CN110958370A - Wisdom thing allies oneself with security protection monitoring device - Google Patents

Abstract

The invention provides an intelligent Internet of things security monitoring device which comprises a camera, a protection mechanism, a first guide unit and a control mechanism, wherein the protection mechanism comprises an accommodating cavity with an opening, and the camera is movably arranged in the accommodating cavity; the opening is provided with a sliding door which is connected with the protection mechanism in a sliding manner; the first guide unit is arranged on the protection mechanism, the first guide unit is connected with the sliding door, and the sliding door slides in a reciprocating mode at the opening through the first guide unit so as to open or close the opening; the control mechanism is in communication connection with the Internet of things system, is connected with the first guide unit and is used for controlling the reciprocating sliding of the first guide unit. Through the opening part that holds the chamber set up reciprocating sliding's sliding door to the protection camera is not damaged, thereby has solved and has installed in the monitoring device of outdoor environment among the prior art and has received the technical problem of bad weather damage easily.

Description

Wisdom thing allies oneself with security protection monitoring device

Technical Field

The invention relates to the technical field of security equipment, in particular to an intelligent Internet of things security monitoring device.

Background

A monitoring device for security protection generally adopts the camera, and the majority all installs in the open air. Because monitoring device is in the changeable outdoor environment of environment, consequently the device itself often can receive the damage because of abominable weather condition, especially in the region of some hail weather, the hail falls fiercely, bulky hail is just as egg size is general, if do not make the protection to monitoring device, then can damage the device body very easily, direct damage even and scrap.

Disclosure of Invention

The invention mainly aims to provide an intelligent Internet of things security monitoring device, a protection mechanism in the monitoring device is provided with an open accommodating cavity, a camera is movably arranged in the accommodating cavity, a sliding door arranged at the opening slides back and forth at the opening through a first guide unit to open or close the opening, so that the camera is protected from being damaged, a control mechanism used for controlling the movement of the first guide unit is also in communication connection with an Internet of things system, a worker in a control center of the Internet of things system can remotely control the opening or closing of the sliding door, the working efficiency is improved, and the technical problem that the monitoring device installed in an outdoor environment is easily damaged by severe weather in the prior art is solved.

In order to achieve the purpose, the invention provides an intelligent Internet of things security monitoring device.

This wisdom thing allies oneself with security protection monitoring device includes camera, protection mechanism, first guide unit and control mechanism, wherein:

the protection mechanism comprises an accommodating cavity with an opening, and the camera is movably arranged in the accommodating cavity; a sliding door is arranged at the opening and is in sliding connection with the protection mechanism;

the first guide unit is arranged on the protection mechanism, the first guide unit is connected with the sliding door, and the sliding door slides in a reciprocating mode at an opening through the first guide unit so as to open or close the opening;

the control mechanism is in communication connection with the Internet of things system, is connected with the first guide unit and is used for controlling the reciprocating sliding of the first guide unit.

Furthermore, the protection mechanism is of a spherical structure, an interlayer inner cavity is arranged on the protection mechanism, and the interlayer inner cavity is arranged along the circumferential direction of the protection mechanism; the sliding door is inserted into the interlayer inner cavity and slides in the interlayer inner cavity in a reciprocating manner.

Further, the first guide unit comprises a first guide rail and a guide piece, and the first guide rail is arranged along the circumferential direction of the inner wall of the accommodating cavity; one end of the guide piece is connected with the first guide rail in a sliding mode, and the other end of the guide piece is connected with the sliding door; the control mechanism is electrically connected with the guide piece and used for controlling the sliding of the guide piece.

Furthermore, a guide through hole communicated with the interlayer inner cavity is formed in the inner wall of the accommodating cavity, the first guide rail covers the guide through hole, and the guide through hole and the first guide rail have the same guide track; one end of the guide piece is connected with the sliding door through the guide through hole.

Furthermore, the device also comprises a second guide unit and a support unit, wherein the second guide unit is arranged in the accommodating cavity, the camera is connected to one end of the support unit, and the other end of the support unit is rotatably connected with the second guide unit; the control mechanism is electrically connected with the second guide unit and is used for controlling the second guide unit to move towards the direction close to or far away from the opening; the control mechanism is electrically connected with the supporting unit and used for controlling the rotation angle of the supporting unit.

Furthermore, the second guide unit comprises a second guide rail and a guide seat, the end parts of the two ends of the second guide rail are respectively connected with the inner wall of the accommodating cavity, and the guide seat is connected with the second guide rail in a sliding manner; the control mechanism is electrically connected with the guide seat and used for controlling the sliding of the guide seat.

Furthermore, the supporting unit comprises a rotating rod and a supporting plate, one end of the rotating rod is rotatably connected with the guide seat, and the other end of the rotating rod is connected with the supporting plate; the camera is arranged on the supporting plate; the dwang with control mechanism electricity is connected, control mechanism is used for controlling the rotation of dwang.

Furthermore, the supporting unit further comprises a reinforcing rib plate, and the reinforcing rib plate is arranged on the supporting plate.

Further, the control mechanism includes a controller, a processor, a wireless communicator and a vibration sensor, wherein:

the vibration sensor is used for detecting vibration of the protection mechanism, processing the vibration to generate vibration information and sending the vibration information to the processor;

the processor is in communication connection with the Internet of things system through the wireless communicator, and is used for acquiring operation information, weather forecast information or vibration information, generating an operation instruction after processing and sending the operation instruction to the controller;

the controller is in data connection with the processor and is used for receiving the operation instruction and controlling the sliding of the guide piece according to the operation instruction;

the controller is used for receiving the operation instruction and controlling the sliding of the guide seat according to the operation instruction;

the controller is used for receiving the operation instruction and controlling the rotation of the rotating rod according to the operation instruction.

Further, the operation information comprises start information, close information and rotation information; the operation instruction comprises a first starting instruction, a second starting instruction, a first closing instruction, a second closing instruction, a third closing instruction and a rotation instruction; the weather forecast information comprises hail weather information, rain and snow weather information and normal weather information; the starting information corresponds to a first starting instruction and a second starting instruction; the closing information corresponds to a first closing instruction and a second closing instruction; the hail weather information and the rain and snow weather information correspond to a first closing instruction and a second closing instruction; the normal weather information corresponds to a first starting instruction and a second starting instruction; the rotation information corresponds to the rotation instruction; the vibration information corresponds to the third closing instruction and the second closing instruction.

In the embodiment of the invention, the protection mechanism in the monitoring device is provided with the accommodating cavity with the opening, the camera is movably arranged in the accommodating cavity, the sliding door arranged at the opening slides in a reciprocating manner at the opening through the first guide unit to open or close the opening, so that the camera is protected from being damaged, the control mechanism for controlling the movement of the first guide unit is also in communication connection with the Internet of things system, a worker in the control center of the Internet of things system can remotely control the opening or closing of the sliding door, the working efficiency is improved, and the technical problem that the monitoring device installed in the outdoor environment in the prior art is easily damaged by severe weather is solved.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the invention. Also, like reference numerals are used to refer to like parts throughout the drawings. In the drawings:

fig. 1 is a sectional view of a protection mechanism provided with a first guide unit in the present invention;

FIG. 2 is a schematic diagram of a first state of the intelligent Internet of things security monitoring device according to the present invention;

FIG. 3 is a diagram illustrating a second state of the intelligent IOT monitoring device according to the present invention;

FIG. 4 is a partial schematic view of FIG. 2 of the present invention shown in FIG. 1;

FIG. 5 is a partial schematic view of FIG. 2 of the present invention;

fig. 6 is a connection block diagram of the intelligent internet of things security monitoring device and the internet of things system in the invention.

In the figure:

1. a camera; 2. a protection mechanism; 3. a sliding door; 4. an interlayer inner cavity; 5. a first guide rail; 6. a guide member; 7. a guide through hole; 8. a controller; 9. a processor; 10. a wireless communicator; 11. a shock sensor; 12. an accommodating chamber; 13. a second guide rail; 14. a guide seat; 15. a support plate; 16. rotating the rod; 17. and a reinforcing plate.

Detailed Description

Exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

The invention discloses an intelligent internet of things security monitoring device, which comprises a camera 1, a protection mechanism 2, a first guide unit and a control mechanism, wherein the camera 1 comprises a first guide unit and a second guide unit, and the first guide unit comprises a first guide unit and a second guide unit, wherein the first guide unit comprises a first guide unit and a second guide unit, and the second guide unit comprises a first guide unit and a second guide unit, wherein the: the protection mechanism 2 comprises an accommodating cavity 12 with an opening, and the camera 1 is movably arranged in the accommodating cavity 12; a sliding door 3 is arranged at the opening, and the sliding door 3 is connected with the protection mechanism 2 in a sliding manner; the first guide unit is arranged on the protection mechanism 2, the first guide unit is connected with the sliding door 3, and the sliding door 3 slides in a reciprocating mode at the opening through the first guide unit to open or close the opening; the control mechanism is in communication connection with the Internet of things system, is connected with the first guide unit and is used for controlling the reciprocating sliding of the first guide unit.

In the above embodiment, the intelligent internet of things security monitoring device is mainly formed by combining a camera 1, a protection mechanism 2, a first guide unit and a control mechanism, wherein an accommodating cavity 12 is formed inside the protection mechanism 2, the camera 1 is arranged in the accommodating cavity 12, the accommodating cavity 12 is provided with an opening, a sliding door 3 is arranged at the opening of the accommodating cavity 12, the sliding door 3 is connected with the protection mechanism 2, the sliding door 3 is connected with the first guide unit, the control mechanism is electrically connected with the first guide unit, and the control mechanism is used for acquiring an operation instruction and controlling the reciprocating sliding of the first guide unit according to the operation instruction, so as to drive the reciprocating sliding of the sliding door 3 to open or close the opening; specifically, when the control mechanism obtains an operation instruction for opening the sliding door 3, the first guide unit is controlled to slide toward a direction away from the opening according to the operation instruction, and the sliding door 3 is driven by the first guide unit to slide toward the same sliding direction as the first guide unit, so that the opening is opened; when the control mechanism acquires an operation instruction for closing the sliding door 3, the first guide unit is controlled to slide toward the opening approaching direction according to the operation instruction, and the sliding door 3 is driven by the first guide unit to slide toward the same sliding direction as the first guide unit, thereby closing the opening. Under normal weather and external environment, the sliding door 3 may be in an open state or a closed state, as appropriate. For example, the sliding door 3 is in an open state, and after the control mechanism obtains an operation instruction for closing the sliding door 3, the opening of the first guide unit is controlled according to the operation instruction, and the first guide unit slides towards the opening direction, so that the sliding door 3 is driven to slide to close the opening, the camera 1 in the accommodating cavity 12 can be protected, and the fragile part of the camera 1 is prevented from being damaged by foreign objects. Moreover, the control mechanism is in communication connection with the internet of things system, and an operator at the internet of things system control center can remotely send an operation instruction to the control mechanism, namely, the operator at the control center can remotely control the opening or closing of the sliding door 3 as required, so that the camera 1 is effectively protected in time, and the safety degree is improved.

As another embodiment of the present invention, the protection mechanism 2 is a spherical structure, the protection mechanism 2 is provided with an interlayer inner cavity 4, and the interlayer inner cavity 4 is arranged along the circumferential direction of the protection mechanism 2; the sliding door 3 is inserted into the interlayer inner cavity 4, and the sliding door 3 slides in the interlayer inner cavity 4 in a reciprocating manner.

As shown in fig. 1, the protection mechanism 2 is a spherical structure, an interlayer inner cavity 4 is circumferentially arranged on the protection mechanism 2 of the spherical structure, the sliding door 3 is slidably inserted into the interlayer inner cavity 4, which can be understood as that the sliding door 3 is inserted into the interlayer inner cavity 4, and the sliding door 3 can reciprocally slide in the interlayer inner cavity 4 under the driving of the guide mechanism, and can open or close the opening of the protection mechanism through reciprocal sliding in the interlayer inner cavity 4.

Further, the sliding door 3 is an arc-shaped door.

As an embodiment, the sliding door 3 has an arc structure, and as shown in fig. 3, when the sliding door 3 is in a closed state, the sliding door 3 and the protection mechanism 2 having a spherical structure form a complete spherical structure.

Furthermore, the sliding door 3 is made of transparent material, and the transparent material is glass or plastic. When the sliding door 3 is made of a transparent material, the camera 1 can continue to monitor in a state where the sliding door 3 is closed. Of course, the sliding door 3 may also be made of an opaque material, such as metal, and the metal material may ensure the strength of the sliding door 3 and resist against hail or other objects, but the monitoring duration may be lost when the sliding door 3 made of the opaque material is in the closed state.

As another embodiment of the present invention, the first guide unit includes a first guide rail 5 and a guide 6, the first guide rail 5 being circumferentially disposed along an inner wall of the accommodating chamber 12; one end of the guide piece 6 is connected with the first guide rail 5 in a sliding way, and the other end is connected with the sliding door 3; the control mechanism is electrically connected to the guide 6 for controlling the sliding of the guide 6.

As shown in fig. 1 and 5, the first guide unit is mainly formed by a combination of a first guide rail 5 and a guide 6, the first guide rail 5 being disposed on an inner wall of the accommodating chamber 12 and being disposed along a circumferential direction of the accommodating chamber 12; the guide member 6 is electrically connected to the control mechanism, and one end of the guide member 6 is slidably connected to the first guide rail 5, and the other end is fixed to the sliding door 3, so that when the control mechanism receives an operation command and controls the guide member 6 to slide along the guide rail 5 according to the operation command, the guide member 6 drives the sliding door 3 to slide, and the sliding directions of the guide member 6 and the sliding door 3 are consistent, so that the sliding door 3 can open or close the opening of the accommodating cavity 12 under the driving of the guide member 6.

Furthermore, a guide through hole 7 communicated with the interlayer inner cavity 4 is formed in the inner wall of the accommodating cavity 12, and the first guide rail 5 is arranged to cover the guide through hole 7; one end of the guide 6 is connected to the sliding door 3 through the guide through-hole 7.

As shown in fig. 1 and 5, a guide through hole 7 is formed on the inner wall of the accommodating cavity 12, and the guide through hole 7 is communicated with the interlayer inner cavity 4; the first guide rail 5 covers the guide through hole 7, and the guide through hole 7 and the first guide rail 5 are arranged along the same guide track, which can be understood that the guide through hole 7 and the first guide rail 5 have the same sliding track in the circumferential direction; one end of the guide piece 6 penetrates through the guide through hole 7 to be connected with the sliding door 3 arranged in the interlayer inner cavity 4, the other end of the guide piece is assembled on the first guide rail 5 in a sliding mode, and the guide piece 6 drives the sliding door 3 to slide in the interlayer inner cavity 4 in a reciprocating mode through the reciprocating sliding on the first guide rail 5 along the guide track so as to open or close the opening of the accommodating cavity 12.

As another embodiment of the invention, the intelligent internet of things security monitoring device further comprises a second guiding unit and a supporting unit, wherein the second guiding unit is arranged in the accommodating cavity 12, the camera 1 is connected to one end of the supporting unit, and the other end of the supporting unit is rotatably connected with the second guiding unit; the control mechanism is electrically connected with the second guide unit and is used for controlling the second guide unit to move towards the direction close to or far away from the opening; the control mechanism is electrically connected with the supporting unit and used for controlling the rotation angle of the supporting unit.

As shown in fig. 2 and 3, the second guiding unit is disposed in the accommodating cavity 12, the camera 1 is connected with the second guiding unit through the supporting unit, specifically, one end of the supporting unit is rotatably connected with the second guiding unit, the other end of the supporting unit is connected with the camera 1, and the control mechanism is electrically connected with the second guiding unit and is used for controlling the second guiding unit to slide towards the direction close to or away from the opening of the accommodating cavity, so that the camera 1 can move towards the direction close to or away from the opening of the accommodating cavity under the driving of the second guiding unit, that is, the camera 1 can move relative to the opening of the accommodating cavity, the relative position of the camera 1 can be adjusted through the second guiding unit, and the monitoring view of the camera 1 can be adjusted as required; the control mechanism is also electrically connected with the supporting unit and is used for controlling the supporting unit to rotate and rotate the angle relative to the second guide unit, so that the projection angle of the camera 1 can be adjusted through the rotation angle of the supporting unit, and the monitoring visual field can be flexibly adjusted.

As another embodiment of the present invention, the second guiding unit includes a second guiding rail 13 and a guiding seat 14, both end portions of the second guiding rail 13 are respectively connected to the inner wall of the accommodating cavity 12, and the guiding seat 14 is slidably connected to the second guiding rail 13; the control mechanism is electrically connected with the guide base 14 and is used for controlling the sliding of the guide base 14.

As shown in fig. 3 and 4, the second guide unit is mainly formed by combining a second guide rail 13 and a guide base 14, the guide base 14 is fixed in the accommodating cavity 12, specifically, the end portions of both ends of the second guide rail 13 are respectively connected with the inner wall of the accommodating cavity 12, the guide base 14 is slidably fitted on the second guide rail 13, and the control mechanism is electrically connected with the guide base 14, and the control mechanism can control the guide base 14 to slide along the second guide rail 13 toward a direction close to or away from the opening of the accommodating cavity.

As another embodiment of the present invention, the supporting unit includes a rotating lever 16 and a supporting plate 15, one end of the rotating lever 16 is rotatably connected with the guide base 14, and the other end is connected with the supporting plate 15; the camera 1 is mounted on the support plate 15; the rotating lever 16 is electrically connected to a control mechanism for controlling the rotation of the rotating lever 16.

As shown in fig. 3 and 4, the supporting unit is mainly formed by combining a rotating rod 16 and a supporting plate 15, one end of the rotating rod 16 is rotatably connected to the guide seat 14, the other end of the rotating rod is connected to the supporting plate 15, the supporting plate 15 is mainly used for fixing the camera 1, and since the rotating rod 16 is electrically connected to a control mechanism, the control mechanism can control the rotation of the rotating rod 16, the projection angle of the camera 1 can be adjusted through the rotation angle of the rotating rod 16, and the monitoring visual field can be flexibly adjusted.

Further, the support unit further comprises a reinforcing rib plate 17, and the reinforcing rib plate 17 is arranged on the support plate 15.

As shown in fig. 4, a reinforcing rib plate 17 is further disposed on the support plate 15, and the connection between the support plate 15 and the rotating lever 16 can be reinforced by the reinforcing rib plate 17, so as to prevent the rotating lever 16 from being broken from the support plate 15 in the rotating process.

As another embodiment of the present invention, the control mechanism comprises a controller 8, a processor 9, and a wireless communicator 10, wherein:

the processor 9 is in communication connection with the internet of things system through the wireless communicator 10 and is used for acquiring operation information or weather forecast information, generating an operation instruction after processing and sending the operation instruction to the controller 8;

the controller 8 is in data connection with the processor 9 and is used for receiving an operation instruction and controlling the sliding of the guide piece 6 according to the operation instruction;

the controller 8 is used for receiving an operation instruction and controlling the sliding of the guide seat 14 according to the operation instruction;

the controller is configured to receive an operation instruction and control the rotation of the rotating lever 16 according to the operation instruction.

Referring to fig. 2, 3 and 6, in the working process of the intelligent internet of things security monitoring device, a processor 9 needs to be continuously connected with an internet of things system through a wireless communicator 10 to periodically or continuously remotely obtain operation information or weather forecast information, the processor 9 generates an operation instruction for controlling the sliding door 3 to be closed or opened according to the obtained operation information or weather forecast information, wherein the operation information includes start information and close information, the weather forecast information includes hail weather information, rain and snow weather information and normal weather information, and the operation instruction includes a first start instruction, a second start instruction, a first close instruction and a second close instruction; the starting information corresponds to a first starting instruction and a second starting instruction; the closing information corresponds to a first closing instruction and a second closing instruction; the hail weather information and the rain and snow weather information correspond to the first closing instruction and the second closing instruction; the normal weather information corresponds to the first start instruction and the second start instruction. For example, when hail is about to occur, the processor 9 receives hail weather information from the internet of things system, generates a first closing instruction for controlling the sliding door 3 to close according to the hail weather information, and sends the first closing instruction to the controller 8; the controller 8 receives the first closing instruction, controls the guide member 6 to slide on the first guide rail 5 along a guide track close to the opening according to the first closing instruction, and the end of the guide member 6, which passes through the guide through hole 7 and is connected with the sliding door 3, synchronously drives the sliding door 3 to slide in the interlayer inner cavity 4 along with the sliding of the guide member 6, and the guide track of the sliding door 3 is the same as the guide track of the guide member 6, so as to close the opening of the accommodating cavity 12, thereby protecting the camera 1 arranged in the accommodating cavity 12 and preventing the fragile part of the camera 1 from being damaged by hail or even scrapped. Correspondingly, when the weather condition is normal, the processor 9 receives normal weather information from the internet of things system, generates a first starting instruction for controlling the sliding door 3 to be opened according to the normal weather information and sends the first starting instruction to the controller 8; the controller 8 receives the first starting instruction, controls the guide piece 6 to slide on the first guide rail 5 along a guide track far away from the opening according to the first starting instruction, and along with the sliding of the guide piece 6, the guide piece 6 penetrates through the guide through hole 7 and is connected with one end of the sliding door 3 to synchronously drive the sliding door 3 to slide in the interlayer inner cavity 4, and the guide track of the sliding door 3 is the same as that of the guide piece 6, so that the opening of the accommodating cavity 12 is opened, and the camera 1 has a clearer monitoring view. Fig. 2 and 3 show the opened and closed states of the sliding door 3, respectively, fig. 2 shows the opened state of the sliding door 3, and fig. 3 shows the closed state of the sliding door 3 with the guide 6.

However, the weather forecast information is not accurately broadcasted, and at the moment, the staff can select the operation information to remotely control the opening or closing of the sliding door 3 according to the actual requirement. Specifically, when hail is about to occur, a worker of the internet of things system control center can remotely send closing information to the processor 9 to instruct to close the sliding door 3; the processor 9 receives the closing information, generates a first closing instruction for controlling the sliding door 3 to close according to the closing information and sends the first closing instruction to the controller 8; the controller 8 receives the first closing command and controls the guide 6 to slide according to the first closing command, thereby sliding the sliding door 3, thereby closing the opening of the accommodating chamber 12. Correspondingly, the staff of the control center of the internet of things system can also remotely send starting information to the processor 9 to indicate to open the sliding door 3; the processor 9 receives the starting information, generates a first starting instruction for controlling the sliding door 3 to be opened according to the starting information and sends the first starting instruction to the controller 8; the controller 8 receives the first start command, and controls the guide member 6 to slide according to the first start command, so as to drive the sliding door 3 to slide, thereby opening the opening of the accommodating cavity 12.

As another embodiment of the present invention, the guide holder 14 may be used in cooperation with the opening and closing of the sliding door 3. Specifically, after the processor 9 acquires the start information, a first start instruction is generated according to the start information and is sent to the controller 8, and meanwhile, the processor 9 generates a second start instruction according to the start information and is sent to the controller 8; the controller 8 receives a first starting instruction and controls the opening of the sliding door 3 according to the first starting instruction, at this time, the opening of the accommodating cavity 12 is opened, meanwhile, the controller 8 receives a second starting instruction and controls the opening of the guide seat 14 according to the second starting instruction, the guide seat 14 moves towards the direction close to the opening along the second guide rail 13, and therefore the camera 1 is driven to move towards the direction close to the opening until the opening is exposed, and the camera 1 has a wider view. Similarly, after the processor 9 obtains the closing information, a first closing instruction is generated according to the closing information and is sent to the controller 8, and meanwhile, the processor 9 generates a second closing instruction according to the closing information and is sent to the controller 8; the controller 8 receives a first closing instruction and controls the sliding door 3 to close according to the first closing instruction, the opening of the accommodating cavity 12 is closed at the moment, meanwhile, the controller 8 receives a second closing instruction and controls the guide seat 14 to close according to the second closing instruction, the guide seat 14 moves towards the direction far away from the opening along the second guide rail 13, therefore, the camera 1 is driven to move towards the direction far away from the opening, the camera 1 is enabled to be far away from the position of the opening, the sliding door 3 smoothly closes the opening at the moment, and the camera 1 is prevented from interfering with the sliding door 3.

As another embodiment of the present invention, the operation information further includes rotation information, the operation instruction further includes a rotation instruction, and the rotation information corresponds to the rotation instruction; the staff at the control center of the internet of things system can remotely send rotation information to indicate the rotation of the rotating rod 16. When the monitoring visual field of the camera 1 needs to be adjusted, the adjustment can be realized by adjusting the projection angle of the camera 1. Specifically, the staff of the control center of the internet of things system can remotely send the rotation information to the processor 9; the processor 9 receives the rotation information, generates a rotation instruction according to the rotation information and sends the rotation instruction to the controller 8; the controller 8 receives the rotation instruction and controls the rotation angle of the rotation rod 16 according to the rotation instruction, so that the camera 1 adjusts the projection angle under the rotation driving of the rotation rod 16, and flexibly adjusts the monitoring visual field.

As another embodiment of the present invention, the control mechanism further comprises a vibration sensor 11, the vibration sensor 11 is disposed in the accommodating cavity 12, and the vibration sensor 11 is in data connection with the processor 9;

the vibration sensor 11 is used for detecting the vibration of the protection mechanism 2, generating vibration information after processing and sending the vibration information to the processor 9;

the processor 9 is configured to receive the vibration information, generate a third closing instruction according to the vibration information, and send the third closing instruction to the controller 8;

the controller 8 is used for receiving a third closing instruction and controlling the sliding of the guide piece 6 according to the third closing instruction; and controls the sliding of the guide shoe 14.

As shown in fig. 2 and 3, the control mechanism further comprises a shock sensor 11, the shock sensor 11 being in data connection with the processor 9, the processor 9 being in data connection with the controller 8. The vibration sensor 11 can sense the vibration state of the monitoring device and generate vibration information to be sent to the processor 9; the processor 9 analyzes and processes the vibration information after acquiring the vibration information, and when the vibration degree represented by the vibration information exceeds a preset value, the monitoring device is indicated to be violently hit at the moment, so that the processor 9 generates a third closing instruction for controlling the sliding door 3 to close and sends the third closing instruction to the controller 8; the controller 8 receives the third closing command, and controls the guide member 6 to move along the guide track on the first guide rail 5 according to the third closing command, and the end of the guide member 6 passing through the guide through hole 7 and connected with the sliding door 3 synchronously drives the sliding door 3 to move in the interlayer inner cavity 4 along with the movement of the guide member 6, thereby closing the opening of the accommodating cavity 12. When the sliding door 3 is closed, the controller 8 receives the second closing command and controls the guide holder 14 to move in the direction away from the opening along the second guide rail 13 according to the second closing command, thereby driving the camera 1 to move in the direction away from the opening, moving the camera 1 away from the opening, smoothly closing the opening with the sliding door 3, and preventing interference with the sliding door 3.

It is to be noted that the term "comprises" and any variations thereof in the description and claims of the present invention is intended to cover non-exclusive inclusions, such that the inclusion of a list of elements is not necessarily limited to those elements explicitly listed, but may include other elements not explicitly listed or inherent to such elements.

In the present invention, the terms "upper", "lower", "bottom", "top", "left", "right", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings. These terms are used primarily to better describe the invention and its embodiments and are not intended to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation.

Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meanings of these terms in the present invention can be understood by those skilled in the art as appropriate.

Furthermore, the description of "first," "second," etc. referred to in this disclosure is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implying any number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (10)

1. The utility model provides an intelligence thing allies oneself with security protection monitoring device which characterized in that, includes camera (1), protection mechanism (2), first guide unit and control mechanism, wherein:

the protection mechanism (2) comprises an accommodating cavity (12) with an opening, and the camera (1) is movably arranged in the accommodating cavity (12); a sliding door (3) is arranged at the opening, and the sliding door (3) is connected with the protection mechanism (2) in a sliding manner;

the first guide unit is arranged on the protection mechanism (2), the first guide unit is connected with the sliding door (3), and the sliding door (3) slides in a reciprocating mode at an opening through the first guide unit so as to open or close the opening;

the control mechanism is in communication connection with the Internet of things system, is connected with the first guide unit and is used for controlling the reciprocating sliding of the first guide unit.

2. The intelligent internet of things security monitoring device according to claim 1, wherein the protection mechanism (2) is a spherical structure, an interlayer inner cavity (4) is arranged on the protection mechanism (2), and the interlayer inner cavity (4) is arranged along the circumferential direction of the protection mechanism (2); the sliding door (3) is inserted into the interlayer inner cavity (4), and the sliding door (3) slides in the interlayer inner cavity (4) in a reciprocating manner.

3. The intelligent internet of things security monitoring device according to claim 2, wherein the first guiding unit comprises a first guiding rail (5) and a guiding member (6), the first guiding rail (5) is circumferentially arranged along the inner wall of the accommodating cavity (12); one end of the guide piece (6) is connected with the first guide rail (5) in a sliding way, and the other end of the guide piece is connected with the sliding door (3); the control mechanism is electrically connected with the guide piece (6) and is used for controlling the sliding of the guide piece (6).

4. The intelligent internet of things security monitoring device according to claim 3, wherein the inner wall of the accommodating cavity (12) is provided with a guide through hole (7) communicated with the interlayer inner cavity (4), the first guide rail (5) is arranged to cover the guide through hole (7), and the guide through hole (7) and the first guide rail (5) have the same guide track; one end of the guide piece (6) is connected with the sliding door (3) through the guide through hole (7).

5. The intelligent internet of things security monitoring device according to claim 3, further comprising a second guiding unit and a supporting unit, wherein the second guiding unit is disposed in the accommodating cavity (12), the camera (1) is connected to one end of the supporting unit, and the other end of the supporting unit is rotatably connected to the second guiding unit; the control mechanism is electrically connected with the second guide unit and is used for controlling the second guide unit to move towards the direction close to or far away from the opening; the control mechanism is electrically connected with the supporting unit and used for controlling the rotation angle of the supporting unit.

6. The intelligent internet of things security monitoring device according to claim 5, wherein the second guiding unit comprises a second guiding rail (13) and a guiding seat (14), the two ends of the second guiding rail (13) are respectively connected with the inner wall of the accommodating cavity (12), and the guiding seat (14) is slidably connected with the second guiding rail (13); the control mechanism is electrically connected with the guide seat (14) and is used for controlling the sliding of the guide seat (14).

7. The intelligent internet of things security monitoring device according to claim 6, wherein the supporting unit comprises a rotating rod (16) and a supporting plate (15), one end of the rotating rod (16) is rotatably connected with the guide seat (14), and the other end of the rotating rod is connected with the supporting plate (15); the camera (1) is arranged on the supporting plate (15); dwang (16) with control mechanism electricity is connected, control mechanism is used for controlling the rotation of dwang (16).

8. The intelligent internet of things security monitoring device according to claim 7, wherein the supporting unit further comprises a reinforcing rib plate (17), and the reinforcing rib plate (17) is arranged on the supporting plate (15).

9. The intelligent internet of things security monitoring device according to claim 5, wherein the control mechanism comprises a controller (8), a processor (9), a wireless communicator (10) and a vibration sensor (11), wherein:

the vibration sensor (11) is used for detecting vibration of the protection mechanism (2), generating vibration information after processing and sending the vibration information to the processor (9);

the processor (9) is in communication connection with the Internet of things system through the wireless communicator (10), and the processor (9) is used for acquiring operation information, weather forecast information or vibration information, generating an operation instruction after processing and sending the operation instruction to the controller (8);

the controller (8) is in data connection with the processor (9), and the controller (8) is used for receiving the operation instruction and controlling the sliding of the guide piece (6) according to the operation instruction;

the controller (8) is used for receiving the operation instruction and controlling the sliding of the guide seat (14) according to the operation instruction;

the controller is used for receiving the operation instruction and controlling the rotation of the rotating rod (16) according to the operation instruction.

10. The intelligent internet of things security monitoring device of claim 9, wherein the operation information comprises start-up information, shut-down information, and rotation information; the operation instruction comprises a first starting instruction, a second starting instruction, a first closing instruction, a second closing instruction, a third closing instruction and a rotation instruction; the weather forecast information comprises hail weather information, rain and snow weather information and normal weather information; the starting information corresponds to a first starting instruction and a second starting instruction; the closing information corresponds to a first closing instruction and a second closing instruction; the hail weather information and the rain and snow weather information correspond to a first closing instruction and a second closing instruction; the normal weather information corresponds to a first starting instruction and a second starting instruction; the rotation information corresponds to the rotation instruction; the vibration information corresponds to the third closing instruction and the second closing instruction.

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