CN220323551U - Monitoring equipment - Google Patents

Abstract

The utility model provides a monitoring device, which relates to the field of monitoring devices and comprises: base, stabilising arrangement, support, mounting bracket and monitoring facilities case, stabilising arrangement connects in the outside of base, and stabilising arrangement includes solid fixed ring and spud pile, gu the fixed ring outer end is connected with wire rope, and the wire rope outer end is connected with the spud pile to be connected with tension sensor before the wire rope, leg joint is in the base upper end, and the mounting bracket is connected in the support upper end to the lightning rod is installed to the mounting bracket upper end, the mounting bracket includes the mounting panel, and the welding of mounting panel lower extreme has the sleeve to the mounting panel outer end articulates there is the articulated rod, and the articulated rod lower extreme articulates there is a packet clamp splice. The utility model solves the problems that geological environment monitoring equipment in the prior art is easy to be influenced by weather change and inconvenient to assemble and carry when being installed and used in the field.

Description

Monitoring equipment

Technical Field

The utility model relates to the technical field of monitoring equipment, in particular to monitoring equipment.

Background

For geological structure survey and detection of underground structures, scientific researchers have developed many effective geophysical survey methods, such as seismic wave survey, conductivity survey, radiometer, infrared temperature detection, etc., and the prior art (application number: CN201822131646. X) describes a portable ground penetrating radar data acquisition device for mine geological environment monitoring, comprising a housing, a data acquisition device integrated inside the housing, a transceiver antenna device mounted at the bottom of the housing and a rotary folding bracket; the data acquisition device comprises a power supply, a central processing unit, a transmitter, a receiver and a data transmission device. The electromagnetic wave signal collection in the geological environment monitoring target area is realized by integrating the most basic data collection equipment in the shell, and then the electromagnetic wave signal is transmitted to the external data processing equipment for processing through the data transmission device. According to the utility model, the data acquisition equipment and the external data processing equipment are arranged separately, so that the structure of the portable ground penetrating radar data acquisition device is simplified to the greatest extent, and the volume and the weight of the portable equipment are reduced; the rotary folding bracket can be stored at the bottom of the shell, so that the volume of the data acquisition device is further reduced, and the portable folding bracket is convenient to carry and use during field operation. "

However, the geological environment monitoring device in the prior art still has some defects although achieving the effect of portability: some existing geological monitoring equipment is installed on the mountain for a long time, equipment at a high place is easy to be damaged by lightning stroke in thunderstorm weather, meanwhile, long-term overcast and rainy weather is encountered, mountain geological landslide is easily caused, equipment is easy to topple over, and secondly, the existing geological environment monitoring equipment is large in size and inconvenient to assemble and disassemble, and therefore the whole mountain is difficult to install.

Disclosure of Invention

In order to overcome the defects existing in the prior art, the monitoring equipment is provided at present, so that the problems that the geological environment monitoring equipment in the prior art is easy to be influenced by weather changes and inconvenient to assemble and carry when being installed and used in the field are solved.

To achieve the above object, there is provided a monitoring apparatus comprising: base, stabilising arrangement, support, mounting bracket and monitoring facilities case, stabilising arrangement connects in the outside of base, and stabilising arrangement includes solid fixed ring and spud pile, gu the fixed ring outer end is connected with wire rope, and the wire rope outer end is connected with the spud pile to be connected with tension sensor before the wire rope, leg joint is in the base upper end, and the mounting bracket is connected in the support upper end to the lightning rod is installed to the mounting bracket upper end, the mounting bracket includes the mounting panel, and the welding of mounting panel lower extreme has the sleeve to the mounting panel outer end articulates there is the articulated rod, and the articulated rod lower extreme articulates there is a packet clamp splice.

Further, the inside sensor cable that is equipped with of base, and sensor cable is equipped with upper and lower two sections to the sensor cable of hypomere is connected with geological detection sensor, and the sensor cable upper end and the monitoring facilities case electric connection of upper segment.

Further, the monitoring equipment box is installed at the upper end of the mounting plate, the upper end of the monitoring equipment box is connected with an antenna, and the photovoltaic panel is installed on the outer wall of the monitoring equipment box.

Further, the lightning rod is installed in the mounting panel upper end, and the lightning rod outer end is connected with the earth connection to the lightning rod is located the monitoring facilities case outside and is higher than the monitoring facilities case.

Further, the sleeve is sleeved at the top of the support, reinforcing ribs of the triangular plate structure are arranged on the outer wall of the sleeve, and the sleeve and the mounting plate are both made of insulating materials.

Further, the wrapping and clamping blocks are of semi-annular structures, the wrapping and clamping blocks are symmetrically wrapped on the outer wall of the support, and the wrapping and clamping blocks are connected through bolts.

Furthermore, the inside of the support is hollow, a window is formed in the outer wall of the support, a cable connector is arranged in the window, and the cable connector connects the two sections of sensor cables.

The utility model has the beneficial effects that:

1. the lightning rod and the grounding wire are utilized, so that a lightning protection effect on the monitoring equipment box is realized in lightning and weather, the fixing ring, the tension sensor, the steel wire rope and the fixing pile which are included in the stabilizing device are utilized, the base is conveniently pulled and fixed in a long distance in the circumferential direction, when the tension sensor detects loosening of the steel wire rope, a remote signal is sent through the monitoring equipment box and the antenna, notification and early warning are realized, and a worker can check in the scene in a driving manner;

2. utilize mounting panel, sleeve, articulated lever and the package clamp splice that the mounting bracket includes, be convenient for carry the whole, support and the independent dismantlement of monitoring facilities case of mounting bracket, be convenient for when the equipment through window and cable joint, with sensor cable junction, then bury the geological monitoring sensor of lower extreme underground, and then be convenient for assemble and carry.

Drawings

Fig. 1 is a schematic overall structure of an embodiment of the present utility model.

Fig. 2 is a schematic structural view of a mounting frame according to an embodiment of the present utility model.

Fig. 3 is a schematic view of an internal structure of a window according to an embodiment of the utility model.

Fig. 4 is a schematic structural diagram of a stabilizing device according to an embodiment of the present utility model.

In the figure: 1. a base; 11. a sensor cable; 2. a stabilizing device; 21. a fixing ring; 22. a tension sensor; 23. a wire rope; 24. fixing piles; 3. a bracket; 31. a window; 32. a cable joint; 4. a mounting frame; 41. a mounting plate; 42. a sleeve; 43. reinforcing ribs; 44. a hinge rod; 45. a clamping block; 5. a photovoltaic panel; 6. a lightning rod; 61. a ground wire; 7. monitoring the equipment box; 71. an antenna.

Detailed Description

Other advantages and effects of the present utility model will become apparent to those skilled in the art from the following disclosure, which describes the embodiments of the present utility model with reference to specific examples. The utility model may be practiced or carried out in other embodiments that depart from the specific details, and the details of the present description may be modified or varied from the spirit and scope of the present utility model.

Referring to fig. 1 to 4, the present utility model provides a monitoring apparatus comprising: base 1, stabilising arrangement 2, support 3, mounting bracket 4 and monitoring equipment box 7.

Specifically, the stabilizer 2 is connected in the outside of the base 1, and the stabilizer 2 includes solid fixed ring 21 and spud 24, gu fixed ring 21 outer end is connected with wire rope 23, wire rope 23 outer end is connected with spud 24, and be connected with tension sensor 22 before the wire rope 23, support 3 connects in base 1 upper end, and mounting bracket 4 connects in support 3 upper end, and lightning rod 6 is installed to mounting bracket 4 upper end, mounting bracket 4 includes mounting panel 41, and the welding of mounting panel 41 lower extreme has sleeve 42, and the mounting panel 41 outer end articulates has articulated pole 44, and articulated pole 44 lower extreme articulates has package clamp splice 45.

In this embodiment, the base 1, the stabilizing device 2, the bracket 3, the mounting frame 4 and the monitoring equipment box 7 constitute a monitoring equipment main body structure referred to in the present application for monitoring and data analysis of geological environment, and the inside of the monitoring equipment box 7 is provided with a geological environment monitoring unit under the prior art.

In this embodiment, the tension sensor 22 is disposed near one side of the fixing ring 21, and the tension sensor 22 is electrically connected to the controller disposed inside the monitoring device box 7 through a wire, so as to facilitate remote transmission of sensor signals.

In this embodiment, the stabilizing device 2 is provided with a plurality of groups around the periphery of the base 1, and the fixing piles 24 are selected to be far away from the fixing points of the bracket 3 during installation, so that landslide of small-area mountains is realized, the probability of directly affecting all the fixing piles 24 is reduced, and the probability of stabilizing equipment is further ensured.

Specifically, the inside sensor cable 11 that is equipped with of base 1, and sensor cable 11 is equipped with upper and lower two sections, and the sensor cable 11 of hypomere is connected with the geology and detects the sensor, the sensor cable 11 upper end and the monitoring equipment case 7 electric connection of upper segment, monitoring equipment case 7 is installed in mounting panel 41 upper end, and monitoring equipment case 7 upper end is connected with antenna 71, and photovoltaic panel 5 is installed to monitoring equipment case 7 outer wall, lightning rod 6 is installed in mounting panel 41 upper end, and lightning rod 6 outer end is connected with earth connection 61, and lightning rod 6 locates monitoring equipment case 7 outside and be higher than monitoring equipment case 7.

As a preferred embodiment, by providing the lightning rod 6 and the ground wire 61, it is facilitated to prevent the possibility of lightning strike to the device.

As a preferred embodiment, the lower end of the base 1 is also provided with a fixing pile 24, and slot holes are reserved in advance at mounting points before the base 1 is fixed, so that the geological detection sensor at the lower end of the sensor cable 11 can be conveniently buried.

Specifically, sleeve 42 cup joints at support 3 top, and sleeve 42 outer wall sets up the strengthening rib 43 of triangle plate structure to sleeve 42 and mounting panel 41 all set up to insulating material, and package clamp splice 45 is established to semi-annular structure, and the symmetrical parcel of package clamp splice 45 is at the outer wall of support 3, and through bolted connection between the package clamp splice 45.

In this embodiment, the lower end of the bracket 3 is detachably connected with the base 1 in a plug-in manner, so that the base 1, the stabilizing device 2, the bracket 3, the mounting rack 4 and the monitoring equipment box 7 can be independently carried up a mountain.

Specifically, the inside of the bracket 3 is hollow, the outer wall of the bracket 3 is provided with a window 31, a cable connector 32 is arranged in the window 31, and the cable connector 32 connects the two sensor cables 11.

As a preferred embodiment, by providing the window 31, the sensor cable 11 is conveniently connected by a cable connector 43 manually after the base 1, the bracket 3 and the monitoring device box 7 are installed.

When the lightning rod is used, the base is fixed, the geological detection sensor at the lower end of the sensor cable is buried in the underground preformed hole, the locating pile of the stabilizing device is pulled open, the tensioning state of the steel wire rope is kept after the locating pile is installed, the bottom of the support is fixed with the base, the sleeve is sleeved at the upper end of the support, the clamping block is wrapped and fixed on the outer wall of the support through the bolt, and then the monitoring equipment box and the lightning rod are installed.

The monitoring equipment can effectively solve the problems that the geological environment monitoring equipment in the prior art is easy to be influenced by weather changes and inconvenient to assemble and carry when being installed and used in the field, and the utility model strengthens the protection of the monitoring equipment box on the basis of the existing monitoring equipment technology, is convenient to carry, and is convenient to play an early warning effect on the whole looseness of the device during the use period, thereby reducing the loss.

Claims (7)

1. A monitoring device, comprising: base (1), stabilising arrangement (2), support (3), mounting bracket (4) and monitoring facilities case (7), its characterized in that: the utility model discloses a lightning protection device for a vehicle, including base (1), stabilising arrangement (2), and stabilising arrangement (2) are connected in the outside of base (1), and stabilising arrangement (2) include solid fixed ring (21) and spud pile (24), gu fixed ring (21) outer end is connected with wire rope (23), and wire rope (23) outer end is connected with spud pile (24) to be connected with tension sensor (22) before, support (3) are connected in base (1) upper end, and mounting bracket (4) are connected in support (3) upper end to lightning rod (6) are installed to mounting bracket (4) upper end, mounting bracket (4) include mounting panel (41), and mounting panel (41) lower extreme welding has sleeve (42), and mounting panel (41) outer end articulates there is articulated pole (44), and articulated pole (44) lower extreme articulates has package clamp block (45).

2. A monitoring device according to claim 1, characterized in that the sensor cable (11) is arranged in the base (1), the sensor cable (11) is provided with an upper section and a lower section, the sensor cable (11) of the lower section is connected with a geological detection sensor, and the upper end of the upper section of the sensor cable (11) is electrically connected with the monitoring device box (7).

3. A monitoring device according to claim 1, characterized in that the monitoring device box (7) is mounted on the upper end of the mounting plate (41), the upper end of the monitoring device box (7) is connected with an antenna (71), and the outer wall of the monitoring device box (7) is provided with a photovoltaic panel (5).

4. A monitoring device according to claim 1, characterized in that the lightning rod (6) is mounted at the upper end of the mounting plate (41), the outer end of the lightning rod (6) is connected with the grounding wire (61), and the lightning rod (6) is arranged outside the monitoring device box (7) and higher than the monitoring device box (7).

5. A monitoring device according to claim 1, characterized in that the sleeve (42) is sleeved on the top of the bracket (3), the outer wall of the sleeve (42) is provided with reinforcing ribs (43) of a triangle plate structure, and the sleeve (42) and the mounting plate (41) are both made of insulating materials.

6. A monitoring device according to claim 1, characterized in that the clamping blocks (45) are arranged in a semi-annular structure, the clamping blocks (45) are symmetrically wrapped on the outer wall of the bracket (3), and the clamping blocks (45) are connected through bolts.

7. A monitoring device according to claim 1, characterized in that the inside of the bracket (3) is hollow, the outer wall of the bracket (3) is provided with a window (31), a cable joint (32) is arranged in the window (31), and the cable joint (32) connects the two sensor cables (11).