CN219266324U - Intelligent investigation monitoring facilities - Google Patents

Abstract

The utility model relates to the technical field of monitoring equipment, and discloses intelligent investigation monitoring equipment, which comprises a monitoring component; the monitoring assembly includes: the top of the supporting frame is rotationally connected with a camera; the anemometer is arranged on the side face of the camera; the signal emitter is arranged at the top of the supporting frame; the signal receiver is arranged at the top of the supporting frame; when dismantling, directly upwards stimulate the anemograph, make two buckles and fixed block upwards slide out respectively from two draw-in grooves and casing one inside, until after two buckles slide out from two draw-in grooves, the fixed block slides out from casing one, accomplish the dismantlement to the anemograph, install the anemograph on the contrary, it dismantles the anemograph to have accomplished the convenience, make things convenient for the staff to dismantle the anemograph from the support frame, change or maintain, and the dismantlement mode is simple swift, work efficiency is improved, the problem that current intelligent investigation monitoring facilities does not possess better dismantlement function has been solved.

Description

Intelligent investigation monitoring facilities

Technical Field

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

Background

The domestic resource is a material foundation for the existence of the domestic and resident thereof, and is a material entity composed of natural resources and socioeconomic resources, including natural resources such as land, rivers, lakes and seas, mineral resources, living beings, climate and the like, population resources and socioeconomic resources, and intelligent investigation and monitoring equipment is needed to monitor the domestic resource.

The intelligent investigation monitoring equipment on the market is generally provided with a camera, a signal receiving and transmitting device, an anemometer and the like, and is arranged on a vertical rod with a base, but the existing intelligent investigation monitoring equipment does not have a good disassembly function, when the anemometer is installed or disassembled, a plurality of bolts are required to be screwed in sequence, inconvenience is brought to the installation and disassembly work, the inconvenient use is caused, for example, china patent with publication number CN211425518U discloses the real-time dynamic intelligent investigation monitoring equipment for the territory space resource, when the intelligent investigation monitoring equipment is disassembled, a protection block is unscrewed, then the anemometer is taken down, then maintenance is carried out, then a fixing bolt at the bottom end of the maintained anemometer is aligned with a fixing nut at one side of a solar battery, and then the protection block is rotated, so that the anemometer can be disassembled, and although the anemometer can be disassembled, the disassembly mode is still complex, and the use by a staff is inconvenient.

The existing intelligent investigation monitoring equipment does not have a good disassembly function, is inconvenient to disassemble and maintain the anemograph, brings inconvenience to staff and is inconvenient to use.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the utility model provides intelligent investigation monitoring equipment which has the advantage of convenient disassembly and solves the problem that the existing intelligent investigation monitoring equipment does not have a good disassembly function.

(II) technical scheme

In order to achieve the above purpose, the present utility model provides the following technical solutions: an intelligent investigation monitoring device comprises a monitoring component; the monitoring assembly includes: the top of the supporting frame is rotationally connected with a camera; the anemometer is arranged on the side face of the camera; the signal emitter is arranged at the top of the supporting frame; the signal receiver is arranged at the top of the supporting frame; the top of the support frame is provided with a disassembly component; the disassembly assembly includes: the first shell is fixedly connected to the top of the support frame; the limiting rods are symmetrically and fixedly connected to the inner bottom surface of the shell; the fixed block is fixedly connected to the bottom of the anemometer, the fixed block is embedded into the first shell, and the two limiting rods are embedded into the fixed block; the buckle is symmetrically and fixedly connected to the bottom of the anemometer; the clamping grooves are symmetrically formed in the top of the shell, and the two buckles are respectively embedded into the two clamping grooves.

Preferably: the disassembly assembly further includes: and the second shell is fixedly connected to the outer side wall of the anemometer, and the inner side wall of the second shell is tightly attached to the outer side wall of the first shell.

Preferably: the bottom of the second shell is lower than the bottom of the buckle.

Preferably: the disassembly assembly further includes: the first sliding groove is arranged on two sides of the first shell; the first sliding blocks are symmetrically and fixedly connected to the inner side walls of the second shell, and the first sliding grooves are respectively embedded into the first sliding blocks.

Preferably: the bottom of the first sliding groove is lower than the bottom of the first sliding block.

Preferably: limiting components are symmetrically arranged on the outer side wall of the first shell; the spacing subassembly includes: the sliding groove II is symmetrically arranged in the first shell; the second sliding block is connected in the second sliding grooves in a sliding manner; the spring is arranged in the two sliding grooves II, and two ends of the spring are fixedly connected with the opposite surfaces of the two sliding blocks II and the back surfaces of the two sliding grooves II respectively; the groove body is arranged on one opposite surface of the two sliding blocks.

Preferably: the disassembly assembly is provided with at least one set.

Preferably: each fixing block is rectangular in transverse section.

(III) beneficial effects

Compared with the prior art, the utility model provides intelligent investigation monitoring equipment, which has the following beneficial effects:

the utility model has the advantage of convenient disassembly, when the anemometer is disassembled, the anemometer is directly pulled upwards, so that the two buckles and the fixed block respectively slide out from the two clamping grooves and the first shell, until the two buckles slide out from the two clamping grooves, the fixed block slides out from the first shell, the anemometer is disassembled, otherwise, the anemometer is conveniently assembled, the anemometer is conveniently disassembled from the supporting frame by staff, the replacement or the maintenance is carried out, the disassembly mode is simple and rapid, the working efficiency is improved, and the problem that the existing intelligent investigation monitoring equipment does not have a good disassembly function is solved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the front internal structure of the disassembly assembly of the present utility model;

fig. 3 is a schematic view of a partial enlarged structure at a in fig. 2 according to the present utility model.

In the figure:

1. a monitoring component; 11. a support frame; 12. a camera; 13. an anemometer; 14. a signal transmitter; 15. a signal receiver;

2. disassembling the assembly; 21. a first shell; 22. a limit rod; 23. a fixed block; 24. a buckle; 25. a clamping groove; 26. a second shell; 27. a first chute; 28. a first sliding block;

3. a limit component; 31. a second chute; 32. a second slide block; 33. a spring; 34. a groove body.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

An intelligent investigation monitoring device comprises a monitoring component 1; the monitoring assembly 1 comprises: a support frame 11, the top of which is rotatably connected with a camera 12; an anemometer 13 disposed on a side surface of the camera 12; the signal emitter 14 is arranged at the top of the supporting frame 11; the signal receiver 15 is arranged at the top of the supporting frame 11; the top of the supporting frame 11 is provided with a dismounting assembly 2; the dismounting assembly 2 comprises: the first shell 21 is fixedly connected to the top of the supporting frame 11; the limiting rods 22 are symmetrically and fixedly connected to the inner bottom surface of the first shell 21; the fixed block 23 is fixedly connected to the bottom of the anemometer 13, the fixed block 23 is embedded into the first shell 21, and the two limiting rods 22 are embedded into the fixed block 23; the buckle 24 is symmetrically and fixedly connected to the bottom of the anemometer 13; the clamping grooves 25 are symmetrically formed in the top of the first shell 21, and the two buckles 24 are respectively embedded into the two clamping grooves 25; the dismounting assembly 2 further comprises: the second shell 26 is fixedly connected to the outer side wall of the anemometer 13, and the inner side wall of the second shell 26 is tightly attached to the outer side wall of the first shell 21; the bottom of the second housing 26 is lower than the bottom of the buckle 24; the dismounting assembly 2 further comprises: the first sliding chute 27 is arranged on two sides of the first shell 21; the first sliding blocks 28 are symmetrically and fixedly connected to the inner side wall of the second shell 26, and the first sliding grooves 27 are respectively embedded into the first sliding blocks 28; the bottom of the first sliding groove 27 is lower than the bottom of the first sliding block 28.

Referring to fig. 1-3, when in use, the part of investigation and monitoring of the homeland space resources are realized through the camera 12 and the anemometer 13, and the signal transmitter 14 and the signal receiver 15 are respectively responsible for transmitting and receiving signals, when the anemometer 13 needs to be disassembled, the anemometer 13 is directly pulled upwards, so that the anemometer 13 slides upwards and simultaneously drives the two buckles 24 and the fixed block 23 to slide upwards from the two clamping grooves 25 and the first shell 21 respectively until the two buckles 24 slide out from the two clamping grooves 25, the anemometer 13 is continuously pulled upwards, and the fixed block 23 slides out from the first shell 21, and then the anemometer 13 is disassembled, and otherwise the anemometer 13 is installed; when the wind speed indicator is installed, after the two buckles 24 are respectively embedded into the two clamping grooves 25, the second shell 26 is tightly attached to the first shell 21, so that the buckles 24 are prevented from bearing torsion force due to the action of wind power or external force on the wind speed indicator 13, and the practicability of the device is improved; after the anemometer 13 is detached from the first shell 21, the second shell 26 plays a good role in shielding and protecting the two buckles 24; during installation, the fixing block 23 is embedded into the first shell 21, and simultaneously, the anemometer 13 is continuously pushed downwards, so that the first two sliding blocks 28 are respectively embedded into the first two sliding grooves 27, and are continuously pushed downwards, so that the two buckles 24 are directly embedded into the two clamping grooves 25, the calibration effect is achieved, the buckles 24 are prevented from being not aligned with the clamping grooves 25, the buckles 24 are prevented from being damaged, and the practicability of the device is improved; during installation, workers can conveniently process the first sliding block 28 to be embedded into the first sliding groove 27, and the sliding block is convenient to use.

Example two

The limiting function is added on the basis of the first embodiment;

limiting assemblies 3 are symmetrically arranged on the outer side wall of the first shell 21; the limiting assembly 3 includes: the second chute 31 is symmetrically arranged in the first shell 21; the second sliding block 32 is connected in the second sliding grooves 31 in a sliding manner; the spring 33 is arranged in the two second sliding grooves 31, and two ends of the spring 33 are fixedly connected with the opposite surfaces of the two second sliding blocks 32 and the opposite surfaces of the two second sliding grooves 31 respectively; the groove 34 is formed on the opposite surfaces of the two first sliding blocks 28; the disassembly assembly 2 is provided with at least one group; each of the fixing blocks 23 has a rectangular transverse cross section.

Referring to fig. 1-3, during installation, after the first slide blocks 28 are respectively embedded into the first slide grooves 27, the first slide blocks 28 slide downwards in the first slide grooves 27, the bottoms of the first slide blocks 28 are respectively contacted with arc-shaped parts on the back surfaces of the second slide blocks 32, the second slide blocks 32 slide in the second slide grooves 31 respectively, the springs 33 are respectively extruded, the second slide blocks 32 slide into the second slide grooves 31 respectively, the first slide blocks 28 slide downwards continuously until the second slide grooves 31 are aligned with the first groove bodies 34, the second slide blocks 32 are respectively embedded into the second groove bodies 34 through resilience force of the first springs 33, the first slide blocks 28 are limited, and stability of the device is improved; when in installation, the camera 12, the anemometer 13, the signal transmitter 14 and the signal receiver 15 can be respectively and quickly disassembled by the plurality of groups of disassembly components 2; during installation, the fixing block 23 is embedded into the first shell 21, and meanwhile, the anemometer 13 is directly pushed downwards, so that the limiting rods 22 are embedded into the fixing block 23, the clamping buckles 24 are directly embedded into the clamping grooves 25, the first sliding block 28 is also directly embedded into the first sliding groove 27, and the installation is convenient.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. An intelligent investigation monitoring device comprises a monitoring component (1); the monitoring assembly (1) comprises:

the top of the supporting frame (11) is rotatably connected with a camera (12);

the anemometer (13) is arranged on the side surface of the camera (12);

the signal emitter (14) is arranged at the top of the supporting frame (11);

the signal receiver (15) is arranged at the top of the supporting frame (11);

the method is characterized in that: the top of the supporting frame (11) is provided with a dismounting assembly (2); the disassembly assembly (2) comprises:

the first shell (21) is fixedly connected to the top of the supporting frame (11);

the limiting rods (22) are symmetrically and fixedly connected to the inner bottom surface of the first shell (21);

the fixed block (23) is fixedly connected to the bottom of the anemometer (13), the fixed block (23) is embedded into the first shell (21), and the two limiting rods (22) are embedded into the fixed block (23);

the buckle (24) is symmetrically and fixedly connected to the bottom of the anemometer (13);

the clamping grooves (25) are symmetrically formed in the top of the first shell (21), and the two buckles (24) are respectively embedded into the two clamping grooves (25).

2. An intelligent investigation monitoring device according to claim 1, characterized in that: the disassembly assembly (2) further comprises:

and the second shell (26) is fixedly connected to the outer side wall of the anemometer (13), and the inner side wall of the second shell (26) is tightly attached to the outer side wall of the first shell (21).

3. An intelligent investigation monitoring device according to claim 2, characterized in that: the bottom of the second shell (26) is lower than the bottom of the buckle (24).

4. An intelligent investigation monitoring device according to claim 2, characterized in that: the disassembly assembly (2) further comprises:

the first sliding chute (27) is arranged on two sides of the first shell (21);

the first sliding blocks (28) are symmetrically and fixedly connected to the inner side wall of the second shell (26), and the two first sliding grooves (27) are respectively embedded into the two first sliding blocks (28).

5. The intelligent survey monitoring apparatus of claim 4 wherein: the bottom of the first sliding groove (27) is lower than the bottom of the first sliding block (28).

6. The intelligent survey monitoring apparatus of claim 5 wherein: limiting assemblies (3) are symmetrically arranged on the outer side wall of the first shell (21); the limit assembly (3) comprises:

the second sliding chute (31) is symmetrically arranged in the first shell (21);

the second sliding block (32) is connected in the two second sliding grooves (31) in a sliding manner;

the springs (33) are arranged in the two sliding grooves (31), and two ends of each spring (33) are fixedly connected with the opposite surfaces of the two sliding blocks (32) and the opposite surfaces of the two sliding grooves (31);

and the groove body (34) is arranged on the opposite surfaces of the two first sliding blocks (28).

7. The intelligent survey monitoring apparatus of claim 6 wherein: the disassembly assembly (2) is provided with at least one group.

8. The intelligent survey monitoring apparatus of claim 7 wherein: each fixing block (23) is rectangular in transverse section.

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