CN117176033A - Intelligent monitoring equipment based on internet - Google Patents

Abstract

The application relates to the technical field of video monitoring security and protection, and provides intelligent monitoring equipment based on the Internet, which comprises a mounting frame, a driving mechanism, a climbing mechanism, a box body, a supporting component, a door opening and closing mechanism and a locking mechanism, wherein the driving mechanism comprises a motor, the output end of the motor is connected with an output shaft which is coaxially arranged through a coupler, when the mounting frame needs to be mounted through the arrangement of the motor, the output shaft and the like, the motor is started to drive the output shaft to rotate, a follow-up shaft is driven to rotate, a belt is driven to rotate, a climbing gear is driven to rotate, the mounting frame is driven to climb, and when the climbing is carried out to the topmost end, a locking block is clamped on a limiting block due to a third spring, so that the integral arrangement of the mounting frame is completed. Through the technical scheme, the problems of complex operation and non-environment-friendly use in the prior art are solved.

Description

Intelligent monitoring equipment based on internet

Technical Field

The application relates to the technical field of video monitoring security, in particular to intelligent monitoring equipment based on the Internet.

Background

At present, a typical television monitoring system mainly comprises a front-end device and a back-end device, wherein the front-end device is usually composed of a camera, a manual or electric lens, a holder, a protective cover, a monitor, an alarm detector, a multifunctional decoder and the like, and the front-end device and the back-end device respectively perform the functions and establish corresponding connection with various devices of a central control system through wired, wireless or optical fiber transmission media.

The authorized bulletin number in the prior art is: CN 211321422U's an intelligent video monitoring equipment based on internet technology, this patent discloses an intelligent video monitoring equipment based on internet technology, including the side fixed plate, side fixed plate side is fixed with the support column, support column side fixedly connected with jib, jib bottom and protection casing top fixed connection, top fixedly connected with connecting rod in the protection casing, connecting rod bottom fixedly connected with spherical control, protection casing top is fixed to be equipped with motor protection casing, and this intelligent video monitoring equipment based on internet technology is through setting up air exhauster, first air pipe, second air pipe and third air pipe, thereby in transporting the third air pipe through air exhauster with air through first air pipe and second air pipe, air-dry work to spherical control surface rainwater is realized through the third air pipe, realizes the fixed work to protection casing through the side mount, and is used for protecting spherical control through protection casing, however the artifical ladder of using of installation of this patent is accomplished the installation, needs artifical area equipment to install when the installation, and is in the use of high ladder carelessly just produces danger easily, installs the operation and need be the danger to destroy in the time of the high-efficient use of the outdoor power consumption, the outdoor power consumption of this patent is high enough, if the life is used, the life is destroyed in the life, the life is easy, the life is used to be the life, and is easy to be exposed to the life, the life is used, and is used to the life is easy to the life, and is used to the life.

Disclosure of Invention

The application provides intelligent monitoring equipment based on the Internet, which solves the problems of complex operation and non-environment-friendly use in the related technology.

The technical scheme of the application is as follows: an intelligent monitoring device based on the Internet comprises a mounting frame, a driving mechanism, a supporting component and a box body; the box body is fixedly arranged, the mounting frame is vertically and slidably mounted in the box body, and the supporting component is used for fixedly mounting the solar panel and is matched with the upper part of the mounting frame; the driving mechanism is arranged at the lower part of the mounting frame and is in fit connection with the box body through the climbing mechanism; the driving mechanism is also connected with the supporting component through a traction structure; when solar power supply is needed, the driving mechanism is suitable for being started along a first direction, and the mounting frame and the supporting component are driven by the climbing mechanism to vertically move upwards from a storage state in the box body until the supporting component drives the solar panel to extend out of the box body; in the process, the supporting component is suitable for driving the horizontally-contained solar panel to carry out angle adjustment under the driving of the traction structure; when the solar panel is required to be stored again, the driving mechanism is started along the second direction, so that the mounting frame and the supporting component are driven to move vertically downwards into the box body, and the supporting component is suitable for driving the solar panel to reset to a horizontal storage state in the process.

Preferably, the driving mechanism comprises a motor, and the motor is vertically and fixedly arranged at the lower part of the mounting frame; the climbing mechanism comprises a follow-up shaft and a driven shaft; the driven shaft is horizontally and rotatably arranged on one side of the upper part of the mounting frame, and is in transmission connection with the output shaft of the motor through the follow-up shaft; climbing gears are symmetrically arranged at two ends of the driven shaft, and rack sections are vertically arranged on the side parts of the box body; the driven shaft is suitable for being meshed with the rack section through the climbing gear under the driving of the motor, and then the mounting frame and the supporting component are driven to vertically move along the box body.

Preferably, a locking mechanism is further arranged between the box body and the mounting frame; when the motor starts in a first direction, the mounting frame performs a first action and a second action; wherein, the first action: the mounting frame is driven by the climbing mechanism to vertically move upwards to the top of the box body, at the moment, the climbing gear is just out of engagement with the rack section, and the mounting frame is locked with the box body through the locking mechanism; in the process, the solar panel is lifted to a set inclination angle from the horizontal by the support component under the driving of the traction structure; a second action: the installation frame is kept static through the locking mechanism, and then the supporting component drives the inclined solar panel to rotate in the circumferential direction under the driving of the traction structure.

Preferably, the locking mechanism comprises a locking block which is horizontally and elastically mounted on the top of the mounting frame in a sliding manner; a limiting block is fixed at the top of the inner side of the box body; when the mounting frame vertically moves up to the top of the box body, the locking block and the limiting block are in extrusion fit through inclined planes, and then the locking block horizontally and elastically slides to cross the limiting block, so that the limiting block is propped against the horizontal bottom surface of the locking block through the horizontal top surface; when the motor rotates in a second direction, the driven shaft is suitable for unlocking the locking block and the limiting block, so that the climbing gear is meshed with the rack section again.

Preferably, the locking block is located at the side of the top of the mounting frame, and a top plate is arranged on one side, away from the mounting frame, of the locking block in an extending manner; the driven shaft is provided with a cam through a one-way bearing; when the motor starts in a first direction, the one-way bearing is in a free state, so that the cam is vertically downward under the action of gravity; when the motor starts in the second direction, the one-way bearing is in a meshed state to drive the cam to rotate along with the driven shaft, and then the cam abuts against the top plate to drive the locking block to slide in the direction away from the limiting block until the locking block is separated from the limiting block.

Preferably, the support assembly comprises a mounting plate, a support plate and a traction rod; the mounting plate is used for fixedly mounting the solar panel, and is positioned at the upper end of the supporting plate and connected with one side of the supporting plate; the supporting plate is rotatably arranged at the upper end of the mounting frame and matched through a clutch structure; the lower end of the traction rod is matched with the output shaft of the motor through the traction structure, and the upper end of the traction rod is suitable for being in sliding connection and matched with a sliding groove arranged at the lower end of the mounting plate through a fixed pin rod; when the first action is carried out, the supporting plate is kept stationary through the clutch structure, and the traction rod axially moves under the driving of the traction structure so as to drive the mounting plate to lift around the supporting plate; when the second action is performed, the traction rod synchronously rotates along with the output shaft through the traction structure, and then the supporting plate synchronously rotates along with the mounting plate through separation of the clutch structure.

Preferably, the traction rod is suitable for sleeving the output shaft; the traction structure comprises a traction groove which is arranged at the inner side of the output shaft and is in a spiral structure, and a traction block which is arranged at the outer side of the traction rod; when the first action is carried out, the output shaft rotates, and the traction rod is driven to axially move through the relative sliding of the traction groove and the traction block; until the traction block slides to the uppermost end of the traction groove or the mounting plate is lifted to a maximum angle; so that the axial movement of the drawbar is limited during the second action.

Preferably, the lower end of the supporting plate is rotationally connected with the mounting frame through a fixed rotating sleeve; the clutch structure comprises a clutch block which is elastically and slidably arranged on the mounting frame along the radial direction, and a clutch groove which is arranged on the outer side of the rotating sleeve; when the clutch block is clamped with the clutch groove under the action of elasticity, the clutch structure is in a meshed state; when the clutch block is separated from the clutch groove under the action of external force, the clutch structure is in a separation state.

Preferably, the top of the box body is provided with an anti-theft door, and the anti-theft door is connected with the mounting frame through a door opening and closing mechanism; when the mounting frame moves vertically upwards, the door opening and closing mechanism is suitable for driving the anti-theft door to be opened; when the mounting frame moves vertically downwards, the door opening and closing mechanism is suitable for driving the anti-theft door to close.

Preferably, the inside of the door opening and closing mechanism comprises two jacking blocks, the two jacking blocks are all slidingly assembled in the box, one side of each jacking block is fixedly connected with a sliding rack through a screw, two sides of each mounting frame are rotatably provided with a linkage shaft, driving gears are fixedly sleeved on the outer peripheral surfaces of the two linkage shafts, the sliding racks are meshed with the driving gears, and the two outer peripheral surfaces of the two linkage shafts are jointly provided with the burglary-resisting door.

The working principle and the beneficial effects of the application are as follows:

1. according to the application, through the arrangement of the motor, the output shaft and other structures, when the mounting frame is required to be mounted, the motor is started, the output shaft is driven to rotate, the follow-up shaft is driven to rotate, the belt is driven to rotate, the driven shaft is driven to rotate, the climbing gear is driven to rotate, the mounting frame is driven to climb, and when the mounting frame climbs to the topmost end, the locking block is clamped on the limiting block due to the third spring, so that the integral arrangement of the mounting frame is completed, and the mounting frame is simple, quick and safe in use.

2. According to the application, through the arrangement of the inner hole sleeve, the first spring and other structures, the rotating sleeve is driven to rotate while the output shaft rotates, the traction rod is driven to ascend, the mounting plate is driven to be opened slowly, the mounting plate is opened completely while the mounting frame reaches the top, and the solar panel is arranged on the mounting plate, so that energy can be charged for equipment, and the equipment is more environment-friendly and efficient to use.

3. According to the application, through the arrangement of the structure such as the jacking block, the second spring and the like, when the mounting frame ascends to the top, the mounting frame ascends to drive the jacking block to ascend, the sliding rack to ascend, the driving gear to rotate, the linkage shaft to rotate and the anti-theft door to be opened, and when the mounting frame descends, the jacking block returns to the original position due to the second spring and simultaneously drives the anti-theft door to be closed, so that the equipment is protected.

Drawings

The application will be described in further detail with reference to the drawings and the detailed description.

Fig. 1 is an overall schematic view of the omitted burglary-resisting door of the present application.

FIG. 2 is a schematic diagram of the installation structure of the case and the burglarproof door in the present application.

Fig. 3 is a schematic view of a partial structure of the inner side of the case in the present application.

Fig. 4 is an enlarged partial schematic view of fig. 3 a in accordance with the present application.

Fig. 5 is a schematic view of the outer structure of the case in the present application.

Fig. 6 is an enlarged partial schematic view of the present application at B in fig. 5.

Fig. 7 is a schematic view showing an exploded state of the support assembly and the mounting frame according to the present application.

FIG. 8 is a schematic diagram of the connection structure of the driven shaft and the driven shaft according to the present application.

Fig. 9 is a schematic view showing an exploded state of the climbing mechanism in the present application.

Fig. 10 is a schematic structural view of a locking mechanism in the present application.

Fig. 11 is a schematic view of the internal structure of the output shaft according to the present application.

Fig. 12 is a schematic view showing an exploded state of the support assembly according to the present application.

Fig. 13 is a schematic view showing a state in which the mounting frame is housed in the case.

Fig. 14 is a schematic view showing a matching state of the supporting component, the output shaft and the box body when the mounting frame is in a storage state.

Fig. 15 is a schematic view showing the fitting state of the locking mechanism when the mounting frame is positioned at the top of the case.

Fig. 16 is a schematic view showing a state in which the solar panel is driven to rotate circumferentially by the support assembly according to the present application.

Fig. 17 is a schematic view showing a clutch structure when the support assembly drives the solar panel to rotate circumferentially.

Fig. 18 is a schematic view showing the engagement state of the cam and the lock block when the mounting frame is reset according to the present application.

In the figure: the drive mechanism 1, the motor 11, the output shaft 12, the traction groove 121, the first bevel gear 13, the climbing mechanism 2, the follower shaft 21, the second bevel gear 211, the first rotating wheel 212, the belt 213, the driven shaft 22, the cam 222, the one-way bearing 223, the climbing gear 224, the second rotating wheel 23, the case 3, the mounting frame 301, the mounting case 302, the rack section 31, the stopper 32, the support assembly 4, the inner hole sleeve 41, the first spring 42, the clutch block 43, the swivel 44, the clutch groove 441, the traction rod 45, the traction block 451, the pin 452, the mounting plate 46, the inner hole plate 47, the support plate 48, the door opening and closing mechanism 5, the top connection block 51, the second spring 52, the sliding rack 53, the driving gear 54, the linkage shaft 55, the antitheft door 56, the locking mechanism 6, the inner hole restriction block 61, the stopper 62, the guide rod 63, the third spring 64, the lock block 65, the sliding block 66, and the top plate 67.

Detailed Description

The technical solutions of the embodiments of the present application will be clearly and completely described below in conjunction with the embodiments of the present application, and it is apparent that the described embodiments are only some embodiments of the present application, not all embodiments. All other embodiments, which can be made by one of ordinary skill 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.

One embodiment of the present application, as shown in fig. 1 to 18, an internet-based intelligent monitoring apparatus includes a mounting frame 301, a driving mechanism 1, a supporting assembly 4, and a case 3. The box body 3 is fixedly arranged, the mounting frame 301 is vertically and slidably mounted in the box body 3, and the supporting component 4 is used for fixedly mounting the solar panel and is matched with the upper part of the mounting frame 301; the driving mechanism 1 is arranged at the lower part of the mounting frame 301 and is in matched connection with the box body 3 through the climbing mechanism 2; the driving mechanism 1 is also connected with the supporting component 4 through a traction structure.

When solar power supply is needed, the driving mechanism 1 can be started along the first direction, and then the climbing mechanism 2 drives the mounting frame 301 and the supporting component 4 to vertically move upwards from the containing state in the box body 3 until the supporting component 4 drives the solar panel to extend out of the box body 3; in the process, the supporting component 4 is suitable for driving the horizontally-stored solar panel to perform angle adjustment under the driving of the traction structure.

When the solar panel needs to be stored again, the driving mechanism 1 is started along the second direction, so as to drive the mounting frame 301 and the supporting component 4 to move vertically downward into the box 3, and the supporting component 4 is suitable for driving the solar panel to reset to a horizontal storage state in the process.

It can be appreciated that in order to improve the use safety of the existing monitoring device and reduce the energy consumption thereof, the prior art generally performs multi-energy driving on the monitoring device. The common multi-energy driving method is a combined driving mode of solar energy and traditional electric power grid electric energy. When the weather is clear, the monitoring equipment can be powered by solar energy, and redundant electric energy is stored; and in the night or in the weather with insufficient light irradiation, the monitoring equipment is powered by the stored electric energy or the power grid. Of course, in order to reduce the failure rate of the monitoring device or prevent the monitoring device from being damaged by human or environment, the solar panel may be stored into the box 3 at night or when the light is insufficient, and only when the weather is clear, the solar panel may be extended out of the box 3 to perform solar power supply.

In the present embodiment, as shown in fig. 1, 3, 7 to 9, and 13 and 15, the driving mechanism 1 includes a motor 11, and the motor 11 is vertically fixedly mounted to the lower portion of the mounting frame 301. The climbing mechanism 2 comprises a follower shaft 21 and a follower shaft 22; the driven shaft 22 is horizontally rotatably mounted on one side of the upper portion of the mounting frame 301, and the driven shaft 22 is in transmission connection with the output shaft 12 of the motor 11 through the follower shaft 21. Climbing gears 224 are symmetrically arranged at two ends of the driven shaft 22, and rack segments 31 are vertically arranged on the side part of the box body 3; the driven shaft 22 can be meshed with the rack section 31 through the climbing gear 224 under the driving of the motor 11, so as to drive the mounting frame 301 and the supporting component 4 to vertically move along the box 3.

It should be noted that there are various transmission structures between the follower shaft 21 and the follower shaft 22, and one of them will be described below for the sake of convenience of understanding.

Specifically, as shown in fig. 1, 7 and 8, an output end of a motor 11 is connected with an output shaft 12 coaxially arranged through a coupling, a first bevel gear 13 is fixedly sleeved on the outer peripheral surface of the output shaft 12, a second bevel gear 211 and a first rotating wheel 212 are fixedly sleeved on the outer peripheral surface of a driven shaft 21 respectively, and the first bevel gear 13 and the second bevel gear 211 are meshed; the outer peripheral surface of the driven shaft 22 is fixedly sleeved with a second rotating wheel 23 and two symmetrically arranged climbing gears 224 respectively, and the outer peripheral surfaces of the first rotating wheel 212 and the second rotating wheel 23 are jointly provided with a belt 213, so that when the motor 11 drives the output shaft 12 to rotate, the driven shaft 22 synchronously rotates through a belt transmission structure.

In one embodiment of the present application, as shown in fig. 1, 7, 13 and 15, a locking mechanism 6 is further provided between the case 3 and the mounting frame 301. When the motor 11 is started in the first direction, the mounting frame 301 performs the first and second actions; wherein, the first action: the mounting frame 301 is driven by the climbing mechanism 2 to vertically move up to the top of the box 3, at the moment, the climbing gear 224 is just out of engagement with the rack section 31, and the mounting frame 301 is locked with the box 3 through the locking mechanism 6; in this process, the support component 4 lifts the solar panel from the horizontal to a set inclination angle under the driving of the traction structure. A second action: the mounting frame 301 is kept stationary by the locking mechanism 6, and the supporting component 4 drives the inclined solar panel to rotate in the circumferential direction under the driving of the traction structure.

It will be appreciated that the angle of elevation of the solar panel relative to the horizontal depends on the geographical location (angle to the sun) where the monitoring device is installed. Therefore, the lifting angle of the solar panel is generally determined, so that the solar panel can be lifted to a desired set angle under the driving of the supporting component 4 in the process that the mounting frame 301 drives the solar panel to extend out of the box 3. So that the rotational adjustment of the solar panel can be performed by the support assembly 4 after the mounting frame 301 is raised to the highest position. In order to separate the lifting and rotating actions of the solar panel, when the mounting frame 301 is lifted to the highest position, the matching structure of the mounting frame 301 and the box 3 may be separated, so as to avoid interference of the angle adjustment process of the solar panel due to the matching between the mounting frame 301 and the box 3.

In this embodiment, as shown in fig. 3, 7, 10, 13, 15 and 18, the locking mechanism 6 includes a locking block 65 horizontally elastically slidably mounted on the top of the mounting frame 301; a limiting block 32 is fixed at the top of the inner side of the box body 3; when the mounting frame 301 moves vertically upwards to the top of the box body 3, the locking block 65 and the limiting block 32 are in extrusion fit through inclined planes, and then the limiting block 32 is crossed by the horizontal elastic sliding of the locking block 65, so that the limiting block 32 is propped against the horizontal bottom surface of the locking block 65 through the horizontal top surface; when the motor 11 rotates in the second direction, the driven shaft 22 can release the locking of the locking block 65 and the limiting block 32, so that the climbing gear 224 is meshed with the rack segment 31 again.

Specifically, as shown in fig. 3, 7, 10, 13, 15 and 18, the locking mechanism 6 further includes an inner hole limiting block 61, the inner hole limiting block 61 is fixedly connected to the top of the mounting frame 301 by a screw, a guide rod 63 is slidably mounted in the inner hole limiting block 61, one end of the guide rod 63 is fixedly connected with a stop block 62 by a screw, the other end of the guide rod 63 is fixedly connected with a locking block 65 by a screw, the bottom of the locking block 65 is fixedly connected with a sliding block 66 by a screw, and one side of the locking block 65 is fixedly connected with a top plate 67 by a screw. The locking block 65 is horizontally matched with the top of the mounting frame 301 in a sliding way through the sliding block 66, a third spring 64 is sleeved on the guide rod 63, one end of the third spring 64 abuts against the locking block 65, and the other end abuts against the inner hole limiting block 61; the third spring 64 is always in a deformed state.

Meanwhile, the locking block 65 is located at the top side of the mounting frame 301, and a top plate 67 is arranged on one side of the locking block 65 away from the mounting frame 301 in an extending manner; the driven shaft 22 is provided with a cam 222 through a one-way bearing 223; when the motor 11 is started in the first direction, the one-way bearing 223 is in a free state so that the cam 222 is vertically downward under the action of gravity; when the motor 11 is started in the second direction, the one-way bearing 223 is in a meshed state to drive the cam 222 to rotate along with the driven shaft 22, so that the locking block 65 is driven to slide in a direction away from the limiting block 32 by the abutment of the cam 222 and the top plate 67 until the locking block 65 is separated from the limiting block 32.

For ease of understanding, a specific course of movement of the mounting frame 301 may be described below.

When the mounting frame 301 needs to be driven to extend out of the box 3 by the accommodating state, the motor 11 is started to rotate in the first direction, the motor 11 rotates to drive the output shaft 12 to rotate, the output shaft 12 rotates to drive the follow-up shaft 21 to rotate, the follow-up shaft 21 rotates to drive the belt 213 to rotate, the belt 213 rotates to drive the driven shaft 22 to rotate, the driven shaft 22 rotates to drive the climbing gear 224 to rotate, the climbing gear 224 rotates to drive the mounting frame 301 to climb, when climbing to the topmost end, the locking block 65 and the limiting block 32 are both provided with inclined sliding surfaces, and due to the third spring 64, the locking block 65 retracts when contacting the limiting block 32, rebounds after the inclined sliding surfaces are walked, the locking block 65 is clamped on the limiting block 32, and the whole arrangement of the mounting frame 301 is completed.

When the installation frame 301 is required to drive the solar panel to descend and store, the motor 11 is started to rotate reversely, the motor 11 rotates reversely to drive the driven shaft 22 to rotate reversely, the one-way bearing 223 is arranged on the driven shaft 22, the one-way bearing 223 rotates reversely to drive the cam 222 to rotate only when the driven shaft 22 rotates reversely, the one-way bearing 223 of the installation cam 222 is in a meshed state, the cam 222 can rotate along with the driven shaft 22, in the rotating process of the cam 222, the cam 222 can extrude with the top plate 67 of the locking block 65 to drive the locking block 65 to slide in a direction far away from the limiting block 32, and the climbing gear 224 can be meshed with the rack section 31 by slightly moving downwards by a certain distance under the action of gravity, so that the installation frame 301 can move vertically to the initial position under the driving of the driven shaft 22.

In one embodiment of the present application, as shown in fig. 7, 12, 14 and 17, the support assembly 4 includes a mounting plate 46, a support plate 48 and a drawbar 45; the mounting plate 46 is used for fixedly mounting the solar panel, and the mounting plate 46 is positioned at the upper end of the supporting plate 48 and is connected with one side of the supporting plate; the support plate 48 is rotatably installed at the upper end of the installation frame 301 and is engaged by a clutch structure; the lower end of the traction rod 45 is matched with the output shaft 12 of the motor 11 through a traction structure, and the upper end of the traction rod 45 is suitable for being in sliding connection and matched with a sliding groove arranged at the lower end of the mounting plate 46 through a fixed pin 452; when the first action is performed, the supporting plate 48 is kept static through the clutch structure, and then the traction rod 45 moves axially under the driving of the traction structure so as to drive the mounting plate 46 to lift around the supporting plate 48; when the second action is performed, the drawbar 45 rotates synchronously with the output shaft 12 via the traction structure, and the support plate 48 is further separated via the clutch structure to rotate synchronously with the mounting plate 46.

Specifically, the top of backup pad 48 is installed through the round pin axle rotation mounting panel 46, and solar panel is installed at the top of mounting panel 46, and the bottom of mounting panel 46 is through screw fixedly connected with interior hole board 47, and interior hole board 47 is through self structure in order to form the spout that is used for with pin 452 sliding fit.

In this embodiment, as shown in fig. 11, 12, 14 and 17, the traction rod 45 may be sleeved with the output shaft 12; the traction structure includes a traction groove 121 provided on the inner side of the output shaft 12 in a spiral structure, and a traction block 451 provided on the outer side of the traction rod 45. When the first action is performed, the output shaft 12 rotates, and the traction rod 45 is driven to axially move by the relative sliding of the traction groove 121 and the traction block 451; until the traction block 451 slides to the uppermost end of the traction groove 121, or the mounting plate 46 is lifted to a maximum angle; so that the axial movement of the drawbar 45 is limited during the second action.

In this embodiment, as shown in fig. 7, 12, 14 and 17, the lower end of the support plate 48 is rotatably connected to the mounting frame 301 through the fixed swivel 44; the clutch structure comprises a clutch block 43 which is elastically and slidably arranged on the mounting frame 301 along the radial direction, and a clutch groove 441 which is arranged on the outer side of the rotating sleeve 44; when the clutch block 43 is clamped with the clutch groove 441 under the action of elasticity, the clutch structure is in a meshed state; when the clutch block 43 is separated from the clutch groove 441 by an external force, the clutch structure is in a separated state.

Specifically, the top of installing frame 301 is through screw fixedly connected with hole sleeve 41, and the inside of hole sleeve 41 radially is equipped with a plurality of evenly distributed's clutch piece 43 through first spring 42 elastic sliding fit, and the inside of hole sleeve 41 is equipped with changeing cover 44, changes cover 44 and the inside of output shaft 12 and rotates jointly and install traction lever 45, is fixed with traction piece 451 on the outer peripheral surface of traction lever 45, and the top of traction lever 45 is through screw fixedly connected with pin 452, and the top of changeing cover 44 is through screw fixedly connected with backup pad 48. Through the setting of hole sleeve 41, first spring 42 isotructure, when output shaft 12 rotates, the change cover 44 keeps static through clutch structure for support group board 48 is through the rotation that is connected with mounting panel 46 restriction traction lever 45, make traction lever 45 carry out the axial under the drive of output shaft 12 and rise, and then can drive mounting panel 46 and slowly open for backup pad 48, when mounting frame 301 reaches the top, mounting panel 46 is opened completely, there is the solar panel on the mounting panel 46, can fill can for equipment, the use of messenger's equipment is more environmental protection high efficiency.

As shown in fig. 1 to 10, a first circular hole is formed in the inner portion of the inner bore sleeve 41, the rotary sleeve 44 is rotatably mounted in the first circular hole, a second circular hole is formed in the output shaft 12, and the traction rod 45 is rotatably mounted in the second circular hole.

As shown in fig. 4 to 10, a traction groove 121 is formed in the output shaft 12, a traction block 451 is slidably assembled in the traction groove 121, a plurality of evenly distributed circular sliding grooves are formed in the inner hole sleeve 41, a clutch block 43 is slidably connected in the circular sliding grooves, and a first spring 42 is commonly connected between the circular sliding grooves and the inner wall of the clutch block 43.

As shown in fig. 4 to 10, a rotating groove is formed in the mounting frame 301, the driven shaft 22 is rotatably mounted in the rotating groove, a plurality of evenly distributed clamping grooves are formed in the rotating sleeve 44, and a plurality of clutch blocks 43 are slidably connected in the clamping grooves respectively.

In this embodiment, in the supporting assembly 4, the first spring 42 and the clutch block 43 form a clutch structure, and when the output shaft 12 rotates, the traction groove 121 and the traction block 451 cooperate to drive the traction rod 45 to move axially with a resistance smaller than the engagement force of the clutch structure, so that the clutch structure is in a clamped state, so that the traction rod 45 can only ascend to drive the mounting plate 46 to slowly open. At the same time that the mounting frame 301 reaches the top, the mounting plate 46 is fully open, as the output shaft 12 continues to rotate; because the mounting plate 46 is inclined to a limit angle, or the traction block 451 is located at the uppermost end of the traction groove 121, the axial movement of the traction rod 45 is limited, and meanwhile, the pin 452 and the sliding groove are also in a rotation limiting state in the circumferential rotation direction, namely, the resistance of the axial movement of the traction rod 45 becomes extremely high, so that the clutch structure is disengaged from the clamping state and is in a free state, and the clutch structure at the top of the mounting frame 301 is separated, so that the support plate 48 can rotate circumferentially with the mounting plate 46 under the trend of the traction rod 45, and the traction rod 45 and the output shaft 12 remain relatively static in the process; during this process, the driven shaft 22 is in rotation, but the climbing gear 224 is not engaged with the rack segment 31.

It should be noted that, when the solar panel angle is adjusted, the rotation angle of the support plate 48 is generally not more than 180 degrees, so before the solar panel is required to be stored again, the support plate 48 can be rotated 360 degrees to the initial position by continuing to rotate the motor 11 along the first direction, and then when the motor 11 drives the output shaft 12 to rotate along the second direction, the traction rod 45 only needs to drive the mounting plate 46 to reset and deflect around the support plate 48 to a horizontal state, and the clutch structure of the support plate 48 is in a meshed state in the process.

In one embodiment of the present application, as shown in fig. 2 to 6, the top of the case 3 is provided with a burglary-resisting door 56, and the burglary-resisting door 56 is connected with the mounting frame 301 through a door opening and closing mechanism 5; further, when the mounting frame 301 moves vertically upwards, the door opening and closing mechanism 5 is suitable for driving the anti-theft door 56 to open; the door opening and closing mechanism 5 is adapted to actuate the closing of the antitheft door 56 when the mounting frame 301 is vertically moved downward.

Specifically, as shown in fig. 2 to 6, the door opening and closing mechanism 5 includes two top connection blocks 51, the two top connection blocks 51 are slidably assembled in the installation box 302, one side of the top connection block 51 is fixedly connected with a sliding rack 53 through a screw, two sides of the installation frame 301 are rotatably provided with a linkage shaft 55, the outer peripheral surfaces of the two linkage shafts 55 are fixedly sleeved with driving gears 54, the sliding rack 53 is meshed with the driving gears 54, the outer peripheral surfaces of the two linkage shafts 55 are jointly provided with an anti-theft door 56, when the installation frame 301 is lifted to the top through the arrangement of the top connection blocks 51, the second springs 52 and other structures, the installation frame 301 is lifted to drive the top connection block 51 to lift to drive the sliding rack 53 to lift to drive the driving gears 54 to rotate to drive the linkage shaft 55 to drive the anti-theft door 56 to open, and when the installation frame 301 is lifted, the top connection block 51 is returned to the original position due to the second springs 52 to drive the anti-theft door 56 to close.

As shown in fig. 2 to 6, the box 3 includes a mounting box 302, two inner hole sliding grooves symmetrically arranged are provided in the mounting box 302, the inner part of the inner hole sliding groove is slidably connected with a top connection block 51, and a second spring 52 is commonly connected between the inner hole sliding groove and the top connection block 51.

In this embodiment, when the mounting frame 301 rises to the top, the mounting frame 301 rises to drive the propping block 51 to rise, the propping block 51 rises to drive the sliding rack 53 to rise, the sliding rack 53 rises to drive the driving gear 54 to rotate, the driving gear 54 rotates to drive the linkage shaft 55 to rotate, the linkage shaft 55 rotates to drive the anti-theft door 56 to rotate for opening, and when the mounting frame 301 descends, the propping block 51 returns to the original position due to the second spring 52, and meanwhile, the anti-theft door 56 is driven to close, so that equipment is protected, and damage to the equipment due to external factors is prevented.

The foregoing description of the preferred embodiments of the application is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the application.

Claims (10)

1. An intelligent monitoring device based on internet, which is characterized by comprising:

the box body is fixedly arranged;

a mounting frame; the mounting frame is vertically and slidably mounted in the box body;

a support assembly; the support component is used for fixedly mounting the solar panel and is matched and mounted on the upper part of the mounting frame; and

a driving mechanism; the driving mechanism is arranged at the lower part of the mounting frame and is in fit connection with the box body through the climbing mechanism; the driving mechanism is also connected with the supporting component through a traction structure;

when the driving mechanism is suitable for being started along a first direction, the climbing mechanism drives the mounting frame to vertically move upwards from a storage state in the box body to extend out of the box body; in the process, the supporting component is suitable for driving the horizontally-contained solar panel to carry out angle adjustment under the driving of the traction structure;

when the driving mechanism is started in the second direction, the mounting frame and the supporting component move vertically downwards into the box body, and the solar panel is driven to be in a horizontal storage state.

2. The intelligent internet-based monitoring device of claim 1, wherein: the driving mechanism comprises a motor, and the motor is vertically and fixedly arranged at the lower part of the mounting frame; the climbing mechanism comprises a follow-up shaft and a driven shaft; the driven shaft is horizontally and rotatably arranged on one side of the upper part of the mounting frame, and is in transmission connection with the output shaft of the motor through the follow-up shaft; climbing gears are symmetrically arranged at two ends of the driven shaft, and rack sections are vertically arranged on the side parts of the box body; the driven shaft is suitable for being meshed with the rack section through the climbing gear under the driving of the motor, and then the mounting frame and the supporting component are driven to vertically move along the box body.

3. An internet-based intelligent monitoring device according to claim 2, wherein: a locking mechanism is further arranged between the box body and the mounting frame;

when the motor starts in a first direction, the mounting frame performs a first action and a second action; wherein the method comprises the steps of

A first action: the mounting frame is driven by the climbing mechanism to vertically move upwards to the top of the box body, at the moment, the climbing gear is just out of engagement with the rack section, and the mounting frame is locked with the box body through the locking mechanism; in the process, the supporting component lifts the solar panel by a set angle from the horizontal under the driving of the traction structure;

a second action: the installation frame is kept static through the locking mechanism, and then the supporting component drives the inclined solar panel to rotate in the circumferential direction under the driving of the traction structure.

4. An internet-based intelligent monitoring device according to claim 3, wherein: the locking mechanism comprises a locking block which is horizontally and elastically slidably arranged at the top of the mounting frame; a limiting block is fixed at the top of the inner side of the box body;

when the mounting frame vertically moves up to the top of the box body, the locking block and the limiting block are in extrusion fit through inclined planes, and then the locking block horizontally and elastically slides to cross the limiting block, so that the limiting block is propped against the horizontal bottom surface of the locking block through the horizontal top surface;

when the motor rotates in a second direction, the driven shaft is suitable for unlocking the locking block and the limiting block, so that the climbing gear is meshed with the rack section again.

5. The intelligent monitoring device based on the internet according to claim 4, wherein: the locking block is positioned at the side of the top of the mounting frame, and a top plate is arranged on one side of the locking block away from the mounting frame in an extending manner; the driven shaft is provided with a cam through a one-way bearing;

when the motor starts in a first direction, the one-way bearing is in a free state, so that the cam is vertically downward under the action of gravity;

when the motor starts in the second direction, the one-way bearing is in a meshed state to drive the cam to rotate along with the driven shaft, and then the cam abuts against the top plate to drive the locking block to slide in the direction away from the limiting block until the locking block is separated from the limiting block.

6. An internet-based intelligent monitoring device according to claim 3, wherein: the support assembly comprises a mounting plate, a support plate and a traction rod; the mounting plate is used for fixedly mounting the solar panel, and is positioned at the upper end of the supporting plate and connected with one side of the supporting plate; the supporting plate is rotatably arranged at the upper end of the mounting frame and matched through a clutch structure; the lower end of the traction rod is matched with the output shaft of the motor through the traction structure, and the upper end of the traction rod is suitable for being in sliding connection and matched with a sliding groove arranged at the lower end of the mounting plate through a fixed pin rod;

when the first action is carried out, the supporting plate is kept stationary through the clutch structure, and the traction rod axially moves under the driving of the traction structure so as to drive the mounting plate to lift around the supporting plate;

when the second action is performed, the traction rod synchronously rotates along with the output shaft through the traction structure, and then the supporting plate synchronously rotates along with the mounting plate through separation of the clutch structure.

7. The intelligent internet-based monitoring device of claim 6, wherein: the traction rod is suitable for being sleeved with the output shaft; the traction structure comprises a traction groove which is arranged at the inner side of the output shaft and is in a spiral structure, and a traction block which is arranged at the outer side of the traction rod;

when the first action is carried out, the output shaft rotates, and the traction rod is driven to axially move through the relative sliding of the traction groove and the traction block; until the traction block slides to the uppermost end of the traction groove or the mounting plate is lifted to a maximum angle; so that the axial movement of the drawbar is limited during the second action.

8. The intelligent internet-based monitoring device of claim 6, wherein: the lower end of the supporting plate is rotationally connected with the mounting frame through a fixed rotating sleeve; the clutch structure comprises a clutch block which is elastically and slidably arranged on the mounting frame along the radial direction, and a clutch groove which is arranged on the outer side of the rotating sleeve;

when the clutch block is clamped with the clutch groove under the action of elasticity, the clutch structure is in a meshed state;

when the clutch block is separated from the clutch groove under the action of external force, the clutch structure is in a separation state.

9. An internet-based intelligent monitoring device according to any of claims 1-8, wherein: the top of the box body is provided with an anti-theft door, and the anti-theft door is connected with the mounting frame through a door opening and closing mechanism;

when the mounting frame moves vertically upwards, the door opening and closing mechanism is suitable for driving the anti-theft door to open;

when the mounting frame moves vertically downwards, the door opening and closing mechanism is suitable for driving the anti-theft door to close.

10. The intelligent internet-based monitoring device of claim 9, wherein: the inside of door opening and closing mechanism includes two top connection pieces, two the equal sliding assembly of top connection piece is in the inside of box, one side of top connection piece is through screw fixedly connected with slip rack, the universal driving shaft is all installed in the both sides rotation of installing frame, two all fixed cover is equipped with the driving gear on the outer peripheral face of universal driving shaft, slip rack with the driving gear meshes mutually, two install jointly on the outer peripheral face of universal driving shaft the burglary-resisting door.