KR200275568Y1 - Non-powered automatic extraction device for furnace internal monitoring - Google Patents

Abstract

The present invention monitors the inside of the furnace at any time during the operation of the furnace to monitor the inside of the furnace at any time and to provide a standard for judgment in controlling temperature. This invention relates to a non-powered automatic extraction device that can insert a vision tube into a furnace and extract power without force. The conventional extraction system is expensive, bulky, complicated to install, and should be installed by a professional. It was difficult to repair and had a high repair cost.

In order to make up for the above disadvantages, the present invention is easy to install through small size and light weight, and it is easy to repair, and to develop an automatic extraction apparatus that can insert a vision tube by using a spring and extract the power to reduce the repair cost. The purpose is.

Description

Powerless automatic extraction device for internal furnace monitoring

The present invention observes the inside of the furnace at any time during the operation of the furnace to monitor the inside of the furnace at any time and to monitor the inside of the furnace so that it can be a standard of judgment in controlling the temperature. It relates to a camera system.

In general, the type of industrial furnace (furnace) is divided into several types depending on the product produced.

For example, there are industrial incinerators for incineration of wastes, steel mill furnaces used to dissolve metals, gases used to dissolve glass, cement furnaces, ceramics furnaces, and fired furnaces.

One of the common demands of operators in these different types of furnaces is whether the inside of the furnace can be observed from time to time with clean images during the operation of the furnace.

Once the furnace starts to operate, it is operated continuously for a certain period of time unless a special failure occurs, so the inside of the furnace should be monitored from time to time to check the conditions in the furnace.

In the conventional method of observing the inside of an industrial furnace, a hole having a certain size is formed in the furnace wall, and the entrance of the hole is opened and opened to open and close the door where the operator is closed as necessary. It is common practice to visually check the inside of the furnace through the following holes.

This method accounts for more than 70% of the furnace currently in operation. When looking inside the furnace in the same way as above, infrared glass is attached to protect eyesight and block strong visible light. A separate face mask must be used.

However, since this method has a hole formed in the furnace wall, the thermal efficiency decreases and external air flows in, resulting in fluctuations in the combustion mixing ratio, and the hole wall size is small and the furnace wall is thick. The viewing angle that can be viewed with the naked eye is limited to only a few parts, and the operator may be burned.

Another embodiment of the prior art for improving the above problems is to form a window in the furnace glass wall and quartz glass or heat-resistant glass that can withstand high temperature and to install the camera and the camera protection housing on the outside There is a method of monitoring the image inside the furnace by capturing the image formed in the window using a camera and a lens.

However, the above method also has a limitation in monitoring the situation inside the furnace because only a very limited image can be seen through the hole drilled in the wall of the furnace.

In addition, the glass itself is resistant to heat, but it is weak to impact and weak to abrasion and corrosion, and as a result, fly ashes, such as dust burned in the furnace, adhere to the inner surface of the window, resulting in a lack of transparency. Since there is no maintenance, it must be maintained.

Such a method has advantages over the previous embodiment but is inadequate for large furnaces or furnaces that require precise control of temperature.

Another example of the related art is a method of inserting an imaging device called a lens tube into a furnace and observing the inside of the furnace through a monitor.

The method arranges the lenses in the lens tube 1 in a row, connects the camera protection housing 3 to the rear of the lens tube, and mounts a general camera inside the housing.

It is installed on the rail (7) for the cylinder as shown in Figure 1, the cylinder (8) and the housing pedestal (6) is fixed and the compressed air supply valve 25 at the rear end of the compressed air supply valve 25 in the cylinder (8) 6) Move and insert the lens tube 1 into the furnace to shoot / monitor the inside of the furnace, and pressurized air supply valve at the front end of the cylinder during inspection or when an emergency occurs such as in case of power failure or interruption of compressed air. Compressed air is supplied to (25) to extract the lens tube (1) from the inside to protect the lens tube (1) from the high temperature inside the furnace.

The image inside the furnace taken by the above method passes through the lenses arranged in a line inside the lens tube 1 and is transferred to the image sensor of the camera installed in the camera protection housing 3 to form an ELECTRIC CONTROL BOX (30). The inside of the furnace can be monitored by displaying it on the monitoring room monitor 100 via the < RTI ID = 0.0 >

At this time, since the inside of the furnace is in a high temperature state, the camera protection housing 3 and the lens tube 1, which are specially manufactured for the protection of the camera, are cooled by receiving high-pressure compressed air from the AIR CONRTOL BOX 31. It is injected to the outside via a certain path.

However, since the internal monitoring system according to the method described above uses a cylinder type extraction device and a camera protection housing 3, a separate structural device is required to fix it, so that the device is equipped with large-scale equipment and power. It can be a cause of breakdown, and the cost of maintenance and equipment becomes expensive.

The present invention is to develop a non-powered automatic extraction device that can insert and extract the vision tube 12 for monitoring the inside of the furnace, small and light weight developed to compensate for the above disadvantages. There is a purpose.

In order to achieve the above object, the present invention uses a lightweight vision tube 12 with a small camera instead of using the existing lens tube 1 and the camera protection housing 3.

As shown in FIG. 3, a signal generated from the CONTROL BOX 14 is transmitted to the electric locking device 15 using the solenoid at the time of maintenance by using the spring 13, in case of power failure, or in an emergency in which compressed air is blocked. By automatically extracting (12) with no power, the vision tube (12) is protected from the high temperature inside the furnace.

At this time, in order to protect the vision tube 12 entering the furnace from the high temperature, as shown in FIG. 5, compressed air is supplied from the control box 14, which is injected through the front part of the vision tube through a predetermined passage.

It is to provide a non-powered automatic extraction apparatus of the vision tube for monitoring inside the furnace, characterized in that the operator to observe / monitor the image inside the furnace through the monitor 100 by the above method.

1 is a schematic diagram of a furnace monitoring system using a retractor using a cylinder and a housing for protecting a camera as another embodiment of the existing technology.

2 is a system configuration diagram of another embodiment of the existing technology

3 is a schematic view of a non-powered automatic extraction device and vision tube using a spring spring when the vision tube is inserted into the furnace as an embodiment of the present invention

4 is a schematic view of a non-powered automatic extraction device and vision tube using a spring spring when the vision tube is extracted in the furnace as an embodiment of the present invention

5 is a configuration diagram of an internal monitoring system according to an embodiment of the present invention

Figure 6 is a cross-sectional view of the furnace internal monitoring system as an embodiment of the present invention from the back

<Explanation of symbols for main parts of drawing>

1: lens tube 3: camera protection housing

6 housing support 7 cylinder rail 8 cylinder

12: Vision tube 13: Spring 14: CONTROL BOX

15: electric locking device 17: vision tube fixing bracket

18: carriage plate 19: rail 20: wall sleeve

21: flange 22: frame 23: latch

25: compressed air supply valve 28: shock absorber

29: protective cap 30: ELECTRIC CONTROL BOX

31: AIR CONTROL BOX 100: monitor

Hereinafter, an internal furnace monitoring system according to the present invention will be described with reference to the accompanying drawings.

First, in order to monitor the inside of the furnace, the carriage plate 18 connected to the vision tube fixing bracket 17 is coupled with the rail 19 as shown in FIG. 6, and the flange 21 of the wall sleeve 20 and the vision tube 12 is removed. The compressed air to be supplied is closely contacted with each other, and the locking device 23 attached to the electric locking device 15 installed on the installed frame 22 and the vision tube fixing bracket 17 are coupled.

As shown in FIG. 3, one end of the spring 13 is fixed to the vision tube fixing bracket 17 and the other is fixed to the frame 22, and then the vision tube 12 is pushed toward the inlet of the furnace. In the present invention, the lens tube is not extracted from the inside of the furnace by a power such as a conventional cylinder or a motor, but is automatically extracted by the elastic force of the spring 13 without a force.

At this time, the electric lock 15 prevents the vision tube 12 from being randomly extracted by the elasticity of the spring 13 fixed to the frame 22, and the operator switches the switch from the control box 14 for automatic extraction in case of emergency. It automatically detects in case of an emergency such as operation or power failure or abnormal supply of compressed air, and releases the fasteners 23 installed on the electric locking device 15 and the vision tube fixing bracket 17 to enable automatic extraction. Function.

The image inside the furnace to be monitored for the first time passes through the objective lens 16 through a small hole in the front end of the vision tube 12 and is made of a block-type lens 10 so that the removable lens and the relay can be detached. After passing to the lens, it passes through the light attenuation filter and is sent to the CONTROL BOX 14 through a small camera located at the rear of the vision tube, and this image is transmitted to the monitor 100 of the central surveillance room for monitoring. .

In addition, the present invention is cooled by using compressed air to protect the vision tube 12 to be inserted into the furnace from the high temperature.

At this time, the compressed air for protecting the vision tube 12 is supplied in the field, sent to the control box (14), purged through the filter in the control box (14) to remove impurities and supplied at a constant pressure using a pressure switch Done.

The compressed air is connected to the compressed air supply valve 25 connected to the rear end of the vision tube through a pipe, and the wall sleeve 20 installed on the vision tube and the furnace wall to protect the vision tube 12. The compressed air is supplied to the compressed air supply valve 25 so that the high temperature is caused by the cooling effect generated by passing through the space between the vision tube 12 and the furnace hole and injecting into the furnace through the vision tube 12. Will be able to withstand

5 is a schematic view of a non-powered automatic extraction device and vision tube using a spring spring when the vision tube 12 is extracted in the furnace as an embodiment of the present invention

In order to maintain the vision tube supplying the inside of the furnace, the operator may manually extract it by operating the switch attached to the CONTROL BOX (14), or compressed air may not be supplied to the vision tube, or it may be below a certain supply pressure. When this is detected by the pressure switch built in the CONTROL BOX (14) automatically sends a signal to the electric locking device (15), the locking device is released by the elasticity of the spring automatically loosening the binding.

At this time, in order to protect the vision tube extracted by the elasticity of the spring to install a shock-absorbing shock absorber 28 fixed to the frame 22 in the retracted position of the vision tube fixing bracket 17 to mitigate the impact.

In addition, after the vision tube is extracted, the vision tube is automatically extracted to protect external life from the flame caused by the pressure difference from the inside of the furnace, and passes through the inlet of the wall sleeve 20 and at the same time a protective cap ( 29 automatically blocks the opening of the wall sleeve 20 to block the flame.

The non-powered automatic extraction device for inserting or extracting the vision tube 12, which is composed of a block-type lens and a small camera, by the above-described method into the furnace, instead of using an existing bulky and difficult installation device, Simple, lightweight and easy to install by the general public, and the signal generated from the CONTROL BOX (14) in the case of maintenance / inspection and power failure or the compressed air is blocked by using the spring (13) electric lock device using the solenoid ( 15) the vision tube (12) is automatically extracted without power to remove the failure factors generated during the extraction by the power.

In addition, by providing high-performance products at low cost, it is possible to monitor the inside of furnaces such as steel mills, cement plants, incinerators, power plants, etc. and improve the reliability and merchandise of the products. It is a useful design.

Claims (4)

In the furnace monitoring system for monitoring the inside of the furnace by inserting the vision tube 12 into the hole formed in the furnace wall, The vision tube fixing bracket 17 and the carriage plate 16 are configured by binding the rail 19 fixed to the frame as shown in FIG. One side of the spring is fixed to the rear end of the vision tube fixing bracket 17, and the other side is configured to be fixed to the rear end of the frame 22, When the vision tube 12 is inserted into the furnace, the electric locking device 15 fixed to the frame and the vision tube fixing bracket 17 are configured to be coupled as shown in FIG. Non-powered automatic extraction device, characterized in that consisting of a shock absorber 28 fixed to the frame 22 in the retracted position of the vision tube fixing bracket 17 The method according to claim 1, Non-powered automatic extraction device, characterized in that the spring used for automatic extraction is composed of a spring. The method according to claim 1, A non-powered automatic extraction device, characterized in that the spring used for automatic extraction is composed of a coil spring. delete