CN214790546U - Third-party construction monitoring equipment for natural gas pipeline - Google Patents

Abstract

The utility model provides a third-party construction monitoring device for a natural gas pipeline, which comprises a monitoring component and a mobile operation component, the outer side wall of the monitoring component is provided with a movable operation component, the monitoring component comprises a shell, a first motor, a first bearing, a first gear, a second bearing, a second gear, a block body, a groove, an infrared laser lamp, a controller and a gas detector, the inner side wall of the shell is welded with the first motor, the utility model adopts the sliding rail arranged on the finished pipeline, the infrared ray produced by the infrared laser lamp is utilized to lead the infrared inductor to receive the finished pipeline, the rack drives the fourth gear to carry out linkage, thereby make the casing carry out horizontal movement, utilize the gas detection appearance accuracy of installation to detect the leakage point, saved manpower resources on the one hand, on the other hand effectively improves the guardianship effect to can reach the effect to timely processing and the early warning of information.

Description

Third-party construction monitoring equipment for natural gas pipeline

Technical Field

The utility model relates to a natural gas line third party construction monitoring technology field, in particular to a third party construction supervisory equipment for natural gas line.

Background

The natural gas pipeline is a pipeline for conveying natural gas (including associated gas produced in an oil field) from an exploitation place or a treatment plant to an urban distribution center or an industrial enterprise user, and is also called as a gas transmission pipeline, and the natural gas pipeline has the advantages of low transportation cost, small occupied area, quick construction, large oil and gas transportation amount, high safety performance, low transportation loss, no three-waste discharge, small leakage risk, small environmental pollution, small adverse weather influence, small equipment maintenance amount, convenience in management, easiness in remote centralized monitoring and the like;

in the pipeline construction, pipeline accidents are caused by unsafe factors such as environment, human factors and the like, wherein the most serious is leakage accidents, so that not only is the resource waste caused, but also the environment is polluted, the personal and property safety is endangered, and even fire or explosion accidents are caused in serious cases;

however, the existing pipeline construction monitoring method still carries out on-site monitoring manually, so that a large amount of manpower is needed, and because the construction operation area is wide, information is difficult to effectively process and early warning effects, therefore, a third-party construction monitoring device for the natural gas pipeline is provided.

SUMMERY OF THE UTILITY MODEL

In view of this, embodiments of the present invention are intended to provide a third-party construction monitoring device for a natural gas pipeline, so as to solve or alleviate the technical problems in the prior art, and at least provide a useful choice.

The embodiment of the utility model provides a technical scheme is so realized: a third-party construction monitoring device for a natural gas pipeline comprises a monitoring component and a movable operation component, wherein the movable operation component is arranged on the outer side wall of the monitoring component;

the monitoring assembly comprises a shell, a first motor, a first bearing, a first gear, a second bearing, a second gear, a block body, a groove, an infrared laser lamp, a controller and a gas detector;

the utility model discloses a laser lamp, including casing, first motor, first bearing, second bearing, infrared laser lamp and first gear, the inside wall welding of casing has first motor, the output shaft of first motor rotates through first bearing and connects in one side of casing, the output shaft welding of first motor has first gear, one side welding that first motor was kept away from to first gear has the second bearing, the outer lane of second bearing welds in one side of casing, the lateral wall meshing of first gear is connected with the second gear, the last surface welding of second gear has the block, one side of block is seted up flutedly, the infrared laser lamp is installed to the inside wall of recess.

In some embodiments, a controller is installed on the inner side wall of the shell, and the controller drives the second motor to work.

In some embodiments, a gas detector penetrates through the lower surface of the shell, and whether the pipeline generates gas leakage or not is detected in real time through the gas detector.

In some embodiments, the moving operation assembly comprises a second motor, a third bearing, a third gear, a rack, a fourth gear, a connecting plate, a pipeline, a sliding rail, a rod body, a sliding block, a connecting rod and an infrared sensor;

the welding of the inside wall of casing has the second motor, the output shaft of second motor passes through the third bearing and rotates to be connected in the front surface of casing, the welding of the output shaft of second motor has the third gear, drives the third gear through the output shaft of second motor and rotates.

In some embodiments, a rack is engaged and connected to an outer side wall of the third gear, a fourth gear is engaged and connected to an inner side wall of the rack and below the third gear, and the third gear and the fourth gear are connected by the rack.

In some embodiments, two connecting plates are symmetrically welded to the lower surface of the shell, a pipeline is attached to the lower surfaces of the two connecting plates, and the shell is placed on the outer side of the pipeline through the connecting plates.

In some embodiments, a slide rail is welded on the front surface of the pipeline, a rod body penetrates through the front surface of the fourth gear, a connecting rod is welded on the front surface of the shell and is used for connecting an internal sliding block through the slide rail, and the rod body and the connecting rod are used for connecting the sliding block.

In some embodiments, the inner side wall of the slide rail is slidably connected to the rear surfaces of the rod body and the connecting rod, the infrared sensor penetrates through the outer side wall of the pipeline, and the pipeline slides inside the slide rail through the slider, so that the shell moves horizontally.

The embodiment of the utility model provides a owing to adopt above technical scheme, it has following advantage:

the utility model discloses a set up the slide rail on accomplishing the pipeline, the infrared ray that utilizes infrared laser lamp to produce makes infrared inductor receive it, when taking place to leak, can borrow by infrared inductor with signal transmission for the controller, the controller drives the second motor, utilize its output shaft to drive the third gear and rotate, drive the fourth gear by the rack and link, thereby make the casing carry out horizontal motion, utilize the accurate leakage point that detects of the gas detection appearance of installation, manpower resources have been saved on the one hand, on the other hand effectively improves the guardianship effect, thereby can reach the effect to the timely processing of information and early warning.

The foregoing summary is provided for the purpose of description only and is not intended to be limiting in any way. In addition to the illustrative aspects, embodiments, and features described above, further aspects, embodiments, and features of the present invention will be readily apparent by reference to the drawings and following detailed description.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments or technical descriptions will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a block diagram of the present invention;

FIG. 2 is a sectional view of the housing of the present invention;

FIG. 3 is a side view of the housing of the present invention;

fig. 4 is a connection structure diagram of the first gear and the second gear of the present invention.

Reference numerals: 1. a monitoring component; 101. a housing; 11. a first motor; 12. a first bearing; 13. a first gear; 14. a second bearing; 15. a second gear; 16. a block body; 17. a groove; 18. an infrared laser lamp; 19. a controller; 20. a gas detector; 3. moving the operating assembly; 301. a second motor; 31. a third bearing; 32. a third gear; 33. a rack; 34. a fourth gear; 35. a connecting plate; 36. a pipeline; 37. a slide rail; 38. a rod body; 39. a slider; 40. a connecting rod; 41. an infrared sensor.

Detailed Description

In the following, only certain exemplary embodiments are briefly described. As those skilled in the art will recognize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not as restrictive.

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1-4, an embodiment of the present invention provides a third-party construction monitoring device for a natural gas pipeline, including a monitoring component 1 and a mobile operation component 3, where the outer sidewall of the monitoring component 1 is provided with the mobile operation component 3;

the monitoring assembly 1 comprises a housing 101, a first motor 11, a first bearing 12, a first gear 13, a second bearing 14, a second gear 15, a block 16, a groove 17, an infrared laser lamp 18, a controller 19 and a gas detector 20;

the inside wall welding of casing 101 has first motor 11, the output shaft of first motor 11 rotates through first bearing 12 and connects in one side of casing 101, the output shaft welding of first motor 11 has first gear 13, one side welding that first motor 11 was kept away from to first gear 13 has second bearing 14, the outer lane of second bearing 14 welds in one side of casing 101, the outside wall meshing of first gear 13 is connected with second gear 15, the last skin weld of second gear 15 has block 16, recess 17 has been seted up to one side of block 16, infrared laser lamp 18 is installed to the inside wall of recess 17.

In one embodiment, a controller 19 is installed on the inner side wall of the housing 101, and the second motor 301 is driven to operate by the installed controller 19, so as to drive the housing 101 to move horizontally.

In one embodiment, the gas detector 20 penetrates through the lower surface of the housing 101, and whether gas leakage occurs at a designated position is detected by the installed gas detector 20.

In one embodiment, the moving operation assembly 3 includes a second motor 301, a third bearing 31, a third gear 32, a rack 33, a fourth gear 34, a connecting plate 35, a pipe 36, a slide rail 37, a rod body 38, a slider 39, a connecting rod 40, and an infrared sensor 41;

the welding of the inside wall of casing 101 has second motor 301, and the output shaft of second motor 301 passes through third bearing 31 and rotates to be connected in the front surface of casing 101, and the welding of the output shaft of second motor 301 has third gear 32, and through the second motor 301 that sets up, utilizes its output shaft to drive the third gear 32 of connection and rotates.

In one embodiment, a rack 33 is engaged and connected to an outer side wall of the third gear 32, a fourth gear 34 is engaged and connected to an inner side wall of the rack 33 and located below the third gear 32, and the rack 33 is arranged to connect the third gear 32 and the fourth gear 34, so that the second motor 301 is used for driving the third gear 32 to enable the fourth gear 34 to be linked.

In one embodiment, two connecting plates 35 are symmetrically welded on the lower surface of the shell 101, the pipeline 36 is attached to the lower surfaces of the two connecting plates 35, and the shell 101 is placed on the outer side of the pipeline 36 through the arrangement of the connecting plates 35.

In one embodiment, a sliding rail 37 is welded on the front surface of the pipeline 36, a rod 38 penetrates through the front surface of the fourth gear 34, a connecting rod 40 is welded on the front surface of the casing 101, the sliding rail 37 is used for connecting with an internal sliding block 39, and the rod 38 and the connecting rod 40 are used for connecting with the sliding block 39.

In one embodiment, the inner side wall of the slide rail 37 and the rear surfaces of the rod body 38 and the connecting rod 40 are both slidably connected with a sliding block 39, the outer side wall of the pipeline 36 is penetrated with an infrared sensor 41, the sliding block 39 is arranged to slide inside the slide rail 37, so that the casing 101 horizontally moves, and the infrared sensor 41 is arranged to sense the light emitted by the infrared laser lamp 18.

In this embodiment, a switch set for starting and closing the first motor 11, the infrared laser lamp 18, the controller 19, the gas detector 20, the second motor 301, and the infrared sensor 41 is installed on one side of the housing 101, and the switch set is connected to an external commercial power to supply power to the first motor 11, the infrared laser lamp 18, the controller 19, the gas detector 20, the second motor 301, and the infrared sensor 41.

In this embodiment: the first motor 11 is model YVP 315S.

In this embodiment: the infrared laser light 18 is model number SL-H3.

In this embodiment: the controller 19 is of the type DR 1-2000.

In this embodiment: the gas detector 20 is of the type SK-600-4H.

In this embodiment: the second motor 301 is of type Y802-4.

In this embodiment: the infrared sensor 41 is of the type XKC-003K 4.

The utility model discloses at the during operation: the staff opens the switch group to start the first motor 11, the output shaft of the first motor 11 drives the first gear 13 connected with the first motor to rotate through the action of the first bearing 12 and the second bearing 14, because the first gear 13 is fixed, the second gear 15 connected with the first motor in a meshing way carries out circular motion, the infrared laser lamp 18 connected with the second gear 15 through the block 16 carries out rotation irradiation, the irradiated infrared ray can be fed back to the infrared inductor 41, when gas leaks, the phenomenon that light is refracted can be caused after the light is irradiated from the upper part of the gas, so that the infrared inductor 41 can not receive the light, the infrared inductor 41 transmits signals to the controller 19, the controller 19 controls the second motor 301 to work, the output shaft of the second motor 301 drives the third gear 32 to rotate, the fourth gear 34 connected with the help of the rack 33 to carry out linkage, connect in pivoted fourth gear 34 through the body of rod 38 to can drive the slider 39 of connection and carry out the horizontal motion, be connected to another slider 39 on casing 101 through connecting rod 40 and carry out the linkage, thereby drive casing 101 wholly and carry out the horizontal motion along slide rail 37, detect pipeline 36 again with the help of installing gas detector 20 on casing 101, pinpoint the leakage point.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily think of various changes or substitutions within the technical scope of the present invention, which should be covered by the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (8)

1. A third party construction monitoring equipment for natural gas pipeline, includes monitoring subassembly (1) and removal operation subassembly (3), its characterized in that: the outer side wall of the monitoring component (1) is provided with a movable operation component (3);

the monitoring assembly (1) comprises a shell (101), a first motor (11), a first bearing (12), a first gear (13), a second bearing (14), a second gear (15), a block body (16), a groove (17), an infrared laser lamp (18), a controller (19) and a gas detector (20);

the utility model discloses a solar energy water heater, including casing (101), the inside wall welding of casing (101) has first motor (11), the output shaft of first motor (11) rotates through first bearing (12) and connects in one side of casing (101), the output shaft welding of first motor (11) has first gear (13), one side welding that first motor (11) were kept away from in first gear (13) has second bearing (14), the outer lane of second bearing (14) welds in one side of casing (101), the lateral wall meshing of first gear (13) is connected with second gear (15), the last skin weld of second gear (15) has block (16), one side of block (16) is seted up flutedly (17), infrared laser lamp (18) are installed to the inside wall of recess (17).

2. The third party construction monitoring device for a natural gas pipeline according to claim 1, wherein: the controller (19) is installed to the inside wall of casing (101).

3. The third party construction monitoring device for a natural gas pipeline according to claim 1, wherein: and a gas detector (20) penetrates through the lower surface of the shell (101).

4. The third party construction monitoring device for a natural gas pipeline according to claim 1, wherein: the mobile operation assembly (3) comprises a second motor (301), a third bearing (31), a third gear (32), a rack (33), a fourth gear (34), a connecting plate (35), a pipeline (36), a sliding rail (37), a rod body (38), a sliding block (39), a connecting rod (40) and an infrared sensor (41);

the welding of the inside wall of casing (101) has second motor (301), the output shaft of second motor (301) passes through third bearing (31) and rotates to be connected in the front surface of casing (101), the welding of the output shaft of second motor (301) has third gear (32).

5. The third party construction monitoring device for a natural gas pipeline according to claim 4, wherein: the outer side wall of the third gear (32) is connected with a rack (33) in a meshed mode, and the inner side wall of the rack (33) is located below the third gear (32) and connected with a fourth gear (34) in a meshed mode.

6. The third party construction monitoring device for a natural gas pipeline according to claim 4, wherein: the lower surface symmetry welding of casing (101) has two connecting plates (35), two the lower surface laminating of connecting plate (35) has pipeline (36).

7. The third party construction monitoring device for a natural gas pipeline of claim 6, wherein: the front surface welding of pipeline (36) has slide rail (37), the front surface of fourth gear (34) has run through the body of rod (38), the front surface welding of casing (101) has connecting rod (40).

8. The third party construction monitoring device for a natural gas pipeline according to claim 7, wherein: the inside wall of slide rail (37) just is located the body of rod (38) with the equal sliding connection of rear surface of connecting rod (40) has slider (39), infrared inductor (41) have been run through to the outside wall of pipeline (36).

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