CN220120297U - Intelligent imaging heat supply pipeline inspection device - Google Patents

Abstract

The utility model relates to the technical field of heat supply pipeline inspection, and discloses an intelligent imaging heat supply pipeline inspection device which comprises a vertical pipe, wherein one end of the vertical pipe is provided with a handle, the other end of the vertical pipe is arranged on a base in a penetrating manner, and both ends of the base are provided with moving wheels in a rotating manner; a laser lamp and a binocular thermal imaging camera are arranged on the stand pipe at a position close to the base, the binocular thermal imaging camera is fixed on the laser lamp, and the binocular thermal imaging camera and an external intelligent terminal are in data wireless transmission; an electronic leakage detecting rod is movably inserted into the inner cavity of the vertical pipe. According to the utility model, after the suspected leakage point is detected, the inspection personnel can outwards draw the limit pull rod, the limit pull rod is separated from the slide block, the electric box and the electronic hearing leakage rod slide down on the vertical pipe until the tail sound collecting part of the electronic hearing leakage rod contacts the place of the suspected leakage point, and sound Bluetooth is transmitted to a Bluetooth headset worn by the inspection personnel, and final determination is performed.

Description

Intelligent imaging heat supply pipeline inspection device

Technical Field

The utility model belongs to the technical field of heat supply pipeline inspection, and particularly relates to an intelligent imaging heat supply pipeline inspection device.

Background

The urban heat supply pipe network is one of the important infrastructures of the city, and the scale and pipe diameter of the heat supply pipe network are larger and larger along with the rapid development of urban central heat supply. By 2020, the length of the central heating pipeline in China is 42.6 kilometers, and the maximum pipe diameter reaches DN1600. The operation time of the heat supply pipeline is increased year by year, the heat supply pipeline built in early stage tends to be aged, pipeline corrosion and water hammer pressure mutation are carried out, natural disasters such as earthquake and the like affect the heat supply pipeline, the heat supply pipeline leakage accident is induced to climb year by year, the loss and the waste of energy and water resources are caused, even the ground collapse is caused, and the urban heat supply and the life and property safety of people are seriously influenced. The direct-buried laying mode has the advantages of energy conservation, low cost, small occupied area, convenient construction and the like, and is rapidly developed in China. However, when the direct-buried pipeline leaks, the position of the leakage point is difficult to confirm, the heat stopping time is long, the rush repair cost is high, and if the leakage point cannot be found in time, serious accidents which influence public safety are easily caused.

At present, a common leakage detection method for a directly buried heat supply pipeline is a manual inspection method, generally, inspection staff holds a binocular thermal imaging camera to shoot a heat supply pipeline along the way, once suspicious leakage points are found, a carried electronic leakage detecting rod is taken out for identification, but the objects are carried obviously, so that the working intensity of the inspection staff is increased, and therefore, the operator wants to design a simple device which integrates the electronic leakage detecting rod and the binocular camera and can be pushed.

The present utility model has been made in view of this.

Disclosure of Invention

In order to solve the technical problems, the utility model adopts the basic conception of the technical scheme that:

the intelligent imaging heat supply pipeline inspection device comprises a vertical pipe, wherein a handle is installed at one end of the vertical pipe, the other end of the vertical pipe is installed on a base in a penetrating manner, and movable wheels are installed at two ends of the base in a rotating manner; a laser lamp and a binocular thermal imaging camera are arranged on the stand pipe at a position close to the base, the binocular thermal imaging camera is fixed on the laser lamp, and the binocular thermal imaging camera and an external intelligent terminal are in data wireless transmission; the side wall of the vertical pipe is provided with an electric box, an electronic hearing leakage rod is movably inserted into the inner cavity of the vertical pipe, one end of the electronic hearing leakage rod is fixed on the side wall of the sliding block, and the sliding block movably penetrates through the vertical pipe and is fixed with the electric box.

As a preferred implementation mode of the utility model, a Bluetooth module, a lithium battery and a processor are arranged in the electric box, the electronic hearing-leakage rod transmits data to the processor after being amplified by the sound wave amplifier, and the processor transmits an audio signal to an external Bluetooth earphone through the Bluetooth module.

As a preferred implementation mode of the utility model, a sliding port matched with the sliding block is formed on the side wall of the vertical pipe, and a rubber buffer block is arranged at the bottom of the sliding port.

As a preferred implementation mode of the utility model, the side wall of the vertical pipe is movably penetrated with a limiting pull rod, the limiting pull rod is provided with a spring, and the limiting pull rod is movably inserted into an insertion port formed in the end face of the sliding block.

As a preferable implementation mode of the utility model, the outer wall of the vertical pipe is also movably hinged with a supporting rod, and the outer wall of the vertical pipe is fixed with a clamp which is matched with the supporting rod.

As a preferred embodiment of the utility model, the vertical pipe is also provided with a collecting bracket box and a storage battery, and the storage battery supplies power for the laser lamp and the binocular thermal imaging camera.

Compared with the prior art, the utility model has the following beneficial effects:

in the practical use process, a patrol personnel holds a handle to push a riser to move along a pre-buried route of a heating pipeline through a moving wheel, in the moving process, a binocular thermal imaging camera on the riser carries out thermal shooting on the heating pipeline in real time, a thermal imaging picture is wirelessly transmitted to a mobile intelligent terminal of the patrol personnel to be displayed, after a suspected leakage point is detected, the patrol personnel can draw a limiting pull rod outwards, the limiting pull rod is separated from the sliding block, and the sliding block, an electric box and an electronic hearing leakage rod slide down on the riser until a tail sound collecting part of the electronic hearing leakage rod contacts a suspected leakage point, and sound Bluetooth is transmitted to a Bluetooth earphone worn by the patrol personnel to carry out final determination; when confirming the leak source, the personnel of patrolling and examining can take off the bracing piece from the clamp in to rotatory slope, thereby can support the riser, thereby make things convenient for the personnel of patrolling and examining to carry out other work.

The following describes the embodiments of the present utility model in further detail with reference to the accompanying drawings.

Drawings

In the drawings:

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

FIG. 2 is an enlarged schematic view of the structure of FIG. 1A according to the present utility model;

FIG. 3 is a schematic view of the layout of the electronic leak beam in the riser according to the present utility model;

FIG. 4 is a schematic view of the distribution position of two moving wheels on a base;

FIG. 5 is a schematic view showing the structure of the support bar of the present utility model after the support bar is received and clamped on the clip;

fig. 6 is a schematic view of the distribution structure in the electrical box of the present utility model.

In the figure: 1-a vertical pipe; 2-a storage battery; 3-a laser lamp; 4-binocular thermal imaging camera; 5-moving wheels; 6-a base; 7-clamping; 8-supporting rods; 9-a handle; 10-a mobile phone support box; 11-an electrical box; 12-sliding opening; 13-a rubber buffer block; 14-an electronic hearing rod; 15-a slider; 16-limiting pull rods; 17-a processor; 18-a Bluetooth module; 19-lithium battery.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions in the embodiments will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and the following embodiments are used to illustrate the present utility model.

As shown in fig. 1 to 3, an intelligent imaging heat supply pipeline inspection device comprises a vertical pipe 1, wherein one end of the vertical pipe 1 is provided with a handle 9, the other end of the vertical pipe is installed on a base 6 in a penetrating manner, and both ends of the base 6 are rotatably provided with moving wheels 5; a laser lamp 3 and a binocular thermal imaging camera 4 are arranged on the stand pipe 1 at a position close to the base 6, the binocular thermal imaging camera 4 is fixed on the laser lamp 3, and the binocular thermal imaging camera 4 and external intelligent terminal data are transmitted in a wireless mode; the riser 1 lateral wall is provided with electric box 11, and riser 1 inner chamber activity grafting has electron to listen to leak the pole 14, and electron is listened to leak one of them end of pole 14 and is fixed at slider 15 lateral wall, slider 15 activity run through in riser 1 and with electric box 11 fixed, in the in-service use, patrol and examine personnel's handheld handle 9 and promote riser 1 and remove at the pre-buried route of heating pipeline through removing wheel 5, in the removal in-process, because the real-time heat shooting of heating pipeline along the line of binocular thermal imaging camera 4 on riser 1 to show on patrol and examine personnel's mobile intelligent terminal with the picture wireless transmission of thermal imaging.

As shown in fig. 1 to 3, in a specific embodiment, a bluetooth module 18, a lithium battery 19 and a processor 17 are installed in an electrical box 11, after the electronic hearing rod 14 is amplified by an acoustic wave amplifier, data is transmitted to the processor 17, the processor 17 transmits audio signals to an external bluetooth headset through the bluetooth module 18, a sliding port 12 matched with a sliding block 15 is formed in the side wall of a vertical pipe 1, a rubber buffer block 13 is arranged at the bottom of the sliding port 12, a limiting pull rod 16 movably penetrates through the side wall of the vertical pipe 1, a spring is arranged on the limiting pull rod 16, and the limiting pull rod 16 is movably inserted into an insertion port formed in the end face of the sliding block 15.

As shown in fig. 1 to 3, further, the outer wall of the vertical tube 1 is further movably hinged with a supporting rod 8, the outer wall of the vertical tube 1 is fixed with a clamp 7 matched with the supporting rod 8, the vertical tube 1 is further provided with a collecting bracket 10 and a storage battery 2, and the storage battery 2 supplies power for the laser lamp 3 and the binocular thermal imaging camera 4. In this setting, after the suspected leak source is detected, the inspection personnel can outwards draw the limit pull rod 16, and limit pull rod 16 and slider 15 separation, slider 15, electric box 11 and electron that this moment can slide down on riser 1, until the afterbody sound collection part of electron tin drain 14 contacts the place of suspected leak source to with sound bluetooth transmission for the bluetooth headset that inspection personnel wore, and carry out final determination.

The implementation principle of the intelligent imaging heat supply pipeline inspection device is as follows: in the practical use process, the patrol personnel holds the handle 9 and promotes riser 1 through removing wheel 5 and remove at the pre-buried route of heating pipeline, in the removal in-process, because the binocular thermal imaging camera 4 on riser 1 carries out the heat shooting to the heating pipeline along the line in real time, and wireless transmission with the picture of thermal imaging shows on the mobile intelligent terminal of patrol personnel, after detecting suspected leak source, can conveniently confirm concrete leak source after pointing to the position of leak source through laser lamp 3, patrol personnel can outwards draw spacing pull rod 16, spacing pull rod 16 and slider 15 separation, slider 15, electric box 11 and electron that this moment can fall down on riser 1, until the afterbody sound collection part of electron hearing leak rod 14 contacts the place of suspected leak source, and with sound bluetooth headset that the bluetooth was worn by the patrol personnel, and carry out final determination.

When the leakage point is determined, the inspection staff can take down the support rod 8 from the clamp 7 and rotate and incline, so that the pipe 1 can be supported, and the inspection staff can conveniently carry out other works.

Claims (6)

1. The utility model provides an intelligent imaging's heating pipeline inspection device, includes riser (1), its characterized in that, handle (9) are installed to one end of riser (1), and the other end runs through and installs on base (6), the both ends of base (6) are all rotated and are installed movable wheel (5);

a laser lamp (3) and a binocular thermal imaging camera (4) are arranged on the vertical pipe (1) close to the base (6), the binocular thermal imaging camera (4) is fixed on the laser lamp (3), and the binocular thermal imaging camera (4) and an external intelligent terminal are in data wireless transmission;

the side wall of the vertical pipe (1) is provided with an electric box (11), an electronic leakage listening rod (14) is movably inserted into the inner cavity of the vertical pipe (1), one end of the electronic leakage listening rod (14) is fixed on the side wall of a sliding block (15), and the sliding block (15) movably penetrates through the vertical pipe (1) and is fixed with the electric box (11).

2. The intelligent imaging heat supply pipeline inspection device according to claim 1, wherein a Bluetooth module (18), a lithium battery (19) and a processor (17) are arranged in the electric box (11), the electronic hearing-leakage rod (14) transmits data to the processor (17) after being amplified by the sound wave amplifier, and the processor (17) transmits an audio signal to an external Bluetooth earphone through the Bluetooth module (18).

3. The intelligent imaging heat supply pipeline inspection device according to claim 1, wherein a sliding port (12) matched with a sliding block (15) is formed in the side wall of the vertical pipe (1), and a rubber buffer block (13) is arranged at the bottom of the sliding port (12).

4. The intelligent imaging heat supply pipeline inspection device according to claim 1, wherein a limiting pull rod (16) is movably penetrated through the side wall of the vertical pipe (1), a spring is arranged on the limiting pull rod (16), and the limiting pull rod (16) is movably inserted into an insertion port formed in the end face of the sliding block (15).

5. The intelligent imaging heat supply pipeline inspection device according to claim 1, wherein the outer wall of the vertical pipe (1) is further movably hinged with a supporting rod (8), and a clamp (7) matched with the supporting rod (8) is fixed on the outer wall of the vertical pipe (1).

6. The intelligent imaging heat supply pipeline inspection device according to claim 1, wherein the vertical pipe (1) is further provided with a collecting bracket box (10) and a storage battery (2), and the storage battery (2) supplies power for the laser lamp (3) and the binocular thermal imaging camera (4).