KR20010061660A - Camera case with anti-inflow of different thing - Google Patents

Abstract

PURPOSE: A camera case is provided to discharge air reversely flowing into the case, outside, with an impurities inflow prevention device. CONSTITUTION: An impurities inflow prevention device(100) of a camera case consists of a transmitting plate(8) formed in the front side of a camera; a pipe(15) formed in the front side of the transmitting plate while covering the transmitting plate; and air injecting pipes(11,14) injecting air(20) into the rear end of the pipe. Herein, the air flows forward along the pipe after flowing along the face of the transmitting pipe. Reversely flowing air flows to the rear side of the pipe and switches the flowing direction by a slit(55) formed along the inner circumference of the pipe. Further, the impurities inflow prevention device contains an inner pipe having a smaller pipe than the diameter of the pipe and a rounded connecting portion connecting the pipe and the inner pipe.

Description

Camera case with anti-inflow device

The present invention relates to a camera case to prevent foreign matter is attached to the protective glass of the camera located in a harsh environment, so as not to interfere with the imaging, in particular, foreign matter inflow prevention device to prevent the foreign matter adhered to the protective glass by the backflow of the air It relates to a camera case having a.

Steel mills monitor the work process in many places. However, in steel mills, there are many poor working environments in which high temperature and a large amount of dust are generated, and in such places, a worker installs a surveillance camera because it is difficult for an operator to monitor a work process.

However, the surveillance camera installed in such a poor working environment is also attached to the lens by foreign matter, dust, etc. in the lens tangled with moisture, which degrades the function of the surveillance camera.

Therefore, while installing the surveillance camera inside the camera case to prevent the attachment of dust and the like, the cooling water is injected into the case to reduce the heat received by the camera, and the air is injected to block the dust and the like introduced into the case.

1 is a conceptual diagram showing the installation relationship of a general CCD camera, Figure 2 is a cross-sectional view of the foreign matter inflow prevention apparatus according to an embodiment of the prior art, Figure 3 is a cross-sectional view of the foreign matter inflow prevention apparatus according to another embodiment of the prior art to be.

1 and 2, an inner case 3 having a cooling water supply path 5 is installed around the CCD camera 1, and a cooling water supply pipe for supplying cooling water to the left side of the inner case 3. 7a is connected, and on the right side, a cooling water discharge pipe 7b through which the cooling water flowing along the cooling water supply passage 5 is discharged is formed. Therefore, the cooling water is supplied through the cooling water supply pipe 7a, flows along the cooling water supply path 5, and is discharged to the cooling water discharge pipe 7b to take away the surrounding heat.

The heat resistant glass 8 is installed at the distal end of the inner case 3, that is, in the direction in which the lens of the CCD camera 1 is positioned so that the CCD camera 1 receives the reflected light of the subject passing through the heat resistant glass 8. do.

On the other hand, the foreign material inflow prevention device 10 is installed around the heat-resistant glass (8).

The foreign material inflow prevention device 10 includes a first cylindrical tube 13 and a second cylindrical tube 15 located inside the first cylindrical tube 13.

The first cylindrical tube 13 has its rear end wrapped around the heat-resistant glass 8 and fixed to the inner case 3. The air supply pipe 11 is connected to the left and right sides of the first cylindrical pipe 13 at 180 °. The second cylindrical tube 15 has a diameter relatively smaller than the diameter of the first cylindrical tube 13 and is located inside the first cylindrical tube 13, and the rear end portion of the second cylindrical tube 15 is internal. A gap 17 of about 0.5 mm is formed at regular intervals so as not to contact the case 3, and an air supply path 14 of about 1 mm is spaced between the first cylindrical tube 13 and the second cylindrical tube 15. ) Is formed, and the air 20 supplied through the air supply pipe 11 proceeds along the air supply path 14 and is spaced apart from the second cylindrical pipe 15 and the inner case 3. While discharging through the inner case (3) and the heat-resistant glass (8) while flowing along the inside of the second cylindrical tube (15), proceeds along the second cylindrical tube (15) while the second cylindrical tube It is discharged outside of 15, that is, toward the distal end of the second cylindrical tube 15.

The outer case 4 surrounds the inner case 3 and the foreign matter inflow prevention device 10. The reflected light of the subject passes through the inside of the second cylindrical tube 15, passes through the heat-resistant glass 8, and enters the CCD camera 1.

As described above, referring to the flow of air of the foreign matter inflow prevention device, as shown in FIG. 2, the air flowing along the air supply path 14 is disposed between the inner case 3 and the second cylindrical tube 15. It moves along the front end surface and the heat-resistant glass 8 surface of the inner case 3 through the gap 17 formed in the, and is discharged forward while moving along the second cylindrical tube (15). However, according to the difference between the air pressure at the tip central portion of the second cylindrical tube 15 and the air pressure at the tip edge of the second cylindrical tube 15, the backflow air 30 is heat-resistant along the inner edge of the second cylindrical tube 15. It moves to the glass 8. The backflow air 30 includes dust and the like containing moisture, and thus dust and the like are attached to the heat-resistant glass 8.

On the other hand, as shown in FIG. 3 to compensate for this problem, the backflow prevention jaw 19 is installed at the rear end of the second cylindrical tube 15. The non-return jaw 19 is fixed to the inner rear end of the second cylindrical tube 15 is a circular plate formed hollow. However, the backflow prevention jaw 19 does not effectively block the backflow air 30. This is because the backflow air 30 moves over the backflow prevention jaw 19 and moves toward the heat-resistant glass 8 while moving along the surface of the flat backflow prevention jaw 19.

The present invention has been made to solve the problems of the prior art as described above, an object of the present invention to provide a camera case having a foreign matter inflow prevention device that can discharge the air back to the inside of the case to the outside.

1 is a conceptual diagram showing the installation relationship of a general CCD camera,

Figure 2 is a cross-sectional view of the foreign matter inflow prevention device according to an embodiment of the prior art,

3 is a cross-sectional view of the foreign matter inflow prevention device according to another embodiment of the prior art,

Figure 4 is a cross-sectional view of the foreign matter inflow prevention device according to an embodiment of the present invention,

FIG. 5 is a flow chart illustrating the flow of air in the foreign matter inflow prevention device of FIG. 4.

♠ Explanation of symbols on the main parts of the drawing ♠

1: CCD camera 3: inner case

5: cooling water supply passage 8: heat-resistant glass

10, 100: foreign material inflow prevention device 14: air supply path

17: gap 20: air

30: backflow air 50: backflow prevention jaw

51: rounding portion 52: cylindrical jaw

According to the present invention for achieving the object as described above, a tube formed in front of the camera, a tube surrounding the flood plate and formed in front of the flood plate, and the tube after moving along the surface of the flood plate A camera case having a foreign matter inflow prevention device including an air injection pipe for injecting air moving forward along the rear end of the pipe, wherein the air introduced from the front of the pipe is inside the pipe There is provided a camera case having a foreign matter inflow prevention device including a slit formed along the inner circumference of the tube so as to move backward along the inner surface and change direction toward the front of the tube.

In addition, according to the present invention, the slit is formed of an inner tube having a diameter smaller than the diameter of the tube located inside the tube, and a connecting portion connecting the tube and the inner tube and being rounded.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of a camera case having a foreign matter inflow prevention device according to the present invention will be described in detail.

In the drawings, Figure 4 is a cross-sectional view of the foreign matter inflow prevention device according to an embodiment of the present invention, Figure 5 is a flow diagram of the air flow in the foreign matter intrusion prevention device shown in FIG.

As shown in Figure 4 and 5, the backflow prevention jaw 50 is fixed to the rear end of the second cylindrical tube (15). The backflow preventing jaw 50 has a diameter smaller than the diameter of the second cylindrical pipe 15 and is located inside the second cylindrical pipe 15, and the rear end and the second end of the cylindrical jaw 52. It is composed of a rounding part 51 which is connected to the cylindrical tube 15 and is rounded. Therefore, when the process proceeds to the rear end along the inner surface of the second cylindrical tube 15, the slit 55 is formed between the cylindrical jaw 52 along the circumference of the inner surface of the second cylindrical tube 15, The bottom face of the slit 55 is a rounding part 51.

When the second cylindrical tube 15 is advanced toward the rear end of the second cylindrical tube 15 along the inner surface, the second cylindrical tube 15 is along the surface of the rounding part 51 at the rear end of the second cylindrical tube 15. ), And in the reverse direction in the direction of traveling along the inner surface of the second cylindrical tube 15 along the outer surface of the cylindrical jaw 52, that is, in the direction of the distal end of the second cylindrical tube 15. Will proceed.

Therefore, as shown in Figure 5, when the air 20 is introduced from the air supply pipe 11 installed on both sides of the foreign matter inflow prevention device 100, the air 20 is the air supply path 14 of about 1mm It moves along, and it moves to the surface of the heat-resistant glass 8 through the clearance 17 of about 0.5 mm formed in the rear end of the 2nd cylindrical pipe 15. As shown in FIG. At this time, while the air 20 moves from the air supply path 14 of about 1 mm to the gap 17 of about 0.5 mm, the air 20 passes through the gap 17 at low pressure and high speed.

The air 20-1 passing through the gap 17 changes the traveling direction while forming a laminar flow gently along the outer surface of the rounding part 51, and the air 20-2 is inside the cylindrical jaw 52. Proceeding along the surface in the direction opposite to the direction moving along the air supply path 14, that is, the direction of the tip of the second cylindrical tube (15).

On the other hand, the backflow air 30 flows into the inside of the second cylindrical tube 15 by the pressure difference between the central portion of the second cylindrical tube 15 and the inner edge of the second cylindrical tube 15. At this time, the backflow air 30 is moved toward the rear end of the second cylindrical pipe 15 along the inner surface of the second cylindrical pipe 15, the backflow air 30 is moved so that the slit 55 Inflowed into the inner surface, the inner surface of the rounded portion 51 is in contact with the inner surface. At this time, the backflow air 30 proceeds along the inner surface of the rounding part 51, and eventually comes into contact with the outer surface of the cylindrical jaw 52. The portion 30-1 of the backflow air 30 in contact with the outer surface of the cylindrical jaw 52 is formed along with the air 20-2 along the outer surface of the cylindrical jaw 52 of the second cylindrical pipe 15. The other end 30-2 moves toward the heat-resistant glass 8 beyond the cylindrical jaw 52.

At this time, the counter flow air 30 of the other part 30-2 passes through the gap 17 and forms a laminar flow so that a collision with the air 20-1 moving along the outer surface of the rounding part 51 occurs. Under the influence of the air 20-1 passing through the gap 17 at a low pressure high speed, the backflow air 20-1 moves together to the front end of the second cylindrical pipe 15.

On the other hand, a very small portion of the backflow air 30-2 colliding with the low pressure high-speed air 20-1 is moved toward the heat-resistant glass 8 due to the pressure difference, but its influence is extremely small.

Therefore, the air traveling along the surface of the heat-resistant glass 8 is mostly the air 20 supplied through the air supply pipe 11, and thus, the heat-resistant glass (by preventing the contact of the backflow air 30 including dust) The adhesion of dust in 8) can be prevented.

As described in detail above, the camera case provided with the foreign matter inflow prevention device of the present invention is to prevent the air flowing from the outside of the case is in contact with the heat-resistant glass to prevent the dust contained in the air introduced to the heat-resistant glass The advantage is that the reflected light of the subject can be incident smoothly.

Although the technical idea of the camera case provided with the foreign matter inflow prevention apparatus of the present invention has been described above with the accompanying drawings, this is illustrative of the best embodiment of the present invention and is not intended to limit the present invention. In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Claims (2)

The light-transmitting plate formed in front of the camera, the tube surrounding the light-transmitting plate and formed in front of the light-transmitting plate, and the air moving forward along the pipe after moving along the surface of the light-transmitting plate at the rear end of the tube In the camera case provided with a foreign matter inflow prevention device comprising an air injection pipe, The interior of the tube includes a slit formed along the inner circumference of the tube so that the air introduced from the front of the tube moves backward along the inner surface of the tube and can be turned in front of the tube Camera case equipped with a foreign matter inflow prevention device. The method of claim 1, The slit is located inside the tube and the camera case having a foreign matter inflow prevention device comprising an inner tube having a diameter smaller than the diameter of the tube, and a connecting portion connecting the tube and the inner tube rounded .