CN210372769U

CN210372769U - High altitude supervisory equipment extending structure

Info

Publication number: CN210372769U
Application number: CN201920965692.1U
Authority: CN
Inventors: 张俊伟; 张松松; 张沈兵
Original assignee: Maanshan Xiaogu Precision Electromechanical Science And Technology Co ltd
Current assignee: Maanshan Xiaogu Precision Electromechanical Science And Technology Co ltd
Priority date: 2019-06-26
Filing date: 2019-06-26
Publication date: 2020-04-21
Anticipated expiration: 2029-06-26

Abstract

The utility model relates to the technical field of monitoring equipment, a high altitude supervisory equipment extending structure is disclosed, including the mounting panel, set up the shifting chute on the mounting panel, set up the motor mounting hole on the vertical cell wall of one end of shifting chute, fixedly connected with motor in the motor mounting hole, the output of motor is connected with the axis of rotation through the shaft coupling, and the other end of axis of rotation is connected with the backup pad through telescopic machanism, and the lower extreme of backup pad is connected with the camera, and telescopic machanism sets up in the shifting chute; the telescopic mechanism comprises a threaded rod, two nuts and two transmission rods, one end of the threaded rod is fixedly connected to one end, far away from the motor, of the rotating shaft, the threaded rod is arranged in the moving groove, symmetrical and opposite threads are arranged on the threaded rod, the two nuts are symmetrically in threaded connection with the rod wall of the threaded rod, and one ends of the two transmission rods are hinged to the annular side wall of the corresponding nut respectively. The utility model discloses realize the lift of camera, the demand of adaptation site activity.

Description

High altitude supervisory equipment extending structure

Technical Field

The utility model relates to a supervisory equipment technical field especially relates to a high altitude supervisory equipment extending structure.

Background

The monitoring equipment is mainly used for shooting and recording abnormal events in the area, and is convenient for follow-up afterwards. Some large-scale rooms often hold various activities, and in order to ensure smooth activities, monitoring equipment such as a plurality of cameras or video cameras need to be temporarily installed at activity sites, but the existing monitoring equipment cannot be adjusted in height and cannot meet the requirements of activity sites, and improvement is urgently needed.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem that the monitoring equipment can not be adjusted in height in the prior art, can not adapt to the needs of the activity site, and the problem of improvement is urgently needed, and a high altitude monitoring equipment extending structure who provides.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a telescopic structure of high-altitude monitoring equipment comprises a mounting plate, wherein a moving groove is formed in the mounting plate, a motor mounting hole is formed in a vertical groove wall at one end of the moving groove, a motor is fixedly connected in the motor mounting hole, the output end of the motor is connected with a rotating shaft through a coupler, the other end of the rotating shaft is connected with a supporting plate through a telescopic mechanism, the lower end of the supporting plate is connected with a camera, and the telescopic mechanism is arranged in the moving groove;

telescopic machanism includes threaded rod, two nuts and two transfer lines, the one end fixed connection of threaded rod is in the one end that the motor was kept away from to the axis of rotation, the threaded rod sets up in the shifting chute, just be equipped with symmetry and opposite screw thread on the threaded rod, two nut symmetry threaded connection is on the pole wall of threaded rod, two the one end of transfer line articulates respectively on the annular side wall of a nut that corresponds, and two the other end of transfer line articulates the one end of keeping away from the camera in the backup pad.

Preferably, fixedly connected with heat dissipation mechanism on the axle wall of axis of rotation, heat dissipation mechanism is including support frame, bearing, rotating tube and the flabellum that is "ten" word, support frame fixed connection is on the pore wall of motor mounting hole, the rotation hole has been seted up to the center department of support frame, the annular lateral wall of bearing is connected with the pore wall in rotation hole, the outer pipe wall of rotating tube is connected with the inner circle wall of bearing, just the both ends of rotating tube all pass the bearing and outwards extend, the fixed cup joint of flabellum is on the outer pipe wall of rotating tube, the rotating tube setting is passed to the axis of rotation, just the fixed cup joint of rotating tube is on the axle wall of axis of rotation.

Preferably, the one end fixedly connected with bearing frame that the motor mounting hole was kept away from to the shifting chute, the one end that the axis of rotation was kept away from to the threaded rod extends to in the bearing frame, just the threaded rod is connected with the inner circle of bearing frame.

Preferably, the notch center department fixedly connected with of shifting chute is the carriage of "U", the one end fixedly connected with telescopic link that the carriage is close to the backup pad, just the other end of telescopic link is connected with the backup pad.

Preferably, a rolling groove is formed in the annular side wall of one end, close to the bottom of the moving groove, of the nut, rolling balls are arranged in the rolling groove, one end, far away from the bottom of the rolling groove, of each ball penetrates through the notch of the corresponding rolling groove, and the balls are connected to the bottom of the moving groove in a rolling mode.

Preferably, a filter screen is fixedly connected in an orifice of one end of the motor mounting hole, which is far away from the moving groove.

Preferably, the telescopic rod comprises an outer tube and an inner rod, the outer tube is fixedly connected to the supporting frame, the inner rod is connected to the outer tube in a sliding mode, and one end, close to the supporting plate, of the inner rod is connected with the supporting plate.

Preferably, the ball has a ball diameter larger than a groove diameter of the rolling groove opening.

Preferably, the rod wall of the inner rod at the position far away from one end of the support plate is symmetrically and fixedly connected with sliding blocks, the inner pipe wall of the outer pipe is provided with sliding grooves in the vertical direction, and the sliding blocks are slidably connected in the corresponding sliding grooves.

Compared with the prior art, the utility model provides a high altitude supervisory equipment extending structure possesses following beneficial effect:

1. this high altitude supervisory equipment extending structure, through setting up the threaded rod, a telescopic machanism is constituteed to nut and transfer line, the direction of current that changes the motor can change the direction of rotation of motor output, the motor passes through the axis of rotation and drives the threaded rod and rotate, along with the rotation of threaded rod, corresponding opposite directions or back-to-back motion is done according to the direction of rotation of threaded rod to two nuts, the motion of vertical direction is done to drive the backup pad through two transfer lines during two nut motions, thereby realize the lift of camera, the demand of adaptation scene activity.

2. This high altitude supervisory equipment extending structure constitutes a heat dissipation mechanism through setting up support frame, bearing, rotating tube and flabellum, and when the motor drove the axis of rotation and rotates, the axis of rotation drove the rotating tube at the bearing internal rotation of support frame, drove the flabellum when the rotating tube rotates and rotates for the velocity of flow of air in the motor mounting hole, accelerate the radiating effect to the motor.

The part that does not relate to in the device all is the same with prior art or can adopt prior art to realize, the utility model discloses realize the lift of camera, adapt to the demand of field activity.

Drawings

Fig. 1 is a schematic structural view of a telescopic structure of an overhead monitoring device provided by the present invention;

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

FIG. 3 is an enlarged view of portion B of FIG. 1;

fig. 4 is the utility model provides a high altitude supervisory equipment extending structure's telescopic rod structure sketch map.

In the figure: the camera comprises a mounting plate 1, a moving groove 2, a motor mounting hole 3, a motor 4, a rotating shaft 5, a telescopic mechanism 6, a threaded rod 61, a nut 62, a transmission rod 63, a support plate 7, a camera 8, a heat dissipation mechanism 9, a support frame 91, a bearing 92, a rotating pipe 93, fan blades 94, a bearing seat 10, a support frame 11, a telescopic rod 12, an outer tube 121, an inner rod 122, a rolling groove 13, a ball 14, a filter screen 15, a sliding block 16 and a sliding groove 17.

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.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Referring to fig. 1-4, the telescopic structure of the high-altitude monitoring equipment comprises a mounting plate 1, wherein a moving groove 2 is formed in the mounting plate 1, a motor mounting hole 3 is formed in a vertical groove wall at one end of the moving groove 2, a motor 4 is fixedly connected in the motor mounting hole 3, the output end of the motor 4 is connected with a rotating shaft 5 through a coupling, the other end of the rotating shaft 5 is connected with a supporting plate 7 through a telescopic mechanism 6, the lower end of the supporting plate 7 is connected with a camera 8, and the telescopic mechanism 6 is arranged in the moving groove 2;

the telescopic mechanism 6 comprises a threaded rod 61, two nuts 62 and two transmission rods 63, one end of the threaded rod 61 is fixedly connected to one end, far away from the motor 4, of the rotating shaft 5, the threaded rod 61 is arranged in the moving groove 2, symmetrical and opposite threads are arranged on the threaded rod 61, the two nuts 62 are symmetrically and threadedly connected to the rod wall of the threaded rod 61, one ends of the two transmission rods 63 are respectively hinged to the annular side wall of the corresponding nut 62, the other ends of the two transmission rods 63 are hinged to one end, far away from the camera 8, of the supporting plate 7, the rotating direction of the output end of the motor 4 can be changed by changing the current direction of the motor 4, the motor 4 drives the threaded rod 61 to rotate through the rotating shaft 5, the two nuts 62 correspondingly move in the opposite direction or the opposite direction according to the rotating direction of the threaded rod 61 along with the rotation of the threaded rod, thereby realizing the lifting of the camera 9 and adapting to the requirements of field activities.

The heat dissipation mechanism 9 is fixedly connected to the shaft wall of the rotating shaft 5, the heat dissipation mechanism 9 includes a cross-shaped support frame 91, a bearing 92, a rotating tube 93 and a fan blade 94, the support frame 91 is fixedly connected to the hole wall of the motor mounting hole 3, a rotating hole is formed in the center of the support frame 91, the annular outer side wall of the bearing 92 is connected to the hole wall of the rotating hole, the outer wall of the rotating tube 93 is connected to the inner wall of the bearing 92, both ends of the rotating tube 93 penetrate through the bearing 92 and extend outwards, the fan blade 94 is fixedly sleeved on the outer wall of the rotating tube 93, the rotating shaft 5 penetrates through the rotating tube 93, the rotating tube 93 is fixedly sleeved on the shaft wall of the rotating shaft 5, when the motor 4 drives the rotating shaft 5 to rotate, the rotating tube 5 drives the rotating tube 93 to rotate in the bearing 92 of the support frame 91, when the rotating tube 93 rotates, the fan blade 94 is driven, the heat radiation effect to the motor 4 is accelerated.

The one end fixedly connected with bearing frame 10 that motor mounting hole 3 was kept away from to shifting chute 2, the one end that axis of rotation 5 was kept away from to threaded rod 61 extends to in the bearing frame 10, and threaded rod 61 is connected with the inner circle of bearing frame 10, supports the one end of threaded rod 61 through bearing frame 10 for threaded rod 61 is stable in shifting chute 2 rotates.

The notch center department fixedly connected with that removes groove 2 is the carriage 11 of "U", and carriage 11 is close to the one end fixedly connected with telescopic link 12 of backup pad 7, and the other end of telescopic link 12 is connected with backup pad 7, because the motion of vertical direction can only be to telescopic link 12, carries on spacingly to the moving direction of backup pad 7 for nut 62 can not rotate along with the rotation of threaded rod 61.

The annular side wall of one end, close to the bottom of the moving groove 2, of the nut 62 is provided with a rolling groove 13, rolling balls 14 are arranged in the rolling groove 13, one end, far away from the bottom of the rolling groove 13, of each ball 14 penetrates through the notch of the rolling groove 13, the balls 14 are connected to the bottom of the moving groove 2 in a rolling mode, and when the nut 62 moves in the moving groove 2, the balls 14 in the rolling groove 13 are driven to roll at the bottom of the moving groove 2, so that the nut 62 can move stably in the moving groove 2.

The filter screen 15 is fixedly connected in the orifice of one end of the motor mounting hole 3, which is far away from the moving groove 2, and is used for filtering air entering the motor mounting hole 3.

The telescopic rod 12 comprises an outer tube 121 and an inner rod 122, the outer tube 121 is fixedly connected to the support frame 11, the inner rod 122 is slidably connected to the outer tube 121, and one end of the inner rod 122, which is close to the support plate 7, is connected to the support plate 7.

The ball 14 has a larger spherical diameter than the groove diameter of the notch of the rolling groove 13, preventing the ball 14 from slipping out of the rolling groove 13.

The inner rod 122 is symmetrically and fixedly connected with the sliding blocks 16 on the rod wall at the position of the end, away from the supporting plate 7, of the inner rod 122, the sliding grooves 17 are formed in the inner tube wall of the outer tube 121 in the vertical direction, the sliding blocks 16 are connected in the corresponding sliding grooves 17 in a sliding mode, the sliding blocks 16 are driven to move synchronously in the sliding grooves 17 when the inner rod 122 moves, and the inner rod 122 is prevented from being separated from the outer tube 121.

In the utility model, the rotation direction of the output end of the motor 4 can be changed by changing the current direction of the motor 4, the motor 4 drives the threaded rod 61 to rotate through the rotating shaft 5, along with the rotation of the threaded rod 61, the two nuts 62 correspondingly move in opposite directions or back to back according to the rotation direction of the threaded rod 61, and the two nuts 62 drive the support plate 7 to move in the vertical direction through the two transmission rods 63 when moving, so that the camera 9 is lifted to meet the requirements of field activities; when motor 4 drives axis of rotation 5 and rotates, axis of rotation 5 drives rotating tube 93 and rotates in bearing 92 of support frame 91, drives flabellum 94 when rotating tube 93 rotates and rotates for the velocity of flow of air in motor mounting hole 3, accelerates the radiating effect to motor 4.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims

1. A telescopic structure of high-altitude monitoring equipment comprises a mounting plate (1), and is characterized in that a moving groove (2) is formed in the mounting plate (1), a motor mounting hole (3) is formed in a vertical groove wall at one end of the moving groove (2), a motor (4) is fixedly connected in the motor mounting hole (3), an output end of the motor (4) is connected with a rotating shaft (5) through a coupling, the other end of the rotating shaft (5) is connected with a supporting plate (7) through a telescopic mechanism (6), the lower end of the supporting plate (7) is connected with a camera (8), and the telescopic mechanism (6) is arranged in the moving groove (2);

telescopic machanism (6) include threaded rod (61), two nuts (62) and two transfer lines (63), the one end fixed connection of threaded rod (61) is in the one end of keeping away from motor (4) in axis of rotation (5), threaded rod (61) sets up in shifting chute (2), just be equipped with symmetry and opposite screw thread on threaded rod (61), two nut (62) symmetry threaded connection is on the pole wall of threaded rod (61), two the one end of transfer line (63) articulates respectively on the annular side wall of a nut (62) that corresponds, and two the other end of transfer line (63) articulates the one end of keeping away from camera (8) in backup pad (7).

2. The aerial monitoring device telescopic structure according to claim 1, wherein a heat dissipation mechanism (9) is fixedly connected to the shaft wall of the rotating shaft (5), the heat dissipation mechanism (9) comprises a cross-shaped support frame (91), a bearing (92), a rotating pipe (93) and fan blades (94), the support frame (91) is fixedly connected to the hole wall of the motor mounting hole (3), a rotating hole is formed in the center of the support frame (91), the annular outer side wall of the bearing (92) is connected with the hole wall of the rotating hole, the outer pipe wall of the rotating pipe (93) is connected with the inner ring wall of the bearing (92), two ends of the rotating pipe (93) penetrate through the bearing (92) and extend outwards, the fan blades (94) are fixedly sleeved on the outer pipe wall of the rotating pipe (93), and the rotating shaft (5) penetrates through the rotating pipe (93), and the rotating pipe (93) is fixedly sleeved on the shaft wall of the rotating shaft (5).

3. The telescopic structure of the high altitude monitoring equipment according to claim 1, wherein a bearing seat (10) is fixedly connected to one end of the moving groove (2) far away from the motor mounting hole (3), one end of the threaded rod (61) far away from the rotating shaft (5) extends into the bearing seat (10), and the threaded rod (61) is connected with an inner ring of the bearing seat (10).

4. The telescopic structure of the high altitude monitoring equipment according to claim 1, wherein a support frame (11) in a U shape is fixedly connected to the center of the opening of the moving groove (2), a telescopic rod (12) is fixedly connected to one end of the support frame (11) close to the support plate (7), and the other end of the telescopic rod (12) is connected to the support plate (7).

5. The telescopic structure of the high altitude monitoring equipment is characterized in that a rolling groove (13) is formed in the annular side wall of the nut (62) close to one end of the bottom of the moving groove (2), a rolling ball (14) is arranged in the rolling groove (13), one end, far away from the bottom of the rolling groove (13), of the rolling ball (14) penetrates through the notch of the rolling groove (13), and the rolling ball (14) is connected to the bottom of the moving groove (2) in a rolling mode.

6. The telescopic structure of the high-altitude monitoring equipment is characterized in that a filter screen (15) is fixedly connected in an orifice at one end, far away from the moving groove (2), of the motor mounting hole (3).

7. The telescopic structure of the high altitude monitoring equipment is characterized in that the telescopic rod (12) comprises an outer tube (121) and an inner rod (122), the outer tube (121) is fixedly connected to the support frame (11), the inner rod (122) is slidably connected to the inner tube (121), and one end, close to the support plate (7), of the inner rod (122) is connected with the support plate (7).

8. A telescopic structure for high altitude monitoring equipment according to claim 5, characterized in that the ball diameter of the ball (14) is larger than the groove diameter of the notch of the rolling groove (13).

9. The telescopic structure of the high altitude monitoring equipment according to claim 7, characterized in that the rod wall of the inner rod (122) at a position far away from the supporting plate (7) is symmetrically and fixedly connected with sliding blocks (16), the inner tube wall of the outer tube (121) is provided with sliding grooves (17) along the vertical direction, and the sliding blocks (16) are slidably connected in the corresponding sliding grooves (17).