KR100504385B1 - Monitor Camera With Air Curtain For Use with Furnace - Google Patents

Abstract

The present invention relates to a monitoring camera in a boiler provided with an air curtain, and more particularly, to an air curtain provided in the front of the monitoring camera to prevent dust from adhering to the monitoring window of the camera. It is about a surveillance camera.

To this end, the present invention is a cylindrical camera housing; A surveillance window installed at an end of the housing to secure a field of view of the camera; A sleeve installed in a shape surrounding the housing and having a cooling passage for cooling the camera; An air nozzle installed at the front end of the camera sleeve to inject air supplied through the cooling passage to the front of the monitoring window to form an air curtain; And a computer connected to the camera to output and store the captured image.

As described above, according to the present invention, the camera housing is cooled by the cooling passage of the camera sleeve, and the air is provided at the front of the camera by an air nozzle provided at the end of the sleeve, whereby dust or the like is monitored by the camera. It can prevent it from being attached to the window.

Description

Monitor Camera With Air Curtain For Use with Furnace

The present invention relates to a surveillance camera in a boiler equipped with an air curtain, and more particularly, dust is attached to the surveillance window of the camera by forming an air curtain in front of the surveillance camera installed to observe the combustion state inside the industrial furnace. It relates to an in-house surveillance camera provided with an air curtain that can be prevented.

Industrial furnaces include chemical reactors, boilers for thermal power plants, and steelmaking furnaces, but the following description will be given by taking boilers of thermal power plants as examples.

In general, thermal power plants are equipped with a surveillance camera inside the boiler to observe the combustion process in detail when burning fuel such as crude oil, heavy oil, and coal in the boiler. By observing the combustion process in detail, it is possible to easily grasp the chemical reaction and gas flow phenomenon occurring inside the boiler, and to obtain important information for the operation and design of the boiler.

In addition, the monitoring camera is installed in an industrial furnace in which it is necessary to visually observe the phenomenon inside the reactor in operation, such as a chemical reactor or a gasifier.

However, it is a very difficult technique to observe inside the reactor operated under high temperature and high pressure.

1 is a schematic diagram showing an installation state of a surveillance camera installed in an industrial furnace according to the prior art.

In general, the monitoring device installed in the industrial furnace 100, as shown in Figure 1, through the monitoring hole passing from the outside to the inside to one side of the furnace wall 110 to install the housing 130 and the housing 130 The front end of the monitoring window 160 is formed of a transparent heat-resistant glass of quartz plate material that can withstand the high temperature, high pressure, is closed inside the housing 130 so that the interior of the furnace through the monitoring window 160 can be taken A circuit camera is mounted and a computer 140 capable of outputting and storing images and data in the furnace captured by the closed circuit camera is connected to the camera.

The internal monitoring apparatus of the thermal power plant boiler configured as described above photographs the phenomenon inside the boiler through the monitoring window 160 during operation of the boiler, and the captured image and data are output and stored through the computer 140.

These images and other data obtained by photographing the reaction phenomena inside the thermal power plant boiler are useful data when operating or designing the thermal power plant boiler.

Looking at the structure of the surveillance camera used at high temperature and high pressure in more detail, in order to protect the camera from high heat, the camera is installed in a housing 130 made of heat-resistant alloy, and a separate cooling water supply jacket is installed in the camera body The front end of the camera housing 130 has a monitoring window 160 made of heat-resistant glass. Therefore, when the camera needs to be repaired and regularly cleaned, the surveillance camera mounted inside the housing can be retracted and taken out to be repaired and then remounted.

However, when the surveillance camera having the above-described configuration is used in a boiler of high temperature and high pressure, moisture and dust generated by incomplete combustion inside the boiler are attached to the surveillance window 160 to make it difficult to secure the view of the camera. In order to remove dust attached to the monitoring window 160, the photographing operation must be frequently stopped.

In addition, since the camera housing continuously absorbs radiant heat in the furnace, such heat absorption may cause a failure of the surveillance camera.

In order to solve the above problems, the present invention provides a cooling air through the cooling passage formed in the inner space of the camera sleeve, by installing an air curtain in the front of the camera monitoring window through a nozzle formed at the end of the sleeve, the surveillance camera It is an object of the present invention to provide an in-camera surveillance camera equipped with an air curtain that can protect it from high temperature and prevent dust from being attached to the camera surveillance window due to incomplete combustion.

According to the present invention for achieving the above object, an in-house surveillance camera equipped with an air curtain is a cylindrical housing formed to accommodate the camera therein; A surveillance window installed at an end of the housing to secure a field of view of the camera; A sleeve installed in a shape surrounding the housing and having a cooling passage configured to cool the outer surface of the camera housing; An air nozzle installed at the front end of the camera sleeve to inject air supplied through the cooling passage to the front of the monitoring window to form an air curtain; A pipe connected to the sleeve to supply cooling air; A pressure regulating valve installed in the middle of the pipe to adjust a pressure of cooling air; A pressure pump connected to the pipe to supply cooling air of a predetermined pressure or more; And a computer connected to the camera to output and store the captured image.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

FIG. 2 is a schematic view showing an installation state of a surveillance camera installed in an industrial furnace according to the present invention, and FIG. 3 is a cross-sectional view of the furnace surveillance camera provided with the air curtain of the present invention.

As shown in Figures 2 and 3, the interior monitoring camera equipped with the air curtain of the present invention is a surveillance camera 326, the housing 304 is inserted into the camera 326, the housing 304 ) And a monitoring window 260 installed at the front end of the camera housing 304 to secure the field of view of the camera and to protect the camera lens from high temperature.

In addition, a support arm 270 connecting and fixing the camera 326 to an external support, a cooling air moving pipe 280 for supplying cooling air to the sleeve 306, and a cooling passage of the sleeve 306 The air nozzle 320 formed at the outlet of the 322, and the computer 240 for outputting the image data photographed by the camera 326 further comprises.

The housing 304 in which the camera 326 is accommodated is formed in a cylindrical shape and the front is opened so that the camera 326 can photograph the inside of an industrial furnace, and the rear side is a structure in which a cover 310 is installed through a rubber packing. .

The housing 304 of the above structure is installed through the furnace wall 210 and connected to the external support 220, and is fixed at an angle necessary for photographing.

The camera 326 is mounted inside the housing 304 to prevent damage by high temperature heat and the rear portion of the camera is coupled to the support arm 270 and fixed to the support 220 outside the furnace.

The sleeve 306 has a shape that surrounds the housing 304 from the outside to protect the outer surface of the camera housing 304 from high temperature heat and the cooling air is moved between the housing 304 and the sleeve 306 while the housing is moved. A cooling passage 322 is formed to cool the outer surface of the 304.

In addition, as shown in FIG. 5, according to the second embodiment of the present invention, a spiral protrusion 502 is formed in the cooling passage 322 inside the sleeve 306 to be supplied through the pipe 280. Air is injected through the nozzle while rotating along the spiral groove of the cooling passage 322 to form a spiral air curtain.

The monitoring window 260 is made of transparent high strength heat-resistant glass to protect the camera lens from dust in the furnace, gas of high temperature and high pressure, and to secure the field of view of the camera, and is installed at the front of the housing 304.

The air nozzle 320 is formed by the backflow prevention jaw 324 of the sleeve end having a narrow angle between the end of the sleeve 306 and the end of the housing 304 and the inclined angle. The air nozzle 320 has a narrow cross-sectional area compared to the width of the cooling passage 322 formed inside the sleeve 306. Therefore, since the flow of the cooling air that has moved through the cooling passage 322 of the sleeve 306 is faster, the injection pressure of the air curtain formed through the air nozzle 320 is higher than the gas pressure in the furnace.

The backflow prevention jaw 324 serves as a guide so that the air curtain injected from the air nozzle 320 has a constant angle at the front of the monitoring window 260.

That is, the angle of the backflow prevention jaw 324 is preferably about 50 to 70 degrees from the horizontal, and thus the air curtain formed at a constant angle prevents dust gas inside the furnace from approaching the surface of the monitoring window 260. .

The support arm 270 is a bar shape that is bent at approximately right angles, one side of which is coupled to the rear of the camera 326, and the other side of which is coupled to the support 220 of the outside of the furnace. Therefore, as the support arm 270 is horizontally moved by driving the actuator of the support unit 220, the camera 326 can be moved forward and backward, so that the camera 326 is externally repaired and repaired. In order to take out, the support arm 270 coupled to the rear of the camera 326 may be retracted to allow the camera 326 to be discharged out of the housing 304.

The pipe 280 through which the cooling air moves is connected at one end to the pressure pump 270 and the other end is connected to the rear of the sleeve 306 of the camera to supply cooling air supplied from the pressure pump 270 to the sleeve 306. The cooling air is supplied to the cooling passage 322, and the cooling air passes through the cooling passage 322 of the sleeve 306 and is injected from the air nozzle 320 installed at the front of the sleeve 306 to the front of the monitoring window 260. Form an air curtain on the part.

Here, the cooling air may be used as general air, but when it should not affect the chemical reaction inside the furnace, such as a chemical reactor, nitrogen gas or argon gas, which is an inert gas, may be used.

The pressure control valve 260 is installed in the middle of the cooling air supply pipe 280 to adjust the pressure of the cooling air supplied through the pipe 280 and the cooling passage 322 of the camera sleeve, the pressure control A constant pressure of air is maintained by the valve 260. The pressure control valve 260 may be manually adjusted, but may be connected to the computer 240 to be automatically adjusted according to the environment inside the furnace.

The computer 240 is installed inside the housing 304 and connected to a camera 326 which captures combustion reactions and chemical reactions inside the reactor, and outputs and stores the captured image data. In addition, it may be connected to the control system of the industrial furnace 200 to automatically control the furnace atmosphere in accordance with the analysis of the image data in the furnace.

An operating state of the in-role surveillance camera provided with the air curtain nozzle having the above-described configuration will be described in detail with reference to FIGS. 4 and 5.

4 is a flow chart of the air curtain air flow and backflow air according to the first embodiment of the present invention, Figure 5 is a flow chart of the air curtain air flow and backflow air according to a second embodiment of the present invention.

As shown in FIG. 4, the cooling air supplied from the pressure pump 270 through the pipe 280 passes through the cooling passage 322 formed inside the camera's sleeve 306 and passes through the housing 304 of the camera. Cool.

The camera 326 itself includes a water-cooled cooling jacket, but since radiant heat generated during the combustion process may accumulate on the outer surface of the housing 304 and damage the camera 326, the air curtain may be used as an auxiliary cooling device. Cooling air used for 402 passes through a cooling passage 322 formed inside the sleeve 306 to prevent the outer surface of the housing 304 from overheating.

The cooling air that has passed through the cooling passage 322 of the sleeve 306 passes through the air nozzle 320 formed at the outlet of the cooling passage 322 and changes its moving speed very rapidly. Therefore, even if the pressure pump 270 is not used with a large capacity, the injection pressure of the air forming the air curtain 402 is always higher than the gas pressure in the furnace.

In the case of thermal power plant boilers, relatively large amounts of unburned dust or smoke are generated at the initial stage of ignition, but the amount of unburned dust or smoke is reduced at a high temperature of 1000 ° C or higher. Therefore, since the injection pressure of the air curtain 402 is preferably changed accordingly, by connecting the computer 240 to the pressure control valve 260, the injection pressure of the air curtain 402 can be adjusted according to the temperature inside the furnace. Make sure

Cooling air, which has increased speed while passing through the air nozzle 320, is redirected by the non-return jaw 324 provided at an angle to the end of the sleeve 306 to front the surveillance window 260 to protect the camera lens. Toward the angle of about 50 to 70 degrees. That is, the air curtain 402 formed at an angle of about 50 to 70 degrees from horizontal prevents dust or the like, which is an incomplete combustion product inside the furnace, from being attached to the monitoring window of the camera.

That is, the flow of the backflow air 404 containing a large amount of dust and water generated due to incomplete combustion does not approach the monitoring window 260 of the camera by the air curtain 402 and the backflow prevention jaw 324. Follow the flow of curtain 402 back into the furnace.

In addition, as shown in FIG. 5, when air passes through the cooling passage 322 while the air rotates by the spiral protrusion 502 formed in the cooling passage 322 of the sleeve 306, the cooling of the camera housing 304 is performed. Not only to increase the effect but also to form a spiral air curtain 402 in the process of being injected into the air nozzle 320, the effect of preventing the dust gas inside from approaching the monitoring window 302 of the camera 1st embodiment Even higher.

In this case, it is preferable to smooth the torsion angle of the spiral protrusion 502 formed in the cooling passage 322 so that the flow of air passing through the cooling passage 322 of the sleeve 306 is not inhibited.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

As described above, according to the present invention, the outer surface of the camera housing is prevented from being overheated by the heat of combustion by the cooling air passing through the cooling passage formed inside the camera sleeve, and the air nozzle provided at the end of the sleeve The air blown out by forming an air curtain on the front of the camera at a predetermined angle can prevent dust or the like caused by incomplete combustion from being attached to the monitoring window of the camera.

1 is a schematic diagram showing an installation state of a surveillance camera installed in an industrial furnace according to the prior art;

2 is a schematic view showing an installation state of a surveillance camera installed in an industrial furnace according to the present invention;

Figure 3 is a cross-sectional view of the interior of the surveillance camera equipped with an air curtain of the present invention,

4 is a flow chart of the air curtain air flow and backflow air according to the first embodiment of the present invention;

5 is a flow chart of the air curtain air flow and backflow air according to the second embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100, 200: industrial furnace 110, 210: furnace wall

120, 220: support 130, 230: camera

140, 240: computer 150, 250: support arm

160, 260: monitoring window 270: pressure pump

280: pipe 290: pressure regulating valve

304 housing 306 sleeve

310: housing cover 320: air nozzle

322 cooling path 324 backflow prevention jaw

402: air curtain 404: backflow air

502: spiral projection

Claims (6)

In the internal monitoring device installed in an industrial furnace, Surveillance cameras that can be used at high temperatures; A housing having a cylindrical shape sized to accommodate the surveillance camera therein for protecting the surveillance camera from the high temperature and the high pressure in the furnace, the front end of which is open and the rear part of which is covered by a housing cover; A surveillance window provided at the front end of the housing to secure a view of the surveillance camera and protect the lens of the camera; It is installed in a shape surrounding the housing while maintaining a constant distance from the housing, a cooling air passage for cooling the outer surface of the housing is formed inside, while the air supplied through the cooling air passage rotates the air nozzle A sleeve having a spiral protrusion formed in the cooling air passage to be sprayed through to form a spiral air curtain; An air nozzle installed at the front end of the camera sleeve to form the air curtain at the front of the camera surveillance window by spraying the air supplied through the cooling passage; A pipe having one end connected to the cooling passage of the sleeve and the other end connected to the pressure pump to supply cooling air supplied from the pressure pump to the cooling passage of the sleeve; A pressure pump connected to the pipe to supply cooling air of a predetermined pressure or more; And A computer connected to the surveillance camera for outputting and storing image data captured by the surveillance camera; In-house surveillance camera provided with an air curtain comprising a. The method of claim 1, The air nozzle is provided with an air curtain, characterized in that the air curtain is installed so as to form an angle of 50 to 70 degrees from the horizontal toward the front of the monitoring window. The method of claim 1, And a backflow prevention jaw installed at the front end of the sleeve to prevent dust gas inside the industrial furnace from approaching the monitoring window of the surveillance camera and guide the angle of the air curtain injected through the nozzle. In-house surveillance camera with air curtain. The method of claim 1, And a pressure regulating valve installed in the middle of the pipe to adjust the spray pressure of the air curtain. The method of claim 4, wherein In-house monitoring camera equipped with an air curtain, characterized in that the computer is connected to the pressure control valve and the pressure control valve is controlled by the computer to automatically adjust the injection pressure of the air curtain in accordance with the combustion state in the industrial furnace . delete