CN220082535U - Monitoring equipment capable of being independently adjusted in all directions - Google Patents

Abstract

The utility model relates to monitoring equipment capable of being independently and omnidirectionally adjusted, which comprises a bracket shell, wherein two ends of the bracket shell are opened; the two adjusting shells are symmetrically and rotatably arranged at two sides of the support shell, and the front end of the adjusting shell and one end of the adjusting shell, which is away from the support shell, are both arranged in an open manner and form an adjusting groove; the camera comprises a camera lens and a camera shell, wherein the camera shell is clamped to the adjusting shell and can rotate along the adjusting shell, and the camera lens is arranged on the camera shell and is arranged outside the adjusting shell; and the bracket component is arranged on the bracket shell and is used for fixing the bracket shell. The utility model can solve the problem of incomplete coverage of the monitoring range of a single traditional camera.

Description

Monitoring equipment capable of being independently adjusted in all directions

Technical Field

The utility model belongs to the technical field of monitoring equipment, relates to camera monitoring equipment, and particularly relates to monitoring equipment capable of being independently and omnidirectionally adjusted.

Background

With the continuous progress of society and the demand of various aspects for monitoring video data, monitoring cameras are installed in large quantities, and the monitoring range of conventional monitoring devices has a great limitation.

Through searching, patent CN202020067250.8 discloses a security camera device with a multi-angle rotation function, the angle adjustment range of which is limited to the angle adjustment in a single dimension, and when the direction of other dimensions needs to be monitored, the security camera device needs to be detached and the position needs to be selected again for installation. In addition, the current monitoring setting is just planning camera installation angle in advance before the installation, can not adjust after the installation again, has also increased the installation degree of difficulty.

In view of the above problems, the present utility model provides a monitoring device with an adjustable monitoring range after installation.

Disclosure of Invention

The utility model aims to overcome the defects in the prior art, and provides monitoring equipment capable of being independently and omnidirectionally adjusted, which can solve the problem of insufficient coverage of the monitoring range of a traditional camera.

A separately omni-directionally adjustable monitoring device, comprising:

the bracket shell is provided with two open ends;

the two adjusting shells are symmetrically and rotatably arranged at two sides of the support shell, and the front end of the adjusting shell and one end of the adjusting shell, which is away from the support shell, are both arranged in an open manner and form an adjusting groove;

the camera comprises a camera lens and a camera shell, wherein the camera shell is clamped to the adjusting shell and can rotate along the adjusting shell, and the camera lens is arranged on the camera shell and is arranged outside the adjusting shell;

and the bracket component is arranged on the bracket shell and is used for fixing equipment.

Moreover, the camera shooting shell is of a sphere structure, the inner wall of the cavity of the adjusting shell is of a sphere curved surface structure matched with the camera shooting shell, and the camera shooting shell can be wrapped by the adjusting shell.

And the upper and lower width of the adjusting groove of the adjusting shell is consistent with the upper and lower width of the joint of the camera shooting shell and the camera shooting lens.

Furthermore, the camera lens can rotate 0-90 degrees along the adjusting groove.

Moreover, it still includes the mounting disc, the mounting disc is close to adjustment shell one side end edge and is equipped with the buckle, be equipped with on the adjustment shell inner wall with the corresponding draw-in groove of buckle, the mounting disc is through the buckle card and in the draw-in groove, be equipped with the shirt rim on the mounting disc is close to support shell one side peripheral wall, be equipped with annular groove on the support shell inner wall, the mounting disc passes through the shirt rim and rotates to install in annular inslot, the mounting disc is equipped with the mounting hole with adjustment shell position corresponding department, pass through the mounting hole with its position fixing through set screw between adjustment shell and the support shell.

And the bracket component comprises a fixed bracket and a fixed seat, wherein the fixed seat is arranged on the bracket shell, and the fixed bracket is detachably connected with the fixed seat.

The side, close to the support shell, of the fixing seat is an arc-shaped surface which is matched with the shape of the support shell, the side, away from the support shell, of the fixing seat is provided with a mounting groove, a supporting seat is arranged in the mounting groove, and a splicing groove is formed between the supporting seat and the inner wall of the mounting groove;

the fixed support comprises a support seat and a connecting seat, and the connecting seat can be inserted into the inserting groove and is connected with the support seat through a fastener.

Moreover, the connecting seat is of a cuboid cavity structure with the lower end face and the front end face being open, a square notch is arranged below the connecting seat deviating from the support seat, and the inserting groove is of an isosceles trapezoid structure matched with the position below the front end of the connecting seat.

Moreover, the length of the inner wall of the inserting groove close to the bracket shell is consistent with the diagonal length of the square notch.

Moreover, the bracket shell is of a cylindrical structure.

The utility model has the advantages and beneficial effects that:

1. the two groups of cameras are respectively positioned at the left side and the right side, can be independently adjusted at any angle and cover any angle monitoring range so as to realize 360-degree omnidirectional monitoring of the cameras.

2. The bracket component is positioned at the rear part of the equipment, and can realize two mounting forms of wall mounting and hoisting in different assembly modes so as to adapt to different use scenes.

Drawings

Fig. 1 is a schematic diagram of an independently omni-adjustable monitoring device provided by the present utility model;

fig. 2 is a schematic diagram of a horizontal adjustment mode of a camera of the monitoring device (taking a left camera as an example) capable of being independently adjusted in all directions;

fig. 3 is a schematic diagram of a vertical direction adjustment mode of a camera of the monitoring device capable of being independently adjusted in an omni-directional manner (taking a left camera as an example);

FIG. 4 is a state diagram of a first embodiment of an independently omni-directionally adjustable monitoring device in accordance with the present utility model;

fig. 5 is a state diagram of a second embodiment of an independently omni-directionally adjustable monitoring device in accordance with the present utility model;

FIG. 6 is a schematic view of a portion of the bracket shell with the adjustment shell in a disassembled state (a is a cross-sectional view of the bracket shell in a closed state);

reference numerals illustrate:

bracket shell 1, adjusting shell 2, camera 3, camera lens 31, camera housing 32, bracket assembly 4, fixed bolster 41, fixing base 42, supporting seat 43, jack-in groove 44, bracket seat 410, connecting seat 411, mounting plate 5, buckle 51, skirt 52, annular groove 53, mounting hole 54, set screw 55.

Detailed Description

The following describes the embodiments of the present utility model further with reference to the drawings and examples. The following examples are only for more clearly illustrating the technical aspects of the present utility model, and are not intended to limit the scope of the present utility model.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

An independently omnidirectionally adjustable monitoring device, as shown in figures 1-6, comprises

The two ends of the bracket shell 1 are opened;

the two adjusting shells 2 are symmetrically and rotatably arranged at two sides of the support shell 1, and the front end of the adjusting shell 2 and one end of the adjusting shell 2, which is away from the support shell 1, are both open and form an adjusting groove;

the camera 3 comprises a camera lens 31 and a camera shell 32, wherein the camera shell 32 is clamped to the adjusting shell 2 and can rotate along the adjusting shell 2, and the camera lens 31 is arranged on the camera shell 32 and is arranged outside the adjusting shell 2;

and a bracket assembly 4 mounted on the bracket shell 1 for equipment fixation.

In this embodiment, the camera housing 32 has a spherical structure, the inner wall of the cavity of the adjusting housing 2 has a spherical curved surface structure that is matched with the camera housing 32, and the camera housing 32 can be wrapped by the adjusting housing 2.

In this embodiment, the vertical width of the adjusting slot of the adjusting housing 2 is identical to the vertical width of the joint between the image pickup housing 32 and the image pickup lens 31.

In this embodiment, the imaging lens 31 is rotatable 0-90 ° along the adjustment groove.

In this embodiment, it still includes mounting plate 5, mounting plate 5 is close to adjusting shell 2 one side end edge and is equipped with buckle 51, be equipped with on the adjusting shell 2 inner wall with buckle 51 position and size looks adaptation draw-in groove, mounting plate 5 is through buckle 51 card and in the draw-in groove, mounting plate 5 is close to be equipped with shirt rim 52 on the outer peripheral wall of support shell 1 one side, be equipped with annular groove 53 on the support shell 1 inner wall, mounting plate 5 passes through shirt rim 52 rotation and installs in annular groove 53, mounting plate 5 and adjusting shell 2 position corresponding department all are equipped with mounting hole 54, pass through mounting hole 54 with its position fixing through set screw 55 between adjusting shell 2 and the support shell 1.

In the technical scheme, the adjusting shell is rotationally connected with the support shell, 360-degree rotation can be achieved, and the adjusting shell and the support shell are fixed in position through the fixing screw, so that the adjusting shell and the support shell can stay at any position.

In this embodiment, the bracket assembly 4 includes a fixing bracket 41 and a fixing base 42, the fixing base 42 is mounted on the bracket shell 1, and the fixing bracket 41 is detachably connected with the fixing base 42.

In this embodiment, the fixing base and the bracket shell are integrally formed.

In this embodiment, the side of the fixing base 42 near the bracket shell 1 is an arc surface matching with the shape of the bracket shell 1, the side of the fixing base 42 away from the bracket shell 1 is a mounting groove, a supporting seat 43 is arranged in the mounting groove, and a plugging groove 44 is formed between the supporting seat 43 and the inner wall of the mounting groove;

the fixing bracket 41 includes a bracket seat 410 and a connection seat 411, and the connection seat 411 can be inserted into the insertion slot 44 and connected with the support seat 43 through a fastener. The fastener adopts a bolt.

In this embodiment, the connection seat 411 has a rectangular structure with an open lower end surface and an open front end surface, a square notch is provided under the connection seat 411 facing away from the support seat 410, and the insertion slot 44 has an isosceles trapezoid structure matching with the lower part of the front end of the connection seat 411.

In this embodiment, the length of the insertion groove 44 near the inner wall of the bracket shell 1 is consistent with the diagonal length of the square notch.

In this embodiment, the bracket shell 1 has a cylindrical structure.

The implementation principle of the utility model is as follows:

as shown in fig. 2, taking a left camera as an example, the camera can be rotated to any angle within the range of 0-90 degrees in the horizontal direction in a graphical manner; similarly, the right camera can perform the same adjustment.

As shown in fig. 3, taking a left camera as an example, the camera can be rotated to any angle within the range of 0-360 degrees in the vertical direction in an illustration mode; similarly, the right camera can perform the same adjustment.

After the adjustment of fig. 2 and 3 to a proper angle is completed, the fixing screws of the left camera and the right camera are respectively screwed, so that the adjusted angle can be fixed.

As shown in fig. 4, the fixing bracket is installed in the direction of illustration to complete the wall mounting of the monitoring device.

As shown in fig. 5, the fixing bracket is installed in the direction of illustration, and the hoisting installation of the monitoring equipment is completed.

It should be emphasized that the embodiments described herein are illustrative rather than limiting, and that this utility model encompasses other embodiments which may be made by those skilled in the art based on the teachings herein and which fall within the scope of this utility model.

Claims (10)

1. Monitoring equipment capable of being independently and omnidirectionally adjusted, which is characterized in that: it comprises

A bracket shell (1) with two open ends;

the two adjusting shells (2) are symmetrically and rotatably arranged at two sides of the support shell (1), and the front end of the adjusting shell (2) and one end of the adjusting shell (2) deviating from the support shell (1) are both opened to form an adjusting groove;

the camera (3) comprises a camera lens (31) and a camera shell (32), wherein the camera shell (32) is clamped to the adjusting shell (2) and can rotate along the adjusting shell (2), and the camera lens (31) is arranged on the camera shell (32) and is arranged outside the adjusting shell (2);

and the bracket component (4) is arranged on the bracket shell (1) and is used for fixing equipment.

2. An independently omnidirectionally adjustable monitoring device according to claim 1 wherein: the camera shooting shell (32) is of a sphere structure, the inner wall of the cavity of the adjusting shell (2) is of a sphere curved surface structure matched with the camera shooting shell (32), and the camera shooting shell (32) can be wrapped by the adjusting shell (2).

3. An independently omnidirectionally adjustable monitoring device according to claim 2 wherein: the upper and lower width of the adjusting groove of the adjusting shell (2) is consistent with the upper and lower width of the joint of the camera shooting shell (32) and the camera shooting lens (31).

4. A self-contained omni-directional adjustable monitoring device according to claim 3, wherein: the camera lens (31) can rotate 0-90 degrees along the adjusting groove.

5. An independently omnidirectionally adjustable monitoring device according to claim 1 wherein: it still includes mounting disc (5), mounting disc (5) are close to adjusting shell (2) one side end edge and are equipped with buckle (51), be equipped with on adjusting shell (2) inner wall with buckle (51) position and size looks adaptation draw-in groove, mounting disc (5) are equipped with shirt rim (52) on being close to support shell (1) one side peripheral wall through buckle (51) card and in the draw-in groove, be equipped with annular groove (53) on support shell (1) inner wall, mounting disc (5) are installed in annular groove (53) through shirt rim (52) rotation, mounting disc (5) all are equipped with mounting hole (54) with adjusting shell (2) position corresponding department, pass through mounting hole (54) with its position fixing between adjusting shell (2) and support shell (1) through set screw (55).

6. An independently omnidirectionally adjustable monitoring device according to claim 1 wherein: the support assembly (4) comprises a fixed support (41) and a fixed seat (42), wherein the fixed seat (42) is arranged on the support shell (1), and the fixed support (41) is detachably connected with the fixed seat (42).

7. An independently omnidirectionally adjustable monitoring device according to claim 6 wherein: one side of the fixed seat (42) close to the support shell (1) is an arc-shaped surface which is matched with the shape of the support shell (1), one side of the fixed seat (42) away from the support shell (1) is a mounting groove, a supporting seat (43) is arranged in the mounting groove, and a plugging groove (44) is formed between the supporting seat (43) and the inner wall of the mounting groove;

the fixed support (41) comprises a support seat (410) and a connecting seat (411), and the connecting seat (411) can be inserted into the inserting groove (44) and is connected with the support seat (43) through a fastener.

8. An independently omnidirectionally adjustable monitoring device according to claim 7 wherein: the connecting seat (411) is of a cuboid cavity structure with an open lower end face and an open front end face, a square notch is arranged below the connecting seat (411) deviating from the support seat (410), and the inserting groove (44) is of an isosceles trapezoid structure matched with the lower part of the front end of the connecting seat (411).

9. An independently omnidirectionally adjustable monitoring device according to claim 8 wherein: the length of the inner wall of the inserting groove (44) close to the bracket shell (1) is consistent with the diagonal length of the square notch.

10. An independently omnidirectionally adjustable monitoring device according to claim 1 wherein: the support shell (1) is of a cylindrical structure.