CN216795076U - Multi-cloud-platform linkage camera - Google Patents

Abstract

The utility model discloses a multi-cloud-platform linkage camera which comprises a mounting disc and a rotating support rotatably connected with the mounting disc, wherein the rotating support is rotatably arranged on the mounting disc in the vertical direction, a first rotating body rotatable in the horizontal direction is arranged on the rotating support, a first monitoring assembly is arranged on the first rotating body, the first monitoring assembly is rotatably arranged on the first rotating body in the horizontal direction, two opposite sides of the rotating support are respectively and fixedly connected with a fixed support, second rotating bodies rotatable in the vertical direction are respectively arranged on the fixed supports, and a second monitoring assembly is respectively arranged on the second rotating body and rotatably arranged on the second rotating body in the horizontal direction. The multi-cloud-station linkage camera provided by the utility model is wide in monitoring range, can effectively cover a target area, can realize multi-point monitoring, effectively avoids blind areas, and is convenient to install and convenient for later maintenance.

Description

Multi-cloud-platform linkage camera

Technical Field

The utility model relates to the technical field of monitoring equipment, in particular to a multi-cloud platform linkage camera.

Background

Along with the construction and development of cities, road conditions of parts of road sections in cities are more and more complex, for example, the working pressure of road monitoring equipment is increased at positions such as intersection of curves or upper and lower intersections of highways. Because the coverage area of the existing monitoring equipment is small and can not completely cover all lanes of the intersection, in order to ensure that the lanes are respectively monitored in the area with complex road conditions, a plurality of monitoring equipment are required to be installed, so that the installation workload is large and the cost is high, a plurality of vehicles can also travel simultaneously in each lane, the existing monitoring equipment can not independently monitor each vehicle so as to form blind areas, and inconvenience is caused to the maintenance of traffic order.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is as follows: the multi-cloud-station linkage camera with a wide monitoring range is provided.

In order to solve the technical problems, the utility model adopts the technical scheme that: a multi-cloud-platform linkage camera comprises a mounting disc and a rotating support rotatably connected with the mounting disc, wherein the rotating support is rotatably arranged on the mounting disc in the vertical direction, a first rotating body rotatable in the horizontal direction is arranged on the rotating support, a first monitoring assembly is arranged on the first rotating body, the first monitoring assembly is rotatably arranged on the first rotating body in the horizontal direction, two opposite sides of the rotating support are respectively and fixedly connected with a fixed support, second rotating bodies rotatable in the vertical direction are respectively arranged on the fixed supports, and a second monitoring assembly is respectively arranged on the second rotating bodies and rotatably arranged on the second rotating bodies in the horizontal direction.

Furthermore, a first rotating shaft is arranged on the mounting disc, the axial direction of the first rotating shaft is a vertical direction, and the rotating support and the first rotating body are respectively in rotating connection with the first rotating shaft.

Furthermore, the first rotating body comprises a first cavity, a first driving part is arranged in the first cavity, and the first driving part is in transmission connection with the first rotating shaft.

Furthermore, the first monitoring assembly comprises a first camera and a first shell wrapping the first camera, a second rotating shaft is arranged on the first rotating body, the axial direction of the second rotating shaft is the horizontal direction, and the first shell is rotatably connected with the second rotating shaft.

Furthermore, the first rotating body comprises a first cavity, a second driving piece is arranged in the first cavity, and the second driving piece is in transmission connection with the second rotating shaft.

Furthermore, a third rotating shaft is arranged on the fixed support, the axial direction of the third rotating shaft is vertical, and the second rotating body is rotatably connected with the third rotating shaft.

Furthermore, the second rotating body comprises a second cavity, a third driving piece is arranged in the second cavity, and the third driving piece is in transmission connection with a third rotating shaft.

Furthermore, the second monitoring assembly comprises a second camera and a second shell wrapping the second camera, a fourth rotating shaft is arranged on the second rotating body, the axial direction of the fourth rotating shaft is the horizontal direction, and the second shell is rotatably connected with the fourth rotating shaft.

Furthermore, the second rotating body comprises a second cavity, a fourth driving part is arranged in the second cavity, and the fourth driving part is in transmission connection with the fourth rotating shaft.

Furthermore, the two opposite sides of the rotating support are respectively provided with an accommodating cavity, and part of the fixing support extends into the accommodating cavities and is fixedly connected with the rotating support.

The utility model has the beneficial effects that: the utility model provides a multi-cloud-platform linkage camera, which comprises a mounting plate, wherein a rotating bracket which can rotate around the vertical direction is arranged on the mounting plate, a first rotating body which can rotate around the vertical direction independently of the rotating bracket is arranged on the rotating bracket, a first monitoring component which can rotate around the horizontal direction is arranged on the first rotating body, the monitoring range of the first monitoring component can be adjusted through the actions of the first rotating body and the first monitoring component, fixed brackets are respectively arranged at two opposite sides of the rotating bracket, second rotating bodies which can rotate around the vertical direction are respectively arranged on the two fixed brackets, a second monitoring component which can rotate around the horizontal direction is arranged on the second rotating body, the monitoring ranges of the two second monitoring components can be respectively adjusted through the actions of the rotating bracket, the second rotating body and the second monitoring component, and further the monitoring ranges of the first monitoring component and the two second monitoring components can be respectively adjusted, the monitoring range of many cloud platform linkage cameras is improved greatly to ensure that the monitoring range of many cloud platform linkage cameras covers the target area, and the orientation of other monitoring component of accessible adjustment when one or two in first monitoring component and two second monitoring components are monitored alone certain target realizes the multiple spot control, effectively avoids appearing the blind area, and simple to operate is convenient for later maintenance simultaneously.

Drawings

Fig. 1 is a schematic structural diagram of a multi-cloud-station linkage camera according to a first embodiment of the present invention;

fig. 2 is an exploded view of a multi-cloud linked camera according to a first embodiment of the present invention;

fig. 3 is a schematic structural diagram of a first rotating body and a first monitoring assembly in the multi-cloud-platform linkage camera according to the first embodiment of the present invention;

fig. 4 is a cross-sectional view of a first rotating body and a first monitoring assembly in the multi-cloud-platform linkage camera according to the first embodiment of the utility model;

fig. 5 is an exploded view of a part of the structure in the multi-cloud-platform linkage camera according to the first embodiment of the present invention;

fig. 6 is a cross-sectional view of a second rotating body and a second monitoring assembly in the multi-cloud-platform-linked camera according to the first embodiment of the utility model;

fig. 7 is an exploded view of a mounting plate in the multi-platform linkage camera according to the first embodiment of the present invention;

fig. 8 is a cross-sectional view of a rotating bracket in the multi-cloud-platform linkage camera according to the first embodiment of the utility model.

Description of reference numerals:

1. mounting a disc; 11. a first rotating shaft; 12. a guard ring; 13. an upper cover; 14. a lower cover; 15. mounting holes; 2. rotating the bracket; 21. an accommodating cavity; 22. a third chamber; 23. a fifth driving member; 24. a fifth bearing; 25. a mounting surface; 26. hole site; 3. a first rotating body; 31. a first chamber; 32. a first driving member; 33. a second driving member; 34. a first bearing; 35. a second bearing; 4. a first monitoring component; 41. a first camera; 42. a first housing; 43. a second rotating shaft; 5. a fixed bracket; 51. a third rotating shaft; 52. an upper shell; 53. a lower case; 6. a second rotating body; 61. a second chamber; 62. a third driving member; 63. a fourth drive; 64. a third bearing; 65. a fourth bearing; 7. a second monitoring component; 71. a second camera; 72. a second housing; 73. and a fourth rotating shaft.

Detailed Description

In order to explain technical contents, achieved objects, and effects of the present invention in detail, the following description is made with reference to the accompanying drawings in combination with the embodiments.

Referring to fig. 1 to 8, a multi-cloud-platform linkage camera includes a mounting plate 1 and a rotating bracket 2 rotatably connected to the mounting plate 1, where the rotating bracket 2 is rotatably disposed on the mounting plate 1 in a vertical direction, a first rotating body 3 rotatable in a horizontal direction is disposed on the rotating bracket 2, a first monitoring assembly 4 is disposed on the first rotating body 3, the first monitoring assembly 4 is rotatably disposed on the first rotating body 3 in the horizontal direction, two opposite sides of the rotating bracket 2 are also fixedly connected to fixing brackets 5, second rotating bodies 6 rotatable in the vertical direction are disposed on the fixing brackets 5, second monitoring assemblies 7 are disposed on the second rotating bodies 6, and the second monitoring assemblies 7 are rotatably disposed on the second rotating bodies 6 in the horizontal direction.

From the above description, the beneficial effects of the present invention are: the multi-cloud-station linkage camera provided by the utility model is wide in monitoring range, can effectively cover a target area, can realize multi-point monitoring, effectively avoids blind areas, and is convenient to install and convenient for later maintenance.

Further, a first rotating shaft 11 is arranged on the mounting disc 1, the axial direction of the first rotating shaft 11 is a vertical direction, and the rotating support 2 and the first rotating body 3 are respectively connected with the first rotating shaft 11 in a rotating manner.

Further, the first rotating body 3 includes a first cavity 31, a first driving member 32 is disposed in the first cavity 31, and the first driving member 32 is in transmission connection with the first revolving shaft 11.

As can be seen from the above description, the first rotating body 3 is driven by the first driving member 32 to rotate around the first rotating shaft 11, so as to drive the fixed bracket 5 and the second monitoring component 7 disposed on the fixed bracket 5 to rotate, so as to adjust the position of the second monitoring component 7.

Further, the first monitoring assembly 4 includes a first camera 41 and a first housing 42 covering the first camera 41, the first rotating body 3 is provided with a second rotating shaft 43, an axial direction of the second rotating shaft 43 is a horizontal direction, and the first housing 42 is rotatably connected to the second rotating shaft 43.

Further, the first rotating body 3 includes a first chamber 31, a second driving member 33 is disposed in the first chamber 31, and the second driving member 33 is in transmission connection with the second rotating shaft 43.

As can be seen from the above description, the first monitoring assembly 4 is driven by the second driving element 33 to rotate around the second rotation shaft 43 to adjust the pitch angle of the first monitoring assembly 4.

Furthermore, a third rotating shaft 51 is arranged on the fixed support 5, the axial direction of the third rotating shaft 51 is the vertical direction, and the second rotating body 6 is rotatably connected with the third rotating shaft 51.

Further, the second rotating body 6 comprises a second cavity 61, a third driving member 62 is arranged in the second cavity 61, and the third driving member 62 is in transmission connection with the third revolving shaft 51.

As can be seen from the above description, the two second rotating bodies 6 rotate around the third rotating shaft 51, so that the two second rotating bodies can independently operate, and the two second monitoring units 7 can face different directions to cover different monitoring areas.

Furthermore, the second monitoring assembly 7 includes a second camera 71 and a second housing 72 covering the second camera 71, the second rotating body 6 is provided with a fourth rotating shaft 73, the axial direction of the fourth rotating shaft 73 is the horizontal direction, and the second housing 72 is rotatably connected with the fourth rotating shaft 73.

Further, the second rotating body 6 includes a second chamber 61, a fourth driving member 63 is disposed in the second chamber 61, and the fourth driving member 63 is in transmission connection with the fourth rotating shaft 73.

As can be seen from the above description, the pitch angle of the second monitoring assembly 7 is implemented by the fourth driving assembly driving the second monitoring assembly 7 to rotate around the fourth rotation axis 73, so that the second monitoring assembly 7 can adjust the direction according to the position of the target.

Furthermore, the two opposite sides of the rotating support 2 are respectively provided with an accommodating cavity 21, and part of the fixed support 5 extends into the accommodating cavity 21 and is fixedly connected with the rotating support 2.

As can be seen from the above description, the accommodating chamber 21 for accommodating part of the fixing bracket 5 is formed in the rotating bracket 2, so that the fixing bracket 5 is stably connected to the rotating bracket 2, and the fixing bracket 5 is prevented from falling off from the rotating bracket 2.

Example one

Referring to fig. 1 to 8, a first embodiment of the present invention is: a multi-cloud-platform linkage camera is installed in areas with busy traffic, such as intersections, stations, wharfs and the like, and is used for monitoring the running condition of vehicles on roads.

As shown in fig. 1 and 2, the multi-cloud-platform linkage camera includes a mounting plate 1 and a rotating bracket 2 matched with the mounting plate 1, the rotating bracket 2 is rotatably disposed on the mounting plate 1 in a vertical direction, a first rotating body 3 rotatable in the vertical direction is further disposed on the rotating bracket 2, the first rotating body 3 is independent of the rotating bracket 2 and rotatable relative to the mounting plate 1, a first monitoring component 4 is disposed on the first rotating body 3, the first monitoring component 4 is rotatably disposed on the first rotating body 3 in a horizontal direction, two opposite sides of the rotating bracket 2 are respectively and fixedly connected with a fixed bracket 5, two fixed brackets 5 are respectively provided with a second rotating body 6, the second rotating body 6 is rotatable in the vertical direction, two second rotating bodies 6 are respectively provided with a second monitoring component 7, and the second monitoring component 7 is rotatable on the second rotating body 6 in the horizontal direction And (4) rotationally arranging.

Specifically, the orientation and the pitch angle of the first monitoring unit 4 can be adjusted by the rotation of the first rotating body 3 relative to the mounting plate 1 and the rotation of the first monitoring unit 4 relative to the first rotating body 3, so as to adjust the monitoring range of the first monitoring unit 4 and enable the first monitoring unit 4 to track a specific target; in a similar way, through the rotation of the rotating bracket 2, the rotation of the second rotating body 6 and the rotation of the second monitoring assembly 7 can make two the second monitoring assembly 7 operate independently of each other, and adjust two respectively the orientation and the pitching angle of the second monitoring assembly 7 realize adjusting or making two respectively the monitoring range of the second monitoring assembly 7 tracks the target respectively. And then the monitoring range of the multi-cloud platform linkage camera can cover a target area and can be conveniently adjusted according to actual conditions, so that multi-point monitoring is realized while the using requirements of busy road sections are met, and blind areas are effectively avoided.

Referring to fig. 2, fig. 3 and fig. 4, a first rotating shaft 11 is disposed on the mounting disc 1, an axial direction of the first rotating shaft 11 is a vertical direction, the first rotating body 3 is rotatably connected to the first rotating shaft 11, the first rotating body 3 has a first cavity 31, a first bearing 34 is disposed in the first cavity 31, the first bearing 34 is sleeved on the first rotating shaft 11 so that the first rotating body 3 can rotate smoothly relative to the mounting disc 1, a first driving member 32 in transmission connection with the first rotating shaft 11 is further disposed in the first cavity 31, and the first rotating body 3 is driven by the first driving member 32 to rotate around the first rotating shaft 11 so as to drive the first monitoring assembly 4 to rotate around the vertical direction.

Specifically, the first monitoring assembly 4 includes a first camera 41 and a first housing 42 wrapping the first camera 41, a second rotating shaft 43 is disposed on the first housing 42, an axial direction of the second rotating shaft 43 is a horizontal direction, the first chamber 31 further includes a second bearing 35 sleeved on the second rotating shaft 43 and a second driving member 33 in transmission connection with the second rotating shaft 43, so that the first monitoring assembly 4 can smoothly rotate relative to the first rotating member 3 under the driving of the second driving member 33, and the adjustment of the pitch angle of the first camera 41 is achieved.

As shown in fig. 4 and 5, a third revolving shaft 51 is disposed on the fixing support 5, an axial direction of the third revolving shaft 51 is a vertical direction, the second rotating body 6 is matched with the third revolving shaft 51 so that the second rotating body 6 can rotate relative to the fixing support 5, the second rotating body 6 has a second chamber 61, a third bearing 64 matched with the third revolving shaft 51 and a third driving member 62 in transmission connection with the third revolving shaft 51 are disposed in the second chamber 61, and the second rotating body 6 can rotate around the vertical direction on the fixing support 5 under the driving of the third driving member 62, so as to drive the second monitoring assembly 7 to rotate to adjust the direction of the second monitoring assembly 7.

In detail, the second monitoring assembly 7 includes a second camera 71 and a second housing 72 covering the second camera 71, the second housing 72 has a fourth rotating shaft 73, an axial direction of the fourth rotating shaft 73 is the same as a horizontal direction, a fourth bearing 65 and a fourth driving member 63 are further disposed in the second chamber 61, the fourth bearing 65 is sleeved on the fourth rotating shaft 73 and is matched with the fourth rotating shaft 73, the fourth driving member 63 is in transmission connection with the fourth bearing 65, and the second camera 71 can be adjusted under the driving of the fourth driving member 63.

Referring to fig. 2 and 6, the mounting disc 1 includes an upper cover 13 and a lower cover 14 that are matched with each other, the first rotating shaft 11 is fixedly connected to the lower portion, and the upper cover 13 is provided with a plurality of mounting holes 15 at intervals along the circumferential direction of the first rotating shaft to fix the mounting disc 1 at a working position, so that the multi-pan-tilt linkage camera is mounted while the multi-pan-tilt linkage camera is kept stable at the working position, and the multi-pan-tilt linkage camera is maintained at a later stage.

Preferably, a plurality of protection rings 12 are further arranged on the upper cover 13, and a safety rope can penetrate through the protection rings 12 to hang the multi-cloud-station linkage camera on a working position, so that the multi-cloud-station linkage camera is more tightly connected with the working position, and the multi-cloud-station linkage camera is prevented from accidentally falling.

Referring to fig. 2, fig. 5 and fig. 8, the rotating bracket 2 has a third cavity 22, the first rotating shaft 11 penetrates through the third cavity 22, a fifth bearing 24 is disposed in the third cavity 22, the fifth bearing 24 is sleeved on the first rotating shaft 11 to realize the rotating connection between the rotating bracket 2 and the mounting plate 1, and a fifth driving member 23 for driving the rotating bracket 2 to rotate around the first rotating shaft 11 is further disposed in the third cavity 22, so that the fixed bracket 5 and the second monitoring component 7 disposed on the fixed bracket 5 can be adjusted under the driving of the fifth driving member.

In this embodiment, the fixed bolster 5 includes matched with epitheca 52 and inferior valve 53, just the epitheca 52 with inferior valve 53 fixed connection, the relative both sides of rotating bracket 2 are equipped with the accommodation part respectively the holding chamber 21 of fixed bolster 5, the bottom surface of holding chamber 21 be with the epitheca 52 with the installation face 25 of inferior valve 53 laminating just be equipped with a plurality of confessions on the installation face 25 the hole site 26 that fixed bolster 5 is connected, inferior valve 53 with hole site 26 fixed connection is in order to incite somebody to action fixed bolster 5 is fixed in on rotating bracket 2, ensures fixed bolster 5 with rotating bracket 2 is connected stably in order to prevent fixed bolster 5 pine takes off.

As shown in fig. 1, the working process of the multi-cloud-station linkage camera provided in this embodiment is as follows: after the multi-platform linkage camera is installed at a working position, the first monitoring component 4 and the two second monitoring components 7 respectively monitor partial target areas, the orientation and the pitch angle of the first monitoring component 4 can be adjusted through the rotation of the first rotating body 3 relative to the installation disc 1 and the rotation of the first monitoring component 4 relative to the first rotating body 3, the orientation and the pitch angle of the two second monitoring components 7 can be adjusted through the rotation of the rotating bracket 2 relative to the installation disc 1, the rotation of the second rotating body 6 relative to the fixed bracket 5 and the rotation of the second monitoring component 7 relative to the second rotating body 6 respectively, so as to adjust the monitoring areas of the multi-platform linkage camera according to actual conditions and enable the shooting picture of the first monitoring component 4 and the shooting picture of the second monitoring component 7 to move along with the targets, and multi-point monitoring is realized.

In summary, the multiple-cloud-station linkage camera provided by the utility model has the advantages that the first monitoring component and the two second monitoring components which are independent from each other are arranged to monitor different areas respectively, so that the monitoring coverage area is enlarged, the multiple-cloud-station linkage camera can completely cover a target area, multiple devices are not required to be arranged for monitoring, the installation cost is effectively reduced, the orientation and the pitching angle of the first monitoring component and the two second monitoring components can be adjusted respectively, the monitoring range of the multiple-cloud-station linkage camera can be adjusted according to actual requirements, multi-point monitoring is realized, and the use requirements of busy road sections are met; when the multi-cloud-platform linkage camera is installed, the installation disc is only required to be fixed to the working position, the installation is convenient, the later maintenance is convenient, the safety rope can also penetrate through the protection ring on the installation disc to prevent the multi-cloud-platform linkage camera from accidentally dropping, and the multi-cloud-platform linkage camera is safe and reliable in operation.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all equivalent changes made by using the contents of the present specification and the drawings, or applied directly or indirectly to the related technical fields, are included in the scope of the present invention.

Claims (10)

1. A many cloud platform linkage camera which characterized in that: the device comprises a mounting disc and a rotating support rotatably connected with the mounting disc, wherein the rotating support is rotatably arranged on the mounting disc in the vertical direction, a first rotating body rotatable in the horizontal direction is arranged on the rotating support, a first monitoring assembly is arranged on the first rotating body, the first monitoring assembly is rotatably arranged on the first rotating body in the horizontal direction, two opposite sides of the rotating support are respectively and fixedly connected with a fixed support, second rotating bodies rotatable in the vertical direction are respectively arranged on the fixed supports, and a second monitoring assembly is respectively arranged on the second rotating bodies and rotatably arranged on the second rotating bodies in the horizontal direction.

2. The multi-cloud-station-linked camera according to claim 1, wherein: the mounting disc is provided with a first rotating shaft, the axial direction of the first rotating shaft is vertical, and the rotating support and the first rotating body are respectively connected with the first rotating shaft in a rotating mode.

3. The multi-cloud linked camera of claim 2, wherein: the first rotating body comprises a first cavity, a first driving piece is arranged in the first cavity, and the first driving piece is in transmission connection with the first rotating shaft.

4. The multi-cloud-station-linked camera according to claim 1, wherein: the first monitoring assembly comprises a first camera and a first shell wrapping the first camera, a second rotating shaft is arranged on the first rotating body, the axial direction of the second rotating shaft is the horizontal direction, and the first shell is rotatably connected with the second rotating shaft.

5. The multi-cloud-station linkage camera of claim 4, wherein: the first rotating body comprises a first cavity, a second driving part is arranged in the first cavity, and the second driving part is in transmission connection with the second rotating shaft.

6. The multi-cloud-station-linked camera according to claim 1, wherein: the fixed support is provided with a third rotating shaft, the axial direction of the third rotating shaft is vertical, and the second rotating body is rotatably connected with the third rotating shaft.

7. The multi-cloud linked camera of claim 6, wherein: the second rotating body comprises a second cavity, a third driving piece is arranged in the second cavity, and the third driving piece is in transmission connection with a third rotating shaft.

8. The multi-cloud-station-linked camera according to claim 1, wherein: the second monitoring assembly comprises a second camera and a second shell wrapping the second camera, a fourth rotating shaft is arranged on the second rotating body, the axial direction of the fourth rotating shaft is the horizontal direction, and the second shell is rotatably connected with the fourth rotating shaft.

9. The multi-cloud linked camera of claim 8, wherein: the second rotating body comprises a second cavity, a fourth driving part is arranged in the second cavity, and the fourth driving part is in transmission connection with the fourth rotating shaft.

10. The multi-cloud-station-linked camera according to claim 1, wherein: the two opposite sides of the rotating support are respectively provided with an accommodating cavity, and part of the fixing support extends into the accommodating cavities and is fixedly connected with the rotating support.

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