CN211955271U - X-ray field detection device for overhead conductor - Google Patents

Abstract

The application discloses an X-ray on-site detection device for an overhead conductor, which comprises an upper end frame, a lower end frame, a telescopic pipe and a cable hook; the upper end frame comprises a lifting ring, an imaging plate embedded frame and an imaging plate; the lifting rings are fixed at the upper ends of two sides of the imaging plate embedding frame; the imaging plate is embedded in the imaging plate embedding frame; the lower end frame comprises an X-ray machine embedding frame and an X-ray machine; the X-ray machine is embedded in the X-ray machine embedding frame; the X-ray machine is arranged right below the imaging plate; the top end of the extension tube is connected with the side surface of the upper end frame; the tail end of the extension tube is connected with the side face of the lower end frame; the middle parts of the two extension tubes are respectively provided with one cable hook. This device avoids waiting to detect the cable and takes off the detection, can the on-the-spot detection overhead line defect, and save time promotes work efficiency.

Description

X-ray field detection device for overhead conductor

Technical Field

The application relates to the technical field of power equipment, in particular to an X-ray field detection device for an overhead conductor.

Background

The high-voltage overhead line is divided into a ground wire and a power transmission line, an optical cable communication line is arranged inside the ground wire, a steel pipe protective layer is bound on the outer layer of the optical cable communication line, winding steel wires are bound outside the steel pipe protective layer, and the steel wires are easy to break. The power transmission line is because circuit steel wire surface fracture that seasonal alternation caused, disconnected strand, strand scattered, and the line surface fusing that the thunderbolt led to threaten the various condition of circuit safe operation, all need carry out regular tour to the circuit to whether the inspection power transmission is normal and the trouble is eliminated.

The X-ray projection can deeply detect the line, the imaging quality is good, and the X-ray projection is widely applied to the defect detection of the power grid equipment. The detection of overhead conductor defects by an X-ray machine is feasible, and the detection is finished in a large amount of time because the current detection is to take the defective line part down to a laboratory for detection. There is a need for a device that can detect overhead line defects on-site, save time, and improve work efficiency.

SUMMERY OF THE UTILITY MODEL

The application provides an overhead conductor X-ray field detection device to solve when the circuit defect position need take off and send to the laboratory and detect consuming time, low efficiency technical problem.

An X-ray on-site detection device for an overhead conductor is characterized by comprising an upper end frame, a lower end frame, a telescopic pipe and a cable hook;

the upper end frame comprises a lifting ring, an imaging plate embedded frame and an imaging plate;

the lifting rings are fixed at the upper ends of two sides of the imaging plate embedding frame;

the imaging plate is embedded in the imaging plate embedding frame;

the lower end frame comprises an X-ray machine embedding frame and an X-ray machine;

the X-ray machine is embedded in the X-ray machine embedding frame;

the X-ray machine is arranged right below the imaging plate;

two telescopic pipes are arranged between the imaging plate embedding frame and the X-ray machine embedding frame;

the top end of the extension tube is connected with the side surface of the upper end frame;

the tail end of the extension tube is connected with the side face of the lower end frame;

the middle parts of the two extension tubes are respectively provided with one cable hook.

Optionally, one side on the imaging plate embedding frame is equipped with netted up end lid, netted up end lid with be connected for rotating between the imaging plate embedding frame, the opposite side of imaging plate embedding frame is equipped with the up end hasp, the netted terminal surface lid down that one side of X-ray production apparatus embedding frame was equipped with, netted terminal surface lid down with be connected for rotating between the X-ray production apparatus embedding frame, the opposite side of X-ray production apparatus embedding frame is equipped with down the terminal surface hasp.

Optionally, the imaging plate embedding frame and the X-ray machine embedding frame are made of aluminum alloy.

Optionally, the telescopic tube includes a first telescopic tube, a second telescopic tube and a third telescopic tube, and the first telescopic tube, the second telescopic tube and the third telescopic tube are mutually nested and connected.

Optionally, a camera is disposed on one side of the imaging plate insertion frame.

Optionally, the type of the camera is an optical anti-shake camera.

Optionally, the type of the camera is an auto-focus camera.

Optionally, the cable hook is arranged on the first telescopic pipe.

It can be seen from above-mentioned technical scheme that the on-spot detection device of overhead wire X ray that this application provided includes: the X-ray machine comprises an upper end support frame, a lower end support frame, a telescopic pipe and hooks, wherein the telescopic pipe can be adjusted up and down, the X-ray machine is installed in a lower support embedded frame, an imaging plate is installed in an upper support embedded frame, the telescopic supporting pipe is adjusted to detect the distance up and down, ropes penetrate into rings at the left end and the right end of the upper end support surface and are lifted to the position of a target conductor, the overhead conductor is hung by the left hook and the right hook at the upper end of the upper telescopic pipe, the overhead line is just right between the X-ray machine and the imaging plate, the operation controller can carry out X-ray detection on the overhead line, the working condition of the X-ray machine is observed by using a.

Drawings

In order to more clearly explain the technical solution of the present application, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious to those skilled in the art that other drawings can be obtained according to the drawings without any creative effort.

FIG. 1 is a schematic structural diagram of an overhead conductor X-ray field inspection device of the present application;

the system comprises an upper end frame 1, an upper end frame 11, a lifting ring 12, an imaging plate embedding frame 121, a mesh-shaped upper end face cover body 122, an upper end face lock catch 123, a camera 13, an imaging plate 2, a lower end frame 21, an X-ray machine embedding frame 211, a mesh-shaped lower end face cover body 212, a lower end face lock catch 22, an X-ray machine, a 3-telescopic pipe, a 31-first telescopic pipe, a 32-second telescopic pipe, a 33-third telescopic pipe and a 4-cable hook.

Detailed Description

Referring to fig. 1, a schematic structural diagram of an overhead conductor X-ray field detection device according to the present application is shown.

As can be seen from fig. 1, an embodiment of the present application provides an overhead conductor X-ray field detection device, which includes an upper end frame 1, a lower end frame 2, an extension tube 3, and a cable hook 4;

the upper end frame 1 comprises a hanging ring 11, an imaging plate embedded frame 12 and an imaging plate 13;

the hanging ring 11 is fixed at the upper ends of two sides of the imaging plate embedding frame 12;

the imaging plate 13 is embedded in the imaging plate embedding frame 12;

the lower end frame 2 comprises an X-ray machine embedding frame 21 and an X-ray machine 22;

the X-ray machine 22 is embedded in the X-ray machine embedding frame 21;

the X-ray machine 22 is disposed directly below the imaging plate 13;

two telescopic pipes 3 are arranged between the imaging plate embedding frame 12 and the X-ray machine embedding frame 21;

the top end of the telescopic pipe 3 is connected with the side surface of the upper end frame 1;

the tail end of the telescopic pipe 3 is connected with the side surface of the lower end frame 2;

the middle parts of the two extension tubes 3 are respectively provided with one cable hook 4.

Specifically, in this embodiment, the upper end frame 1 is configured to fix the imaging plate 13 and provide the hanging ring 11, and the lower end frame 2 is configured to fix the X-ray machine 22, so that an operator can align the X-ray machine 22 with the imaging plate 13. The telescopic pipes 3 are respectively connected to two opposite sides of the upper end frame 1, and the telescopic pipes 3 are used for adjusting the distance between the upper end frame 1 and the lower end frame 2, so that different focusing requirements of the X-ray machine 22 are met. The cable hook 4 is used for fixing the cable to be detected between the upper end frame 1 and the lower end frame 2, so that the defect condition of the cable to be detected can be conveniently and quickly detected.

Further, the working process of the overhead conductor X-ray on-site detection device provided by the embodiment of the application is as follows: firstly, a rope penetrates through the hanging rings 11 at the left end and the right end of the upper end support frame to be lifted to a target conductor position, the cable hooks 4 on the extension tubes 3 arranged at the two opposite sides of the device are hung on an overhead line, the cable to be detected is just positioned in the middle of a frame structure, the X-ray machine 22, the overhead conductor and the imaging plate 13 need to be moved and focused in order to improve the X-ray imaging quality in the imaging process, and after the focusing is finished, the defect condition of the cable to be detected can be quickly and accurately detected.

Further, one side on the imaging plate embedding frame 12 is provided with a net-shaped upper end face cover body 121, the net-shaped upper end face cover body 121 is rotatably connected with the imaging plate embedding frame 12, the other side is provided with an upper end face lock catch 122, a net-shaped lower end face cover body 211 is arranged on one side of the X-ray machine embedding frame, the net-shaped lower end face cover body 211 is rotatably connected with the X-ray machine embedding frame 21, and the other side is provided with a lower end face lock catch 212. The imaging plate 13 and the X-ray machine 22 are more firmly fixed in the embedded frame, and the phenomenon that the X-ray machine 22 and the imaging plate 13 fall off from the frame to cause device damage is avoided.

Further, the material used for the imaging plate insertion frame 12 and the X-ray machine insertion frame 21 is aluminum alloy. The aluminum alloy has the characteristics of low density and high strength, and when the device works normally, the weight of the device can be reduced, the device is convenient to lift for use, and meanwhile, the device is not easy to be damaged by external force, and the service life of the device is prolonged.

Further, the telescopic tube 3 comprises a first telescopic tube 31, a second telescopic tube 32 and a third telescopic tube 33, wherein the first telescopic tube 31, the second telescopic tube 32 and the third telescopic tube 33 are nested and connected with each other. The distance between the X-ray machine and the imaging plate can be flexibly controlled, so that the device has a firmer structure.

Further, a camera 123 is disposed in the middle of one side of the imaging plate insertion frame 12. The working condition of the X-ray machine can be observed through the camera 123.

Further, the camera 123 is an optical anti-shake camera. The camera can not work normally due to shaking of the device in work.

Further, the camera 123 is an auto-focus camera. When the distance between the imaging plate 13 and the X-ray machine is fixed, a clearer image can be obtained by adopting an automatic focusing camera, and the observation is convenient.

Further, the cable hook 4 is disposed on the first extension tube 31. The device has the advantages that a larger focusing range can be provided for cables to be detected, so that the device meets detection requirements under different use conditions, and more accurate detection conditions are obtained.

According to the technical scheme, the embodiment of the application also provides the overhead conductor X-ray on-site detection device, which comprises an upper end frame 1, a lower end frame 2, an extension tube 3 and a cable hook 4; the upper end frame 1 comprises a hanging ring 11, an imaging plate embedded frame 12 and an imaging plate 13; the hanging ring 11 is fixed at the upper ends of two sides of the imaging plate embedding frame 12; the imaging plate 13 is embedded in the imaging plate embedding frame 12; the lower end frame 2 comprises an X-ray machine embedding frame 21 and an X-ray machine 22; the X-ray machine 22 is embedded in the X-ray machine embedding frame 21; the X-ray machine 22 is disposed directly below the imaging plate 13; the telescopic pipe 3 is arranged between two side surfaces of the imaging plate embedding frame 12 and the X-ray machine embedding frame 21; the top end of the telescopic pipe 3 is connected with the side surface of the upper end frame 1; the tail end of the telescopic pipe 3 is connected with the side surface of the lower end frame 2; the middle parts of the two extension tubes 3 are respectively provided with one cable hook 4. When the device normally works, a rope penetrates through the left end and the right end of the upper end support frame and the hanging rings 11 to be lifted to a target conductor position, the cable hook 4 on the telescopic pipe 3 is hung on an overhead line, the cable to be detected is just positioned in the middle of a frame structure, the X-ray machine 22, the overhead cable to be detected and the imaging plate 13 need to be moved and focused in order to improve the X-ray imaging quality in the imaging process, and after the focusing is completed, the defect condition of the cable to be detected can be quickly and accurately detected. Compared with the traditional detection mode, the working time is saved, and the working efficiency is improved.

Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. This application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.

It will be understood that the invention is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the present invention is limited only by the appended claims.

Claims (8)

1. An X-ray field detection device for an overhead conductor is characterized by comprising an upper end frame (1), a lower end frame (2), an extension tube (3) and a cable hook (4);

the upper end frame (1) comprises a hanging ring (11), an imaging plate embedded frame (12) and an imaging plate (13);

the lifting rings (11) are fixed at the upper ends of two sides of the imaging plate embedding frame (12);

the imaging plate (13) is embedded in the imaging plate embedding frame (12);

the lower end frame (2) comprises an X-ray machine embedding frame (21) and an X-ray machine (22);

the X-ray machine (22) is embedded in the X-ray machine embedding frame (21);

the X-ray machine (22) is arranged right below the imaging plate (13);

two telescopic pipes (3) are arranged between the imaging plate embedding frame (12) and the X-ray machine embedding frame (21);

the top end of the telescopic pipe (3) is connected with the side surface of the upper end frame (1);

the tail end of the telescopic pipe (3) is connected with the side surface of the lower end frame (2);

the middle parts of the two extension tubes (3) are respectively provided with one cable hook (4).

2. The overhead conductor X-ray on-site detection device according to claim 1, wherein a mesh-shaped upper end cover (121) is arranged on one side of the imaging plate embedding frame (12), the mesh-shaped upper end cover (121) is rotatably connected with the imaging plate embedding frame (12), an upper end lock catch (122) is arranged on the other side of the imaging plate embedding frame (12), a mesh-shaped lower end cover (211) is arranged on one side of the X-ray machine embedding frame (21), the mesh-shaped lower end cover (211) is rotatably connected with the X-ray machine embedding frame (21), and a lower end lock catch (212) is arranged on the other side of the X-ray machine embedding frame (21).

3. The overhead conductor X-ray on-site detection device according to claim 1, wherein the imaging plate embedded frame (12) and the X-ray machine embedded frame (21) are made of aluminum alloy.

4. The overhead conductor X-ray on-site detection device according to claim 1, characterized in that the telescopic pipe (3) comprises a first telescopic pipe (31), a second telescopic pipe (32) and a third telescopic pipe (33), and the first telescopic pipe (31), the second telescopic pipe (32) and the third telescopic pipe (33) are nested and connected with each other.

5. The overhead conductor X-ray on-site detection device as claimed in claim 1, wherein a camera (123) is arranged on one side of the imaging plate embedding frame (12).

6. Overhead conductor X-ray on-site detection device according to claim 5, characterized in that the camera (123) is of the type of an optical anti-shake camera.

7. Overhead conductor X-ray on-site detection device according to claim 5, characterized in that the camera (123) is of the type of an autofocus camera.

8. Overhead conductor X-ray on-site detection device according to claim 4, characterized in that the cable hook (4) is arranged on the first telescopic tube (31).

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