CN114019867B - Intelligent monitoring system for building - Google Patents

Abstract

The application belongs to the technical field of monitoring, in particular to an intelligent monitoring system for building, which comprises a fixed frame, wherein an A sleeve seat is fastened on a bolt at the top of the fixed frame, a synchronous deflection assembly is arranged in the A sleeve seat, one end of the synchronous deflection assembly penetrates out of the A sleeve seat and is in threaded connection with a fixed plate, a monitoring camera is rotationally connected to the top of the fixed plate, a B sleeve seat is fastened on the bolt at the top of the A sleeve seat, a synchronous rotation assembly is arranged in the B sleeve seat, a bracket is fastened on one side of the B sleeve seat through a bolt, a mounting frame is fastened on the bolt at the top of the bracket, and a synchronous lifting assembly is fastened on the bolt at the inner wall of the mounting frame; the application can rapidly install the monitoring camera and synchronously adjust the monitoring angles of the two groups of monitoring cameras through the matching of the synchronous deflection assembly, the synchronous rotation assembly and the synchronous lifting assembly, and simultaneously, the application is convenient for rapidly installing and detaching the monitoring camera through the matching of the rapid assembly and the rapid disassembly assembly, and has good use effect.

Description

Intelligent monitoring system for building

Technical Field

The application belongs to the technical field of monitoring, and particularly relates to an intelligent monitoring system for a building.

Background

In the intelligent monitoring system of building, the surveillance camera is one of them important component, and current surveillance camera is generally mainly installed in corridor corner region and mostly is the individual installation, in order to guarantee the monitoring effect simultaneously, need to adjust surveillance angle of surveillance camera one by one manually after the installation, this kind of operation work efficiency is low, intensity of labour is big, has not satisfied the user demand.

In order to solve the problems, the application provides an intelligent monitoring system for a building.

Disclosure of Invention

In order to solve the problems in the background technology, the application provides an intelligent monitoring system for a building, which has the characteristic of being convenient for adjusting a monitoring camera.

In order to achieve the above purpose, the present application provides the following technical solutions: the utility model provides an intelligent monitored control system of building, includes the mount, mount top bolt is fastened and is had the A cover seat, just A cover seat embeds there is synchronous deflection subassembly, synchronous deflection subassembly one end runs through A cover seat outside and with mount top sliding connection, synchronous deflection subassembly runs through A cover seat outside one end top threaded connection have the fixed plate, just the fixed plate top rotates and is connected with rotatory pedestal, rotatory pedestal inner wall rotates and is connected with the surveillance camera machine, A cover seat top bolt is fastened and is had the B cover seat, just B cover seat embeds synchronous rotation subassembly, synchronous rotation subassembly one end runs through B cover seat top and is connected with the rotation axis frame through the drive belt, B cover seat one side bolt-up has the support, just support top bolt-up has the mounting bracket, mounting bracket surface sliding connection has the traction ring seat, just traction ring seat one end is connected with surveillance camera machine one end surface through the connection guide arm, mounting bracket inner wall bolt-up and is connected with synchronous lifting subassembly, just synchronous lifting subassembly one end is connected with the traction ring seat surface.

As the intelligent monitoring system for the building, the synchronous deflection assembly comprises a box seat, a toothed bar transmission assembly, a gear seat, a rotating wheel seat, a bar frame and a limit protruding rod, wherein the box seat is fastened at the top of a fixed frame and is positioned in an A sleeve seat, the toothed bar transmission assembly is slidably connected to the inner wall of the box seat, the gear seat is symmetrically and rotatably connected at the top of the fixed frame and is positioned at the outer side of the toothed bar transmission assembly, the gear seat is in meshed connection with the toothed bar transmission assembly, the rotating wheel seat is symmetrically and rotatably connected at the top of the fixed frame and is positioned at the outer side of the gear seat, one end of the bar frame, which is far away from the rotating wheel seat, penetrates out of the A sleeve seat, the limit protruding rod is in threaded connection with one end of the bar frame, which penetrates out of the A sleeve seat, and the limit protruding rod is slidably connected with the top of the fixed frame.

As the intelligent monitoring system for the building, the toothed bar transmission assembly comprises a middle toothed seat, an outer toothed seat, a toothed bar, an A motor and a transmission chain belt, wherein the middle toothed seat is rotationally connected to the top of a fixed frame and positioned in a box seat, the outer toothed seat is symmetrically rotationally connected to the top of the fixed frame and positioned on the outer side of the middle toothed seat, the outer toothed seat is in meshed connection with the middle toothed seat, the toothed bar is symmetrically and slidingly connected to the inner wall of the box seat and positioned on the outer side of the outer toothed seat, the toothed bar is in meshed connection with the outer toothed seat, the A motor is fastened on the top of the fixed frame and positioned in the box seat, and the A motor is positioned on the inner side of the toothed bar and is connected with one group of the outer toothed seats through the transmission chain belt.

As the intelligent monitoring system for the building, the rotary shaft bracket comprises the shaft wheel rotary seat and the connecting frame, wherein the shaft wheel rotary seat is rotatably connected to the top of the fixed plate, the shaft wheel rotary seat is connected with the synchronous rotary assembly through the driving belt, the connecting frame is fastened to the top of the shaft wheel rotary seat through bolts, and the monitoring camera is rotatably connected to the inner wall of the connecting frame.

As the optimal choice of the intelligent monitoring system for the building, the synchronous rotating assembly comprises a rotating frame, a first rotating wheel, a second rotating wheel, a transmission shaft column, a third rotating wheel, a fourth rotating wheel, a B motor, a transmission rotating wheel frame and a conveying belt, wherein the rotating frame is rotationally connected to the top of the B sleeve seat, the first rotating wheel is integrally formed at the top of the rotating frame and is positioned at the outer side of the top of the B sleeve seat, the second rotating wheel is integrally formed at the bottom of the rotating frame and is positioned in the B sleeve seat, the transmission shaft column is rotationally connected to the inner wall of the rotating frame, the third rotating wheel is positioned at the outer side of the first rotating wheel and is sleeved at the top of the transmission shaft column, the fourth rotating wheel is positioned in the B sleeve seat and is sleeved on the surface of the transmission shaft column, the fourth rotating wheel is positioned at the outer side of the second rotating wheel, the B motor is fixedly connected to the bottom of the transmission shaft column through bolts, the transmission rotating wheel frame is rotationally connected to the inner wall of the B sleeve seat and is positioned between the second rotating wheel and the fourth rotating wheel, and the transmission shaft column is respectively connected with the fourth rotating wheel and the fourth rotating wheel through the transmission shaft column and the third rotating wheel and the transmission shaft.

As the optimal selection of the intelligent monitoring system for the building, the synchronous lifting assembly comprises a guide wheel frame, a C motor, a conveying ring belt and a connecting block, wherein the guide wheel frame is uniformly and rotatably connected to the inner wall of the mounting frame, the C motor is fastened on the inner wall of the mounting frame through bolts, the output end of the C motor is fixedly connected to one group of guide wheel frame central shafts, the conveying ring belt is sleeved on the outer side of the guide wheel frame, and the connecting block is fixedly connected to the surface of the traction ring seat in a threaded manner and sleeved on the outer side of the conveying ring belt.

As the intelligent monitoring system for the building, the intelligent monitoring system for the building is preferable, quick assembly components are symmetrically arranged on the outer side wall of the monitoring camera, the quick assembly components comprise slotted holes, a cylinder body, clamping columns and A springs, the slotted holes are symmetrically formed in the surface of the monitoring camera, the cylinder body is in threaded connection with the inner wall of the slotted holes, the clamping columns are in sliding connection with the inner wall of the cylinder body, the A springs are arranged in the cylinder body, and two ends of the A springs are respectively fixedly connected with the inner wall of the cylinder body and the surface of the clamping columns.

As the intelligent monitoring system for the building, the outer side wall of the connecting frame is symmetrically provided with the quick-dismantling assembly, the quick-dismantling assembly comprises a clamping hole, a column seat, a push rod and a B spring, the clamping hole is symmetrically formed in the outer side wall of the connecting frame, the clamping column is clamped and fixed in the clamping hole, the column seat is symmetrically fastened on the outer side wall of the connecting frame and positioned at the outer side of the clamping hole, the push rod is slidably connected to the inner wall of the column seat, one end of the push rod penetrates into the clamping hole and is attached to the surface of one end of the clamping column, and the B spring is positioned in the column seat and sleeved on the outer side of the push rod.

As the intelligent monitoring system for the building, the A sleeve seat is internally provided with the sub-controller and is positioned at one side of the box seat, the sub-controller is respectively and electrically connected with the A motor, the B motor and the C motor, the sub-controller is internally provided with the wireless communication module, and the sub-controller is in communication connection with an external control terminal through the wireless communication module.

As the intelligent monitoring system for the building, the intelligent monitoring system for the building is preferable, guide grooves are formed in positions, corresponding to the positions of limiting convex rods, of the top of a fixing frame, the limiting convex rods are slidably connected in the guide grooves, kidney-shaped guide grooves and guide cylinders are respectively formed in positions, corresponding to the tops of toothed bars, of the top of a box seat, the guide cylinders are slidably connected to the inner walls of the kidney-shaped guide grooves, teeth are formed in positions, corresponding to the positions of an outer tooth seat and a gear seat, of the surface of the toothed bar, through grooves are formed in positions, corresponding to the positions of the teeth, of the outer side wall of the box seat, the first rotating wheel is matched with the outer dimension of a third rotating wheel, the second rotating wheel is matched with the outer dimension of a fourth rotating wheel, the two groups of monitoring cameras are arranged in a degree, and distances between the two groups of monitoring cameras and the synchronous deflection assemblies, the synchronous rotation assemblies and the traction ring seat are equal.

Compared with the prior art, the application has the beneficial effects that:

(1) The application has novel design, reasonable structure and simple integral operation, is convenient to use, and is provided with the synchronous deflection assembly, when the horizontal distance between two groups of monitoring cameras and a wall is required to be adjusted, the sub-controller controls the motor A to be electrified and run, the motor A drives one group of external tooth seats to rotate through the transmission chain belt, the external tooth seats rotate to drive the middle tooth seat to rotate and synchronously drive the other group of external tooth seats to rotate, the tooth bars meshed with the two groups of external tooth seats rotate, simultaneously move to one side on the inner wall of the box seat and synchronously drive the two groups of gear seats meshed with the two groups of external tooth seats to reversely rotate, the gear seat rotates and synchronously drive the bar frame to rotate by taking the runner seat as the center, the bar frame rotates and drives the fixing plate screwed connection at the top of one end of the bar frame to synchronously move, and synchronously drive the two groups of monitoring cameras to approach or separate from the wall, so that the horizontal distance between the monitoring cameras and the wall is adjusted, wherein the limit protruding bars play a role in guiding and limiting function on the bar frame, so that the running stability is improved, the integral operation is simple, and the use effect is good.

(2) The synchronous rotating assembly is arranged, when the left and right angles of the two groups of monitoring cameras are required to be adjusted, the sub-controller controls the B motor to be electrified and operated, the B motor is electrified and rotated to drive the transmission shaft post to synchronously rotate, the transmission shaft post is rotated to drive the third rotating wheel and the fourth rotating wheel to synchronously rotate, and the fourth rotating wheel is connected with the transmission rotating wheel frame and the second rotating wheel, so that the second rotating wheel is synchronously driven to rotate while the fourth rotating wheel is rotated, the rotating frame is synchronously driven to rotate by the second rotating wheel, the rotating frame is synchronously driven to rotate in the opposite direction of the first rotating wheel and the third rotating wheel, and then the first rotating wheel and the third rotating wheel are connected with the shaft wheel rotating seat through the transmission belt, so that the shaft wheel rotating seat can also rotate and synchronously drive the monitoring cameras on the connecting frame to synchronously rotate inwards or outwards under the action of the transmission belt, the left and right angles of the monitoring cameras are synchronously driven to be adjusted, the synchronous rotating assembly is convenient to drive the left and right angles of the two groups of monitoring cameras to synchronously adjust inwards or outwards, the operation is simple, and the use effect is good.

(3) The synchronous lifting assembly is arranged, when the up-down angles of the two groups of monitoring cameras are required to be adjusted, the sub-controller controls the C motor to be electrified and operated, the C motor is electrified and rotated to drive one group of guide wheel frames to rotate, the guide wheel frames rotate and drive the other guide wheel frames to synchronously rotate through the conveying endless belt, the conveying endless belt synchronously drives the connecting block to move in the moving process, the connecting block synchronously drives the traction ring seat to move up and down on the surface of the mounting frame, the traction ring seat synchronously drives the monitoring cameras to rotate by taking the inner wall of the connecting frame as the center through the connecting guide rod, one end of each of the monitoring cameras is driven to synchronously move up or down, the up-down angle adjustment of the monitoring cameras is realized, and the synchronous lifting assembly is convenient to drive the up-down angles of the two groups of monitoring cameras to synchronously adjust up or down.

(4) The quick-assembly component and the quick-disassembly component are arranged, when two groups of monitoring cameras are required to be installed, the clamping columns on two sides of the monitoring cameras are pressed and retracted into the cylinder, then the monitoring cameras are placed into the connecting frame, the clamping columns are loosened, the clamping columns are still positioned in the cylinder under the extrusion of the inner wall of the connecting frame, when the clamping columns move to the corresponding positions of the clamping holes, the clamping columns are ejected under the action of the springs A and extend into the clamping holes so as to clamp and fix the monitoring cameras, the quick-assembly component is designed to be convenient for quickly installing the two groups of monitoring cameras, the operation is simple, time and labor are saved, the use effect is good, when the two groups of monitoring cameras are required to be disassembled, the push rods are inwards pressed, the push rods extend into the clamping holes under the action of external force and extrude the clamping columns from the inside the clamping holes, then the monitoring cameras are outwards pulled to complete the disassembly, then the push rods are loosened, and reset under the action of the springs B, and the quick-assembly component is designed to be convenient for quickly disassembling the two groups of monitoring cameras, so that the operation is simple, time and labor are saved, and the use effect is good.

Drawings

The accompanying drawings are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate the application and together with the embodiments of the application, serve to explain the application. In the drawings:

FIG. 1 is a schematic diagram of the structure of the present application;

FIG. 2 is a schematic diagram of a synchronous deflection assembly according to the present application;

FIG. 3 is a schematic view of a rack bar transmission assembly according to the present application;

FIG. 4 is a schematic view of a rotating shaft frame according to the present application;

FIG. 5 is a schematic view of a synchronous rotating assembly according to the present application;

FIG. 6 is a schematic view of a synchronous lifting assembly according to the present application;

FIG. 7 is a schematic view of a quick assembly according to the present application;

fig. 8 is a schematic structural diagram of a quick-release assembly according to the present application.

In the figure:

1. a fixing frame; 2. a sleeve seat A;

3. a synchronous deflection assembly; 31. a box base; 32. a toothed bar transmission assembly; 321. a middle tooth seat; 322. an outer tooth holder; 323. a toothed bar; 324. a, a motor; 325. a drive chain belt; 33. a gear seat; 34. a rotating wheel seat; 35. a pole frame; 36. a limit protruding rod;

4. a fixing plate;

5. a rotating shaft bracket; 51. a shaft wheel rotating seat; 52. a connecting frame;

6. a monitoring camera; 7. a sleeve seat B;

8. a synchronous rotating assembly; 81. a rotating frame; 82. a first wheel; 83. a second wheel; 84. a drive shaft post; 85. a third wheel; 86. a fourth wheel; 87. a motor B; 88. a transmission rotating wheel frame; 89. a conveyor belt;

9. a transmission belt; 10. a bracket; 11. a mounting frame; 12. a traction ring seat; 13. connecting a guide rod;

14. a synchronous lifting assembly; 141. a guide wheel frame; 142. a motor C; 143. a conveyor belt; 144. a connecting block;

15. a quick assembly component; 151. a slot hole; 152. a cylinder; 153. a clamping column; 154. a, a spring;

16. a quick release assembly; 161. a clamping hole; 162. a column base; 163. a push rod; 164. a spring B;

17. a sub-controller;

100. a guide groove; 200. waist-shaped guide grooves; 300. a guide cylinder; 400. teeth.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

Example 1

Please refer to fig. 1-8;

the utility model provides an intelligent monitored control system of building, including mount 1, mount 1 top bolt is fixed A cover seat 2, and A cover seat 2 embeds synchronous deflection unit 3, synchronous deflection unit 3 one end runs through A cover seat 2 outside and with mount 1 top sliding connection, synchronous deflection unit 3 runs through A cover seat 2 outside one end top threaded connection has fixed plate 4, and fixed plate 4 top rotation is connected with rotatory pedestal 5, rotatory pedestal 5 inner wall rotation is connected with surveillance camera machine 6, A cover seat 2 top bolt is fixed B cover seat 7, and B cover seat 7 embeds synchronous rotation unit 8, synchronous rotation unit 8 one end runs through B cover seat 7 top and is connected with rotatory pedestal 5 through drive belt 9, B cover seat 7 one side bolt is fixed support 10, and support 10 top bolt is fixed mounting bracket 11, mounting bracket 11 surface sliding connection has traction ring seat 12, and traction ring seat 12 one end is connected with surveillance camera machine 6 one end surface through connecting guide rod 13, mounting bracket 11 inner wall bolt is fixed synchronous lifting unit 14, and synchronous lifting unit 14 one end is connected with traction ring seat surface.

In this embodiment: when two groups of monitoring cameras 6 are required to be installed, the clamping columns 153 on two sides of the monitoring cameras 6 are pressed and retracted into the barrel 152, then the monitoring cameras 6 are placed into the connecting frame 52, then the clamping columns 153 are loosened, the clamping columns 153 are still positioned in the barrel 152 under the extrusion of the inner wall of the connecting frame 52, when the clamping columns 153 move to the corresponding positions of the clamping holes 161, the clamping columns 153 are ejected under the action of the A springs 154 and extend into the clamping holes 161 so as to clamp and fix the monitoring cameras 6, the quick assembly 15 is designed to be convenient for quickly installing the two groups of monitoring cameras 6, the operation is simple, time and labor are saved, the use effect is good, when the two groups of monitoring cameras 6 are required to be disassembled, the push rod 163 is pressed inwards, the push rod 163 extends into the clamping holes 161 under the action of external force and extrudes the clamping columns 153 from the inside of the clamping holes 161, then the monitoring cameras 6 are pulled outwards to finish the disassembly, then the push rod 163 is released, the push rod 163 is reset under the action of the B spring 164, the quick-release assembly 16 is designed to facilitate the quick-release assembly to detach two groups of monitoring cameras 6, the operation is simple, time and labor are saved, the use effect is good, when the horizontal distance between the two groups of monitoring cameras 6 and the wall is required to be adjusted, the sub-controller 17 controls the A motor 324 to be electrified and operated, the A motor 324 is electrified and rotated and drives one group of outer tooth seats 322 to rotate through the transmission chain belt 325, the outer tooth seats 322 rotate and drive the middle tooth seat 321 to rotate and synchronously drive the other group of outer tooth seats 322 to rotate, the tooth bars 323 which are in meshed connection with the two groups of outer tooth seats 322 rotate, simultaneously drive the two groups of gear seats 33 which are in meshed connection with the two groups of outer tooth seats 31 to reversely rotate, the gear seats 33 rotate and synchronously drive the bar frame 35 to rotate by taking the rotating wheel seat 34 as the center, the rod frame 35 rotates to drive the fixed plate 4 screwed on the top of one end of the rod frame 35 to synchronously move and synchronously drive the two groups of monitoring cameras 6 to synchronously move towards or away from the wall body, so that the adjustment of the horizontal distance between the monitoring cameras 6 and the wall body is realized, wherein the limiting convex rod 36 plays a role in guiding and limiting the rod frame 35, the operation stability is improved, the whole operation is simple, the use effect is good, when the left and right angles of the two groups of monitoring cameras 6 are required to be adjusted, the sub-controller 17 controls the B motor 87 to be electrified and operated, the B motor 87 is electrified and rotated to drive the transmission shaft column 84 to synchronously rotate, the transmission shaft column 84 rotates to drive the third rotary wheel 85 and the fourth rotary wheel 86 to synchronously rotate, the fourth rotary wheel 86 simultaneously drives the second rotary wheel 83 to rotate while the fourth rotary wheel frame 86 rotates, the second rotary wheel 82 rotates to synchronously drive the rotary frame 81, the first rotary wheel 82 rotates in the opposite direction to the third rotary wheel 85, then the first rotary wheel 82 and the third rotary wheel 85 are connected with the rotary wheel 51 through the transmission belt 9, the rotary wheel frame 9 rotates to drive the left and right angles of the monitoring camera 141 through the rotary frame 9, the rotary frame 141 rotates to drive the rotary frame 141 simultaneously when the two groups of the left and right angles of the monitoring cameras 6 are required to be adjusted, the rotary frame 141 rotates to simultaneously, the rotary frame 141 rotates to drive the rotary frame 141 rotates to rotate the monitoring camera is realized by the rotary frame 141, and the rotary frame 141 rotates outside the rotary frame is controlled to simultaneously, and the rotary frame 141 is controlled to rotate the rotary frame is simultaneously, and the rotary frame is connected to the rotary frame is rotated to the rotary frame 141, the conveyer belt 143 is synchronous to drive the connecting block 144 to remove at the removal in-process, and the connecting block 144 removes and drives the traction ring seat 12 in step and is the up-and-down motion on the surface of mounting bracket 11, and the traction ring seat 12 up-and-down motion passes through the synchronous drive surveillance camera machine 6 of connecting guide arm 13 and rotates taking the link 52 inner wall as the center to drive the synchronous upward or downward movement of surveillance camera machine 6 one end, thereby realize the regulation of two sets of surveillance camera machine 6 upper and lower angles, synchronous lifting assembly 14 design is convenient for drive two sets of surveillance camera machine 6 upper and lower angle and synchronous upward or downward regulation, easy operation, excellent in use effect.

Further, the method comprises the following steps:

in an alternative embodiment: the synchronous deflection assembly 3 comprises a box seat 31, a toothed bar transmission assembly 32, a gear seat 33, a rotating wheel seat 34, a rod frame 35 and a limiting convex rod 36, wherein the box seat 31 is fastened at the top of the fixed frame 1 and positioned in the sleeve seat A2, the toothed bar transmission assembly 32 is slidingly connected to the inner wall of the box seat 31, the gear seat 33 is symmetrically and rotationally connected to the top of the fixed frame 1 and positioned at the outer side of the toothed bar transmission assembly 32, the gear seat 33 is meshed with the toothed bar transmission assembly 32, the rotating wheel seat 34 is symmetrically and rotationally connected to the top of the fixed frame 1 and positioned at the outer side of the gear seat 33, the rod frame 35 is rotationally connected to the top of the rotating wheel seat 34 and meshed with the gear seat 33, one end of the rod frame 35 far away from the rotating wheel seat 34 penetrates out of the sleeve seat A2, the limiting convex rod 36 is in threaded connection with the rod frame 35 penetrates out of one end bottom of the sleeve seat A2, and the limiting convex rod 36 is slidingly connected with the top of the fixed frame 1.

In this embodiment, the following description is given of the present application. When the horizontal positions of the two groups of monitoring cameras 6 away from the wall are required to be adjusted, the sub-controller 17 controls the motor 324 to be electrified and operated, the motor 324 is electrified and rotated to drive one group of outer tooth seats 322 to rotate through the transmission chain belt 325, the outer tooth seats 322 rotate to drive the middle tooth seat 321 to rotate and synchronously drive the other group of outer tooth seats 322 to rotate, the tooth bars 323 which are in meshed connection with the two groups of outer tooth seats 322 move to one side on the inner wall of the box seat 31 while the two groups of outer tooth seats 322 rotate, synchronously drive the two groups of gear seats 33 which are in meshed connection with the two groups of outer tooth seats 33 to reversely rotate, the gear seats 33 rotate to synchronously drive the rod frames 35 to rotate by taking the rotary wheel seat 34 as the center, the rod frames 35 rotate to drive the fixed plate 4 which is in threaded connection with one end top of the rod frames 35 to synchronously move, and synchronously drive the two groups of monitoring cameras 6 to synchronously approach or separate from the wall, so that the adjustment of the horizontal distance of the monitoring cameras 6 away from the wall is realized, wherein the limiting convex bars 36 play a role in guiding and limiting function to improve the running stability of the rod frames 35, the whole operation is simple, and good use effect.

Still further, the method comprises:

in an alternative embodiment: the rack transmission assembly 32 comprises a middle rack 321, an external rack 322, a rack 323, an A motor 324 and a transmission chain belt 325, wherein the middle rack 321 is rotationally connected at the top of the fixed frame 1 and positioned in the box seat 31, the external rack 322 is symmetrically rotationally connected at the top of the fixed frame 1 and positioned at the outer side of the middle rack 321, the external rack 322 is meshed with the middle rack 321, the rack 323 is symmetrically and slidingly connected on the inner wall of the box seat 31 and positioned at the outer side of the external rack 322, the rack 323 is meshed with the external rack 322, the A motor 324 is fastened at the top of the fixed frame 1 and positioned in the box seat 31, and the A motor 324 is positioned at the inner side of the rack 323 and connected with one group of the external racks 322 through the transmission chain belt 325.

In this embodiment, the following description is given of the present application. When two sets of gear seats 33 need to be synchronously driven to rotate reversely, the sub-controller 17 controls the A motor 324 to be electrified to run, the A motor 324 is electrified to rotate and drives one set of outer gear seats 322 to rotate through the transmission chain belt 325, the outer gear seats 322 rotate to drive the middle gear seat 321 to rotate and synchronously drive the other set of outer gear seats 322 to rotate, the toothed bar 323 which is meshed with the two sets of outer gear seats 322 moves to one side on the inner wall of the box seat 31 and synchronously drives the gear seats 33 which are meshed with the two sets of outer gear seats to synchronously rotate, and the toothed bar transmission assembly 32 is convenient to drive the two sets of gear seats 33 to synchronously rotate reversely.

Still further, the method comprises:

in an alternative embodiment: the rotating shaft bracket 5 comprises a shaft wheel rotating seat 51 and a connecting frame 52, the shaft wheel rotating seat 51 is rotationally connected to the top of the fixed plate 4, the shaft wheel rotating seat 51 is connected with the synchronous rotating assembly 8 through a transmission belt 9, the connecting frame 52 is fastened to the top of the shaft wheel rotating seat 51 through bolts, and the monitoring camera 6 is rotationally connected to the inner wall of the connecting frame 52.

In this embodiment, the following description is given of the present application. During the use, firstly install the arbor wheel swivel mount 51 rotation at fixed plate 4 top, then be connected arbor wheel swivel mount 51 and synchronous rotatory subassembly 8 through drive belt 9, then with surveillance camera machine 6 rotate install at link 52 inner wall can, rotatory pedestal 5 design be convenient for synchronous rotatory subassembly 8 drive two sets of surveillance camera machine 6 synchronous revolution through drive belt 9, realize controlling angle adjustment, whole easy operation, convenient to use.

Still further, the method comprises:

in an alternative embodiment: the synchronous rotating assembly 8 comprises a rotating frame 81, a first rotating wheel 82, a second rotating wheel 83, a transmission shaft column 84, a third rotating wheel 85, a fourth rotating wheel 86, a B motor 87, a transmission rotating wheel frame 88 and a conveying belt 89, wherein the rotating frame 81 is rotationally connected to the top of the B sleeve seat 7, the first rotating wheel 82 is integrally formed at the top of the rotating frame 81 and is positioned at the outer side of the top of the B sleeve seat 7, the second rotating wheel 83 is integrally formed at the bottom of the rotating frame 81 and is positioned in the B sleeve seat 7, the transmission shaft column 84 is rotationally connected to the inner wall of the rotating frame 81, the third rotating wheel 85 is positioned at the outer side of the first rotating wheel 82 and is sleeved at the top of the transmission shaft column 84, the fourth rotating wheel 86 is positioned in the B sleeve seat 7 and is sleeved on the surface of the transmission shaft column 84, the fourth rotating wheel 86 is positioned at the outer side of the second rotating wheel 83, the B motor 87 is fixedly connected to the bottom of the transmission shaft column 84 through bolts, the transmission rotating wheel frame 88 is rotationally connected to the inner wall of the B sleeve seat 7 and is positioned between the second rotating wheel 83 and the fourth rotating wheel 86, the transmission rotating wheel frame 88 is respectively connected to the fourth rotating wheel frame 86 and the fourth rotating wheel 85 through the conveying belt 89 and the transmission shaft column 51.

In this embodiment, the following description is given of the present application. When the left and right angles of the two groups of monitoring cameras 6 need to be adjusted, the sub-controller 17 controls the B motor 87 to be electrified and operated, the B motor 87 is electrified and rotated to drive the transmission shaft column 84 to synchronously rotate, the transmission shaft column 84 is rotated to drive the third rotating wheel 85 and the fourth rotating wheel 86 to synchronously rotate, and as the conveying belt 89 is connected between the fourth rotating wheel 86 and the transmission rotating wheel frame 88 and the second rotating wheel 83, the fourth rotating wheel 86 is rotated to synchronously drive the second rotating wheel 83 to rotate, the second rotating wheel 83 is rotated to synchronously drive the rotating frame 81 to rotate, the rotating frame 81 is rotated to synchronously drive the first rotating wheel 82 to rotate in the opposite direction with the third rotating wheel 85, and then the first rotating wheel 82 and the third rotating wheel 85 are connected with the shaft wheel rotating seat 51 through the transmission belt 9, so that the shaft wheel rotating seat 51 can also rotate under the action of the transmission belt 9 and synchronously drive the monitoring cameras 6 on the connecting frame 52 to synchronously rotate inwards or outwards, and the left and right angles of the two groups of monitoring cameras 6 are adjusted, and the synchronous rotating assembly 8 is designed to conveniently drive the left and right angles of the two groups of monitoring cameras 6 to synchronously adjust inwards or outwards.

Still further, the method comprises:

in an alternative embodiment: the synchronous lifting assembly 14 comprises a guide wheel frame 141, a C motor 142, a conveying ring belt 143 and a connecting block 144, wherein the guide wheel frame 141 is uniformly and rotatably connected to the inner wall of the mounting frame 11, the C motor 142 is fastened to the inner wall of the mounting frame 11 through bolts, the output end of the C motor 142 is fixedly connected to the central shaft of one group of guide wheel frames 141, the conveying ring belt 143 is sleeved on the outer side of the guide wheel frame 141, and the connecting block 144 is fixedly connected to the surface of the traction ring seat 12 through bolts and sleeved on the outer side of the conveying ring belt 143.

In this embodiment, the following description is given of the present application. When the up-down angles of the two groups of monitoring cameras 6 are required to be adjusted, the sub-controller 17 controls the C motor 142 to be electrified and operated, the C motor 142 is electrified and rotated to drive one group of guide wheel frames 141 to rotate, the guide wheel frames 141 are rotated to drive the other guide wheel frames 141 to synchronously rotate through the conveying ring belt 143, the conveying ring belt 143 synchronously drives the connecting block 144 to move in the moving process, the connecting block 144 synchronously drives the traction ring seat 12 to move up and down on the surface of the mounting frame 11, the traction ring seat 12 synchronously drives the monitoring cameras 6 to rotate by taking the inner wall of the connecting frame 52 as the center through the connecting guide rod 13, so that one ends of the two groups of monitoring cameras 6 are driven to synchronously move up or down, the up-down angle adjustment of the monitoring cameras 6 is realized, the synchronous lifting assembly 14 is designed to conveniently drive the up-down angles of the two groups of monitoring cameras 6 to synchronously adjust up or down, the operation is simple, and the use effect is good.

Still further, the method comprises:

in an alternative embodiment: the outer side wall of the monitoring camera 6 is symmetrically provided with a fast-assembling assembly 15, the fast-assembling assembly 15 comprises a slotted hole 151, a barrel 152, a clamping column 153 and an A spring 154, the slotted hole 151 is symmetrically arranged on the surface of the monitoring camera 6, the barrel 152 is connected with the inner wall of the slotted hole 151 in a threaded manner, the clamping column 153 is connected with the inner wall of the barrel 152 in a sliding manner, the A spring 154 is arranged in the barrel 152, and two ends of the A spring 154 are respectively fixedly connected with the inner wall of the barrel 152 and the surface of the clamping column 153.

In this embodiment, the following description is given of the present application. When two groups of monitoring cameras 6 are required to be installed, the clamping columns 153 on two sides of the monitoring cameras 6 are pressed and retracted into the barrel 152, then the monitoring cameras 6 are placed into the connecting frame 52, the clamping columns 153 are loosened, the clamping columns 153 are still positioned in the barrel 152 under the extrusion of the inner wall of the connecting frame 52, when the clamping columns 153 move to the corresponding positions of the clamping holes 161, the clamping columns are ejected out and extend into the clamping holes 161 under the action of the A springs 154, so that the monitoring cameras 6 are clamped and fixed, and the quick assembly 15 is convenient to install the two groups of monitoring cameras 6 quickly, and is simple in operation, time-saving and labor-saving, and good in use effect.

Still further, the method comprises:

in an alternative embodiment: the outer side wall of the connecting frame 52 is symmetrically provided with a quick-release assembly 16, the quick-release assembly 16 comprises a clamping hole 161, a column seat 162, a push rod 163 and a B spring 164, the clamping hole 161 is symmetrically arranged on the outer side wall of the connecting frame 52, the clamping column 153 is clamped and fixed in the clamping hole 161, the column seat 162 is symmetrically fastened on the outer side wall of the connecting frame 52 and positioned on the outer side of the clamping hole 161, the push rod 163 is slidably connected on the inner wall of the column seat 162, one end of the push rod 163 penetrates into the clamping hole 161 and is attached to the surface of one end of the clamping column 153, and the B spring 164 is positioned in the column seat 162 and sleeved on the outer side of the push rod 163.

In this embodiment, the following description is given of the present application. When two sets of surveillance cameras 6 need be dismantled, inwards press push rod 163, push rod 163 stretches into in card hole 161 and extrude card post 153 from card hole 161 inside under the exogenic action, then outwards pull surveillance camera 6 can accomplish the dismantlement, unclamp push rod 163 afterwards, push rod 163 resets under the effect of B spring 164, quick detach subassembly 16 design is convenient for dismantle two sets of surveillance cameras 6 fast, easy operation, labour saving and time saving, excellent in use effect.

Still further, the method comprises:

in an alternative embodiment: the sub controller 17 is arranged in the A sleeve seat 2 and is positioned on one side of the box seat 31, the sub controller 17 is respectively and electrically connected with the A motor 324, the B motor 87 and the C motor 142, a wireless communication module is arranged in the sub controller 17, and the sub controller 17 is in communication connection with an external control terminal through the wireless communication module.

In this embodiment, the following description is given of the present application. The design of the sub-controller 17 is convenient for respectively controlling the motor A324, the motor B87 and the motor C142 so as to drive the two groups of monitoring cameras 6 to displace and adjust the monitoring angles, meanwhile, the wireless communication module is arranged in the sub-controller, the wireless communication module can receive the instruction sent by the external control terminal, and the sub-controller 17 adjusts the angles of the two groups of monitoring cameras 6 according to the instruction, so that the use effect is good.

Still further, the method comprises:

in an alternative embodiment: the top of the fixing frame 1 is provided with a guide groove 100 corresponding to the position of the limit protruding rod 36, the limit protruding rod 36 is slidably connected in the guide groove 100, the top of the box seat 31 and the position corresponding to the top of the toothed bar 323 are respectively provided with a kidney-shaped guide groove 200 and a guide cylinder 300, the guide cylinder 300 is slidably connected to the inner wall of the kidney-shaped guide groove 200, the positions corresponding to the outer tooth seat 322 and the gear seat 33 on the surface of the toothed bar 323 are respectively provided with teeth 400, the positions corresponding to the teeth 400 on the outer side wall of the box seat 31 are respectively provided with a through groove, the first rotating wheel 82 is matched with the outer dimension of the third rotating wheel 85, the second rotating wheel 83 is matched with the outer dimension of the fourth rotating wheel 86, the two groups of monitoring cameras 6 are arranged at 90 degrees, and the distances between the two groups of monitoring cameras 6 and the synchronous deflection assembly 3, the synchronous rotation assembly 8 and the traction ring seat 12 are equal.

In this embodiment, the following description is given of the present application. The guide groove 100 is designed to be convenient for guide and limit the limit protruding rod 36, stability of the rod frame 35 during operation is improved, the kidney-shaped guide groove 200 and the guide cylinder 300 are convenient for guide and limit the toothed bar 323, stable operation is ensured, the tooth 400 is designed to be convenient for be meshed with the external tooth seat 322 and the gear seat 33 to drive the toothed bar 323 to move, the operation is simple, the first rotating wheel 82 is matched with the third rotating wheel 85 in outline dimension, the second rotating wheel 83 is matched with the fourth rotating wheel 86 in outline dimension, synchronous driving of the transmission belt 9 is convenient for synchronous rotation, operation consistency is improved, the use effect is good, two groups of monitoring cameras 6 are arranged at 90 degrees, are convenient for monitoring the areas in two directions in the corner area, the distances between the two groups of monitoring cameras 6 and the synchronous deflection assembly 3, the synchronous rotation assembly 8 and the traction ring seat 12 are equal, synchronous adjustment is convenient for reducing errors, and the operation is simple, and the use effect is good.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present application, and the present application is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present application has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (7)

1. The utility model provides an intelligent monitored control system of building, includes mount (1), its characterized in that: the utility model discloses a synchronous rotating device, including mount (1) and mounting bracket (7), mount (2) are fixed on the bolt at mount (1) top, and A set seat (2) embeds synchronous deflection subassembly (3), synchronous deflection subassembly (3) one end runs through A set seat (2) outside and with mount (1) top sliding connection, synchronous deflection subassembly (3) run through A set seat (2) outside one end top threaded connection have fixed plate (4), just fixed plate (4) top rotation is connected with rotatory pedestal (5), rotatory pedestal (5) inner wall rotation is connected with surveillance camera machine (6), A set seat (2) top bolt is fixed with B set seat (7), just B set seat (7) embeds synchronous rotating device (8), synchronous rotating device (8) one end runs through B set seat (7) top and is connected with rotatory pedestal (5) through drive belt (9), B set seat (7) one side bolt tightening has support (10), and support (10) top bolt tightening has (11), guide arm (11) are connected with the surface of synchronous pulling ring (14) and one end of installing frame (7) is connected with the synchronous lifting device (13), one end of the synchronous lifting assembly (14) is connected with the surface of the traction ring seat (12);

the synchronous deflection assembly (3) comprises a box seat (31), a toothed bar transmission assembly (32), a gear seat (33), a rotating wheel seat (34), a rod frame (35) and a limit protruding rod (36), wherein the box seat (31) is fastened at the top of the fixed frame (1) through bolts and is positioned in the A sleeve seat (2), the toothed bar transmission assembly (32) is slidingly connected to the inner wall of the box seat (31), the gear seat (33) is symmetrically and rotationally connected to the top of the fixed frame (1) and is positioned at the outer side of the toothed bar transmission assembly (32), the gear seat (33) is in meshed connection with the toothed bar transmission assembly (32), the rotating wheel seat (34) is symmetrically and rotationally connected to the top of the rotating wheel seat (34) and is in meshed connection with the gear seat (33), one end of the rod frame (35) far away from the rotating wheel seat (34) penetrates out of the A sleeve seat (2), the limit protruding rod (36) is in threaded connection with one end of the rod frame (35) penetrating out of the A sleeve seat (2) and is in meshed connection with the outer side of the fixed frame (1);

the synchronous rotating assembly (8) comprises a rotating frame (81), a first rotating wheel (82), a second rotating wheel (83), a transmission shaft post (84), a third rotating wheel (85), a fourth rotating wheel (86), a B motor (87), a transmission rotating wheel frame (88) and a conveying belt (89), wherein the rotating frame (81) is rotationally connected to the top of a B sleeve seat (7), the first rotating wheel (82) is integrally formed on the top of the rotating frame (81) and is positioned on the outer side of the top of the B sleeve seat (7), the second rotating wheel (83) is integrally formed on the bottom of the rotating frame (81) and is positioned in the B sleeve seat (7), the transmission shaft post (84) is rotationally connected to the inner wall of the rotating frame (81), the third rotating wheel (85) is positioned on the outer side of the first rotating wheel (82) and is sleeved on the top of the transmission shaft post (84), the fourth rotating wheel (86) is positioned in the B sleeve seat (7) and is sleeved on the surface of the transmission shaft post (84), the fourth rotating wheel (86) is positioned on the outer side of the second rotating wheel (83), the motor (87) is fastened on the bottom of the B sleeve seat (7) and is fixedly connected to the corresponding transmission shaft post (84) at the bottom of the transmission shaft post (84), the transmission rotating wheel frame (88) is rotatably connected to the inner wall of the sleeve seat (7) and positioned between the second rotating wheel (83) and the fourth rotating wheel (86), the transmission rotating wheel frame (88) is respectively connected with the second rotating wheel (83) and the fourth rotating wheel (86) through a conveying belt (89), and the first rotating wheel (82) and the third rotating wheel (85) are both connected with the shaft wheel rotating seat (51) through a conveying belt (9);

the synchronous lifting assembly (14) comprises a guide wheel frame (141), a C motor (142), a conveying annular belt (143) and a connecting block (144), wherein the guide wheel frame (141) is uniformly and rotatably connected to the inner wall of the mounting frame (11), the C motor (142) is fastened to the inner wall of the mounting frame (11) through bolts, the output end of the C motor (142) is fixedly connected to the central shaft of one group of guide wheel frames (141), the conveying annular belt (143) is sleeved outside the guide wheel frame (141), and the connecting block (144) is fixedly connected to the surface of the traction ring seat (12) in a sleeved mode outside the conveying annular belt (143).

2. The intelligent monitoring system for a building of claim 1, wherein: the utility model provides a rack drive subassembly (32) is including well toothholder (321), external tooth seat (322), ratch (323), A motor (324) and transmission chain belt (325), well toothholder (321) rotate and connect at mount (1) top and be located inside box seat (31), external tooth seat (322) symmetry rotate and connect at mount (1) top and be located in the toothholder (321) outside, external tooth seat (322) are connected with well toothholder (321) meshing, ratch (323) symmetry sliding connection is in box seat (31) inner wall and be located outside toothholder (322), ratch (323) are connected with external tooth seat (322) meshing, A motor (324) bolt-up is at mount (1) top and be located inside box seat (31), A motor (324) are located the ratch (323) inboard and are connected with a set of outside toothholder (322) wherein through transmission chain belt (322).

3. The intelligent monitoring system for a building of claim 2, wherein: the rotating shaft bracket (5) comprises a shaft wheel rotating seat (51) and a connecting frame (52), the shaft wheel rotating seat (51) is rotationally connected to the top of the fixed plate (4), the shaft wheel rotating seat (51) is connected with the synchronous rotating assembly (8) through a transmission belt (9), the connecting frame (52) is fastened to the top of the shaft wheel rotating seat (51), and the monitoring camera (6) is rotationally connected to the inner wall of the connecting frame (52).

4. A building intelligent monitoring system according to claim 3, wherein: the utility model discloses a monitoring camera, including monitor camera (6) lateral wall symmetry is provided with fast-assembling subassembly (15), fast-assembling subassembly (15) are including slotted hole (151), barrel (152), card post (153) and A spring (154), the slotted hole (151) symmetry is seted up on monitor camera (6) surface, barrel (152) threaded connection is at slotted hole (151) inner wall, card post (153) sliding connection is at barrel (152) inner wall, A spring (154) set up inside barrel (152), A spring (154) both ends are fixed connection respectively at barrel (152) inner wall and card post (153) surface.

5. The intelligent monitoring system for a building of claim 4, wherein: the quick-release assembly is characterized in that quick-release assemblies (16) are symmetrically arranged on the outer side wall of the connecting frame (52), each quick-release assembly (16) comprises a clamping hole (161), a column seat (162), a push rod (163) and a B spring (164), the clamping holes (161) are symmetrically formed in the outer side wall of the connecting frame (52), the clamping columns (153) are clamped and fixed in the clamping holes (161), the column seats (162) are symmetrically fastened on the outer side wall of the connecting frame (52) and located on the outer side of the clamping holes (161), the push rod (163) is slidably connected to the inner wall of the column seat (162), one end of each push rod (163) penetrates into the clamping holes (161) and is attached to one end surface of each clamping column (153), and the B spring (164) is located in the column seat (162) and sleeved on the outer side of each push rod (163).

6. The intelligent monitoring system for a building of claim 5, wherein: the A sleeve seat (2) is internally provided with a sub-controller (17) and is positioned on one side of the box seat (31), the sub-controller (17) is electrically connected with an A motor (324), a B motor (87) and a C motor (142) respectively, the sub-controller (17) is internally provided with a wireless communication module, and the sub-controller (17) is in communication connection with an external control terminal through the wireless communication module.

7. The intelligent monitoring system for a building of claim 6, wherein: the utility model discloses a synchronous rotation device is characterized by comprising a box seat (31), a rack (323), a gear seat (33), a fixing frame (1), a gear seat (33), a gear seat (322) and a through groove (400) are respectively arranged at the corresponding position of the top of the fixing frame (1) corresponding to the position of the limit convex rod (36), the limit convex rod (36) is slidingly connected in the guide groove (100), kidney-shaped guide grooves (200) and guide cylinders (300) are respectively arranged at the corresponding positions of the top of the box seat (31) and the top of the gear seat (323), the guide cylinders (300) are slidingly connected on the inner wall of the kidney-shaped guide grooves (200), the corresponding positions of the surface of the gear seat (323) corresponding to the outer tooth seat (322) and the gear seat (33), the corresponding positions of the outer side wall of the box seat (31) corresponding to the gear tooth (400) are respectively provided with a through groove, the first rotating wheel (82) is matched with the overall size of a third rotating wheel (85), the overall size of the second rotating wheel (83) is matched with the fourth rotating wheel (86), two groups of monitoring cameras (6) are arranged at 90 degrees, and the two groups of monitoring cameras (6) are separated from a synchronous deflection assembly (3), a synchronous rotation assembly (8) and a traction ring (12).