CN211509155U - Thermal induction monitoring image acquisition device - Google Patents

Abstract

The utility model discloses a thermoinduction monitoring image collection system, the on-line screen storage device comprises a base, the top fixed mounting of base has first shell body, and one side of first shell body is the opening setting, and fixed mounting has the mounting panel in the first shell body, and one side fixed mounting of mounting panel has thermoinduction camera, and first shell body open-ended one side is equipped with the second shell body, and the both sides of second shell body are the opening setting, and in one side of thermoinduction camera extended to the second shell body, one side fixed mounting that first shell body was kept away from to the second shell body had the glass lens. The utility model relates to a rationally, the practicality is good, is convenient for dismantle the second shell body from first shell body, and is also convenient to the installation of second shell body, need not use specialized tool, only need bare-handed operation can, thermoinduction camera during operation moreover can carry out the forced air cooling heat dissipation to the heat that it produced, has improved the radiating effect, prolongs thermoinduction camera's life.

Description

Thermal induction monitoring image acquisition device

Technical Field

The utility model relates to an image acquisition equipment technical field specifically is a thermoinduction monitoring image collection system.

Background

Nowadays, with the development of society and science and technology, the application range of security monitoring products is wide, and image acquisition equipment is a core component in a security monitoring system, wherein, the use of thermal induction monitoring image acquisition equipment is more and more common, a thermal induction camera is one of the more commonly used thermal induction monitoring image acquisition equipment, the thermal induction camera utilizes the functions of opening, video recording and the like of an infrared thermocouple probe to control the camera, the imaging level of the thermal induction camera is completely changed according to the temperature change of a shot object, the brighter object with higher temperature and the darker object with cooler temperature, and the thermal induction camera is generally composed of a bracket, an outer shell, a camera, a glass lens, a plurality of electrical elements and the like.

However, in the prior art, most of the outer shells of the commonly used thermal induction cameras are fixedly connected through screws, when the internal electrical elements of the thermal induction camera need to be overhauled, the outer shell needs to be disassembled first, in the process of disassembling the outer shell, special tools such as a wrench and the like need to be used, the operation process is complicated, time and labor are wasted, inconvenience is brought to overhaul work, the work efficiency is reduced, the heat dissipation effect of the internal thermal induction camera is not good when the thermal induction camera is used, particularly in hot summer, the internal electrical elements of the thermal induction camera are easily damaged due to the fact that the thermal induction camera is in a high-temperature state for a long time, and the service life of the thermal induction camera is shortened.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

The utility model provides a not enough to prior art, the utility model provides a hot induction monitoring image collection system has solved and has dismantled the in-process to the shell body on the hot induction camera, need use specialized tool such as spanner, the operation process is loaded down with trivial details, waste time and energy, bring inconvenience for maintenance work, reduce work efficiency, and hot induction camera is not good at its inside radiating effect when using moreover, inside being in the high temperature state for a long time of hot induction camera causes its inside electric elements to damage easily, reduces hot induction camera life's problem.

(II) technical scheme

In order to achieve the above object, the utility model provides a following technical scheme: a thermal induction monitoring image acquisition device comprises a base, wherein a first outer shell is fixedly arranged at the top of the base, one side of the first outer shell is provided with an opening, a mounting plate is fixedly arranged in the first outer shell, a thermal induction camera is fixedly arranged at one side of the mounting plate, a second outer shell is arranged at one side of the opening of the first outer shell, both sides of the second outer shell are provided with openings, one side of the thermal induction camera extends into the second outer shell, a glass lens is fixedly arranged at one side of the second outer shell, which is far away from the first outer shell, an annular groove is arranged at one side of the first outer shell, which is close to the second outer shell, an annular seat is fixedly arranged at one side of the second outer shell, which is close to the first outer shell, the annular seat is slidably arranged in the annular groove, fixing plates are fixedly arranged at the top and the bottom of the second outer, equal slidable mounting has the kelly in two first through-holes, the both ends of kelly all extend outside first through-hole, the draw-in groove has all been seted up to the top and the bottom of first shell body, the one end difference slidable mounting that two kellies are close to each other is in corresponding draw-in groove, the connecting plate is all installed firmly to the one end that two kellies kept away from each other, the equal fixed mounting in one side that two connecting plates are close to each other has the spring, two springs are established respectively on corresponding kellies, the one end that two springs are close to each other respectively with corresponding fixed plate fixed connection, two second through-holes have been seted up to one side of mounting panel, two second through-hole symmetries set up the both sides at thermoinduction camera, all rotate in two second through-holes and install the pivot, the both ends of pivot all extend to outside the second through-hole, the equal fixed mounting in one end that two pivots are close to.

Preferably, a motor is fixedly mounted on the inner wall of one side of the first outer shell, a second gear is fixedly mounted on an output shaft end of the motor, and the two first gears are meshed with the second gear.

Preferably, the inner wall of the top of the second outer shell is provided with a heat dissipation hole, and a first dustproof filter screen is fixedly mounted in the heat dissipation hole.

Preferably, the inner wall of the bottom of the second outer shell is provided with an air hole, and a second dustproof filter screen is fixedly arranged in the air hole.

Preferably, a dust guard plate is fixedly mounted at the top of the first outer shell and is obliquely arranged.

Preferably, bearings are fixedly sleeved on the two rotating shafts, and outer rings of the two bearings are fixedly connected with the inner walls of the corresponding second through holes respectively.

(III) advantageous effects

The utility model provides a thermoinduction monitoring image acquisition device. The method has the following beneficial effects:

(1) the thermal induction monitoring image acquisition device has the advantages that the two springs are pulled to move towards the directions away from each other to generate elastic force through tensile deformation, after the two clamping rods are pulled out of the corresponding clamping grooves, the fixation between the second outer shell and the first outer shell is released, the second outer shell can be detached from the first outer shell, so that the electric elements in the first outer shell can be conveniently overhauled, the second outer shell can be rapidly detached without using a special tool, only manual operation is needed, when the second outer shell is assembled back on the first outer shell, the two connecting plates are pulled to move towards the directions away from each other, the two connecting plates drive the corresponding clamping rods to move, the two springs are subjected to the tensile deformation to generate the elastic force, then the annular seat on the second outer shell is inserted into the annular groove, and the two connecting plates are loosened, under the elastic force effect of two springs, make two kellies insert corresponding draw-in grooves respectively in, utilize the joint cooperation of two kellies and two draw-in grooves, accomplish the fixed between second shell body and the first shell body promptly, realized dismantling the quick of second shell body, need not use specialized tool equally, only need bare-handed operation, the simple operation.

(2) This thermal induction monitoring image acquisition device, through work through the starter motor, the motor drives the second gear revolve, the second gear drives two first gears, two pivots and two flabellum rotations, utilize the rotation of two flabellums, the flow of air in first shell body and the second shell body has been accelerated, heat permeable louvre discharges, the permeable bleeder vent of external air gets into in first shell body and the second shell body, thereby carry out the forced air cooling heat dissipation to the heat that produces, the radiating effect has been improved, utilize the dustproof filter screen of first dustproof filter screen and second to block the dust impurity in the external air, the reduction that utilizes the dust board can be great falls to the dust on the dustproof filter screen of first.

Drawings

FIG. 1 is a schematic sectional view of the main view of the present invention;

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is a right side view of the first housing;

fig. 4 is a left side view of the second housing.

In the figure: 1. a base; 2. a first outer case; 3. mounting a plate; 4. a thermal induction camera; 5. a second outer housing; 6. a glass lens; 7. an annular groove; 8. an annular seat; 9. a fixing plate; 10. a first through hole; 11. a clamping rod; 12. a card slot; 13. a connecting plate; 14. a spring; 15. a second through hole; 16. a rotating shaft; 17. a fan blade; 18. a first gear; 19. a motor; 20. a second gear; 21. heat dissipation holes; 22. a first dust screen; 23. air holes are formed; 24. the second dustproof filter screen.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1-4, the utility model provides a technical solution: a thermal induction monitoring image acquisition device comprises a base 1, a first outer shell 2 is fixedly installed at the top of the base 1, one side of the first outer shell 2 is provided with an opening, an installation plate 3 is fixedly installed in the first outer shell 2, a thermal induction camera 4 is fixedly installed at one side of the installation plate 3, a second outer shell 5 is arranged at one side of the opening of the first outer shell 2, both sides of the second outer shell 5 are provided with openings, one side of the thermal induction camera 4 extends into the second outer shell 5, a glass lens 6 is fixedly installed at one side of the second outer shell 5 far away from the first outer shell 2, an annular groove 7 is arranged at one side of the first outer shell 2 close to the second outer shell 5, an annular seat 8 is fixedly installed at one side of the second outer shell 5 close to the first outer shell 2, the annular seat 8 is slidably installed in the annular groove 7, and fixing plates 9 are fixedly installed at, two fixing plates 9 are both of L-shaped structure, one side of each fixing plate 9 far away from each other is provided with a first through hole 10, clamping rods 11 are slidably mounted in the two first through holes 10, two ends of each clamping rod 11 extend out of the first through holes 10, the top and the bottom of the first outer shell 2 are provided with clamping grooves 12, one ends of the two clamping rods 11 close to each other are respectively slidably mounted in the corresponding clamping grooves 12, one ends of the two clamping rods 11 far away from each other are fixedly provided with connecting plates 13, one sides of the two connecting plates 13 close to each other are respectively fixedly provided with springs 14, the two springs 14 are respectively sleeved on the corresponding clamping rods 11, one ends of the two springs 14 close to each other are respectively fixedly connected with the corresponding fixing plates 9, one side of the mounting plate 3 is provided with two second through holes 15, the two second through holes 15 are symmetrically arranged at two sides of the thermal induction camera 4, and rotating shafts 16 are rotatably mounted in the, both ends of the rotating shaft 16 extend to the outside of the second through hole 15, fan blades 17 are fixedly mounted at the ends, close to the glass lenses 6, of the two rotating shafts 16, and first gears 18 are fixedly mounted at the ends, far away from the glass lenses 6, of the two rotating shafts 16.

Fixed mounting has motor 19 on one side inner wall of first shell body 2, the output shaft fixed mounting of motor 19 has second gear 20, two first gears 18 all mesh with second gear 20 mutually, louvre 21 has been seted up on the top inner wall of second shell body 5, fixed mounting has first dustproof filter screen 22 in the louvre 21, bleeder vent 23 has been seted up on the bottom inner wall of second shell body 5, fixed mounting has the dustproof filter screen 24 of second in the bleeder vent 23, the top fixed mounting of first shell body 2 has the dust board, the dust board sets up for the slope, equal fixed cover is equipped with the bearing in two pivots 16, the outer lane of two bearings respectively with the inner wall fixed connection of corresponding second through-hole 15.

When the thermal sensing camera 4 works, the motor 19 also starts to work, when the second outer shell 5 needs to be detached from the first outer shell 2, firstly, the two connecting plates 13 are pulled to move in the direction away from each other, the two connecting plates 13 drive the corresponding clamping rods 11 to slide out of the corresponding clamping grooves 12, the two springs 14 are stretched and deformed to generate elasticity, after the two clamping rods 11 are pulled out of the corresponding clamping grooves 12, the fixation between the second outer shell 5 and the first outer shell 2 is released, the second outer shell 5 can be detached from the first outer shell 2, so that the maintenance of electrical elements in the first outer shell 2 is facilitated, and the rapid detachment of the second outer shell 5 is realized, when the second outer shell 5 is installed back on the first outer shell 2, the two connecting plates 13 are pulled to move in the direction away from each other without using a special tool, the two connecting plates 13 drive the corresponding clamping rods 11 to move, the two springs 14 are stretched and deformed to generate elastic force, then the annular seat 8 on the second outer shell 5 is inserted into the annular groove 7, part of the thermal induction camera 4 is positioned in the second outer shell 5, then the two connecting plates 13 are loosened, the two clamping rods 11 are respectively inserted into the corresponding clamping grooves 12 under the action of the elastic force of the two springs 14, the fixing between the second outer shell 5 and the first outer shell 2 is completed by utilizing the clamping fit of the two clamping rods 11 and the two clamping grooves 12, the quick disassembly of the second outer shell 5 is realized, the use of a special tool is also not needed, the thermal induction camera 4 only needs to be operated by bare hands, the motor 19 drives the second gear 20 to rotate, the second gear 20 drives the two first gears 18 and the two rotating shafts 16 to rotate, the two rotating shafts 16 drive the corresponding fan blades 17 to rotate, the rotation of the two fan blades 17 accelerates the flow of air in the first outer shell 2 and the second outer shell 5, heat is discharged through the heat dissipation holes 21, outside air can enter the first outer shell 2 and the second outer shell 5 through the air holes 23, thereby performing air cooling heat dissipation on heat generated by electrical components inside the thermal induction camera 4, improving the heat dissipation effect, blocking dust impurities in the outside air by using the first dustproof filter screen 22 and the second dustproof filter screen 24, preventing the dust impurities from entering the first outer shell 2 and the second outer shell 5, greatly reducing dust falling on the first dustproof filter screen 22 by using the dust baffle plate, and those not described in detail in this specification are well within the skill of those in the art.

To sum up, the thermal induction monitoring image acquisition device pulls the two connecting plates 13 to move in the direction away from each other, the two springs 14 are stretched and deformed to generate elastic force, so that after the two clamping rods 11 are pulled out of the corresponding clamping grooves 12, the fixation between the second outer shell 5 and the first outer shell 2 is released, the second outer shell 5 can be detached from the first outer shell 2, thereby facilitating the maintenance of the electrical components in the first outer shell 2, realizing the quick detachment of the second outer shell 5, without using a special tool, only needing to operate by bare hands, when the second outer shell 5 is installed back on the first outer shell 2, the two connecting plates 13 are pulled to move in the direction away from each other, the two connecting plates 13 drive the corresponding clamping rods 11 to move, the two springs 14 are stretched and deformed to generate elastic force, and then the annular seat 8 on the second outer shell 5 is inserted into the annular groove 7, two connecting plates 13 are loosened, under the action of the elastic force of two springs 14, two clamping rods 11 are respectively inserted into corresponding clamping grooves 12, the fixation between the second outer shell 5 and the first outer shell 2 is completed by utilizing the clamping fit of the two clamping rods 11 and the two clamping grooves 12, the quick disassembly of the second outer shell 5 is realized, the operation is convenient and fast by only using hands without using special tools, the motor 19 is started to work, the motor 19 drives the second gear 20 to rotate, the second gear 20 drives the two first gears 18, the two rotating shafts 16 and the two fan blades 17 to rotate, the rotation of the two fan blades 17 is utilized to accelerate the air flow in the first outer shell 2 and the second outer shell 5, the heat can be discharged through the heat-radiating holes 21, and the external air can enter the first outer shell 2 and the second outer shell 5 through the air-permeable air holes 23, so as to carry out air-cooling heat radiation on the generated heat, the radiating effect is improved, utilize first dustproof filter screen 22 and the dustproof filter screen 24 of second to stop the dust impurity in the outside air, utilize the reduction that the dust guard can be great to fall to the dust on first dustproof filter screen 22, the utility model relates to a rationally, the practicality is good, be convenient for dismantle second shell 5 from first shell body 2, it is also convenient to the installation of second shell body 5, need not use specialized tool, only need bare-handed operation can, and thermoinduction camera 4 during operation, can carry out the forced air cooling heat dissipation to the heat that it produced, improved the radiating effect, extension thermoinduction camera 4's life.

Claims (6)

1. The utility model provides a thermal induction monitoring image acquisition device, includes base (1), its characterized in that: the glass-reinforced plastic base is characterized in that a first outer shell (2) is fixedly mounted at the top of the base (1), one side of the first outer shell (2) is provided with an opening, a mounting plate (3) is fixedly mounted in the first outer shell (2), a thermal induction camera (4) is fixedly mounted on one side of the mounting plate (3), a second outer shell (5) is arranged on one side of the opening of the first outer shell (2), both sides of the second outer shell (5) are provided with openings, one side of the thermal induction camera (4) extends into the second outer shell (5), a glass lens (6) is fixedly mounted on one side of the second outer shell (5) far away from the first outer shell (2), a ring-shaped groove (7) is formed in one side of the first outer shell (2) close to the second outer shell (5), a ring-shaped seat (8) is fixedly mounted on one side of the second outer shell (5) close to the first outer shell (, the top and the bottom of the second outer shell (5) are fixedly provided with fixed plates (9), the two fixed plates (9) are both of L-shaped structure, one side of each fixed plate (9) far away from each other is provided with a first through hole (10), clamping rods (11) are slidably arranged in the two first through holes (10), two ends of each clamping rod (11) extend out of the first through hole (10), the top and the bottom of the first outer shell (2) are provided with clamping grooves (12), one ends of the two clamping rods (11) close to each other are respectively slidably arranged in the corresponding clamping grooves (12), one ends of the two clamping rods (11) far away from each other are respectively fixedly provided with a connecting plate (13), one sides of the two connecting plates (13) close to each other are respectively fixedly provided with springs (14), the two springs (14) are respectively sleeved on the corresponding clamping rods (11), one ends of the two springs (14) close to each other are respectively fixedly connected with the corresponding fixed plates (9), two second through-holes (15) have been seted up to one side of mounting panel (3), two second through-holes (15) symmetry set up the both sides in thermoinduction camera (4), all rotate in two second through-holes (15) and install pivot (16), the both ends of pivot (16) all extend to outside second through-hole (15), the equal fixed mounting of one end that two pivot (16) are close to glass lens (6) has flabellum (17), the equal fixed mounting of one end that glass lens (6) were kept away from in two pivot (16) has first gear (18).

2. A thermal sensing monitoring image capture device according to claim 1, wherein: the motor (19) is fixedly installed on the inner wall of one side of the first outer shell (2), the second gear (20) is fixedly installed on the output shaft end of the motor (19), and the two first gears (18) are all meshed with the second gear (20).

3. A thermal sensing monitoring image capture device according to claim 1, wherein: the top inner wall of the second outer shell (5) is provided with a heat dissipation hole (21), and a first dustproof filter screen (22) is fixedly installed in the heat dissipation hole (21).

4. A thermal sensing monitoring image capture device according to claim 1, wherein: an air hole (23) is formed in the inner wall of the bottom of the second outer shell (5), and a second dustproof filter screen (24) is fixedly mounted in the air hole (23).

5. A thermal sensing monitoring image capture device according to claim 1, wherein: the top of the first outer shell (2) is fixedly provided with a dust guard plate which is arranged in an inclined manner.

6. A thermal sensing monitoring image capture device according to claim 1, wherein: bearings are fixedly sleeved on the two rotating shafts (16), and outer rings of the two bearings are fixedly connected with the inner walls of the corresponding second through holes (15) respectively.

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