KR200257440Y1 - Low vision internal surveillance tube consisting of block lens and camera block - Google Patents

Abstract

The present invention is used in a furnace monitoring system that can be used as a criterion for judgment in dealing with the furnace situation or controlling the temperature by observing the inside of the furnace at high temperature during operation of the furnace. Regarding the vision tube, the conventional lens tube is expensive, bulky, complex installation, and should be installed by a professional, it is difficult to repair in case of failure, there is a disadvantage that a high repair cost occurs.

In order to compensate for the above drawbacks, the present invention is easy to install, and the lens and camera are blocked for easy repair, and the purpose is to develop a vision tube using a built-in small camera and block lenses to reduce the repair cost. have.

Description

Vision tube for internal surveillance consisting of a block lens and a camera block

The present invention is used in the furnace monitoring system to observe the inside of the furnace at any time during the operation of the furnace so that it can be used as a standard for judgment in responding to the situation of the furnace quickly or controlling the temperature. It is about a lens and a camera.

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, gas furnaces used to dissolve glass, cement furnaces, ceramics furnaces, and kilns.

One of the common demands of the operator in these various 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 unless a special failure occurs. Therefore, the inside of the furnace should be monitored from time to time to check the situation inside 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 can be opened and closed to open 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, a separate face with infrared glass is attached to protect eyesight and block strong visible light. A screen must be used.

However, since this method has a hole 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.

As another embodiment of the prior art, a lens tube is inserted into an inside of a furnace, and a method of observing an image inside a furnace by photographing an image of an inside of a furnace transmitted through a lens and transmitting the image to a monitor. There is this.

The method arranges the lenses 2 in a line in the existing lens tube 8 as shown in FIG. 1, connects the camera protection housing 4 to the rear of the lens tube 8, and the general camera 5 inside the housing. Install it.

This is installed on the rail for the cylinder as shown in FIG. 3, the cylinder and the housing pedestal 9 are fixed, and the compressed air supply valve 20 at the rear end of the cylinder and the housing pedestal 9 is supplied to move the housing pedestal 9 to move the lens tube 8. ) To the inside of the furnace to shoot / monitor the inside of the furnace, and to check the compressed air to the compressed air supply valve 20 at the front end of the cylinder during an inspection or when an emergency occurs, such as in the case of power failure or interruption of compressed air. The lens tube 8 is extracted from the inside to protect the lens tube 8 from the high temperature inside the furnace.

The image inside the furnace, which has passed through the image entrance hole 10 inserted into the furnace by the above method, passes through the lens 2 arranged in a line inside the lens tube 8. It is transmitted to the sensor 3 to be formed and displayed on the monitoring room monitor 100 via the ELECTRIC CONTROL BOX 30 to enable internal monitoring of the furnace.

At this time, since the inside of the furnace is in a high temperature state, the camera protection housing 4 and the lens tube 8, 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 4, a separate structural device is required to fix it, and in case of damage to the lens part, Since the entire lens tube 8 needs to be replaced, it causes a lot of maintenance cost and cost.

The present invention encloses the furnace in monitoring the inside of the furnace to compensate for the above-mentioned disadvantages when using the lens tube, the camera, and the camera protection housing for photographing the inside of the furnace. At the same time, it is easy to install at low cost, it is easy to repair due to the blocking of the lens, and the structure is simple by using the small camera 16, and it is possible to monitor the wider range inside the furnace in high quality. The purpose is to develop a vision tube 12 for internal monitoring.

In order to achieve the above object, instead of using the existing lens tube 8 and the camera protection housing 4, the present invention designs the lens in units of blocks as shown in FIG. It relates to a vision tube 12 embedded in the end to enable monitoring of the furnace internal image.

At this time, in order to protect the vision tube 12 inserted into the furnace from the high temperature, compressed air is supplied from the control box, which is supplied through the image entrance hole 10 in front of the front end lens block 11 of the vision tube through a predetermined passage. Sprayed.

1 is a cross-sectional view of a lens tube and a camera protection housing in which lenses are arranged in a line according to an embodiment of the related art.

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

3 is a cross-sectional view of a vision tube manufactured by using a block-type lens and a small camera mounted therein according to the present invention.

Figure 4 is an embodiment of the use of the present invention equipped with an automatic extraction device for monitoring the inside of the furnace as an embodiment of the present invention

<Explanation of symbols for main parts of drawing>

1: Objective lens 2: Lens 3: Image sensor

4: camera protection housing 5: camera 6: inner tube

7 appearance 8 lens tube 9 housing support

DESCRIPTION OF SYMBOLS 10 Image entrance hole 11 Tip lens block 12 Vision tube

13: relay lens block 14: projection 15: FOCUS adjustment spring

16: compact camera 17: FOCUS control handle

18: FOCUS adjusting bolt 19: I / O connector 20: Compressed air supply valve

21: CONTROL BOX 22: Compressed Air Supply Pipe

30: ELECTRIC CONTROLLER 31: AIR CONTROLLER 100: MONITOR

Hereinafter, with reference to the accompanying drawings will be described a vision tube for monitoring inside the furnace by the present invention.

FIG. 4 is an embodiment of the present invention, in which an automatic extraction apparatus is installed for monitoring the inside of a furnace. In order to monitor the inside of a furnace, a hole having a predetermined size is first formed in the furnace wall. Compressed air is formed and the vision tube 12 is coupled to the carriage plate and the rail connected to the fixing bracket 23 as shown in FIG. 4 and supplied with the wall sleeve 24 and the flange 25 of the vision tube 12. In order not to come out, the electric locking device 22 installed on the installed frame and the latch provided on the vision tube fixing bracket side 23 are engaged to insert the vision tube 12 into the furnace.

In the vision tube 12 inserted into the furnace, as shown in FIG. 3, the image inside the furnace that enters through the image entrance hole 10 formed at the foremost edge of the vision tube 16 is the front lens. Through the block 11, the imaging lens block 12, and the relay lens block 13, an image attenuation is formed on the image sensor of the small camera 16 mounted through the optical attenuation filter and mounted inside the vision tube.

At this time, the projection 14 is formed on each lens block so that the lens block is always positioned at the center of the vision tube. If the lens tube is damaged, the entire lens tube can be replaced to compensate for the cost and long term disadvantage.

In addition, the FOCUS adjustment spring (15) is placed at the front end of the small camera (16), and the FOCUS adjustment bolt (18) is turned by turning the FOCUS adjustment handle (17) using the FOCUS adjustment handle (17) and the FOCUS adjustment bolt (18). Fine-adjust the small camera 16 by reciprocating the left and right, and when the image is not clear due to the initial setting of the vision tube or the internal and external shocks, the image can be adjusted, and the FOCUS adjustment spring ( Due to the elasticity of 15), when the impact is applied, the shock can be alleviated to prevent damage to the lens.

As shown in FIG. 3, the cable connected to the control box at the last input / output connector 19 of the vision tube supplies power to the small camera 16 mounted inside the vision tube, and the inside of the furnace exits through the output terminal of the camera. The video of the camera is transmitted to the control box 21 to enable playback on the monitor.

In addition, the present invention uses compressed air to cool the vision tube inserted into the furnace from high temperatures.

At this time, the compressed air for protecting the vision tube is supplied in the field is sent to the CONTROL BOX (21), purged through the filter in the CONTROL BOX (21) to remove impurities and supplied at a constant pressure using a pressure switch.

The compressed air is connected to the compressed air supply valve 20 connected to the rear end of the vision tube 12 through the compressed air supply pipe 22, and as shown in FIG. 3, the block-type lens and the small camera 16. It passes between the inner tube 6 for protecting the inner tube 6 and the outer tube 7 made of a special material to protect the inner tube 6 from the outside temperature. Sprayed through.

In addition, the compressed air is supplied to the compressed air supply valve 20 of the wall sleeve installed on the wall of the furnace and passes through the space between the vision tube 12 and the furnace hole to pass through the vision tube 12. I) It is sprayed inside.

The vision tube 12 inserted into the furnace in the same manner as described above uses an exterior 7 made of a material that can withstand a high temperature, and is high between the inner tube 6 and the exterior 7 in the vision tube. Compressed air, which is supplied by passing compressed air at a pressure, is injected through the image inlet hole 10 at the foremost end of the vision tube 12, and compressed air is passed between the outside of the vision tube 12 and the wall sleeve. Due to the cooling effect from the injection into the furnace, it can withstand high temperatures.

In the above-described method, a system for monitoring the inside of a furnace by inserting a vision tube 12, which is composed of a block-type lens and a small camera 16, into the furnace is provided with a conventional lens tube 8 and a housing for protecting the camera. Instead of using (4), a small camera (16) is built-in, and it is easy to install by using the vision tube (12), which is designed for easy assembly and disassembly by designing the lens in units of blocks. Easy-to-use, small and low-cost camera-integrated vision tubes monitor more of the interior of the furnace. 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. It is a useful design.

Claims (1)

In a furnace monitoring system that monitors the inside of a furnace at a high temperature where a worker is difficult to approach through a hole in a furnace wall, Block lens is inserted into the furnace to observe the inside of the furnace, and the front end lens and each lens are arranged inside to form a group of lenses to monitor the situation inside the furnace. Inner tube equipped with a small camera for capturing the image inside the furnace transmitted through the combination of and each block lens group, and special heat resistant and corrosion resistant to protect the inner tube from the outside temperature and the surrounding environment. Compression air supplied from CONRTOL BOX passes between the inner tube made from the material and the outside is sprayed to the front part to produce the cooling effect and spring is installed at the front end of the micro camera to adjust the FOCUS. Vision tube characterized in that FOCUS control is possible.