CN219036134U - Image target detection device based on recognition dynamic state - Google Patents

Abstract

The utility model relates to the technical field of image target detection devices, in particular to an image target detection device based on identification dynamic, which comprises: the rain cover is fixedly connected to the top of the detection device body; the two first movable grooves are respectively arranged on two sides of the rain cover and are communicated with the inner cavity of the rain cover, and a rotating rod is movably connected between the two first movable grooves; the utility model solves the problem that the shooting lens can generate fog to influence the use of a user when the weather is cold, and solves the problem that the user can find dead angles which cannot be shot under or over the shooting lens and need to reinstall and adjust angles when the shooting lens is used after the installation is finished.

Description

Image target detection device based on recognition dynamic state

Technical Field

The utility model relates to the technical field of image target detection devices, in particular to an image target detection device based on identification dynamic.

Background

The dynamic image target identification detection device is a common camera device for monitoring a specific area in real time, is widely applied to the field of safety protection, such as various aspects of business, military, home, public facilities and the like, and is one of important technological products in modern life. The camera includes camera body and mount pad, and the camera needs to be installed on wall or desktop, and the mount pad is used for fixed mounting camera, and the camera can rotate on the mount pad.

In the conventional outdoor dynamic image target detection device, when the weather is cold, because the dynamic image target detection device has a certain amount of heat in the dynamic image target detection device, fog is generated on a shooting lens of the dynamic image target detection device, so that a user can blur a picture when the dynamic image target detection device is used, dead angles which cannot be shot are often found below or above a shooting lens when the dynamic image target detection device is used after the user installs the dynamic image target detection device, and because the dynamic image target detection device is installed, the user is required to detach the dynamic image target detection device for reinstallation and adjust the angle, so that we propose the dynamic image target detection device based on the dynamic image target detection device to solve the problems.

Disclosure of Invention

The present utility model is directed to an image object detection device based on recognition dynamic, so as to solve the problems set forth in the background art.

The technical scheme of the utility model is as follows: an image object detection apparatus based on recognition dynamics, comprising:

the rain cover is fixedly connected to the top of the detection device body;

the two first movable grooves are respectively arranged on two sides of the rain cover and are communicated with the inner cavity of the rain cover, and a rotating rod is movably connected between the two first movable grooves;

the sponge is fixedly connected to the periphery of the rotating rod and is positioned in the inner cavity of the rainproof cover;

the driving mechanism is positioned in the rain cover and is used for driving the rotating rod to move between the two first movable grooves;

the fixed block is rotationally connected to one side of the detection device body, and one side of the fixed block is fixedly connected with a fixed plate;

the fixing mechanism is positioned between the detection device body and the fixing block and used for fixing the detection device body on the fixing block.

Preferably, the sponge is movably connected with the rain cover, and the sponge is closely attached to the shooting lens of the detection device body.

Preferably, the driving mechanism includes:

the placing groove is formed in the rain cover, a miniature motor is fixedly connected in the placing groove, and an output shaft of the miniature motor penetrates through the placing groove and extends to the outside;

the rotating plate is fixedly connected to the output shaft of the miniature motor, a second movable groove communicated with the outside is formed in the rotating plate, one end of the rotating rod penetrates through one of the first movable grooves and extends into the second movable groove, and the second movable groove is movably connected with the rotating rod.

Preferably, the output shaft of the miniature motor is rotationally connected with the rain cover, and two ends of the second movable groove are semicircular and have the same diameter as the rotating rod.

Preferably, the fixing mechanism includes:

the fixing holes are formed in one side of the detection device body;

the first sliding groove is formed in the fixed block and is communicated with one of the fixed holes, and the top of the first sliding groove is provided with a second sliding groove communicated with the outside;

the sliding block is connected in the first sliding groove in a sliding manner, the sliding block is in plug-in fit with the corresponding fixing hole, a slot is formed in the top of the sliding block, and one end of the sliding block is fixedly connected with a spring fixed with the inner wall of the first sliding groove;

the inserting block is connected in the second sliding groove in a sliding mode, and the inserting block is matched with the inserting groove in an inserting mode.

Preferably, the fixing holes are arranged in an annular equidistant manner, the bottom ends of the inserting blocks are of inclined structures, and the inserting grooves are of right-angled triangle structures.

The utility model provides an image target detection device based on recognition dynamic through improvement, which has the following improvements and advantages compared with the prior art:

the method comprises the following steps: according to the utility model, through the cooperation between the detection device body, the first movable groove, the rotating rod, the sponge, the micro motor, the rotating plate and the second movable groove, when fog is generated on the shooting lens of the detection device body, the micro motor is started, the output shaft of the micro motor drives the rotating plate to rotate positively and negatively, the rotating plate drives the rotating rod and the sponge to move up and down along the first movable groove through the second movable groove, and when the rotating rod and the sponge move to the position incapable of moving, the sponge wipes the fog generated on the shooting lens of the detection device body, so that the problem that the use of a user is affected by the fog generated on the shooting lens when weather is cold is solved.

And two,: according to the utility model, through the cooperation between the detection device body, the fixed block, the fixed hole, the sliding block, the slot, the spring and the inserting block, when the dead angle which cannot be shot is found below or above the detection device body, the inserting block is pressed by hand, the bottom end of the inserting block drives the sliding block to move away from the fixed hole through the extrusion slot, one end of the sliding block enters the first sliding groove from the corresponding fixed hole, at the moment, the user rotates the detection device body, when the detection device body rotates to a proper position, the user releases the hand which presses the inserting block, one end of the sliding block is contacted with one side of the detection device body under the action of spring rebound force, when the first sliding groove is communicated with the corresponding fixed hole, one end of the sliding block enters the corresponding fixed hole from the first sliding groove under the action of spring rebound force, at the moment, the detection device body is fixed on the fixed block, and the problem that the dead angle which cannot be shot is found right below or above the shooting lens and the angle needs to be reinstalled and adjusted is solved when the user is used after installation is completed.

Drawings

The utility model is further explained below with reference to the drawings and examples:

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

FIG. 2 is one of the schematic cross-sectional structural views of the rain cover of the present utility model;

FIG. 3 is a second schematic cross-sectional view of the rain cover of the present utility model;

FIG. 4 is one of the schematic cross-sectional structural views of the fixing block of the present utility model;

FIG. 5 is a second schematic cross-sectional view of the fixing block of the present utility model;

fig. 6 is a schematic view of a partial explosion structure of the present utility model.

Reference numerals illustrate:

1. a detection device body; 2. a rain cover; 3. a first movable groove; 4. a rotating rod; 5. a sponge; 6. a fixed block; 7. a fixing plate; 8. a micro motor; 9. a rotating plate; 10. a second movable groove; 11. a fixing hole; 12. a first chute; 13. a second chute; 14. a slide block; 15. a slot; 16. a spring; 17. inserting blocks; 18. and (5) placing a groove.

Detailed Description

The following detailed description of the present utility model clearly and fully describes the technical solutions of the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The utility model provides an image target detection device based on identification dynamic through improvement, and the technical scheme of the utility model is as follows:

as shown in fig. 1 to 6, the technical scheme of the present utility model is as follows: an image object detection apparatus based on recognition dynamics, comprising:

the rain cover 2 and the detection device body 1 are fixedly connected with the top of the detection device body 1;

the two first movable grooves 3 are respectively arranged on two sides of the rain cover 2 and are communicated with the inner cavity of the rain cover 2, and a rotating rod 4 is movably connected between the two first movable grooves 3;

the sponge 5 is fixedly connected to the periphery of the rotating rod 4 and is positioned in the inner cavity of the rain cover 2;

the driving mechanism is positioned in the rain cover 2 and used for driving the rotating rod 4 to move between the two first movable grooves 3;

the fixed block 6 is rotatably connected to one side of the detection device body 1, and one side of the fixed block 6 is fixedly connected with a fixed plate 7;

the fixing mechanism is positioned between the detection device body 1 and the fixing block 6 and is used for fixing the detection device body 1 on the fixing block 6.

Further, the sponge 5 is movably connected with the rain cover 2, and the sponge 5 is closely attached to the shooting lens of the detection device body 1.

Ensure that the sponge 5 can normally rotate and slide in the rain cover 2, and ensure that the sponge 5 can be wiped clean by fog on the shooting lens of the detection device body 1 when the sponge 5 is driven by the rotating rod 4 to move along the first movable groove 3.

Further, the driving mechanism includes:

the storage tank 18, the storage tank 18 is opened in the rain cover 2, the miniature motor 8 is fixedly connected in the storage tank 18, and the output shaft of the miniature motor 8 penetrates through the storage tank 18 and extends to the outside;

the rotating plate 9, the rotating plate 9 fixed connection is on the output shaft of miniature motor 8, offered the second movable groove 10 that is linked together with the external world in the rotating plate 9, and the one end of bull stick 4 runs through one of them first movable groove 3 and extends to in the second movable groove 10, second movable groove 10 and bull stick 4 swing joint.

When the detecting device is used, the micro motor 8 is started, the output shaft of the micro motor 8 drives the rotating plate 9 to rotate positively and negatively, the rotating plate 9 drives the rotating rod 4 to move up and down in the first movable groove 3 through the second movable groove 10, meanwhile, the rotating rod 4 drives the sponge 5 to move up and down, and at the moment, the sponge 5 erases fog generated on the shooting lens of the detecting device body 1.

Further, the output shaft of the micro motor 8 is rotatably connected with the rain cover 2, and two ends of the second movable groove 10 are semicircular and have the same diameter as the rotating rod 4.

Ensure that the output shaft of the micro motor 8 can normally rotate in the rain cover 2, and ensure that the rotating rod 4 can be driven to move up and down through the second movable groove 10 when the rotating plate 9 rotates positively and negatively.

Further, the fixing mechanism includes:

a plurality of fixing holes 11, wherein the fixing holes 11 are all arranged on one side of the detection device body 1;

the first sliding chute 12 is arranged in the fixed block 6 and is communicated with one of the fixed holes 11, and the top of the first sliding chute 12 is provided with a second sliding chute 13 communicated with the outside;

the sliding block 14 is in sliding connection in the first sliding groove 12, the sliding block 14 is in plug-in fit with the corresponding fixing hole 11, a slot 15 is formed in the top of the sliding block 14, and one end of the sliding block 14 is fixedly connected with a spring 16 fixed with the inner wall of the first sliding groove 12;

the inserting block 17 is connected in the second sliding groove 13 in a sliding manner, and the inserting block 17 is in plug-in fit with the inserting groove 15.

When in use, a user can press the inserting block 17 downwards by hand to enable the inserting block 17 to move downwards along the second sliding groove 13, meanwhile, the bottom end of the inserting block 17 can drive the sliding block 14 to move towards the direction away from the fixing hole 11 through the extrusion slot 15, one end of the sliding block 14 enters the first sliding groove 12 from the corresponding fixing hole 11, at the moment, the sliding block 14 releases the fixing of the detection device body 1, then the user rotates the detection device body 1 by hand, when the detection device body 1 is rotationally adjusted to a proper position, the user releases the hand holding the inserting block 17, one end of the sliding block 14 is enabled to receive the elastic force of the spring 16, moves towards the fixing hole 11 along the first sliding groove 12 until contacting with one side of the detection device body 1, then the detection device body 1 is continuously rotated, when the first sliding groove 12 is communicated with the corresponding fixing hole 11, one end of the sliding block 14 is enabled to receive the elastic force of the spring 16, at the moment, the detection device body 1 is fixed on the fixing block 6 by the sliding block 14, and the detection device body 1 can be shot downwards or upwards

Further, the fixing holes 11 are arranged at equal intervals in an annular shape, the bottom ends of the inserting blocks 17 are of an inclined structure, and the inserting grooves 15 are of right-angled triangle structures.

The distance between the fixing holes 11 is ensured to be the same, and when the insert block 17 moves downwards along the second sliding groove 13, the insert groove 15 can be extruded to drive the sliding block 14 to move in a direction away from the fixing holes 11.

Notably, are: the rotating rod 4 can rotate and slide in the first movable groove 3 and the second movable groove 10.

Noteworthy are: the fixing plate 7 is fixed to the wall by bolts.

Working principle: when the user finds that the shooting lens of the detection device body 1 produces fog, the user can start the micro motor 8 at this moment, the output shaft of the micro motor 8 drives the rotary plate 9 to rotate positively and negatively, the rotary plate 9 drives the rotary rod 4 to move up and down in the first movable groove 3 through the second movable groove 10, the rotary rod 4 can drive the sponge 5 to move up and down, the sponge 5 produces fog on the shooting lens of the detection device body 1 at this moment, when the user finds that the shooting dead angle is not shot above or below the detection device body 1, the user can press the inserting block 17 downwards by hand, the inserting block 17 moves downwards along the second sliding groove 13, meanwhile, the bottom end of the inserting block 17 can drive the sliding block 14 to move in a direction away from the fixed hole 11 through the extrusion slot 15, one end of the sliding block 14 enters into the first sliding groove 12 from the corresponding fixed hole 11, at this moment, the sliding block 14 is released from fixing the detection device body 1, afterwards, when the user finds that the shooting dead angle is adjusted to a proper position by hand on the shooting lens of the detection device body 1, the user loosens the hand of the sliding block 17, the hand of the user releases the hand of the sliding block 17, the hand of the user is released from the user, the end of the user releases the hand of the detection device body 1, and the user can move from the corresponding fixed hole 11, and the corresponding end of the sliding block 14 to the first sliding block 12, and the user can move in the first sliding groove 12 through the corresponding direction 11, and the corresponding direction 1, and the elastic block 16, and the user can release the user.

The previous description is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (6)

1. An image object detection apparatus based on recognition dynamics, comprising:

the rain cover (2) is fixedly connected to the top of the detection device body (1);

the two first movable grooves (3) are respectively arranged at two sides of the rain cover (2) and are communicated with the inner cavity of the rain cover (2), and a rotating rod (4) is movably connected between the two first movable grooves (3);

the sponge (5) is fixedly connected to the periphery of the rotating rod (4) and is positioned in the inner cavity of the rain cover (2);

the driving mechanism is positioned in the rain cover (2) and is used for driving the rotating rod (4) to move between the two first movable grooves (3);

the fixed block (6), the fixed block (6) is rotatably connected to one side of the detection device body (1), and one side of the fixed block (6) is fixedly connected with a fixed plate (7);

the fixing mechanism is located between the detection device body (1) and the fixing block (6) and used for fixing the detection device body (1) on the fixing block (6).

2. The recognition dynamic-based image object detection apparatus according to claim 1, wherein: the sponge (5) is movably connected with the rain cover (2), and the sponge (5) is closely attached to the shooting lens of the detection device body (1).

3. The recognition dynamic-based image object detection apparatus according to claim 1, wherein the driving mechanism includes:

the storage device comprises a storage groove (18), wherein the storage groove (18) is formed in a rain cover (2), a miniature motor (8) is fixedly connected in the storage groove (18), and an output shaft of the miniature motor (8) penetrates through the storage groove (18) and extends to the outside;

the rotating plate (9), rotating plate (9) fixed connection is on the output shaft of micro motor (8), second movable groove (10) that are linked together with the external world have been seted up in rotating plate (9), and in one of them first movable groove (3) and extension to second movable groove (10) are run through to the one end of bull stick (4), second movable groove (10) and bull stick (4) swing joint.

4. The recognition dynamic-based image object detection apparatus according to claim 3, wherein: the output shaft of the miniature motor (8) is rotationally connected with the rain cover (2), and the two ends of the second movable groove (10) are semicircular and have the same diameter as the rotating rod (4).

5. The recognition dynamic-based image object detection apparatus according to claim 1, wherein the fixing mechanism includes:

a plurality of fixing holes (11), wherein the fixing holes (11) are all arranged on one side of the detection device body (1);

the first sliding chute (12), the first sliding chute (12) is arranged in the fixed block (6) and is communicated with one of the fixed holes (11), and the top of the first sliding chute (12) is provided with a second sliding chute (13) communicated with the outside;

the sliding block (14), the sliding block (14) is connected in the first sliding groove (12) in a sliding way, the sliding block (14) is in plug-in fit with the corresponding fixing hole (11), the top of the sliding block (14) is provided with a slot (15), and one end of the sliding block (14) is fixedly connected with a spring (16) fixed with the inner wall of the first sliding groove (12);

the inserting block (17), the inserting block (17) is connected in the second sliding groove (13) in a sliding mode, and the inserting block (17) is matched with the inserting groove (15) in an inserting mode.

6. The recognition dynamic-based image object detection apparatus according to claim 5, wherein: the fixing holes (11) are arranged at equal intervals in an annular shape, the bottom ends of the inserting blocks (17) are of inclined structures, and the inserting grooves (15) are of right-angled triangle structures.

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