CN114363487A - Self-adaptive digital high-definition camera - Google Patents

Abstract

The invention relates to the technical field of cameras, in particular to a self-adaptive digital high-definition camera which comprises a shell, a device cavity, a camera device, a mounting plate and a first through groove, wherein the device cavity is formed in the shell, the camera device is fixedly mounted on the inner wall of one side of the shell, the mounting plate is fixedly connected to the inner part of the device cavity, the first through groove is formed in the center of one side of the shell, a lens is fixedly mounted on the inner wall of the first through groove, a heating plate is fixedly connected to the outer wall of the center of one side of the shell, a mounting cavity is formed in the mounting plate, and a plurality of first air bags are equidistantly arranged in the mounting cavity. When the camera device works, the first air bag and the first air outlet pipe are matched for use, and high temperature generated by the camera device can be processed at regular time, so that the damage of electronic elements caused by overhigh temperature of the camera device can be prevented, dust at the air inlet can be processed intermittently, and the burden of workers is reduced.

Description

Self-adaptive digital high-definition camera

Technical Field

The invention relates to the technical field of cameras, in particular to a self-adaptive digital high-definition camera.

Background

The digital camera is actually referred to as a digital signal processing camera, that is, the three primary color electric signals obtained by the photoelectric conversion device are still analog signals, but are converted into digital signals in subsequent processing, and a series of digital processing techniques are performed.

But current camera is at the in-process of long-time use, the inside too high condition of temperature that appears easily of camera to lead to inside electronic component's damage easily, and then influence the use of camera, the dust is piled up easily to current camera air intake in addition, needs the manual work to carry out regularly clearance, thereby prevents that the air intake from blockking up the efficiency that influences the cooling.

Therefore, an adaptive digital high-definition camera is provided.

Disclosure of Invention

The invention aims to provide a self-adaptive digital high-definition camera, a motor is turned on to drive a first rotating shaft and a driving wheel to rotate anticlockwise, the driving wheel drives a driven rack to move towards the right side, a connecting plate is extruded by the driven rack to drive a first sliding block to move towards the right side, the first sliding block drives the right side of a first air bag to move at the moment, so that the first air bag pumps air through a first one-way air inlet valve, when the driving wheel rotates to a bottom notch, the left side of the driven rack stops bearing force, at the moment, the first air bag rebounds to conduct sucked air to a first air outlet pipe through a first one-way air outlet valve and then ejects the air from the first air outlet pipe, so that the temperature of a camera device is reduced, when the driven rack begins to rebound, the left side of the driven rack impacts a moving block to enable the moving block to drive a filtering layer at the bottom to move, and through the cooperation between the movable block and the first spring, the movable block is vibrated, so that the dust on the surface of the filter layer can be shaken off, and the problems in the background art are solved.

In order to achieve the purpose, the invention provides the following technical scheme:

a self-adaptive digital high-definition camera comprises a shell, a device cavity, a camera device, a lens, a heating plate, a first through groove, a mounting cavity, a first one-way air inlet valve, a first one-way air outlet valve, a first slider and a connecting plate, wherein the device cavity is arranged in the shell, the camera device is fixedly mounted on the inner wall of one side of the shell, the mounting plate is fixedly connected in the device cavity, the first through groove is arranged in the center of one side of the shell, the lens is fixedly mounted on the inner wall of the first through groove, the heating plate is fixedly connected on the outer wall of the center of one side of the shell, the mounting cavity is arranged in the mounting cavity in an equidistant mode, the top of one side of the first air bag is fixedly provided with the first one-way air inlet valve, the bottom of one side of the first air bag is fixedly provided with the first one-way air outlet valve, the other side of the first air bag is fixedly connected with the first slider, the inside of the mounting cavity is slidably connected with the connecting plate which is fixedly connected with the first slider, it is a plurality of one side that the connecting plate was kept away from to first gasbag is fixed connection with the mounting panel, first one-way air outlet valve one end other end fixedly connected with first outlet duct, first one-way air outlet valve is linked together with first outlet duct, casing outer wall fixed mounting has the motor, the first pivot of motor output end fixedly connected with, first pivot runs through the casing, first pivot is located the inside one end outer wall fixedly connected with action wheel of casing, the meshing of first action wheel outer wall has driven rack, driven rack one end is fixed connection with the connecting plate, driven rack is sliding connection with the mounting panel.

When camera device carries out the during operation, drive first pivot and action wheel through opening the motor and carry out anticlockwise rotation, make the action wheel drive driven rack and remove to the right side, extrude the connecting plate through driven rack, thereby make the connecting plate drive first slider and remove to the right side, first slider drives the right side of first gasbag and removes this moment, thereby make first gasbag through first one-way admission valve extraction air, when the action wheel is rotatory to the bottom opening, driven rack left side stops the atress, first gasbag rebounds this moment, the air that will inhale the entering is conducted to first outlet duct through first one-way air outlet valve, then spout from first outlet duct, thereby realize the cooling to camera device.

Preferably, the number of the first air bags is three, and the opening of the first air outlet pipe faces the camera device.

Through the first one-way air outlet valve and the first air outlet pipe that three first gasbag one side set up to concentrate the heat dissipation to camera device's top, middle part and bottom respectively, thereby improve radiating efficiency.

Preferably, the air inlet has been seted up at casing opposite side center, air inlet top inner wall sliding connection has the movable block, the movable block is located same level with the driven rack, the movable block is close to the first spring of the one end fixedly connected with of air inlet, the movable block is located the bottom one end fixedly connected with filter layer of air inlet inner wall, the filter layer bottom is fixed connection with the air inlet, casing opposite side symmetry fixed mounting has a plurality of gas outlets, gas outlet inner wall fixed mounting has the polymer non-woven fabrics filter layer.

When the first air bag drives the driven rack to rebound, the left side of the driven rack impacts the moving block, so that the moving block drives the filtering layer at the bottom to move, and the moving block vibrates through the matching between the moving block and the first spring, so that dust on the surface of the filtering layer can be shaken off, and the burden of workers is reduced.

Preferably, the outer wall of the camera device is fixedly connected with a heat-conducting plate, and the surface of the heat-conducting plate is provided with an inward concave arc-shaped surface.

The heat that camera device produced is conducted through the heat-conducting plate that sets up at the camera device outer wall, thereby enlarges the area of contact between heat-conducting plate and the gas through setting up the heat-conducting plate into the arc to accelerate the heat dissipation of heat-conducting plate.

Preferably, shells inner wall rotates and is connected with the second pivot, the second pivot is located same axis with the arcwall face of heat-conducting plate one side, equidistant fixedly connected with a plurality of connecting blocks of second pivot outer wall circumference, it is a plurality of connecting block other end fixedly connected with thermal-conductive plastic, the inside coolant liquid that is equipped with of thermal-conductive plastic.

Rebounding the spun gas through the first air bag, blowing the heat-conducting plastic through the first air outlet pipe, and further enabling the heat-conducting plastic to drive the connecting block to rotate on the outer wall of the second rotating shaft, so that the cooling liquid inside the heat-conducting plastic can circularly adsorb the heat of the heat-conducting plate, and the heat-radiating efficiency can be accelerated.

Preferably, the inside symmetry of installation cavity is equipped with a plurality of second gasbags, and is a plurality of the second gasbag is a plurality of the one-way admission valve of second gasbag one end top fixedly connected with second, and is a plurality of the one-way air outlet valve of second gasbag one end bottom fixedly connected with second, the one-way air outlet valve of second other end fixedly connected with second outlet duct, the one-way air outlet valve of second is linked together, and is a plurality of second gasbag other end fixedly connected with second slider, the second slider other end is fixed connection, and is a plurality of one side that the connecting plate was kept away from to the second gasbag is fixed connection with the mounting panel.

When the motor drives first pivot and action wheel and carries out anticlockwise rotation, the action wheel drives driven rack and removes to the right side, the in-process that removes at driven rack drives the connecting plate and removes, make the connecting plate drive the second slider and remove to the right side, the second gasbag begins to inhale outside air through the one-way admission valve of second this moment, when rotatory to the opening in action wheel bottom, action wheel and driven rack temporarily contactless, the second gasbag begins to kick-back, gaseous through the one-way air outlet valve of second and second outlet duct blowout this moment.

Preferably, the second outlet duct is fixed connection with the heating plate, the other end of the second outlet duct penetrates through the heating plate and the opening faces the lens, and heating wires are fixedly mounted on the inner wall of the heating plate.

When the camera device works in the weather with high humidity, the heating wire is electrified when the camera device is used, the gas sprayed by the second outlet pipe enters the heating plate, the temperature of the gas is raised through the heating wire inside the heating plate, and the hot air is sprayed out towards one end of the lens through the second outlet pipe, so that the defogging effect on the lens is achieved.

Preferably, casing bottom center is equipped with the tripod mount pad, tripod mount pad bottom center sliding connection has tensile piece, tensile piece top symmetry fixedly connected with connects the rope, and is a plurality of connect the equal fixedly connected with joint piece of the rope other end, the tripod mount pad is sliding connection with the joint piece, the joint piece is close to the one end fixedly connected with second spring of tripod mount pad, the second spring other end is fixed connection with the tripod mount pad, the casing bottom be equipped with the draw-in groove of joint piece looks adaptation.

When camera device needs fixed use, through tensile piece of downward stretching for tensile piece drives the joint piece through connecting the rope and draws close to tripod mount pad center, and the joint piece extrudees the second spring at the in-process that removes, then places the draw-in groove of camera device bottom at tripod mount pad top, loosens the tensile to tensile piece this moment, then inside the resilience entering draw-in groove of joint piece through the second spring, thereby the completion was fixed between tripod mount pad and the camera device.

Preferably, one end of the driven rack close to the moving block is fixedly connected with a buffer layer, and the buffer layer is made of nylon.

The impact force generated between the driven rack and the moving block is reduced through the buffer layer, and the service life of the buffer layer can be prolonged while noise is reduced.

Preferably, the center of the top of the shell is fixedly connected with a handle, the outer wall of the handle is fixedly connected with an anti-slip layer, the outer wall of the shell is fixedly connected with a controller, and the controller is electrically connected with the motor.

The handle and the controller are convenient for a user to move and control the camera shooting device to use.

Compared with the prior art, the invention has the beneficial effects that:

1. when the camera device works, the first air bag and the first air outlet pipe are matched for use, and high temperature generated by the camera device can be processed at regular time, so that the damage of electronic elements caused by overhigh temperature of the camera device can be prevented, dust at the air inlet can be processed intermittently, and the burden of workers is reduced.

2. The invention can remove dust on the surface of the lens by matching the second air bag and the second air outlet pipe, and can open the heating wire to remove the fog on the lens under the condition of high humidity.

3. The invention provides a tripod mounting base which is convenient to mount and dismount, so that a camera can be conveniently positioned and used.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the overall cross-sectional structure of the first and second airbags of the present invention when inflated;

FIG. 3 is a schematic view of the overall cross-sectional structure of the first and second air bags of the present invention during air injection;

FIG. 4 is a side sectional view of the mounting plate of the present invention;

FIG. 5 is an enlarged view of the structure at A in FIG. 2;

FIG. 6 is an enlarged view of the structure at B in FIG. 2;

FIG. 7 is a schematic diagram of a cross-sectional side view of the heating plate of the present invention;

fig. 8 is an enlarged view of the structure at C of fig. 2.

In the figure: the camera comprises a shell body 1, a device cavity 2, a camera device 3, a mounting plate 4, a first through groove 5, a lens 6, a heating plate 7, a mounting cavity 8, a first air bag 9, a first one-way air inlet valve 10, a first one-way air outlet valve 11, a first sliding block 12, a connecting plate 13, a first air outlet pipe 14, a motor 15, a first rotating shaft 16, a driving wheel 17, a driven rack 18, an air inlet 19, a moving block 20, a first spring 21, a filtering layer 22, an air outlet 23, a heat conducting plate 24, a second rotating shaft 25, a connecting block 26, heat conducting plastic 27, a second air bag 28, a second one-way air inlet valve 29, a second air outlet valve 30, a second sliding block 31, a second air outlet pipe 32, a heating wire 33, a tripod mounting seat 34, a stretching block 35, a connecting rope 36, a clamping block 37, a second spring 38, a clamping groove 39, a handle 40 and a controller 41.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, features defined as "first", "second", may explicitly or implicitly include one or more of the described features. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise. Furthermore, the terms "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 8, the present invention provides a self-adaptive digital high-definition camera, which has the following technical scheme:

a self-adaptive digital high-definition camera comprises a shell 1, a device cavity 2, a camera device 3, a mounting plate 4, a first through groove 5, a lens 6, a heating plate 7, a first one-way air inlet valve 10, a first one-way air outlet valve 11, a first slide block 12, a connecting plate 13 and a first slide block 12, wherein the device cavity 2 is arranged in the shell 1, the camera device 3 is fixedly arranged on the inner wall of one side of the shell 1, the mounting plate 4 is fixedly connected with the inner wall of one side of the device cavity 2, the first through groove 5 is arranged in the center of one side of the shell 1, the lens 6 is fixedly arranged on the inner wall of the first through groove 5, the heating plate 7 is fixedly connected with the outer wall of the center of one side of the shell 1, the mounting cavity 8 is arranged in the mounting plate 4, a plurality of first air bags 9 are equidistantly arranged in the mounting cavity, the top of one side of each first air bag 9 is fixedly arranged with the first one-way air inlet valve 10, the bottom of one side of each first air bag 9 is fixedly arranged with the first one-way air outlet valve 11, the other side of each first air bag 9 is fixedly connected with the first slide block 12, the other side of each first air bag 9, the first slide block 12 is connected with the connecting plate 13 in the mounting cavity 8, one side that connecting plate 13 was kept away from to a plurality of first air bags 9 is fixed connection with mounting panel 4, the first outlet duct 14 of 11 one-way air outlet valve other end fixedly connected with of first one-way, first one-way air outlet valve 11 is linked together with first outlet duct 14, 1 outer wall fixed mounting of casing has motor 15, 15 output end fixedly connected with of motor 16 first pivot 16, first pivot 16 runs through casing 1, first pivot 16 is located the inside one end outer wall fixedly connected with action wheel 17 of casing 1, 17 outer wall meshing of first action wheel has driven rack 18, 18 one end of driven rack is fixed connection with connecting plate 13, driven rack 18 is sliding connection with mounting panel 4.

When camera device 3 carries out the during operation, carry out anticlockwise rotation through opening motor 15 and drive wheel 16 of drive, make drive wheel 17 drive driven rack 18 and remove to the right side, through driven rack 18 extrusion connecting plate 13, thereby make connecting plate 13 drive first slider 12 and remove to the right side, first slider 12 drives the right side of first gasbag 9 and removes this moment, thereby make first gasbag 9 through first one-way admission valve 10 extraction air, when drive wheel 17 is rotatory to the bottom opening, 18 left sides of driven rack stop the atress, first gasbag 9 rebounds this moment, the air that will inhale the entering conducts to first outlet duct 14 through first one-way air outlet valve 11, then from 14 blowout of first outlet duct, thereby realize the cooling to camera device 3.

Referring to fig. 2 and 3, as an embodiment of the present invention, the number of the first air cells 9 is three, and the opening of the first air outlet tube 14 faces the image pickup device 3.

Through the first one-way air outlet valve 11 and the first air outlet pipe 14 that set up in three first gasbag 9 one side to concentrate the heat dissipation to camera device 3's top, middle part and bottom respectively, thereby improve radiating efficiency.

As an embodiment of the present invention, referring to fig. 2, 3 and 5, an air inlet 19 is formed in the center of the other side of the housing 1, a moving block 20 is slidably connected to the inner wall of the top of the air inlet 19, the moving block 20 and the driven rack 18 are located at the same horizontal height, a first spring 21 is fixedly connected to one end of the moving block 20 close to the air inlet 19, a filter layer 22 is fixedly connected to one end of the moving block 20 located at the bottom of the inner wall of the air inlet 19, the bottom of the filter layer 22 is fixedly connected to the air inlet 19, a plurality of air outlets 23 are symmetrically and fixedly installed on the other side of the housing 1, and a polymer non-woven fabric filter layer 22 is fixedly installed on the inner wall of the air outlet 23.

When the first air bag 9 drives the driven rack 18 to rebound, the left side of the driven rack 18 impacts the moving block 20, so that the moving block 20 drives the bottom filtering layer 22 to move, and the moving block 20 vibrates through the matching between the moving block 20 and the first spring 21, so that dust on the surface of the filtering layer 22 can be shaken off, and the burden of workers is reduced.

Referring to fig. 2 and 3, as an embodiment of the present invention, a heat conducting plate 24 is fixedly connected to an outer wall of the image pickup device 3, and an arc surface recessed inward is provided on a surface of the heat conducting plate 24.

The heat generated by the camera device 3 is conducted through the heat conduction plate 24 provided on the outer wall of the camera device 3, and the heat conduction plate 24 is formed into an arc shape to enlarge the contact area between the heat conduction plate 24 and the gas, thereby accelerating the heat dissipation of the heat conduction plate 24.

Referring to fig. 2, 3 and 6, as an embodiment of the present invention, a second rotating shaft 25 is rotatably connected to an inner wall of the casing 1, the second rotating shaft 25 and an arc-shaped surface of one side of the heat conducting plate 24 are located on the same axis, a plurality of connecting blocks 26 are fixedly connected to an outer wall of the second rotating shaft 25 at equal intervals in a circumferential direction, heat conducting plastic 27 is fixedly connected to the other ends of the plurality of connecting blocks 26, and cooling fluid is provided inside the heat conducting plastic 27.

Rebounding the ejected gas through the first air bag 9, blowing the heat conducting plastic 27 through the first air outlet pipe 14, further enabling the heat conducting plastic 27 to drive the connecting block 26 to rotate on the outer wall of the second rotating shaft 25, and enabling the cooling liquid inside the heat conducting plastic 27 to circularly adsorb the heat of the heat conducting plate 24, so that the heat dissipation efficiency can be accelerated.

Referring to fig. 2 and 3, a plurality of second air bags 28 are symmetrically arranged inside the mounting cavity 8, a second one-way air inlet valve 29 is fixedly connected to the top of one end of each of the plurality of second air bags 28, a second one-way air outlet valve 30 is fixedly connected to the bottom of one end of each of the plurality of second air bags 28, a second air outlet pipe 32 is fixedly connected to the other end of each of the plurality of second air bags 30, the second one-way air outlet valve 30 is communicated with the second air outlet pipe 32, a second sliding block 31 is fixedly connected to the other end of each of the plurality of second air bags 28, the other end of each of the second sliding blocks 31 is fixedly connected to the connecting plate 13, and one side of each of the plurality of second air bags 28, which is far away from the connecting plate 13, is fixedly connected to the mounting plate 4.

When the motor 15 drives the first rotating shaft 16 and the driving wheel 17 to rotate anticlockwise, the driving wheel 17 drives the driven rack 18 to move towards the right side, the connecting plate 13 is driven to move in the moving process of the driven rack 18, the connecting plate 13 drives the second sliding block 31 to move towards the right side, at the moment, the second air bag 28 starts to suck external air through the second one-way air inlet valve 29, when the bottom of the driving wheel 17 rotates to the opening, the driving wheel 17 is temporarily not in contact with the driven rack 18, the second air bag 28 starts to rebound, and at the moment, the air is sprayed out through the second one-way air outlet valve 30 and the second air outlet pipe 32.

Referring to fig. 2, 3 and 7, as an embodiment of the present invention, a second air outlet 32 is fixedly connected to the heating plate 7, the other end of the second air outlet 32 penetrates through the heating plate 7, an opening of the second air outlet faces the lens 6, and a heating wire 33 is fixedly mounted on an inner wall of the heating plate 7.

When the camera device 3 works in the weather with high humidity, the heating wire 33 is electrified when the camera device 3 is used, the gas sprayed by the second air outlet pipe 32 enters the heating plate 7 at the moment, the temperature of the gas is raised by the heating wire 33 inside the heating plate 7, and the hot air is sprayed towards one end of the lens 6 through the second air outlet pipe 32 at the moment, so that the defogging effect on the lens 6 is achieved.

Referring to fig. 2 and 8, as an embodiment of the present invention, a tripod mounting base 34 is disposed at the center of the bottom of the casing 1, an extension block 35 is slidably connected to the center of the bottom of the tripod mounting base 34, connection ropes 36 are symmetrically and fixedly connected to the top of the extension block 35, a clamping block 37 is fixedly connected to the other ends of the connection ropes 36, the tripod mounting base 34 is slidably connected to the clamping block 37, a second spring 38 is fixedly connected to one end of the clamping block 37 close to the tripod mounting base 34, the other end of the second spring 38 is fixedly connected to the tripod mounting base 34, and a clamping groove 39 adapted to the clamping block 37 is disposed at the bottom of the casing 1.

When camera device 3 needs fixed use, through tensile piece 35 of downwardly stretching, make tensile piece 35 drive joint piece 37 through connecting rope 36 and draw close to tripod mount pad 34 center, joint piece 37 extrudees second spring 38 at the in-process that removes, then place the draw-in groove 39 of camera device 3 bottom at tripod mount pad 34 top, loosen the tensile to tensile piece 35 this moment, then inside joint piece 37 gets into draw-in groove 39 through the resilience of second spring 38, thereby accomplish the fixed between tripod mount pad 34 and the camera device 3.

Referring to fig. 2 and 3, as an embodiment of the present invention, a buffer layer is fixedly connected to one end of the driven rack 18 close to the moving block 20, and the buffer layer is made of nylon.

The buffer layer reduces the impact force generated between the driven rack 18 and the moving block 20, thereby reducing noise and prolonging the service life.

Referring to fig. 1, a handle 40 is fixedly connected to the center of the top of a housing 1, an anti-slip layer is fixedly connected to the outer wall of the handle 40, a controller 41 is fixedly connected to the outer wall of the housing 1, and the controller 41 is electrically connected to a motor 15.

The user is facilitated to move and control the use of the camera device 3 by the handle 40 and the controller 41.

The working principle is as follows: when the camera device 3 works, the motor 15 is turned on to drive the first rotating shaft 16 and the driving wheel 17 to rotate counterclockwise, so that the driving wheel 17 drives the driven rack 18 to move to the right, the connecting plate 13 is extruded by the driven rack 18, the connecting plate 13 drives the first sliding block 12 and the second sliding block 31 to move to the right at the same time, at this time, the first sliding block 12 drives the right of the first air bag 9 to move, so that the first air bag 9 pumps air through the first one-way air inlet valve 10, the second sliding block 31 drives the right of the second air bag 28 to move, air is pumped through the second one-way air inlet valve 29, when the driving wheel 17 rotates to a bottom notch, the left side of the driven rack 18 stops being stressed, at this time, the first air bag 9 and the second air bag 28 rebound at the same time, the first air bag 9 conducts the sucked air to the first air outlet pipe 14 through the first one-way air outlet valve 11, then the air is sprayed out from the first air outlet pipe 14, thereby cooling the camera device 3 is realized, the second air bag 28 is sprayed out through the second one-way air outlet valve 30 and the second air outlet pipe 32, thereby dust is removed from the lens 6, when the humidity in the air is higher, the heating wire 33 can be electrified, the temperature of the air is raised through the heating wire 33 inside the heating plate 7, at the moment, the hot air is sprayed out towards one end of the lens 6 through the second air outlet pipe 32, thereby the effect of defogging the lens 6 is achieved, when the first air bag 9 drives the driven rack 18 to rebound, the left side of the driven rack 18 impacts the moving block 20, so that the moving block 20 drives the filter layer 22 at the bottom to move, and through the matching use between the moving block 20 and the first spring 21, the moving block 20 vibrates, thereby dust on the surface of the filter layer 22 can be shaken off, thereby the burden of workers is reduced, the gas ejected by the rebound of the first air bag 9 blows the heat conductive plastic 27 through the first air outlet pipe 14, so that the thermally conductive plastic 27 drives the connecting block 26 to rotate on the outer wall of the second rotating shaft 25, so that the cooling liquid inside the thermal conductive plastic 27 can circularly absorb the heat of the thermal conductive plate 24, thereby, the heat dissipation efficiency can be improved, and when the camera device 3 needs to be fixedly used, by stretching the stretching block 35 downward, so that the stretching block 35 drives the clamping block 37 to approach to the center of the tripod mounting seat 34 through the connecting rope 36, the clamping block 37 extrudes the second spring 38 in the moving process, the catch 39 at the bottom of the camera 3 is then placed on top of the tripod mount 34, at which point the tension on the tension block 35 is released, then, the clip block 37 enters the inside of the clip groove 39 by the rebound of the second spring 38, thereby completing the fixation between the tripod mounting base 34 and the image pickup device 3.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. An adaptive digital high definition camera comprises a shell (1);

the device cavity (2) is arranged in the shell (1);

the camera device (3) is fixedly arranged on the inner wall of one side of the shell (1);

the mounting plate (4) is fixedly connected to the inside of the device cavity (2);

the first through groove (5) is formed in the center of one side of the shell (1), and a lens (6) is fixedly mounted on the inner wall of the first through groove (5);

the heating plate (7) is fixedly connected to the outer wall of the center of one side of the shell (1);

the method is characterized in that:

the mounting plate (4) is internally provided with a mounting cavity (8), a plurality of first air bags (9) are arranged in the mounting cavity (8) at equal intervals, a plurality of first one-way air inlet valves (10) are fixedly arranged at the top of one side of the first air bags (9), a plurality of one-way air outlet valves (11) are fixedly arranged at the bottom of one side of the first air bags (9), a plurality of first sliding blocks (12) are fixedly connected with the other side of the first air bags (9), a connecting plate (13) is slidably connected in the mounting cavity (8), the connecting plate (13) is fixedly connected with the first sliding blocks (12), a plurality of one sides of the first air bags (9) far away from the connecting plate (13) are fixedly connected with the mounting plate (4), one end of the first one-way air outlet valves (11) is fixedly connected with a first air outlet pipe (14), the first one-way air outlet valves (11) are communicated with the first air outlet pipe (14), casing (1) outer wall fixed mounting has motor (15), motor (15) output end fixedly connected with first pivot (16), casing (1) is run through in first pivot (16), first pivot (16) are located inside one end outer wall fixedly connected with action wheel (17) of casing (1), the meshing of first action wheel (17) outer wall has driven rack (18), driven rack (18) one end is fixed connection with connecting plate (13), driven rack (18) are sliding connection with mounting panel (4).

2. An adaptive digital high definition camera according to claim 1, characterized in that: the number of the first air bags (9) is three, and the opening of the first air outlet pipe (14) faces the camera device (3).

3. An adaptive digital high definition camera according to claim 1, characterized in that: air inlet (19) have been seted up at casing (1) opposite side center, air inlet (19) top inner wall sliding connection has movable block (20), movable block (20) are located same level with driven rack (18), first spring (21) of one end fixedly connected with that movable block (20) are close to air inlet (19), bottom one end fixedly connected with filter layer (22) that movable block (20) are located air inlet (19) inner wall, filter layer (22) bottom is fixed connection with air inlet (19), casing (1) opposite side symmetry fixed mounting has a plurality of gas outlets (23), gas outlet (23) inner wall fixed mounting has polymer non-woven fabrics filter layer (22).

4. An adaptive digital high definition camera according to claim 1, characterized in that: the outer wall of the camera device (3) is fixedly connected with a heat conduction plate (24), and the surface of the heat conduction plate (24) is provided with an inward concave arc-shaped surface.

5. An adaptive digital high definition camera according to claim 4, characterized in that: casing (1) inner wall rotates and is connected with second pivot (25), second pivot (25) are located same axis with the arcwall face of heat-conducting plate (24) one side, a plurality of connecting blocks (26) of equidistant fixedly connected with of second pivot (25) outer wall circumference, and are a plurality of connecting block (26) other end fixedly connected with thermal-conductive plastic (27), thermal-conductive plastic (27) inside is equipped with the coolant liquid.

6. An adaptive digital high definition camera according to claim 1, characterized in that: the inside symmetry of installation cavity (8) is equipped with a plurality of second gasbag (28), and is a plurality of second gasbag (28) one end top fixedly connected with one-way admission valve of second (29), a plurality of one-way air outlet valve of second gasbag (28) one end bottom fixedly connected with second (30), one-way air outlet valve of second (30) other end fixedly connected with second outlet duct (32), one-way air outlet valve of second (30) is linked together with second outlet duct (32), and is a plurality of second gasbag (28) other end fixedly connected with second slider (31), the second slider (31) other end is fixed connection, and is a plurality of one side and mounting panel (4) that connecting plate (13) were kept away from to second gasbag (28) are fixed connection.

7. An adaptive digital high definition camera according to claim 6, characterized in that: second outlet duct (32) are fixed connection with heating plate (7), the second outlet duct (32) other end runs through heating plate (7) and opening part towards camera lens (6), heating plate (7) inner wall fixed mounting has heater strip (33).

8. An adaptive digital high definition camera according to claim 1, characterized in that: casing (1) bottom center is equipped with tripod mount pad (34), tripod mount pad (34) bottom center sliding connection has tensile piece (35), tensile piece (35) top symmetry fixedly connected with connects rope (36), and is a plurality of connect the equal fixedly connected with joint piece (37) of rope (36) other end, tripod mount pad (34) are sliding connection with joint piece (37), one end fixedly connected with second spring (38) that joint piece (37) are close to tripod mount pad (34), the second spring (38) other end is fixed connection with tripod mount pad (34), casing (1) bottom is equipped with draw-in groove (39) with joint piece (37) looks adaptation.

9. An adaptive digital high definition camera according to claim 3, characterized in that: one end of the driven rack (18) close to the moving block (20) is fixedly connected with a buffer layer, and the buffer layer is made of nylon.

10. An adaptive digital high definition camera according to claim 1, characterized in that: casing (1) top center fixedly connected with handle (40), handle (40) outer wall fixedly connected with skid resistant course, casing (1) outer wall fixedly connected with controller (41), controller (41) and motor (15) are electric connection.

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