KR102388332B1 - Air cooling system for camera - Google Patents

Abstract

An air cooling system for a camera is disclosed. The air cooling system includes: an air inlet pipe for receiving air; a photographing device located in communication with the inlet pipe and having an outlet hole on the other side through which the received air is discharged; and a housing that has an arrangement space for arranging a photographing device, and a discharge hole for discharging the air passing through the photographing device at a position where it communicates with the outlet hole.

Description

AIR COOLING SYSTEM FOR CAMERA

The present invention relates to an air-cooled imaging device cooling system.

In general, a photographing device is an optical device for photographing, and is used in the fields of press photography, commercial photography, architectural photography, etc., or in a wide range of medical, industrial, and academic fields such as micrograph, Roentgen photography, aerial photography, and astrophotography. The conventional photographing apparatus was operated once, but was continuously operated according to the development of technology, and recently it is operated for 24 hours and is used to monitor a specific location.

According to this technological development, there is a problem to be solved in the photographing apparatus, which is a heat problem. Heat is a problem that needs to be solved because electricity is supplied differently from the original intention, and it increases the temperature of the photographing device. Since this heat damages various parts of the imaging device, a cooling structure for cooling the heat is essential.

There may be various methods for cooling the photographing device, but an air cooling method is typically used. Air cooling is a method of cooling by using wind generated by blowing air strongly.

1 relates to a conventional air-cooled imaging device cooling system.

A conventional imaging device cooling system includes an inlet pipe 10 , a housing 20 , and an imaging device 30 disposed in the housing. A glass plate 40 is installed in the housing 10 to protect the lens of the photographing device 30 and to remove particles in the housing according to the rotational movement of air.

However, when the flow of air increases, the particles accumulate near the glass plate 40, and there is a problem that the glass plate must be frequently replaced or cleaned.

Domestic Patent Publication No. 2020-0070028 Domestic registered patent registration number 6745026

The present invention has solved the above problems, and an object of the present invention is to provide an air-cooled imaging device cooling system in which the cooling efficiency of the imaging device is good and particles do not accumulate on a glass plate.

An air-cooled imaging device cooling system according to the present invention includes an inlet tube through which air is introduced, a photographing device having an outlet hole through which the introduced air is discharged, and an outlet hole through which the air is discharged on the other side, and an arrangement space in which the photographing apparatus is disposed. and a housing having an exhaust hole through which the air passing through the photographing device is discharged at a position communicating with the outlet hole.

The housing includes a block plate of a set length that is disposed in a shape to impede the movement of air moving through the outlet hole, and the block plate has an outlet hole communicating with the outlet hole is formed, the block plate and It is characterized in that the side hole is formed in the portion formed due to the difference in length of the housing.

The housing communicates with the discharge hole and the side hole, and a discharge passage is formed in a direction crossing the direction of the discharge hole and the direction of the side hole, so that the air passing through the discharge hole and the side hole is discharged through the discharge passage do it with

The photographing device is characterized in that a protective cover in the form of surrounding the discharge hole is installed.

The protective cover is installed on the cover part to cover the end of the photographing device but not to close the exit hole and to close the exit hole of the photographing device, the auxiliary hole communicating with the exit hole It is characterized in that it comprises a guide portion formed.

The diameter of the auxiliary hole of the guide part is characterized in that it is formed to increase continuously from one side to the other side.

The diameter of the discharge hole is characterized in that it continuously increases from one side to the other side.

The housing is formed with an extension portion extending to one side and a bent portion extending from one side of the extension portion to the other side, so that the air passing through the side hole is guided by the bent portion to guide the passage through the discharge passage. characterized.

The bent portion is inclined toward the other side from one side, so that the size of the discharge passage is formed to be small.

According to the present invention, a protective cover is installed in the photographing device, and when air is supplied through the structure of the housing, cooling of the photographing apparatus is performed, and particles in the housing are removed by utilizing the air flow, so that particles in the housing do not accumulate.

1 relates to a conventional air-cooled imaging device cooling system.
2 relates to an air-cooled imaging device cooling system according to the present invention.
3 is a cross-sectional view of the protective cover of the cooling system for the air-cooled imaging device according to the present invention.
4 is an enlarged view of the accelerator of the cooling system for the air-cooled imaging device according to the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to exemplary drawings. However, this is not intended to limit the scope of the present invention.

In adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms specifically defined in consideration of the structure and operation of the present invention are only for describing the embodiments of the present invention, and do not limit the scope of the present invention.

2 relates to an air-cooled imaging device cooling system according to the present invention.

The present invention's air-cooled imaging device cooling system includes an inlet pipe 100 , an imaging device 500 , a housing 200 , and a protective cover 400 .

The inlet pipe 100 is formed to have different diameters on one side and the other side. One side of the inlet pipe 100 is formed in the shape of a pipe having a set length, and the other side is formed in a shape having a large diameter for support. The other side of the inlet pipe 100 may be disposed on the upper surface of the housing 200 .

The inlet pipe 100 is formed with a hollow part. Accordingly, the air supplied to the inlet pipe 100 may be introduced into the housing 200 .

The photographing device 500 is formed to communicate with the hollow part of the inlet pipe 100 . The photographing apparatus 500 includes a case of a set type. And a circuit board for operation of the photographing apparatus 500 may be disposed therein. In addition, a lens may be installed outside the other side of the photographing apparatus 500 . Here, in the photographing apparatus 500 of the present invention, a hollow portion is formed. When the photographing apparatus 500 is disposed in the arrangement space of the housing 200 , the hollow portion of the photographing apparatus 500 may be formed to communicate with the hollow portion of the inlet pipe 100 .

An exit hole is formed at the other side of the photographing device 500 . Accordingly, the air introduced into one side of the photographing apparatus 500 may be discharged through the outlet hole of the other side.

The housing 200 is formed outside the photographing device 500 . The housing 200 serves to protect the photographing device 500 . A hollow portion may be formed in the upper surface of the housing 200 . Accordingly, the air introduced from the inlet pipe 100 disposed on the upper surface of the housing 200 may move into the housing 200 . The hollow part of the housing 200 communicates with the arrangement space of the housing 200 .

The photographing device 500 is disposed in the arrangement space of the housing 200 . The hollow part of the photographing apparatus 500 may communicate with the hollow part of the upper surface of the housing 200 . Accordingly, the air introduced into the inlet pipe 100 may pass through the photographing device 500 and be discharged to the outlet hole.

The housing 200 includes a block plate, and a discharge hole is formed in the block plate. The block plate is disposed in a direction that intersects the longitudinal direction of the photographing device 500 to prevent the air passing through the photographing device 500 from moving in a straight line. However, since an exhaust hole is formed in the block plate, a portion of the air that has passed through the photographing device 500 may pass through the exhaust hole and move in a straight direction.

However, the air that is prevented from moving by the block plate may be moved to a side hole formed in a position adjacent to the discharge hole and disposed. The side hole is formed at a position spaced apart from the exit hole. Therefore, the supplied air is partially discharged through the discharge hole, but is partially guided by the block plate and discharged through the side hole.

The side hole may be formed by a difference between the length of the block plate and the length of the housing 200 . That is, when the length of the housing 200 is longer than the length of the block plate, and the other side of the block plate is placed in contact with the inside of the housing 200 , a side hole is naturally formed by the difference in length between the block plate and the housing 200 . can be

And the discharge flow path 300 of the housing 200 is formed to pass through the side surface of the housing 200 . The discharge passage 300 of the housing 200 communicates with the side hole and the outlet hole. In addition, the discharge passage 300 has an outlet formed in a direction that does not correspond to the side hole and the discharge hole.

As described above, the air that has cooled the imaging device 500 through the structure of the discharge hole, side hole, and discharge flow path 300 sweeps through the inside of the housing 200 to discharge the particles in the housing 200 to the outside of the housing 200 . can At the same time, air is moved in the direction passing through the discharge hole without blocking any air flow in the discharge hole portion, and air is also moved in the intersecting direction, so that particles may not accumulate on the discharge hole side.

Then, the air sweeps through the arrangement space, passes through the side hole and induces the air to be discharged in the opposite direction to the side hole, so that the particles in the housing 200 can be discharged to the outside.

3 is a cross-sectional view of the protective cover 400 of the cooling system for the air-cooled imaging device according to the present invention.

The protective cover 400 is installed at the other end of the photographing device 500 .

The photographing apparatus 500 is formed in a form in which the other side is elongated due to the lens. The protective cover 400 is installed on the other side of the photographing device 500 . That is, it is formed in a shape surrounding the exit hole of the photographing device 500 . The protective cover 400 is formed with an auxiliary hole communicating with the outlet hole.

A screw thread is formed inside the protective cover 400 , and the other end of the photographing device 500 is also formed with a screw thread, so that the protective cover 400 and the photographing apparatus 500 may be screwed together. However, an adhesive may be applied to the inside of the protective cover 400 to contact the other end of the photographing device 500 . Alternatively, the inner diameter of the protective cover 400 may be formed slightly smaller than the diameter of the other end of the photographing device 500 , so that the protective cover 400 may be fixed to the other end of the photographing apparatus 500 by an interference fit method.

The protective cover 400 includes a cover part 410 and a guide part 420 .

The cover part 410 serves as a case of the protective cover 400 , and is formed to surround the other end of the photographing device 500 . The cover part 410 is formed with a hollow part. The size of the inner space of the cover part 410 is formed to decrease from one side to the other side. A guide part 420 is installed at the center of the cover part 410 .

An auxiliary hole may be formed in the center of the guide part 420 .

The auxiliary hole formed in the guide part 420 is formed to continuously increase in diameter from one side to the other side. The auxiliary hole of the guide part 420 is formed in communication with the exit hole of the photographing apparatus 500 . Accordingly, the air moved while cooling the photographing apparatus 500 may be discharged in the form of being sprayed through the auxiliary hole. That is, the air passing through the auxiliary hole can be guided and moved in the radial direction.

On the other hand, the size of the discharge hole may also be formed to continuously increase in diameter from one side to the other side. Therefore, the size of the discharge hole is preferably formed in such a way that, when there is no gap between the block plate and the auxiliary hole, the diameter starting from one side of the auxiliary hole continuously increases toward the other side.

That is, the diameter of the auxiliary hole and the diameter of the discharge hole are continuous from one side of the auxiliary hole to the other side between the discharge hole of the block plate to increase the diameter, and the block plate is horizontally cut and the cut part is removed. Guide part 420 It is formed as if a gap was formed between the and the block plate.

In this way, the discharge hole is formed so that the air passing through the auxiliary hole can be moved to the discharge passage 300 . However, since the air has no direction, it may move in the arrangement space of the housing 200 . Accordingly, the air may sweep and move within the housing 200 .

4 is an enlarged view of the accelerator of the cooling system for the air-cooled imaging device according to the present invention.

The housing 200 may include an accelerator. The acceleration part may include an extension part 210 and a bent part 220 .

The extension 210 may extend from one side of the side hole in a form that does not close the side hole. The bent portion 220 extends in a direction in which the air that has moved through the exhaust passage 300 at the end of the extension 210 is discharged from the housing 200 . That is, the extended portion 210 and the bent portion 220 may be formed in the shape of 'b' when viewed in cross-section.

Here, the bent portion 220 is formed to be inclined upward from one side to the other side. Accordingly, the size of the flow path between the bent portion 220 and the block plate is formed to become smaller. That is, as shown in FIG. 4 , the discharge flow path 300 may be small in size on the left side and increase in size on the right side.

Here, the bent portion 220 may be formed to be inclined from left to right as shown in FIG. 4 , but may be formed to have a thickness increasing from left to right to narrow the size of the flow path. Through this structure, the air passing through the side hole is accelerated and can move quickly through the discharge passage 300 .

That is, the air moved through the side hole is moved to the discharge flow path 300 , the flow path narrows from the left side to the other side of the discharge flow path 300 , so that the speed is accelerated, so that the discharge flow path 300 can be moved quickly.

Accordingly, the air flow is rapidly formed in the discharge passage 300 to discharge the particles in the housing 200 to the outside of the housing 200 .

In the present invention, the particles in the housing 200 can be discharged to the outside of the housing 200 while cooling the imaging device 500 by supplying air to the inlet pipe 100 due to this guide structure.

Although the present invention has been shown and described in relation to specific embodiments, it is within the art that the present invention can be variously improved and changed without departing from the spirit of the present invention provided by the following claims. It will be obvious to those of ordinary skill in the art.

100: inlet pipe
200: housing
210: extension
220: bent part
300: discharge flow path
400: protective cover
410: cover part
420: guide part
500: shooting device

Claims (9)

an inlet pipe through which air is introduced;
a photographing device located in communication with the inlet pipe and having an outlet hole at the other side through which the introduced air is discharged;
A housing in which an arrangement space in which the photographing device is disposed is formed, and an exhaust hole through which the air passing through the photographing apparatus is discharged is formed at a position communicating with the outlet hole
includes
The housing extends from one surface to the other surface and has a length shorter than the horizontal length of the housing, so that a side hole is formed between the other surface of the housing and a discharge hole whose diameter increases toward the bottom at a position corresponding to the outlet hole is formed. including a block plate;
The other surface of the housing has an extended portion extending downward and a set length, and a bent portion extending in the direction of one surface of the housing and inclined upward is formed.
The air passing through the discharge hole and the air moving through the side hole meet in the discharge passage located below the block plate and discharged
Air-cooled imaging device cooling system. delete delete According to claim 1,
The recording device
A protective cover in the form of enclosing the discharge hole is installed
Air-cooled imaging device cooling system, characterized in that. 5. The method of claim 4,
The protective cover is
a cover portion formed to cover the end of the photographing device but not to close the outlet hole;
Doedoe installed on the cover in the form of closing the exit hole of the photographing device, comprising a guide portion formed with an auxiliary hole communicating with the exit hole
Air-cooled imaging device cooling system, characterized in that. 6. The method of claim 5,
The diameter of the auxiliary hole of the guide part is
Formed to grow continuously from one side to the other
Air-cooled imaging device cooling system, characterized in that. 7. The method of claim 6,
The diameter of the discharge hole is continuously increased from one side to the other side
Air-cooled imaging device cooling system, characterized in that. delete delete

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