CN216646835U - Geological disaster real-time monitoring device based on Beidou - Google Patents

Abstract

The utility model provides a Beidou-based geological disaster real-time monitoring device, wherein a solar panel is installed at the top of a vertical rod to charge the device, a Beidou communication module for communication is installed on the side wall of the vertical rod, a wake-up unit, a vibration sensor and a central processing unit are installed inside the vertical rod, and in a conventional state, the Beidou communication module, the wake-up unit, the vibration sensor and the central processing unit are all in a dormant state. This geological disasters real-time supervision device can keep the dormancy state to save the electric quantity when not taking place geological disasters to respond rapidly when geological disasters take place, be convenient for work at the inconvenient monitoring point of power supply, possess good practicality.

Description

Geological disaster real-time monitoring device based on Beidou

Technical Field

The utility model relates to the field of geological monitoring, in particular to a Beidou-based geological disaster real-time monitoring device.

Background

In the field of geological monitoring, because the positions of some monitoring points are remote, and the cost required by the work of workers at the monitoring points for a long time is high, a monitoring device is often installed at the monitoring points to monitor the monitoring points in real time. Because the power supply of monitoring point is difficult relatively usually, current monitoring devices only rely on the battery to be difficult to realize the work of long-term nature, if rely on solar panel to supply power, for the continuous work who satisfies equipment, then need the great solar panel of installation area, not only the cost is higher, and receives the normal work that damages the influence device easily.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects in the prior art, the utility model provides a Beidou-based geological disaster real-time monitoring device.

The technical scheme provided by the utility model is as follows: the utility model provides a geological disaster real-time supervision device based on big dipper, includes: the device comprises a vertical rod, a Beidou communication module, a solar panel, a wake-up unit, a vibration sensor and a central processing unit; the solar panel is fixedly arranged on the top of the upright rod; the Beidou communication module is fixedly arranged on the side wall of the upright rod; an upper layer of partition board and a lower layer of partition board are arranged on the upper half part of the inner side of the upright stanchion, the vibration sensor is arranged on the upper surface of the upper layer of partition board, and the awakening unit and the central processing unit are fixedly arranged on the upper surface of the lower layer of partition board; the central processing unit is electrically connected with the Beidou communication module, the awakening unit and the vibration sensor.

According to the Beidou-based geological disaster real-time monitoring device, the solar panel is mounted at the top of the vertical rod to charge the device, the Beidou communication module for communication is mounted on the side wall of the vertical rod, the awakening unit, the vibration sensor and the central processing unit are mounted inside the vertical rod, and in a conventional state, the Beidou communication module, the awakening unit, the vibration sensor and the central processing unit are all in a dormant state. This geological disasters real-time supervision device can keep the dormancy state to save the electric quantity when not taking place geological disasters to respond rapidly when geological disasters take place, be convenient for work at the inconvenient monitoring point of power supply, possess good practicality. Specifically, the utility model relates to a Beidou-based geological disaster real-time monitoring device, which comprises: pole setting, big dipper communication module, solar panel, awaken up unit, vibrations sensor and central processing unit. The vertical rod is a cylindrical hollow metal rod and is vertically fixed on the ground at the monitoring point, and when geological disasters occur at the monitoring point, the vertical rod vibrates along with the ground. Solar panel fixed mounting is in the top of pole setting. Big dipper communication module fixed mounting is on the lateral wall of pole setting for receive and dispatch data. The upper half part of the inner side of the upright stanchion is provided with an upper layer of clapboard and a lower layer of clapboard which is a round metal plate. The vibration sensor is arranged on the upper surface of the upper-layer partition plate and used for monitoring vibration data of the vertical rod. The awakening unit and the central processing unit are fixedly arranged on the upper surface of the lower-layer partition plate; the central processing unit is electrically connected with the Beidou communication module, the awakening unit and the vibration sensor. When the pole setting does not take place vibrations or the range of vibrations is not enough to trigger the unit of awakening up, central processing unit, big dipper communication module and vibrations sensor all are in the dormant state, and after the vibrations of pole setting reached the certain degree and triggered the unit of awakening up, central processing unit, big dipper communication module and vibrations sensor got into operating condition, and the vibrations data transmission who will monitor was to high in the clouds.

Preferably, the lower surface of the upper-layer clapboard is fixed with an insulating hanging rack; an insulating bottom plate is fixed on the upper surface of the lower layer clapboard below the insulating hanging rack.

Preferably, the wake-up unit comprises a current monitor, a conductive metal plate and a conductive metal; the conductive metal box is fixed on the upper surface of the insulating bottom plate; the current monitor is fixed on the upper surface of the lower layer clapboard near the insulating bottom plate and is electrically connected with the central processing unit; the current monitor is electrically connected with the conductive metal box through a lead; the current monitor is electrically connected with the conductive metal plate through another conducting wire hung on the insulating hanging rack; the conductive metal plate is suspended inside the conductive metal box through a wire and is spaced from the side wall and the top surface of the conductive metal box by a certain distance.

Preferably, the upper surface of the conductive metal box is provided with a cross-shaped opening through which the lead passes.

Preferably, the tail ends of the wires hung on the insulating hanging rack are divided into four parts, and the four parts are respectively fixedly connected with the edges of the conductive metal plate in four directions.

Preferably, an attitude sensor is fixed on the upper surface of the upper layer partition plate, and the attitude sensor is electrically connected with the central processing unit.

Preferably, two opposite cameras are fixedly mounted on the upper half part of the side wall of the upright rod.

Preferably, a battery and a power supply conversion unit are fixedly arranged in the vertical rod; the battery is electrically connected with the power conversion unit.

The beneficial technical effects of the utility model are as follows:

according to the Beidou-based geological disaster real-time monitoring device, the solar panel is mounted at the top of the vertical rod to charge the device, the Beidou communication module for communication is mounted on the side wall of the vertical rod, the awakening unit, the vibration sensor and the central processing unit are mounted inside the vertical rod, and in a conventional state, the Beidou communication module, the awakening unit, the vibration sensor and the central processing unit are all in a dormant state. This geological disasters real-time supervision device can keep the dormancy state to save the electric quantity when not taking place geological disasters to respond rapidly when geological disasters take place, be convenient for work at the inconvenient monitoring point of power supply, possess good practicality.

Drawings

FIG. 1 is a schematic elevation structure diagram of a Beidou-based geological disaster real-time monitoring device in the utility model;

FIG. 2 is a schematic structural diagram of a front view section of the Beidou-based geological disaster real-time monitoring device in the utility model;

FIG. 3 is an enlarged schematic view of portion A of FIG. 2;

FIG. 4 is a schematic top view of the conductive metal case of the present invention;

fig. 5 is a schematic top sectional view of the conductive metal case of the present invention.

In the drawings: 1. pole setting, 2, big dipper communication module, 3, solar panel, 4, camera, 5, battery, 6, power conversion unit, 71, insulating bottom plate, 72, insulating stores pylon, 73, current monitor, 74, wire, 75, conductive metal plate, 76, conductive metal box, 8, vibrations sensor, 9, attitude sensor, 10, central processing unit, 11, baffle.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Further, in the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

In the following description, suffixes such as "module", "component", or "unit" used to denote elements are used only for facilitating the explanation of the present invention, and have no specific meaning in itself. Thus, "module", "component" or "unit" may be used mixedly.

As shown in FIG. 1, a geological disaster real-time monitoring device based on big dipper includes: the device comprises a vertical rod 1, a Beidou communication module 2, a solar panel 3, a wakeup unit, a vibration sensor 8 and a central processing unit 10; the solar panel 3 is fixedly arranged on the top of the upright rod 1; the Beidou communication module 2 is fixedly arranged on the side wall of the upright rod 1; an upper layer of partition board 11 and a lower layer of partition board 11 are arranged at the upper half part of the inner side of the upright stanchion 1, the vibration sensor 8 is arranged on the upper surface of the upper layer of partition board 11, and the awakening unit and the central processing unit 10 are fixedly arranged on the upper surface of the lower layer of partition board 11; the central processing unit 10 is electrically connected with the Beidou communication module 2, the awakening unit and the vibration sensor 8.

According to the Beidou-based geological disaster real-time monitoring device, the solar panel is mounted at the top of the vertical rod to charge the device, the Beidou communication module for communication is mounted on the side wall of the vertical rod, the awakening unit, the vibration sensor and the central processing unit are mounted inside the vertical rod, and in a conventional state, the Beidou communication module, the awakening unit, the vibration sensor and the central processing unit are all in a dormant state. This geological disasters real-time supervision device can keep the dormancy state to save the electric quantity when not taking place geological disasters to respond rapidly when geological disasters take place, be convenient for work at the inconvenient monitoring point of power supply, possess good practicality. Specifically, as shown in fig. 1 to 3, the utility model provides a Beidou-based geological disaster real-time monitoring device, which comprises: pole setting 1, big dipper communication module 2, solar panel 3, awaken up unit, vibrations sensor 8 and central processing unit 10. The vertical rod 1 is a cylindrical hollow metal rod and is vertically fixed on the ground at a monitoring point, and when geological disasters occur at the monitoring point, the vertical rod 1 vibrates along with the ground. Solar panel 3 fixed mounting is in the top of pole setting 1. Big dipper communication module 2 fixed mounting is used for receiving and dispatching data on the lateral wall of pole setting 1. An upper layer of partition board 11 and a lower layer of partition board 11 are arranged on the upper half part of the inner side of the upright stanchion 1, and the partition board 11 is a circular metal plate. The vibration sensor 8 is arranged on the upper surface of the upper-layer partition plate 11 and used for monitoring vibration data of the vertical rod 1. The awakening unit and the central processing unit 10 are fixedly arranged on the upper surface of the lower partition plate 11; the central processing unit 10 is electrically connected with the Beidou communication module 2, the awakening unit and the vibration sensor 8. When pole setting 1 does not take place vibrations or the range of vibrations is not enough to trigger the unit of awaking, central processing unit 10, big dipper communication module 2 and vibrations sensor 8 all are in the dormant state, and after pole setting 1's vibrations reached the certain degree and triggered the unit of awaking, central processing unit 10, big dipper communication module 2 and vibrations sensor 8 got into operating condition, and the vibrations data transmission who will monitor was to high in the clouds.

In at least one embodiment, as shown in fig. 3, an insulating hanger 72 is fixed to the lower surface of the upper layer separator 11; an insulating bottom plate 71 is fixed on the upper surface of the lower-layer partition plate 11 below the insulating hanging rack 72, the insulating hanging rack 72 and the insulating bottom plate 71 are both made of insulating materials, the insulating hanging rack 72 is in a hook shape, and the insulating bottom plate 71 is in a round cake shape.

In at least one embodiment, as shown in fig. 3, the wake-up unit includes a current monitor 73, a conductive metal plate 75, and conductive metal plates 76. The conductive metal case 76 is a bottomless cylindrical metal case and is fixed to the upper surface of the insulating base plate 71. The current monitor 73 is fixed to the upper surface of the lower partition 11 near the insulating base plate 71, and the current monitor 73 is electrically connected to the cpu 10. The current monitor 73 is electrically connected with the conductive metal box 76 through a lead 74; the current monitor 73 is electrically connected with the conductive metal plate 75 through another wire 74 hung on the insulating hanger 72; the conductive metal plate 75 is suspended inside the conductive metal case 76 by the wire 74 and is spaced apart from the side wall and the top surface of the conductive metal case 76. When vibrations reach certain range in pole setting 1, conductive metal plate 75 rocks and takes place the contact with conductive metal box 76, the circuit switch-on this moment, and electric current is monitored to current monitor 73, sends working signal to central processing unit 10, and central processing unit 10 begins work, sends working signal to vibrations sensor 8 and big dipper communication module 2, and vibrations sensor 8 begins to monitor the vibrations condition, and big dipper communication module 2 will shake data transmission to the high in the clouds. Preferably, after the current monitor 73 does not monitor the current for a certain time, which indicates that the geological disaster has stopped, the central processing unit 10, the beidou communication module 2 and the vibration sensor 8 enter a sleep state.

In at least one embodiment, as shown in FIG. 4, the top surface of the conductive metal box 76 defines a cross-shaped opening through which the wire 74 passes.

In at least one embodiment, as shown in fig. 5, the ends of the wires 74 suspended on the insulating hanger 72 are divided into four, and fixedly connected to four directional edges of the conductive metal plate 75, respectively.

In at least one embodiment, as shown in fig. 3, the attitude sensor 9 is fixed to the upper surface of the upper-layer partition 11, and the attitude sensor 9 is electrically connected to the central processing unit 10. The attitude sensor 9 can detect the current inclined state of the vertical rod 1, and a worker can judge whether the vertical rod 1 is damaged or not.

In at least one embodiment, as shown in fig. 1, two opposite cameras 4 are fixedly mounted on the upper half portion of the side wall of the upright rod 1, the cameras 4 are panoramic cameras, and after the central processing unit 10 starts to work, the working signals are sent to the cameras 4, and the video data shot by the cameras 4 are sent to the cloud end through the beidou communication module 2.

In at least one embodiment, as shown in fig. 2, a battery 5 and a power conversion unit 6 are fixedly mounted inside the vertical rod 1; the battery 5 is electrically connected to the power conversion unit 6. The battery 5 is used for supplying power to the central processing unit 10, the Beidou communication module 2, the vibration sensor 8, the attitude sensor 9 and the camera 4, and the power supply conversion unit 6 is a power supply inverter and is used for converting the output voltage of the battery 5.

Obviously, according to the Beidou-based geological disaster real-time monitoring device provided by the utility model, the solar panel is arranged at the top of the upright rod to charge the device, the Beidou communication module for communication is arranged on the side wall of the upright rod, the awakening unit, the vibration sensor and the central processing unit are arranged in the upright rod, and in a conventional state, the Beidou communication module, the awakening unit, the vibration sensor and the central processing unit are all in a dormant state. This geological disasters real-time supervision device can keep the dormancy state to save the electric quantity when not taking place geological disasters to respond rapidly when geological disasters take place, be convenient for work at the inconvenient monitoring point of power supply, possess good practicality.

The foregoing is a preferred embodiment of the present invention, and it should be understood that those skilled in the art can derive the related technical solutions through logic analysis, reasoning or experiment based on the concepts of the present invention without creative efforts, and therefore, the related technical solutions should be within the protection scope of the present claims.

Claims (8)

1. The utility model provides a geological disaster real-time supervision device based on big dipper which characterized in that includes: the device comprises a vertical rod (1), a Beidou communication module (2), a solar panel (3), a wake-up unit, a vibration sensor (8) and a central processing unit (10); the solar panel (3) is fixedly arranged on the top of the upright rod (1); the Beidou communication module (2) is fixedly arranged on the side wall of the upright rod (1); an upper layer of partition board (11) and a lower layer of partition board (11) are arranged on the upper half part of the inner side of the upright stanchion (1), the vibration sensor (8) is installed on the upper surface of the upper layer of partition board (11), and the awakening unit and the central processing unit (10) are fixedly installed on the upper surface of the lower layer of partition board (11); the central processing unit (10) is electrically connected with the Beidou communication module (2), the awakening unit and the vibration sensor (8).

2. The Beidou based real-time geological disaster monitoring device according to claim 1, characterized in that an insulating hanger (72) is fixed on the lower surface of the upper partition (11); an insulating bottom plate (71) is fixed on the upper surface of the lower-layer partition plate (11) below the insulating hanging frame (72).

3. The Beidou based real-time geological disaster monitoring device according to claim 2, characterized in that the wake-up unit comprises a current monitor (73), a conductive metal plate (75) and a conductive metal box (76); the conductive metal box (76) is fixed on the upper surface of the insulating bottom plate (71); the current monitor (73) is fixed on the upper surface of the lower partition board (11) near the insulating bottom board (71), and the current monitor (73) is electrically connected with the central processing unit (10); the current monitor (73) is electrically connected with the conductive metal box (76) through a lead (74); the current monitor (73) is electrically connected with the conductive metal plate (75) through another lead (74) hung on the insulating hanger (72); the conductive metal plate (75) is suspended inside the conductive metal box (76) by a wire (74) and is spaced apart from the side walls and the top surface of the conductive metal box (76).

4. The Beidou-based real-time geological disaster monitoring device according to claim 3, characterized in that the upper surface of the conductive metal box (76) is provided with a cross-shaped opening for the lead (74) to pass through.

5. The Beidou based real-time geological disaster monitoring device according to claim 4, characterized in that the tail ends of the conducting wires (74) hung on the insulating hanging rack (72) are divided into four, and the four tail ends are fixedly connected with the edges of the conducting metal plate (75) in four directions respectively.

6. The Beidou based real-time geological disaster monitoring device according to claim 5, characterized in that an attitude sensor (9) is fixed on the upper surface of the upper partition (11), and the attitude sensor (9) is electrically connected with the central processing unit (10).

7. The Beidou based real-time geological disaster monitoring device according to claim 6, characterized in that two opposite cameras (4) are fixedly installed on the upper half part of the side wall of the upright (1).

8. The Beidou-based real-time geological disaster monitoring device according to claim 7, characterized in that a battery (5) and a power conversion unit (6) are fixedly installed inside the vertical rod (1); the battery (5) is electrically connected with the power conversion unit (6).

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