CN215891790U - Domatic mud-rock flow monitoring devices - Google Patents

Abstract

The utility model provides a slope debris flow monitoring device which comprises a solar component, a monitor, a supporting rod, a base, a lifting component and a rotating component, wherein the solar component, the monitor, the supporting rod and the base are sequentially arranged from top to bottom; the rotating assembly comprises a horizontal rotating disc and a first motor for driving the horizontal rotating disc to rotate, a support and a second motor fixed on the support are arranged on the horizontal rotating disc, the monitor is arranged in the support, the side wall of the monitor is rotatably connected with the support through a rotating shaft, and the rotating shaft is communicated with the second motor; the lifting assembly comprises an electric telescopic rod connected with the rotating assembly; the solar energy component continuously supplies power to the monitor, the first motor, the second motor and the electric telescopic rod. According to the technical scheme, the monitoring range is enlarged, a plurality of monitors are not needed, and the monitoring cost is saved.

Description

Domatic mud-rock flow monitoring devices

Technical Field

The utility model relates to a slope debris flow monitoring device.

Background

The geological disasters are various, the distribution area is wide, the occurrence frequency is high, and the loss is large. The sudden nature of the slope debris flow is stronger and stronger due to local heavy rainfall and storm caused by strong heat zone storm by change and measurement. Therefore, a monitoring device is required to be installed in an area where debris flow is easy to occur, so that real-time monitoring is achieved, early warning is carried out on the slope debris flow disasters, and loss is reduced.

At present, a monitoring device is generally fixed on a supporting rod, the supporting rod is fixed on the ground, the height of the monitoring device depends on the height of the monitoring device installed on the supporting rod, and the height of the monitoring device after being installed cannot be adjusted, so that the monitoring range of the monitoring device is relatively small. For example, the technical proposal disclosed by the Chinese utility model patent CN206441320U 'a landslide mud-rock flow monitoring device'. In order to fully cover the monitoring range of the debris flow-prone area, a plurality of groups of monitoring devices need to be arranged, which leads to great cost increase.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects in the prior art and provide a slope debris flow monitoring device capable of covering a monitoring area in an all-round manner.

In order to achieve the purpose, the technical scheme adopted by the utility model is as follows:

a slope debris flow monitoring device comprises a solar component, a monitor, a supporting rod, a base, a lifting component and a rotating component, wherein the solar component, the monitor, the supporting rod and the base are sequentially arranged from top to bottom; the monitoring instrument is arranged in the bracket, the side wall of the monitoring instrument is rotationally connected with the bracket through a rotating shaft, and the rotating shaft is communicated with the second motor; the lifting assembly comprises an electric telescopic rod connected with the rotating assembly; the solar energy component is the monitor, the first motor, the second motor and the electric telescopic rod continuously supply power.

Further, the lifting assembly further comprises a mounting plate; at least the upper end part of the supporting rod is provided with a cavity, and the mounting plate is fixed in the cavity; the lower end of the electric telescopic rod is fixed on the mounting plate, and the upper end of the electric telescopic rod extends out of the upper end of the supporting rod and is connected with the rotating assembly.

Furthermore, the lifting assembly also comprises a sleeve, an opening at the lower end of the sleeve is covered outside the upper end of the supporting rod, and the rotating assembly is arranged on the top surface of the sleeve; the inner wall of the sleeve and the side wall of the upper end of the supporting rod are arranged in a sliding mode.

Further, the rotating assembly further comprises a mounting barrel; the mounting barrel is fixed on the sleeve, and the end part of a piston rod of the electric telescopic rod is fixed with the top surface of the sleeve; the hollow interior of the mounting barrel is used for accommodating the first motor; the horizontal rotary disc seals the opening at the upper end of the installation barrel.

Further, the bracket is a first supporting plate and a second supporting plate which are arranged on two sides of the monitor; the second motor is fixed on the outer wall surface of the first supporting plate, one end of the rotating shaft is connected with the end part of an output shaft of the second motor, and the other end of the rotating shaft is rotatably connected with the second supporting plate.

Furthermore, the solar module comprises a fixing plate, a fixing frame, a solar panel, a solar controller and a storage battery; the solar cell panel is arranged on the fixing frame; the fixing plate is arranged above the bracket, the fixing frame is connected with the fixing plate, so that an installation cavity is formed in the fixing frame, and the solar controller and the storage battery are arranged in the installation cavity; the solar cell panel, the solar controller and the storage battery are electrically connected.

Furthermore, the inner wall of the sleeve is also provided with a vertical sliding groove, and the outer wall of the upper end of the supporting rod is provided with a sliding block embedded in the sliding groove; the lower end of the sliding groove is provided with an anti-falling limiting block.

Furthermore, the base is of a trapezoid boss structure with a large lower part and a large upper part and a large lower part.

Furthermore, the base lateral wall is equipped with multichannel hoop antiskid groove.

According to the technical scheme, the lifting assembly, the rotating assembly and the monitors can rotate on the vertical surfaces of the monitoring devices, and all-dimensional coverage in a monitoring area can be realized by only one monitor, so that the monitoring range is enlarged, the debris flow monitoring effect is improved, and the monitoring cost is saved.

Drawings

Fig. 1 is a perspective view of the present invention.

Figure 2 is a cross-sectional view of the rotating assembly and the lifting assembly of the present invention.

Fig. 3 is a partially enlarged view of fig. 2.

Fig. 4 is an assembly view of the rotating assembly, the monitor and the solar module of the present invention.

Fig. 5 is a schematic structural diagram of the base of the present invention.

Detailed Description

The utility model is further described below with reference to the accompanying drawings.

Reference is made to the accompanying drawings. The embodiment comprises a solar module 500, a monitor 450, a rotating module 300, a lifting module 200, a support rod 110 and a base 120 which are arranged in sequence from top to bottom. The rotating assembly 300 includes a horizontal turntable 330, a first motor 320, and a mounting tub 310. The installation barrel 310 is a cylindrical barrel with an opening at the upper end and an accommodating space in the middle, the first motor 320 is installed in the installation barrel 310, and the end part of the output shaft is connected with the bottom of the horizontal turntable 330, so that the first motor 320 can drive the horizontal turntable 330 to rotate 360 degrees in the horizontal direction. The horizontal rotary plate 330 is disposed at the opening of the installation tub 310 and has the same diameter as the outer diameter of the opening of the installation tub 310 so as to shield the opening of the installation tub 310. The mounting barrel 310 is mounted on the lifting assembly 200.

The lifting assembly 200 is disposed at the upper end of the support rod 110 and includes an electric telescopic rod 220, a mounting plate 210 and a sleeve 230. The support bar 110 has a cavity at least at an upper end thereof for fixing the mounting plate 210. Of course, the support rod 110 may be hollow, and the mounting plate 210 is fixed inside the support rod 110 near the upper end of the support rod 110. The lower end opening and the upper end of the sleeve 230 are closed and cover the upper end of the support rod 110, the bottom of the electric telescopic rod 220 is fixed on the upper surface of the mounting plate 210, and the end of the piston rod is connected with the upper end surface of the sleeve 230. Meanwhile, the mounting barrel 310 is mounted on the sleeve 230 through the upper end face of the sleeve 230, so that the electric telescopic rod 220 can drive the horizontal turntable 330 to ascend and descend in the vertical direction, and the monitoring range of the monitor 450 in the vertical direction is improved.

The inner wall of the sleeve 230 is slidably disposed with the side wall of the upper end of the support rod 110. Specifically, in the present embodiment, two sliding grooves 250 are vertically disposed on the inner wall of the sleeve 230, and the sliding blocks 240 are correspondingly welded to the side walls of the upper end of the supporting rod 110, and the sliding blocks 240 slide in the sliding grooves 250. The two sets of sliding blocks 240 and the sliding grooves 250 are symmetrically distributed on two opposite sides of the supporting rod 110. When the sleeve 230 slides on the supporting rod 110, the sliding block 240 on the supporting rod 110 slides along the sliding groove 250 on the sleeve 230, so that the frictional resistance between the sleeve 230 and the supporting rod 110 can be reduced, and meanwhile, the sleeve 230 is prevented from rotating, the arrangement of the sliding block 240 and the sliding groove 250 plays a role in guiding and preventing rotation, the arrangement of the two groups of sliding blocks 240 and the sliding groove 250 enhances the stability during sliding, in order to prevent the sleeve 230 from sliding out of the top end of the supporting rod 110 when sliding upwards, a limiting block 260 is fixed at the end part of the lower end of the sliding groove 250, the sliding block 240 is arranged above the limiting block 260, when the sleeve 230 moves upwards, the limiting block 260 is driven to move upwards until the upper end of the limiting block 260 contacts with the lower end of the sliding block 240, the limiting block 260 is blocked to stop moving, and then the sleeve 230 stops moving, and prevents the supporting rod 110 from sliding out, and plays a role in limiting and protecting.

The horizontal turntable 330 is provided with a pitch angle adjusting assembly 400, which comprises a monitor 450, a second motor 430, and a first support plate 410 and a second support plate 420 located at two sides of the monitor 450. The second motor 430 is fixed to the outer wall surface of the first support plate 410. One end of the rotation shaft 440 is connected to an output shaft end of the second motor 430, and the other end is rotatably connected to the second support plate 420. The monitor 450 is fixedly installed on the rotating shaft 440, so that the monitor 450 can rotate in the vertical direction under the action of the second motor 430.

The solar module 500 includes a fixing plate 510, a fixing frame 520, a solar cell panel 530, a solar controller 540, and a storage battery 550. The solar cell panel 530 is installed on each surface of the fixing frame 520, the fixing plate 510 is horizontally disposed above the first and second support plates 410 and 420, the fixing frame 520 is coupled with the fixing plate 510 such that an installation cavity is formed in the fixing frame 520, and the solar controller 540 and the storage battery 550 are disposed in the installation cavity. The solar panel 530 is electrically connected to the solar controller 540, and the solar controller 540 is electrically connected to the battery 550. The storage battery 550 is electrically connected with the first motor 320, the second motor 430, the electric telescopic rod 220 and the monitor 450 respectively, so that solar energy is converted into electric energy, the electric energy is provided for the whole device, energy is saved, and cost is reduced. Specifically, the fixing frame 520 is in a ladder-shaped design with a small top and a large bottom, the solar cell panel 530 is fixedly mounted on the four sides and the top end of the fixing frame 520, and after the fixing frame 520 rotates for any angle along with the rotating disc, the solar cell panel 530 is aligned to the sun, so that power generation is facilitated.

The lower end of the support rod 110 is disposed on the base 120, and the base 120 has a trapezoidal boss structure with a large lower part and a large upper part. When the base 120 is buried in the ground, the increased shape of the base 120 may increase resistance between the base 120 and the ground, thereby enhancing firmness and stability of installation. Particularly, the outer surface of the base 120 is uniformly provided with a plurality of circumferential anti-slip grooves 121 for increasing the frictional resistance between the base 120 and the ground, and improving the firmness and stability of the device mounted on the ground.

It should be noted that the above describes exemplifying embodiments of the utility model. It will be understood by those skilled in the art, however, that the present invention is not limited to the embodiments described above, which are given by way of illustration of the principles of the present invention, but that various changes and modifications may be made without departing from the scope of the utility model as defined by the appended claims.

Claims (10)

1. A slope debris flow monitoring device is characterized by comprising a solar component, a monitor, a supporting rod, a base, a lifting component and a rotating component, wherein the solar component, the monitor, the supporting rod and the base are sequentially arranged from top to bottom; the monitoring instrument is arranged in the bracket, the side wall of the monitoring instrument is rotationally connected with the bracket through a rotating shaft, and the rotating shaft is communicated with the second motor; the lifting assembly comprises an electric telescopic rod connected with the rotating assembly; the solar energy component is the monitor, the first motor, the second motor and the electric telescopic rod continuously supply power.

2. The slope debris flow monitoring device of claim 1, wherein the lifting assembly further comprises a mounting plate; at least the upper end part of the supporting rod is provided with a cavity, and the mounting plate is fixed in the cavity; the lower end of the electric telescopic rod is fixed on the mounting plate, and the upper end of the electric telescopic rod extends out of the upper end of the supporting rod and is connected with the rotating assembly.

3. The slope debris flow monitoring device according to claim 2, wherein the lifting assembly further comprises a sleeve, an opening at the lower end of the sleeve is covered outside the upper end of the support rod, and the rotating assembly is mounted on the top surface of the sleeve; the inner wall of the sleeve and the side wall of the upper end of the supporting rod are arranged in a sliding mode.

4. The slope debris flow monitoring device of claim 1, wherein the rotating assembly further comprises a mounting bucket; the bottom surface of the mounting barrel is connected with the electric telescopic rod, and the first motor is accommodated in the hollow interior; the horizontal rotary disc seals the opening at the upper end of the installation barrel.

5. The slope debris flow monitoring device of claim 3, wherein the rotating assembly further comprises a mounting bucket; the mounting barrel is fixed on the sleeve, and the end part of a piston rod of the electric telescopic rod is fixed with the top surface of the sleeve; the hollow interior of the mounting barrel is used for accommodating the first motor; the horizontal rotary disc seals the opening at the upper end of the installation barrel.

6. The slope debris flow monitoring device according to claim 1, wherein the support comprises a first support plate and a second support plate disposed on both sides of the monitor; the second motor is fixed on the outer wall surface of the first supporting plate, one end of the rotating shaft is connected with the end part of an output shaft of the second motor, and the other end of the rotating shaft is rotatably connected with the second supporting plate.

7. The slope debris flow monitoring device of claim 1, wherein the solar module comprises a fixing plate, a fixing frame, a solar panel, a solar controller and a storage battery; the solar cell panel is arranged on the fixing frame; the fixing plate is arranged above the bracket, the fixing frame is connected with the fixing plate, so that an installation cavity is formed in the fixing frame, and the solar controller and the storage battery are arranged in the installation cavity; the solar cell panel, the solar controller and the storage battery are electrically connected.

8. The slope debris flow monitoring device of claim 3 or 5, wherein the inner wall of the sleeve is further provided with a vertical chute, and the outer wall of the upper end of the support rod is provided with a slide block embedded in the chute; the lower end of the sliding groove is provided with an anti-falling limiting block.

9. The slope debris flow monitoring device of claim 1, wherein the base is of a trapezoidal boss structure with a large lower part and a large upper part and a large lower part.

10. The slope debris flow monitoring device of claim 1 or 9, wherein the side wall of the base is provided with a plurality of circumferential anti-slip grooves.

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