas efficiently. For the initial ignition of the Annealing Furnace,

By installing a tubular insulating material on the outside of the conductor to prevent bias due to thermal deformation and to maintain a constant gap forming sparks, and to form a protective tube between the outer circumferential surface of the insulating tube and the housing body. It prevents deformation of the tip and improves the ignition operation rate by maintaining the uniform temperature distribution in the furnace by preventing the combustion gas mixed with the feed and passing through the nozzle after turning in the housing. .

Description

Initial ignition of annealing furnace

The present invention improves the internal ignition function for the initial ignition of the initial ignition device of the annealing furnace, more specifically, the combustion control process of the annealing furnace, and prevents the function deterioration due to the deformation of the conductor installed in the ignition device. Of course, the present invention relates to an initial ignition apparatus for an annealing furnace that enables efficient supply of combustion gas.

In general, the ignition process of the annealing furnace can be classified into various types according to the ignition method and the control aspect, but the air sucked by the air is introduced into the heat exchanger through the air damper by the pressure of the suction fan and the combustion gas is sucked. By preheating before and after about 400 ° C., a pull type that is supplied to a combustion device, that is, a burner and combusted through a contact tube, which is a preheating air moving tube, is mainly used in an annealing process.

The conventional annealing furnace combustion initial ignition device is installed in close contact with the main burner 10 as shown in FIG. 1 (a), and the initial ignition device is shown in FIG. 1 (b).

That is, a spark is formed at the end of the conductor 4 by the high-voltage power supply (about 7,000 V) supplied to the plug 1, and the conductor 4 is divided into three portions of the initial burner and the insulating material 2a. And a combustion tube 6 provided at the rear end of the nozzle 5 using the combustion gas supplied from the igniter main body through the part 3 installed with the one side insulating material 2a. Combustion will take place within

At this time, the nozzle 5 serves to constantly pass the combustion mixture gas.

However, as each insulating material 2a, 2b, 2c, which supports the conductor 4 installed therein during the ignition process, and prevents the discharge of the current dissipated to the outside of the combustion tube 6, is divided into three divided methods In the long-term use, the conductor 4 in the form of wires is biased to one side due to deterioration due to high temperature and thermal expansion.

The bias phenomenon of the conductor 4 is out of the range (2-3 mm) in which the gap is formed during the initial ignition, which hinders the occurrence of sparks and causes the ignition failure of combustion, while the main burner 10 which is the main heat supply source of the annealing furnace. This resulted in a fatal result, and further adversely affected the delay of the initial warming operation of the furnace and the resulting increase in productivity.

At this time, FIG. 2 shows a bias due to thermal deformation of the conductor 4 due to poor insulation of each insulating material 2a, 2b, and 2c which divides and supports the conductor 4, and thus the gap between the conductors 4. It can be seen that the deviation (1.3mm, 1.8mm, 1.2mm) much more than this reference range (2 ~ 3mm), the problem has been described above.

The present invention has been made in view of the above problems of the conventional initial ignition device, the object is to provide an initial ignition device of the annealing furnace that can prevent deformation of the conductor causing the spark by the ignition.

Another object of the present invention is to provide an initial ignition apparatus of the annealing furnace that can shorten the initial ignition time by the change of the structure of the nozzle.

The present invention for achieving this purpose is to prevent the bias due to thermal deformation by installing a tubular cutting pipe on the outside of the conductor and to maintain a constant gap to form a spark, and the outer peripheral surface and A protective tube is formed on the housing body to prevent deformation of the end of the conductor, and the combustion gas mixed with the feed gas is rotated in the housing and then passed through the nozzle, thereby improving the ignition operation rate, thereby providing a uniform temperature in the furnace. Maintain distribution and prevent delay of imagination.

1 (a) is a schematic diagram showing an initial ignition device installed in a conventional main burner.

Figure 1 (b) is an excerpt of the initial ignition device.

2 is a configuration diagram illustrating a modified state of the initial ignition device;

3 is a block diagram showing an initial ignition device of an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

10: main burner 20: housing body

21 connector 22 inlet

30: plug 31: conductor

32: insulated tube 33: blender

40: protective tube 50: injection nozzle

Hereinafter, an initial ignition device of the annealing furnace of the present invention will be described with reference to the accompanying drawings.

3 is a cross-sectional configuration diagram of an initial ignition device according to an embodiment of the present invention, in which a plug 30 for supplying power to one end of the housing body 20 to induce sparks is mounted through a connector 21 and the plug ( 30 is connected to the conductor 31 is installed in the hollow portion of the housing body 20.

The outer circumferential surface of the conductor 31 is coupled to the heat insulation tube 32 made of a tubular body to maintain an appropriate gap, and the mixer side 33 is supplied to the end side of the insulated tube by rotating the mixed gas to supply the optimum mixing ratio. ) Is installed.

Between the outer circumferential surface of the insulator tube 32 into which the conductor 31 is inserted and the inner circumferential surface of the housing main body 20, a protective plate 40 for maintaining a gap between the ends of the conductor 31 is coupled, and the connector 21 Inlet 22 is formed on the outer circumferential surface of the housing main body 20 of the portion where the coupling is connected, and the injection nozzle 50 is installed on the other side of the housing main body 20 corresponding to the plug 30. It is.

Therefore, the present invention as described above, the high-voltage voltage is induced in the conductor 31 through the plug 30 to form a spark at the front end portion of the combustion gas introduced through the inlet 22 of the housing body 20. Combustion occurs at the end of the main nozzle 50 by using.

At this time, since the outer circumferential surface of the conductor 31 installed on the hollow pipe passage of the housing body 20 is supported by the insulated pipe 32 having a tubular shape, deflection and bias due to thermal deformation applied to the conductor 31 are prevented. The tip of the conductor 31, which prevents and forms a spark, is always kept at an optimum gap (3 mm).

On the other hand, the material of the conductor 31 is preferably formed of Inconel 600 resistant to oxidation corrosion.

A mixer 33 for blowing wind toward the injection nozzle 50 is installed at the tip end side of the conductor 31 so as to mix the mixed gas introduced into the housing main body 20 through the inlet 22 in an optimal state to achieve a combustion rate. Will be improved.

The present invention prevents bias due to thermal deformation of a conductor forming a spark, thereby preventing loss of current and thermal lag due to discharge, and stably supplying mixed gas by the action of a mixer to improve combustion function.

In addition, the entire outer circumferential surface of the conductor is wrapped by the insulated tube to extend the service life and increase the initial ignition function to shorten the initial temperature raising operation as well as to improve the efficiency.

Claims (1)

A plug 30 for supplying power to one end of the housing main body 20 to induce sparks is mounted through the connector 21, and the plug 30 is installed in the hollow portion of the housing main body 20. 31) is connected to form a spark, the outer circumferential surface of the conductor 31 is coupled to the insulating tube 32 made of tubular body to maintain a proper gap, and the mixed gas is rotated to the end side of the insulating tube and mixed A mixer 33 is provided to supply the optimum ratio, and a gap between the outer peripheral surface of the insulator tube 32 into which the conductor 31 is inserted and the inner peripheral surface of the housing body 20 is always provided. The protection tube 40 is coupled to maintain the, and the other side of the housing body 20 corresponding to the plug 30, the initial ignition device of the annealing furnace, characterized in that the injection nozzle 50 is installed.