KR101149262B1 - Cooling Structure For Security Camera - Google Patents

Abstract

The present invention relates to a cooling structure for a surveillance camera. The present invention comprises an in-housing 34 in which an installation space 30 is shielded from the outside so that the camera body is installed; An out housing 52 formed to have a circumferential length greater than that of the in housing 34, and an air flow path 54 formed between the in housing 34; A fan 50 installed in the fan installation spaces 44 formed at both sides of the outer surface of the in-housing 34 to allow low temperature external air to flow into the installation space 30 and the air flow passage 54; One side is fixedly installed on the wall surface (W), the other side is fastened to the upper end portion 36 of the out housing 52, the mounting bracket 58 for supporting the out housing 52; The air passage 54 is in communication with the installation space 30 through the downstream side of the air passage (54). The cooling structure for a surveillance camera according to the present invention continuously introduces low-temperature external air into the installation space 30 and smoothly circulates the introduced air, thereby further reducing the hot air formed in the installation space 30. There is an advantage.

Surveillance camera, connecting bracket, 2nd through hole, air flow path

Description

Cooling Structure For Security Camera

1 is a cross-sectional view showing a cooling structure for a surveillance camera according to the prior art.

Figure 2 is an operating state diagram showing the air circulation path according to the prior art.

3 is a cross-sectional view showing a preferred embodiment of the cooling structure for a surveillance camera according to the present invention.

Figure 4 is an operating state diagram showing the air circulation environment path of the embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

30: installation space 32: housing

34: housing 36: top

36 ': The first penetration 38: Slant part

40: vertical part 42: protrusion part

44: fan installation space 46: fastening flange

48: lens cover 50: fan

52: out housing 54: air passage

56: Connecting bracket 56 ': Second through hole

58: Mounting bracket W: Wall

The present invention relates to a camera, and more particularly, to a cooling structure of a surveillance camera installed on a ceiling or a wall for security or theft prevention.

As shown in FIG. 1, the housing 4 which protects the camera body (not shown) installed in the installation space 2 from the outside has an in-housing 6 shielding the installation space 2 and the in-housing. It consists of the out housing 8 which has a perimeter length larger than (6).

An air passage 10 is formed between the in housing 6 and the out housing 8. The air flow path 10 is a space through which external air introduced by the fan 14 to be described below flows. As such, the air introduced into the air passage 10 is heat-exchanged with the outside air through the out housing 8 formed of a material having good thermal conductivity such as aluminum.

Fan installation spaces 12 protruding toward the out housing 8 are formed on both outer circumferential surfaces of the in housing 6. A fan 14 is installed in the fan installation space 12, and the fan installation space 12 is formed to have a size of approximately 50 × 50 × 10 (㎣) corresponding to the size of the fan 14.

The upper ends of the in-housing 6 and the out-housing 8 are fastened to each other by screwing the connecting bracket 16 and the mounting bracket 18, and firmly by being mounted on the wall. Supported.

The connecting bracket 16 serves to fasten the upper ends of the in-housing 6 and the out-housing 8 to the mounting bracket 18. In addition, one side of the mounting bracket 18 is fastened to the wall surface, and the other side is screwed with the connection bracket 16 in the state connected to the upper surface of the out housing (8). Although not shown, a hole having a predetermined size is formed at one side of the mounting bracket 18, and a power line is connected to the camera body through the hole.

The base plate 20 is screwed to a portion extending in a step shape from the upper end of the in-housing 6. The base plate 20 is installed to support the camera body.

On the other hand, the lens cover portion 22 is fastened to the lower end of the in the housing 6 and the out housing (8). Although not shown in the lens cover portion 22, the lens portion provided at the front end of the camera body is located.

However, the prior art as described above has the following problems.

That is, the camera body installed in the installation space 2 includes a motor for zooming in or out of the lens unit or rotating the camera body. As such, the camera body includes a plurality of motors to perform various functions, so that heat is generated in the installation space 2 by driving the motor. Due to the heat, a high temperature air layer is formed inside the installation space 2.

Since such heat shortens the product life, the prior art is provided with a fan 14 which sucks external cold air into the installation space 2. As shown in FIG. 2, the air introduced by the fan 14 is first diluted with the hot air layer inside the installation space 2, and secondly, the air flows into the air flow path 10 to out-housing ( 8) it exchanges heat with cold air.

However, the air flow path 10 is sealed by the in-housing 6 and the out-housing 8, so that the amount of low-temperature external air that can be introduced by the fan 14 gradually decreases over time. do. That is, since the amount of air that can be introduced through the air flow path 10 formed in the enclosed space is limited, a small amount in a state in which sufficient air flow flows into the air flow path 10 but a gap formed due to tolerances between parts. Alternatively, only the amount of air that flows out of the air passage 10 back to the installation space 2 through the fan 14 may be introduced into the outside air.

As a result, in the prior art, it is impossible to supply low-temperature external air to the fan 14 and supply it to the air flow path 10, so that it is not efficient in lowering the hot heat inside the installation space 2, thereby extending the life of the product. There is a problem of shortening.

In addition, since the flow of air is not smooth in the sealed air passage 10, the fan that introduces external air into the air passage 10 receives a lot of load. Accordingly, there is a problem in that the durability of the fan 14 is reduced, which shortens the life of the product.

Accordingly, an object of the present invention is to solve the problems described above, and to provide a cooling structure for a surveillance camera that can continuously introduce low-temperature external air into the installation space.

Another object of the present invention is to facilitate the flow of air in the air passage.

According to a feature of the present invention for achieving the above object, the present invention comprises: an in-housing for forming an installation space shielded from the outside so that the camera body is installed; An out housing formed to have a circumferential length larger than that of the in housing, wherein an air flow path is formed between the in housing and the in housing; A fan installed in the fan installation spaces formed at both sides of the outer surface of the in-housing to allow low temperature external air to flow into the installation space; One side is fixedly installed on the wall surface, the other side is fastened to the upper end of the out housing mounting bracket for supporting the out housing; and the air flow path is communicated with the installation space through the air flow downstream one side.

The upper end of the in-housing is fastened to and supported by a connection bracket, and second through-holes are formed at both sides of the connection bracket so that air flowing through the air flow path enters the installation space.

Both sides of the in housing are provided with protrusions protruding in the installation space direction, and a fan is installed in the fan installation space provided in the protrusion.

The in-housing has an upper end portion formed with a first through-hole penetrated in the vertical direction; An inclined portion extending obliquely downward from the upper end portion; A vertical portion extending vertically downward from the inclined portion; Protrusions protruding from both sides of the vertical portion in an installation space direction to secure the air flow path; And a fastening flange formed around the edge of the protrusion.

Lens cover parts are fastened to both sides of the fastening flange of the in-housing to shield the lower portion of the installation space.

Cooling structure for a surveillance camera according to the present invention having such a configuration has the advantage of further lowering the hot air formed in the installation space by continually flowing low-temperature external air into the installation space and smoothly circulated the introduced air. .

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the cooling structure for a surveillance camera according to the present invention will be described in detail.

As shown in FIG. 3, the housing 32 that protects the camera body (not shown) installed in the installation space 30 from the outside is provided with an in-housing 34 forming the installation space 30. Here, although not shown, the camera body is supported by a base plate coupled to the in-housing 34.

An upper end 36 of which the first through hole 36 ′ penetrated in the vertical direction is formed at the upper end of the in housing 34. The first through hole 36 ′ is for allowing external air sucked by the fan 50 to flow into the installation space 30.

The in housing 34 is provided with an inclined portion 38 extending obliquely downward from the upper end 36 and a vertical portion 40 extending vertically downward from the inclined portion 38. In the housing 34, a protrusion 42 protruding from the vertical portion 40 toward the installation space 30 is provided. The protrusion 42 is to secure the space between the in-housing 34 and the out-housing 52 to be described below, that is, the space of the air passage 54 to be described below as large as possible. Accordingly, the amount of air that can be introduced into the air passage 54 is relatively increased, so that heat exchange between the introduced air and the out housing is further activated.

The outer surface of the protrusion 42 is formed with a fan installation space 44 for installing the fan 50 to be described below. The fan installation space 44 is preferably formed by injection molding of the in-housing 34, but a member formed separately from the in-housing 34 is formed by being attached to an outer surface of the protrusion 42. It is also possible.

In this embodiment, the fan installation space 44 is formed to a size of 60 × 60 × 15 (㎣) to correspond to the size of the fan 50. However, the present invention is not necessarily limited thereto, and the fan installation space 44 may be formed to correspond to the size of the fan 50 capable of efficiently sucking external air.

The in-housing 34 has a fastening flange 46 extending around the bottom edge of the protrusion 42. The fastening flange 46 is a part which is fastened to both upper ends of the lens cover 48. Here, the lens cover portion 48 is formed in a dome shape, the lens portion (not shown) provided in the front end of the camera body is located therein. The lens cover 48 is fastened to the fastening flange 46 of the in-housing 34 to shield the installation space 30.

The fan 50 is installed in the fan installation space 44. The fan 50 is a device that sucks the outside air to the installation space 30, the outer air introduced into the installation space has an outer housing 52 having a larger circumference than the in-housing 34 and the in-housing 32. It serves to flow into the air flow path (54) corresponding to the space between.

The out housing 52 is formed of a material having a high thermal conductivity such as aluminum. The out housing 52 is formed to have an outer circumference larger than that of the in housing 34, so as to form the air passage 54 between the in housing 34.

On the other hand, the upper end 36 of the in housing 34 is fastened to the connection bracket 56 by a fastening means such as a screw. The second through hole 56 'is formed at both sides of the connection bracket 56. The second through hole 56 ′ is for allowing the air introduced into the air passage 54 by the fan 50 to flow back into the installation space 30. That is, the second through hole 56 ′ is formed at one side of each of the connection brackets 56 corresponding to the downstream portion of the air passage 54 so that the air passage 54 and the installation space 30 communicate with each other. do.

In addition, the upper end portion 36 of the connection bracket 56 is fastened by fastening means such as a screw on both sides of the mounting bracket 58 together with the out housing 52. The mounting bracket 58 is fixed to the wall surface W, and serves to support the in-housing 34 and the out-housing 52 fastened to the connection bracket 56.

Although not shown, a hole having a predetermined size is formed at one side of the mounting bracket 58, and a power line is connected to the camera body through the hole. Then, the outside air is sucked by the fan 50 through the hole and flows into the installation space 30.

Hereinafter, the operation of the cooling structure for a surveillance camera according to the present invention having the configuration as described above will be described in detail.

Looking at the process of the surveillance camera according to the present invention is installed on the wall (W), first attach the mounting bracket 58 to the wall (W), the in-housing 34 is connected to the lower end of the connecting bracket 56 Along with the out housing 52 is fastened to the mounting bracket 58 by a fastening member such as a screw. Then, the lens cover 48 is fastened to the fastening flange 46 of the in-housing 34, and the lower end of the out housing 52 is fastened to the lens cover 48. Here, although not shown, the base plate is fitted to the in-housing 34 is coupled or fastened by a fastening member such as a screw. The base plate is fixed to the camera body.

In this state, the air passage 54 through which air flows is formed between the in-housing 34 and the out-housing 52. As shown in FIG. 4, the fan 50 sucks external air into the installation space 30 through a hole formed so that a power line is inserted into one side of the mounting bracket 58. Accordingly, the external cold air is diluted with the hot air inside the installation space 30 to primarily lower the high temperature air in the installation space 30.

As such, the air introduced into the installation space 30 flows into the air passage 54. In addition, the air introduced into the air passage 54 is secondly heat-exchanged with the outside air through the out housing 52 having a large thermal conductivity. As a result, the air introduced into the air passage 54 is further lowered.

In addition, the air introduced into the air passage 54 flows back into the installation space 30 through the second through hole 56 ′ of the connection bracket 56. The air exiting through the second through hole 56 ′ is diluted with low temperature external air drawn into the installation space 30 by the fan 50. The air passage 54 is further lowered in temperature than the air lowered in temperature.

As a result, the hot air formed in the installation space 30 is firstly cooled by the external air introduced by the fan 50, and then secondly flows into the air passage 54 to exchange heat with the outhousing 52. The temperature is lowered, and then flows from the air flow path 54 to the installation space 30 through the second through hole 56 'and is further diluted with external air to lower the temperature.

In addition, the air introduced into the air passage 54 by the fan 50 flows back into the installation space 30 through the second through hole 56 ′ and circulates smoothly in the housing 32. . As the air circulates smoothly as described above, the temperature of the hot air is further lowered, and the amount of external air that can be introduced into the installation space 30 by the fan 50 decreases due to the air channel 54 being closed. Is prevented.

In the present invention, since the fan 50 uses a relatively larger capacity than the prior art, the amount of external air that can be sucked by the fan 50 increases.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

Cooling structure for a surveillance camera according to the present invention as described in detail above has the following effects.

That is, by forming the second through-holes on both sides of the connecting bracket so that the outside air introduced into the installation space by the fan can be smoothly circulated, the hot air formed in the installation space by the motor or the like is well diluted with the external air to lower the temperature. There is.

In addition, the air is smoothly circulated through the installation space and the air flow path to continuously suck low-temperature external air into the installation space by the fan, so that the hot air in the installation space is further lowered.

In addition, by configuring the fan installation space to protrude toward the installation space, the air passage space is not narrowed by the fan, so that a relatively large amount of air can be introduced into the air passage, so that heat exchange between the introduced air and the out housing is prevented. It is also activated to lower the temperature.

On the other hand, by smoothing the flow of air in the air flow path, the load received by the fan is relatively small. Therefore, the durability of the fan is improved, so that the fan can be used for a long time, so that the hot air in the installation space can be continuously lowered in temperature.

Claims (5)

An in-housing provided with an installation space in which the camera body is installed, and having a first through hole communicating with the outside at an upper portion thereof; An out housing formed at an outer side of the in housing to form an air flow path therebetween; A fan installed at an outer side surface of the in-housing to introduce low-temperature external air into the installation space and the air passage; One side is fixed to the wall surface, the other side is configured to include a mounting bracket for fastening to the upper end of the out housing to support the out housing; Cooling structure for a surveillance camera, characterized in that through the air passage through the air passage communicates with the installation space. The method of claim 1, The upper end of the in-housing is fastened to be supported by a connecting bracket, the second through hole is formed on both sides of the connection bracket is characterized in that the air flowing through the air passage flows into the installation space through the second through hole Cooling structure for surveillance camera. The method according to claim 1 or 2, Cooling structure for the monitoring camera, characterized in that the both sides of the in housing is provided with a projection protruding in the direction of the installation space, the fan is installed in the fan installation space provided in the projection. The method of claim 3, The in-housing An upper end portion formed with a first through hole penetrating in a vertical direction; An inclined portion extending obliquely downward from the upper end portion; A vertical portion extending vertically downward from the inclined portion; Protrusions protruding from both sides of the vertical portion in an installation space direction to secure the air flow path; Cooling structure for a surveillance camera, characterized in that it comprises a; fastening flange formed around the edge of the protrusion. The method of claim 4, wherein Cooling structure for a surveillance camera, characterized in that the lens cover is fastened to shield the lower portion of the installation space on both sides of the fastening flange of the in-housing.

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