CN220416919U - Engineering supervisory equipment is rebuild to geological disaster - Google Patents

Abstract

The utility model relates to the field of monitoring equipment, and particularly discloses geological disaster reconstruction engineering monitoring equipment which comprises a mounting plate fixed on the side surface of a first upright post and a telescopic rod, wherein one end of the telescopic rod is connected with the mounting plate; the telescopic rod comprises an outer sleeve, an inner pipe and a mounting pipe, wherein the left end of the outer sleeve is fixed outside the first upright, the inner pipe is telescopically inserted into the right end of the outer sleeve, the mounting pipe is mounted at the right end of the inner pipe, a second upright is arranged below the right end of the mounting pipe, a rotatable first camera is mounted at the bottom end of the second upright, a second camera and a third camera are arranged on the upper side surface of the mounting pipe from left to right, the second camera is rotatably mounted on a second roll-over stand, the second roll-over stand is rotatably mounted on a second base, and the second base is fixed on the mounting pipe; the third camera is rotatably arranged on the third roll-over stand, the third roll-over stand is rotatably arranged on the third base, and the third base is fixed on the mounting tube. The three cameras can be turned over to enlarge the visual field range, and the positions of the three cameras are adjusted, so that the three cameras are flexible to use and convenient to install.

Description

Engineering supervisory equipment is rebuild to geological disaster

Technical Field

The utility model relates to the field of monitoring equipment, in particular to geological disaster reconstruction engineering monitoring equipment.

Background

When geological disasters are heavy, surrounding environments need to be monitored, and personal safety of workers is guaranteed. In particular, when geological disasters are rebuilt, an engineering monitoring system is required to be arranged, so that disasters are monitored again, a special working environment of a construction site is monitored, along with the increasing importance of safety of the construction site, the positions of the construction site are scattered, and the environments caused by different scales are more complicated. The monitoring points are arranged at key positions and personnel access places of each construction site, and a prevention and control system combining people prevention and technical prevention is implemented, so that the safety coefficient can be better enhanced, the investment can be reduced, and the safety accidents are controlled to be within the minimum. The technical protection of saving manpower and material resources is taken as an important means for protecting the security of the station.

Engineering monitoring systems generally include front-end cameras, transmission cables, video monitoring platforms. The camera can be divided into a network digital camera and an analog camera, and can be used for collecting front-end video image signals. The complete video monitoring system consists of most 5 parts of shooting, transmission, control, display and record registration. The video camera transmits video images to the control host through the network cable or the coaxial video cable, the control host distributes video signals to each monitor and video equipment, and simultaneously, voice signals to be transmitted can be synchronously recorded into the video recorder. Through the control host, an operator can send out instructions to control the actions of the cradle head, such as up, down, left and right, and perform focusing and zooming operations on the lens, and can realize the switching of multiple cameras through the video matrix. The special video processing mode is utilized to carry out operations such as recording, playback, calling out, storage and the like on the image.

However, the current monitoring system is generally bound on the post through an adhesive tape, the monitoring visual field range is limited, flexible adjustment cannot be realized, the installed monitoring quantity is limited, and the installation is inconvenient.

Disclosure of Invention

In order to solve the problems, the utility model provides geological disaster reconstruction engineering monitoring equipment which can enlarge the monitoring visual field range, can realize flexible adjustment, increases the installation quantity and is convenient to install.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the monitoring equipment for geological disaster reconstruction engineering comprises a first upright post driven into the ground after geological disaster, a mounting plate fixed on the side surface of the first upright post, and a telescopic rod with one end connected with the mounting plate; the telescopic rod comprises an outer sleeve, an inner pipe and a mounting pipe, wherein the left end of the outer sleeve is fixed outside the first upright, the inner pipe is inserted into the right end of the outer sleeve in a telescopic manner, the mounting pipe is mounted at the right end of the inner pipe, a second upright is arranged below the right end of the mounting pipe, a rotatable first camera is mounted at the bottom end of the second upright, a second camera and a third camera are arranged on the upper side surface of the mounting pipe from left to right, the second camera is rotatably mounted on a second roll-over stand, the second roll-over stand is rotatably mounted on a second base, and the second base is fixed on the mounting pipe; the third camera is rotatably arranged on the third roll-over stand, the third roll-over stand is rotatably arranged on the third base, the third base is fixed on the mounting tube, and the outer sleeve is connected with the mounting plate through the inclined tube.

The first camera, the second camera and the third camera are distributed along the mounting pipe, the three cameras can rotate, the second overturning frame and the third overturning frame can drive the second camera and the third camera to overturn, the monitoring range is enlarged, the mounting pipe moves under the driving of the telescopic pipe, the positions of the three cameras are adjusted, and the use is flexible; the installation of three cameras can be realized by installing one installation pipe, the installation is more convenient, and the reasonable utilization of the limited space is realized.

Further, a second middle frame is arranged between the second base and the second roll-over frame, and a third middle frame is arranged between the third base and the third roll-over frame. Firm and stable installation, flexible and convenient use.

In summary, the utility model has the following beneficial effects: the three cameras are distributed along the mounting tube, the three cameras can rotate, the two cameras can turn over to enlarge the visual field range, the telescopic tube drives the mounting tube to move, the positions of the three cameras are adjusted, and the use is flexible; the installation of three cameras can be realized by installing one telescopic pipe, the installation is convenient, and the reasonable utilization of the limited space is realized.

Drawings

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

FIG. 2 is a schematic view of a portion of the structure of the present utility model;

wherein the first upright 100; a mounting plate 1; the telescopic rod 2, the outer sleeve 21, the mounting pipe 22 and the second upright 23; a first camera 3; a second camera 4, a second roll-over stand 41, a second base 42, a second intermediate stand 43; a third camera 5, a third roll-over stand 51, a third base 52, a third intermediate stand 53; and an inclined tube 6.

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.

As shown in fig. 1 and 2, a monitoring device for geological disaster reconstruction engineering is provided, in which a camera, a transmission cable and a video monitoring platform are all existing products, and are not described in detail herein, but only the installation of the camera is improved. The ground after the geological disaster is driven into the first upright post 100, and the monitoring equipment for the geological disaster reconstruction engineering comprises a mounting plate 1 and a telescopic rod 2. Wherein, first stand 100 is the cuboid, and mounting panel 1 passes through screw fixation in first stand 100 side, and mounting panel 1 is connected to telescopic link 2 one end, and telescopic link 2 is slope or horizon bar, and telescopic link 2 is scalable structure. The telescopic rod 2 includes an outer sleeve 21, an inner tube, and a mounting tube 22. The left end of the outer sleeve 21 is fixed outside the first upright 100, the inner tube is telescopically inserted into the right end of the outer sleeve 21, the mounting tube 22 is mounted at the right end of the inner tube, and then the mounting tube 22 can be driven to stretch together when the inner tube moves along the outer sleeve 21, and the telescopic tube 2 can be of an existing structure.

The right-hand member below of installation pipe 22 is equipped with second stand 23, and first camera 3 is installed to second stand 23 bottom, and the rotatable and upset design of first camera 3, this camera can select to use current product, for example TCLTCL-C1 LD.

The upper side surface of the mounting tube 22 is provided with a second camera 4 and a third camera 5 from left to right. Specifically, the second camera 4 is rotatably mounted on the second roll-over stand 41, the second roll-over stand 41 is rotatably mounted on the second base 42, and the second base 42 is fixed on the mounting tube 22; the third camera 5 is rotatably mounted on a third roll-over stand 51, the third roll-over stand 51 is rotatably mounted on a third base 52, the third base 52 is fixed on the mounting tube 22, and the outer sleeve 21 is connected with the mounting plate 1 through the inclined tube 6.

A second intermediate frame 43 is installed between the second base 42 and the second roll-over frame 41, and a third intermediate frame 53 is provided between the third base 52 and the third roll-over frame 51.

The second camera 4 and the third camera 5 are respectively DS-2CD3T47EWDV3-L, the second base 42 and the third base 52 are respectively rectangular frames, the lower sides of the rectangular frames are fastened on the mounting pipe 22 through first bolts, the second middle frame 43 and the third middle frame 53 are respectively rectangular frames, the lower sides of the second middle frame 43 are mounted on the second base 42 through second bolts, and the third middle frame 53 is mounted on the third middle frame 53 through fourth bolts. The second roll-over stand 41 and the third roll-over stand 51 each comprise a lower U-shaped stand with an upward opening and an upper U-shaped stand with an upward opening, two sides of the lower U-shaped stand and the upper U-shaped stand are hinged through a rotating shaft, the upper U-shaped stand can roll over relative to the lower U-shaped stand, the lower U-shaped stand of the second roll-over stand 41 is fixed on the upper surface of the second middle stand 43 through a fourth bolt, and the second camera 4 is fixed on the top surface of the upper U-shaped stand of the second roll-over stand 41 through a fifth bolt. Similarly, the lower U-shaped frame of the third roll-over frame 51 is fixed to the upper surface of the third intermediate frame 53 by a sixth bolt, and the third camera 5 is fixed to the upper U-shaped frame top surface of the third roll-over frame 51 by a sixth bolt.

The foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (2)

1. Engineering supervisory equipment is rebuild to geological disaster, drives into first stand (100) in the ground behind geological disaster, its characterized in that: comprises a mounting plate (1) fixed on the side surface of a first upright post (100), and a telescopic rod (2) with one end connected with the mounting plate (1); the telescopic rod (2) comprises an outer sleeve (21) with the left end fixed outside the first upright post (100), an inner tube which is telescopically inserted into the right end of the outer sleeve (21) and a mounting tube (22) which is mounted at the right end of the inner tube, a second upright post (23) is arranged below the right end of the mounting tube, a rotatable first camera (3) is mounted at the bottom end of the second upright post (23), a second camera (4) and a third camera (5) are arranged on the upper side surface of the mounting tube (22) from left to right, the second camera (4) is rotatably mounted on a second roll-over stand (41), the second roll-over stand (41) is rotatably mounted on a second base (42), and the second base (42) is fixed on the mounting tube (22); the third camera (5) is rotatably arranged on the third roll-over stand (51), the third roll-over stand (51) is rotatably arranged on the third base (52), the third base (52) is fixed on the mounting pipe (22), and the outer sleeve (21) is connected with the mounting plate (1) through the inclined pipe (6).

2. The geological disaster reconstruction engineering monitoring device according to claim 1, wherein: a second middle frame (43) is arranged between the second base (42) and the second roll-over frame (41), and a third middle frame (53) is arranged between the third base (52) and the third roll-over frame (51).