KR20160009749A - Infrared LED security camera - Google Patents

Abstract

The present invention relates to an infrared LED surveillance camera which comprises: a camera module including a lens unit; an infrared LED module having a first insertion hole formed at a center portion thereof to insert the lens unit, and including a plurality of infrared LEDs provided along the circumference of the first insertion hole; an electrically insulating and thermally conductive thermal pad having a second insertion hole formed at the center portion thereof in response to the infrared LED module, and provided to be in contact with a rear surface of the infrared LED module; a heat dissipation unit of which one end is in contact with the thermal pad to be coupled; and a housing in which a heat radiation fin is integrally formed on an external side wall, and the other end of the heat dissipation unit is in contact with an inner side wall to be inserted. Accordingly, the infrared LED surveillance camera can perform the effective heat radiation with the heat dissipation unit and the heat radiation fin of the housing, can protect the camera module from light emitted from an infrared LED and heat generated from the infrared LED module with a protective pipe, and also, can further include a thermoelectric device and a cooling fan, thereby having a maximized heat radiation function.

Description

Infrared LED security camera}

The present invention relates to an infrared LED surveillance camera, and more particularly, to an infrared LED surveillance camera that effectively dissipates heat generated from an infrared LED module.

Infrared surveillance cameras are surveillance cameras that can shoot objects clearly in night or in dark places by using infrared rays. In this case, an infrared LED surveillance camera uses an infrared LED as an infrared light source. Such an infrared LED surveillance camera has a problem that thermal damage occurs inside the infrared surveillance camera because the infrared LED emits heat when the infrared ray is emitted.

In order to solve such a problem, Korean Patent Laid-Open No. 10-2007-0019214 (Feb. 15, 2007, 2007) discloses a method of cooling a heat by installing a fan therein. In this method, When foreign matter such as moisture or dust flows into the inside of the infrared surveillance camera when it is inflow, it causes various parts installed in the infrared surveillance camera, and when the fan stops due to a failure of the fan, There is still a problem that it is difficult to maintain and repair equipment due to loss of function.

Accordingly, there is a need in the art for a new heat dissipating technology that effectively dissipates the heat generated by the infrared LEDs without a fan inside to maximize the heat dissipation effect.

Korean Patent Publication No. 10-2007-0019214

An object of the present invention is to provide an infrared LED surveillance camera that efficiently emits heat generated from an infrared LED module, and can shoot and send an object clearly at a place with low nighttime and low illuminance.

An infrared LED monitoring camera according to the present invention includes a camera module including a lens unit; An infrared LED module including a plurality of infrared LEDs provided along a periphery of the first insertion port, the infrared LED module having a first insertion port formed at a central portion thereof to insert the lens portion; A thermal pad having a second insertion port formed at a central portion corresponding to the infrared LED module and being provided to be in contact with a rear surface of the infrared LED module and electrically insulative and thermally conductive; A heat dissipating unit having one end thereof abutted against the thermal pad; And a housing in which a radiating fin is integrally formed on the outer side wall and the other end of the radiating unit is inserted in contact with the inner side wall.

The thermal pad may include a column formed along the periphery of the second insertion port and a protrusion formed at an end of the column, and the column and the protrusion may form a coupling groove with a width corresponding to the thickness of the heat- ,

Wherein the heat dissipation units are formed as a pair and include concave portions formed on mutually opposite surfaces, and when the concave portions of the heat dissipation unit are in contact with the column portions of the thermal pad from both sides thereof, However,

The thermal pad may be formed of a composite material in which a thermally conductive polymer is mixed with an electrically insulating resin forming a matrix,

The thermoelectric module according to any one of claims 1 to 3, further comprising a thermoelectric element that has a heat absorbing surface to cool the contact surface and emits heat by radiating heat on the other surface, wherein the heat absorbing surface of the thermoelectric element is in contact with the heat radiating unit, Can be contacted,

The housing may be formed on an inner side wall thereof in a longitudinal direction of the housing and may include at least a part of the heat dissipation unit or a guide groove into which the thermoelectric element is inserted,

The heat dissipation unit may have a width equal to the width of the inner side wall of the housing and the other end may have the same width as the guide groove. The heat dissipation unit may include a step portion corresponding to the thickness of the thermoelectric element, Which can contact the inner side wall of the housing,

The radiating fins may extend in the longitudinal direction of the housing and the radiating fins may have a lower height than other portions where the cooling fan is provided,

And the guide groove is formed in the longitudinal side of the housing And a fixing member for pressing the other end of the heat dissipating unit fitted in the guide groove by elasticity to closely contact the inner side wall of the housing,

And an elastic protrusion of the rear cover is inserted into the housing when the rear cover is coupled to the housing, and the resilient protrusion of the rear cover is inserted into the housing, Can be brought into contact with the other end of the unit to apply a force to the inner side wall of the housing,

The lens unit may further include a protective tube penetrating the center portion to insert the lens unit and preventing light emitted from the infrared LED or heat generated from the infrared LED module from being transmitted to the lens unit.

In the infrared LED monitoring camera according to the present invention, since the thermal pad is mounted on the rear surface of the infrared LED module, not only the rear surface of the infrared LED module is insulated, but also the heat generated from the infrared LED is transmitted to the heat radiation unit, The heat dissipating unit is disposed in contact with the thermal pad, so that heat is efficiently conducted from the thermal pad, and a large area is closely attached to the inner side wall of the housing, so that heat can be smoothly discharged from the housing to the outside.

In addition, since the camera module is inserted into the protective tube and the light emitted from the infrared LED or the heat generated from the infrared LED module is prevented from being transmitted to the camera module, the camera module is prevented from malfunctioning, So that it is possible to radiate heat and cool it.

In addition, if a thermoelectric element is mounted on the heat dissipation unit, the internal temperature can be effectively lowered because the heat dissipation unit can be cooled close to the heat source, and heat dissipation in the housing can be maximized by disposing a cooling fan on the outside of the housing.

Therefore, according to the infrared LED surveillance camera of the present invention, the heat radiation can be effectively performed by the thermal pad, the heat radiation unit and the heat radiation fins, and the protection of the camera module from the heat generated by the infrared LED module or the light emitted from the infrared LED And it is possible to maximize heat dissipation by further mounting a thermoelectric element and a cooling fan.

1 is an exploded perspective view showing an infrared LED surveillance camera according to an embodiment of the present invention;
FIG. 2 is a view showing a coupling relationship between a thermal pad and a heat dissipating unit according to an embodiment of the present invention. FIG.
3 is a view showing a coupling relation between a heat dissipating unit and a housing according to an embodiment of the present invention.
4 is a rear view of a housing showing a holding member according to an embodiment of the present invention;
5 is a view showing an elastic protrusion of a rear cover according to an embodiment of the present invention;

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. In the description, the same components are denoted by the same reference numerals, and the drawings are partially exaggerated in size to accurately describe the embodiments of the present invention, and the same reference numerals denote the same elements in the drawings.

1 is an exploded perspective view showing an infrared LED surveillance camera according to an embodiment of the present invention.

Referring to FIG. 1, an infrared LED surveillance camera 100 according to an embodiment of the present invention includes a camera module 110 including a lens unit 111; An infrared LED module 120 including a plurality of infrared LEDs 122 formed along a periphery of the first insertion opening 121 and having a first insertion opening 121 formed at a central portion thereof to insert the lens portion 111; A thermal pad 130 which is electrically insulative and thermally conductive and is provided to be in contact with the rear surface of the infrared LED module 120 and has a second insertion hole 131 formed at the center thereof corresponding to the infrared LED module 120; A heat dissipating unit 140 having one end thereof coupled to the thermal pad 130; And a housing 150 in which a radiating fin 151 is integrally formed on an outer side wall and the other end of the radiating unit 140 is inserted in contact with an inner side wall.

The camera module 110 includes the lens unit 111 and acquires an image by the light received through the lens unit 111 and transmits the image. The lens unit 111 may include a zoom lens, a filter unit, and a zoom lens control unit.

The zoom lens can change the focal length continuously without changing the focus or aperture value because the focal distance is not fixed, and performs a zoom-in and a zoom-out function. The filter unit is composed of a daytime optical filter for passing visible light and an optical filter for nighttime passing only the infrared band, and filters light incident through the lens unit 111.

The zoom lens control unit generates the zoom lens operation signal based on the day / night signal. More specifically, the zoom lens control unit processes the zoom lens to automatically adjust the zoom distance to the infrared light when the operation mode of the infrared LED surveillance camera 100 is changed from daytime to nighttime, When the operation mode of the zoom lens 100 is changed from night to day, the zoom lens is automatically adjusted to the focal distance with respect to the visible light. When the operation mode of the infrared LED surveillance camera 100 is changed from daytime to nighttime, the zoom lens control unit may increase the aperture of the zoom lens to maximize the sensitivity. At this time, the wavelength of the visible light used in the camera module 110 during the day is 380 to 780 nm, and the infrared light used in the camera module 110 at night is 830 to 880 nm. Therefore, although the focal length may vary due to the difference between the wavelengths of the visible light and the infrared rays, the focal point may be distorted. However, by automatically adjusting the focal length and aperture size of the zoom lens, So that it can be photographed.

As described above, when the operation mode of the infrared LED surveillance camera 100 is changed from daytime to nighttime, only the infrared ray band light passes through the infrared ray surveillance camera 100, so that the illumination device (for example, , A vehicle, and the like), and a sensitivity control circuit may be installed in the camera module 110 to greatly improve sensitivity. In addition, since the visible light is blocked, And by using diffraction phenomenon by moisture of long wavelength, infrared rays, it is possible to improve the fog transmittance by more than 40%, and to provide improved images in the fog area.

The camera module 110 may further include an image pickup unit and a video processing signal unit. The image pickup unit converts a light signal through the lens unit 111 into an electric signal, and the video processing signal unit And converts image information outputted as an electric signal through the image pickup unit into a video signal and outputs the video signal. The image pickup unit may include an image pickup device, which converts an optical image signal input from an external light source through the lens unit 111 into an electric signal in accordance with a vertical synchronization signal and a horizontal synchronization signal. In addition, the camera module 110 is not limited to the configuration, and may be configured in various ways.

The lens unit 111 is inserted into the first insertion hole 121 of the infrared LED module 120 so that the infrared LED 122 can be disposed along the periphery of the lens unit 111, 120 are installed. The infrared LED module 120 is an illuminating means that enables the infrared LED surveillance camera 100 to perform its function even in a dark place where light is not available or light is weak and it is impossible to confirm an object. Since it is useful for surveillance because it can not be done, it is mainly used as illumination means of surveillance camera. The infrared LED module 120 includes the plurality of infrared LEDs 122 and a circuit board, but the configuration is not particularly limited.

In addition, the infrared LED module 120 may be arranged radially from the center of the circuit board by arranging the plurality of infrared LEDs 122 in a line. Since the infrared LED module 120 generates a large amount of heat during the illumination process, the area of the circuit board on which the infrared LED 122 is mounted However, this is limited by securing the light quantity of the camera module 110 and the size of the infrared LED surveillance camera 100. Therefore, it is necessary to arrange the plurality of infrared LEDs 122 in an optimal heat dissipation condition on a circuit board having a predetermined area. The plurality of infrared LEDs 122 are arranged radially from the central portion of the circuit board to the edge, The heat radiation effect is most excellent.

Since the structure and operation principle of the infrared LED 122 and the circuit board included in the infrared LED module 120 are well known in the art, a detailed description thereof will be omitted.

Next, the thermal pad 130 is mounted on the rear surface of the infrared LED module 120. The thermal pad 130 includes the second insertion port 131 at a central portion corresponding to the infrared LED module 120 and electrically connects the infrared LED module 120 to the rear side of the infrared LED module 120. [ And to conduct the heat generated by the infrared LED module 120 to the heat dissipation unit 140. The heat dissipation unit 140 may be formed of an insulating material, If the heat dissipation unit made of metal without the thermal pad 130 is brought into direct contact with the rear surface of the infrared LED module 120, a short circuit may occur and an electric short may be generated. In addition to solving these problems, the heat generated from the infrared LED module 120 can be smoothly transmitted to the heat dissipation unit 140. The thermal pad 130 is formed of a material that can be electrically insulated and has a high thermal conductivity. The thermal pad 130 may be formed of a composite material obtained by mixing a polymer capable of complementing thermal conductivity with an electrically insulating resin (for example, silicone) It is not limited to the material, and it is sufficient to use a material capable of performing insulation and heat radiation.

The thermal pad 130 may form a pattern to improve the insulation and heat radiation function by increasing the adhesion with the infrared LED module 120. The pattern may form a concave pattern corresponding to the protrusion of the infrared LED module 120 or may form a convex pattern corresponding to the concave portion of the infrared LED module 120 so that the infrared LED module 120 may be wider So that the area is closely adhered. In this case, the projecting portion of the infrared LED module 120 may be an electrical connecting means formed at a position where the infrared LED 122 is mounted. In this case, the concave pattern portion of the thermal pad 130 is connected to the infrared LED 122 The thermal pad 130 can be prevented from being electrically connected to the infrared LED module 120 and the infrared LED module 120 can be prevented from being electrically short- So that the thermal efficiency is improved.

In addition, a pair of the heat dissipating units 140 are coupled to the thermal pad 130 at one end thereof. The heat dissipation unit 140 serves to conduct the heat of the thermal pad 130 to the housing 150. The heat dissipation unit 140 may be formed of a metal or metal oxide such as aluminum, magnesium, copper, Al, Mg-based metal materials or two or more composite materials are attracting attention because they are excellent in thermal conductivity, low in cost, and light in weight, but they are not particularly limited to the materials Do not. The heat dissipation unit 140 may have a maximally large area to increase the thermal conductivity and may have as much area as possible so as to contact the inner side wall of the thermal pad 130 and the housing 150, . When one pair of the pair of heat dissipating units 140 is in contact with one end of a pair of the heat dissipating units 140 in a bent shape of a long rectangular metal plate, ',' ∠ ',' <', and the like, but is not particularly limited to the shape, composition, and formation method thereof.

Next, components such as the camera module 110 are inserted into the housing 150 such that the other end of the heat dissipation unit 140 contacts the inner side wall of the housing 150. The housing 150 serves to discharge the heat conducted from the heat dissipating unit 140 to the outside, and the radiating fins 151 may be integrally formed on the outer sidewall to improve the heat dissipating efficiency. The radiating fins 151 are formed to extend in a longitudinal direction of the housing 150. The radiating fins 151 are formed to extend in a longitudinal direction of the housing 150 , It is possible to effectively dissipate heat because the heat dissipating area in contact with air is wider than that formed in a plane. When the radiating fins 151 are integrally formed on the outer side wall of the housing 150, heat is directly received from the radiating unit 140 and is discharged to the outside. Thus, an additional process of coupling the housing and the radiating fin is not required So that it is possible to effectively radiate heat. The housing 150 may be formed of any one metal or metal oxide of aluminum, magnesium, copper, and tungsten having a high thermal conductivity, or an alloy or a plurality of materials of two or more of the metals. The material of the housing 150 is not particularly limited, It would be ideal to use lightweight materials with high strength and high strength. The housing 150 receives components such as the camera module 110 in a hollow internal space and the camera module 110 is mounted on the inner side wall of the housing 150, The camera module 110 may be formed to have a size larger than the size of the camera module 110, and the front surface or the rear surface may be formed to be open, but the present invention is not limited thereto. In addition, although the housing 150 having a box-like shape corresponding to the shape of a general infrared LED surveillance camera is shown in the figure, this is merely an example of the embodiment.

A front glass 153 and a front cover 154 are coupled to the front surface of the housing 150 and a rear cover 155 is coupled to the rear surface of the housing 150.

The infrared LED surveillance camera 100 may include a protruded column 161 formed at each corner so that the camera module 110 can be coupled with the heat dissipating unit 140 while being separated from the heat dissipating unit 140 The camera module 110 is attached to the assembly plate 160 and a plurality of insertion holes 141 are formed in the heat dissipation unit 140 corresponding to the protrusive posts 161, And inserted into the insertion holes 141 corresponding to each other. Since the heat dissipating unit 140 is separated from a heat dissipating path (for example, a heat dissipating unit), the heat dissipating unit 140 is less affected by heat, In addition, the camera module 110 is also stably fixed.

The infrared LED surveillance camera 100 may further include a thermoelectric element 170 that cools the contact surface due to an endothermic reaction on one side and emits heat when an exothermic reaction occurs on the other side. The heat absorbing surface of the thermoelectric element 170 functions to cool the contact surface of the heat dissipating unit 140 by contacting the heat dissipating unit 140. The heat absorbing surface of the thermoelectric element 170 is connected to the heat dissipating unit 140, And the heat generating surface of the thermoelectric element 170 may be provided so as to be in contact with the inner side wall of the housing 150. The heat absorbing surface of the thermoelectric element 170 is located at a middle height between the lower end and the upper end of the heat dissipating unit 140 and the heat generating surface of the thermoelectric element 170 is located at a lower end of the inner side wall of the housing 150, By being positioned at the intermediate height, uniform cooling and heat dissipation can be performed irrespective of height or position.

In the infrared LED monitoring camera 100 according to the present invention, the heating surface of the thermoelectric element 170 is arranged on the inner side wall of the housing 150 The heat generated by the heating surface of the thermoelectric element 170 can be effectively dissipated to the outside without accumulating in the infrared LED surveillance camera 100. [

The heat generated from the heating surface of the thermoelectric element 170 is accumulated in the infrared LED surveillance camera 100 without being radiated to the outside of the infrared LED surveillance camera 100 to increase the temperature of the housing 150, The housing 150 may further include a cooling fan 180 provided on the outside of the housing 150 for more sufficient heat dissipation in order to prevent such a problem because the function of the housing 150 may be deformed or the internal parts of the housing 150 may be damaged You may. The cooling fan 180 may be positioned corresponding to the heat generating surface of the thermoelectric element 170 to intensively cool the heat generating surface of the thermoelectric element 170 generating a lot of heat. In this case, the portion having a high temperature in the housing 150 is rapidly cooled due to the cooling fan 180, and the portion having a low temperature can be gradually cooled through the air, Therefore, overall effective heat dissipation is possible. The cooling fan 180 may be installed at an intermediate height of the outer side wall of the housing 150. In this case, uniform heat dissipation of the housing 150 is possible. In addition, the cooling fan 180 may be provided on the radiating fin 151 so that the radiating fin is more effective. In this case, the portion where the cooling fan 180 is provided is lower in height than other portions, . Thus, the cooling fan 180 can be prevented from protruding, and the portion of the radiator fin having a lower height than the radiator fin portion has a relatively smooth flow of air, thereby effectively dissipating heat. At this time, the height of the radiating fins at the upper and lower ends can be increased and the height of the radiating fins of the intermediate portion can be lowered. By providing the cooling fan 180 to the intermediate portion having a low radiating fin height, So that it is easy to position in correspondence with the thermoelectric element 170 located at the middle height of the inner side wall of the housing 150 and uniform heat radiation is possible. In this case, it is preferable to increase the height of the radiating fins at the upper and lower ends and lower the height of the radiating fins at the middle portion. This is because the wind is hardly blown in the valley The flow of the air is smoothly performed at the lower end of the radiating fin as the height of the radiating fin is low, so that the radiating fin 151 is not particularly limited in its shape and formation method.

And a protective tube 190 having a through hole 191 formed at a central portion thereof to allow the lens unit 111 to be inserted thereinto. The protection tube 190 blocks the light emitted from the infrared LED 122 from being transmitted to the lens unit 111 and transmits heat generated from the infrared LED module 120 to the camera module 110 And can be formed of a material such as carbon, ceramic, synthetic resin, rubber, silicon, etc., which is a material having a heat insulating function, a foam thereof, or two or more compounds. When the protection tube 190 is used, the light emitted from the infrared LED 122 is prevented from being directly transmitted to the lens unit 111, thereby preventing deterioration of image quality due to interference of light, It is possible to protect the camera module 110 from the heat generated from the infrared LED module 120, thereby preventing damage to the internal components of the camera module 110.

In addition, the housing 150 may have a guide groove 152 formed on the inner side wall thereof in the longitudinal direction of the housing 150. The guide groove 152 guides the position of the heat dissipating unit 140 so that the other end of the heat dissipating unit 140 can be closely contacted with the inner side wall of the housing 150 when the other end of the heat dissipating unit 140 is inserted into the housing 150. [ And a part of the heat dissipation unit 140 or the thermoelectric element 170 can be inserted into the heat dissipation unit 140. The heat dissipation unit 140 or the thermoelectric element 170 can be stably supported, So as to increase the cooling effect. When the thermoelectric element 170 is inserted into the guide groove 152, the area of the heat dissipation unit 140 contacting the inner side wall of the housing 150 is widened and the thermoelectric element 170 is stably supported And may have a depth corresponding to the thickness of the thermoelectric element 170 so as to increase the cooling effect. The guide groove 152 may be formed at a middle height of the inner side wall of the housing 150 to uniformly dissipate heat. When the guide groove 152 is formed, a part of the heat dissipating unit 140 inserted into the guide groove 152 Since the thermoelectric element 170 can be positioned at the middle height of the inner side wall of the housing 150, the problem of the poor heat dissipation on the far side can be solved, and uniform heat dissipation can be achieved. In this case, since the position of the cooling fan 180 can correspond to the height of the thermoelectric element 170 only by providing the cooling fan 180 at a middle height of the outer side wall of the housing 150, It is easy to install the cooling fan 180 in correspondence with the position of the thermoelectric element 170. The cooling fan 180 is installed at a middle height of the outer side wall of the housing 150 according to the position of the thermoelectric element 170 So that the housing 150 can be uniformly dissipated. A detailed description of the coupling relationship between the housing 150 and the heat dissipating unit 140 and the thermoelectric element 170 inserted into the housing 150 will be described later.

2 (a) is an exploded perspective view of the thermal pad and the heat dissipating unit, and FIG. 2 (b) is an exploded perspective view of the thermal pad and the heat dissipating unit. Fig.

2, the thermal pad 210 includes a column 212 formed along the periphery of the second insertion port 211 on the rear surface of the surface contacting the infrared LED module, And the protrusions 213 may be formed to have a width corresponding to the thickness of the heat dissipating unit 220 so that the heat dissipating unit 220 can be inserted and coupled thereto. The groove 214 can be formed. The pillar portion 212 guides the position of the heat dissipating unit 220 when the heat dissipating unit 220 is coupled, and the pair of the heat dissipating units 220 are inserted and coupled to the coupling groove 214. The columnar section 212 may be formed in various shapes such as a columnar shape, a triangular columnar shape, and a quadrangular columnar shape in accordance with the shape of the heat dissipation unit 220. The columnar section 212 may protrude at the same height to form a step, The coupling groove 214 may be formed.

The heat-dissipating unit 220 may include a concave portion 221 formed by one pair of the heat-dissipating units 220 at one end thereof to be opened. The concave portion 221 is inserted into the coupling groove 214. When the concave portion 221 is brought into contact with the column portion 212 and a pair of the heat radiating units 220 are brought into contact with each other, The recess 221 is inserted into the coupling groove 214 so that the thermal pad 210 and the heat dissipating unit 220 are coupled to each other. In this way, the heat dissipation unit 220 can be brought into close contact with the thermal pad 210 by inducing the position of the heat dissipation unit 220 to be mutually symmetrical with respect to the camera module, In addition, the bonding force can be increased, which makes it easy to combine without additional devices or processes. The concave portions 221 may be formed in a semicircular shape such as a circle, a rectangle, a triangle, or a rhombus so that a pair of the concave portions 221 are in contact with each other. , And the shape is not particularly limited.

3 is a perspective view of a heat dissipating unit, FIG. 3 (b) is a front view of the housing, FIG. 3 (c) is a front view of the heat dissipating unit, FIG. 3 (d) is a front view of the heat dissipating unit and the thermoelectric element coupled to the housing. FIG.

3, the width of the heat dissipation unit 310 may be equal to the height of the housing 320, and the width of the other end may be the same as the width of the guide groove 321. In addition, the interruption (between one end and the other end) may be formed so as to have an intermediate width between one end and the other end, which may be composed of three stages or more stages. In the case where the width of the heat dissipation unit 310 is three stages, a bent portion 311 may be formed at one end of the heat dissipation unit 310 so that a pair of the heat dissipation units 310 can be brought into contact with each other. And the width of the other end is narrower than the height of the housing 320 when the housing 320 is coupled with the housing 320. Therefore, the heat dissipating unit 310 can be easily inserted .

The heat dissipation unit 310 may have a step 312 formed at the other end of the heat dissipation unit 310 inserted into the inner side wall of the housing 320. The area of the heat dissipation unit 310 can be maximized corresponding to the internal structure of the housing 320 even if the length of the housing 320 is shortened when the step portion 312 is formed, 310 may be inserted into and coupled with the housing 320 to increase the coupling force with the housing 320. The stepped portion 312 may be formed corresponding to the thickness of the thermoelectric element 330 when the thermoelectric element 330 is attached to the heat dissipating unit 310. In this case, The other end of the heat dissipating unit 310 may be in contact with both the heat absorbing surface of the thermoelectric element 330 and the inner side wall of the housing 320 Since the other end of the heat dissipating unit 310 contacting the inner sidewall of the housing 320 and the thermoelectric element 330 are flattened, the heat generating surface of the thermoelectric element 330 is also in contact with the inner sidewall of the housing 320, As shown in FIG. When the width of the heat dissipation unit 310 is three, the other end of the thermoelectric module 330 and the heat dissipation unit 310 are inserted into the guide groove 321, A method of forming the bent portion 311 and the stepped portion 312 of the heat dissipating unit 310 and the method of forming the heat dissipating unit 310 may be formed by considering the size and thickness of the thermoelectric element 330, The shape of the unit 310 is not particularly limited.

4 is a rear view of a housing showing a holding member according to an embodiment of the present invention.

Referring to FIG. 4, at least one fixing member 430 may further be provided on the longitudinal side of the guide groove 411 (of the housing 410). The fixing member 430 presses the other end of the heat dissipating unit 420 inserted into the guide groove 411 with elasticity to closely contact the inner side wall of the housing 410 and uses a material having elasticity It is preferable to use a material having a heat insulating function so that the shape and function are not deformed by the heat of high temperature conducted to the heat dissipating unit 420. There is no particular limitation on the material. The fixing member 430 may be formed on both sides of the fixing member 430 and may be pressed on both sides of the fixing member 430. Alternatively, the fixing member 430 may be formed on only one side of the fixing member 430, Or may be formed only at the other end of the heat-dissipating unit 420. Further, the fixing member 430 may be formed in a shape of a triangle or an elastic pin, and the shape, the forming position, and the forming method are not particularly limited.

5A is a perspective view of a rear cover with an elastic protrusion formed thereon, and FIG. 5B is a view showing a function of an elastic protrusion according to an embodiment of the present invention. FIG. 5A is a perspective view of an elastic protrusion of a rear cover according to an embodiment of the present invention .

Referring to FIG. 5, at least two elastic protrusions 531 may be formed on the rear cover 530 of the infrared LED monitoring camera. The elastic protrusion 531 is inserted into the housing 510 when the rear cover 530 is coupled to the rear surface of the housing 510 and urges the inner side wall of the housing 510 by elasticity And the other end of the heat dissipating unit 520 is in close contact with the inner side wall of the housing 510. The heat dissipating unit 520 can be formed using a material having elasticity, It is preferable to use a material which does not deform the shape and function by heat while releasing the heat well to the outside, but there is no particular limitation on the material. In addition, the elastic protrusions 531 may be formed in two in the middle of the two side portions, and may be four in each of the two side portions corresponding to the upper and lower ends of the other end of the heat dissipating unit 520. In the case where the width of the other end is wide, it is preferable that the width of the heat dissipating unit 520 is broadened so as to be four in two on both sides corresponding to the upper and lower ends of the other end of the heat dissipating unit 520, The elastic protrusions 531 may be formed simply in the form of resilient fins, or may be formed in such a manner that the resilient protrusions 531 are hooked to the rear of the side wall of the housing 510 like a gripper using the principle of a lever. There is no particular limitation.

The infrared LED surveillance camera 100 may further include a day / night determination unit to sense a change in day and night by sensing the illuminance, generate a day / night signal according to the detection result, and transmit the generated day / night signal to the zoom lens control unit. Is about 4 ㏓ or more, and it is judged that it is night when the roughness sensing result is less than about 4..

On the other hand, by installing an optical sensor on the infrared LED surveillance camera 100, day and night can be determined by sensing light intensity. The photosensor can be formed as a CdS photoconductive cell having a characteristic that cadmium sulfide (CdS) is a main component and internal resistance varies according to incident light energy. In the CdS photoconductive cell, the larger the energy of the incident light is, the lower the resistance value becomes. In other words, when there is no light energy, the near-insulator becomes close to the insulator. When the incident energy is received, the internal resistance is reduced corresponding to the incident energy. . This feature has the effect of turning on a street lamp or an apartment stairway at night and turning off during the day, and the optical sensor can also apply the principle of this effect.

As described above, the infrared LED surveillance camera 100 according to the embodiment of the present invention can prevent the electrical short-circuit in the infrared LED module by the insulation function of the thermal pad, and the heat radiation unit can prevent the short- The space that is in contact with the inner side wall in a large area as well as the distance of conduction to the radiating fins of the housing where heat is generated in the heat source is close to allow efficient heat radiation. In addition, the camera module can be protected from the light emitted from the infrared LED or the heat generated from the infrared LED module by the protective tube, and the thermoelectric element and the cooling fan can be further installed to maximize heat dissipation. And a pair of heat dissipation units and a pair of the heat dissipation units are coupled to each other, and the other end of the heat dissipation unit is coupled to the housing The fixing member or the elastic protrusion (of the rear cover) is fixed to the other end of the heat dissipating unit after being inserted into the groove, so that it can be easily and stably coupled without any other apparatus or process. Further, the camera module is spaced apart from one end of the heat dissipating unit by the assembly plate and is separated from the other end of the heat dissipating unit that is in close contact with the inner side wall of the housing, so that the camera module which is weak in heat is less affected by heat .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the embodiments set forth herein. Those skilled in the art will appreciate that various modifications and equivalent embodiments may be possible. Accordingly, the technical scope of the present invention should be defined by the following claims.

100: Infrared LED surveillance camera 110: Camera module
111: Lens part 120: Infrared LED module
121: first insertion port 122: infrared LED
130, 210: thermal pad 131, 211: second insertion hole
140, 220, 310, 420, 520: heat dissipating unit 141:
150, 320, 410, 510: housing 151:
152, 321, 411: guide groove 153: front glass
154: front cover 155, 530: rear cover
160: Assembly plate 161:
170, 330: thermoelectric element 180: cooling fan
190: Protection tube 191: Through hole
212: column portion 213:
214: coupling groove 221:
311: bent portion 312: stepped portion
430: fixing member 531: elastic protrusion

Claims (12)

A camera module including a lens portion;
An infrared LED module including a plurality of infrared LEDs provided along a periphery of the first insertion port, the infrared LED module having a first insertion port formed at a central portion thereof to insert the lens portion;
A thermal pad having a second insertion port formed at a central portion corresponding to the infrared LED module and being provided to be in contact with a rear surface of the infrared LED module and electrically insulative and thermally conductive;
A heat dissipating unit having one end thereof abutted against the thermal pad; And
And a housing in which a radiating fin is integrally formed on an outer side wall and the other end of the radiating unit is inserted in contact with an inner side wall.
The method according to claim 1,
Wherein the thermal pad includes a column portion formed along a periphery of the second insertion port and a protrusion formed at an end portion of the column portion, wherein the column portion and the protrusion portion are formed by an infrared LED having a width corresponding to the thickness of the heat- Surveillance camera.
The method of claim 2,
Wherein the heat dissipation unit comprises a pair of recesses formed in mutually opposing surfaces and the concave portion of the heat dissipation unit is in contact with the column portion of the thermal pad at both sides thereof, LED surveillance camera.
The method according to claim 1,
Wherein the thermal pad is formed of a composite material in which a thermally conductive polymer is mixed with an electrically insulating resin forming a matrix.
The method according to claim 1,
Further comprising a thermoelectric element for cooling the contact surface by absorbing heat on one surface and generating heat on the other surface to emit heat,
Wherein the heat absorbing surface of the thermoelectric element is in contact with the heat dissipating unit and the heat generating surface of the thermoelectric element is in contact with the inner side wall of the housing.
The method of claim 5,
Wherein the housing extends in the longitudinal direction of the housing on an inner side wall, and at least a part of the heat radiating unit or a guide groove into which the thermoelectric element is inserted is formed.
The method of claim 6,
Wherein one end of the heat dissipation unit has the same width as the inner side wall of the housing and the other end has the same width as the guide groove.
The method of claim 5,
Wherein the heat dissipation unit includes a step portion corresponding to a thickness of the thermoelectric element to contact the heat absorbing surface of the thermoelectric element and the inner side wall of the housing.
The method of claim 5,
Further comprising a cooling fan provided corresponding to the position of the thermoelectric element,
Wherein the radiating fins extend in a longitudinal direction of the housing and the radiating fins have a lower height than other portions of the radiating fins.
The method of claim 7,
And the guide groove is formed in the longitudinal side of the housing And a fixing member for pressing the other end of the heat dissipating unit, which is located in the guide groove, by elasticity and closely contact the inner side wall of the housing.
The method according to claim 1,
Further comprising a rear cover coupled to a rear surface of the housing, the rear cover including an elastic projection,
Wherein the elastic protrusion of the rear cover is inserted into the housing when the rear cover is coupled to the housing and contacts the other end of the heat dissipating unit by elasticity to apply force to the inner side wall of the housing.
The method according to claim 1,
Further comprising a protective tube penetrating the center portion so as to insert the lens portion and preventing light emitted from the infrared LED or heat generated from the infrared LED module from being transmitted to the lens portion.

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