CN220153514U - Automatic monitoring device for push pipe propulsion stress of thermodynamic pipeline - Google Patents

Abstract

The utility model discloses an automatic monitoring device for pushing stress of a heating power pipeline jacking pipe, which comprises a base, wherein a plurality of rectangular holes are formed in the upper end surface of the base, a first electromagnetic track is fixedly connected to the surface of one side of the upper end of the base, a hydraulic rod is started and drives a U-shaped connecting block to move forwards so as to drive the heating power pipeline to move forwards, when a first infrared sensor monitors that the U-shaped connecting block moves to a set distance, the hydraulic rod stops moving, so that pushing operation of the heating power pipeline jacking pipe by manually controlling a pushing device is avoided, the situation that errors occur in pushing distance of the heating power pipeline jacking pipe due to visual interference of the manually operated pushing device is avoided, and further, when errors occur in pushing distance of the heating power pipeline, fine adjustment of pushing distance of the heating power pipeline by using the pushing device is avoided, time is consumed, and progress of the whole engineering is influenced.

Description

Automatic monitoring device for push pipe propulsion stress of thermodynamic pipeline

Technical Field

The utility model relates to the technical field of push pipes of thermal pipelines, in particular to an automatic push pipe propulsion stress monitoring device of a thermal pipeline.

Background

The heating power pipeline network is also called a heating power pipeline, and starts from a boiler room, a direct-fired machine room, a heating center and the like, and the heating power pipeline is led to a heating power inlet of a building from a heat source, so that the heating power pipeline jacking pipe is pushed to operate by manually controlling a pushing device at present, but the manually operating pushing device is subjected to visual interference, so that the pushing distance of the heating power pipeline jacking pipe is subjected to error, and when the pushing distance of the heating power pipeline is subjected to error, the pushing distance of the manpower pipeline is required to be finely adjusted by using the pushing device, so that time is consumed, and the progress of the whole engineering is influenced.

Disclosure of Invention

The utility model aims to provide an automatic monitoring device for push pipe propulsion stress of a thermal pipeline, which aims to solve the problems in the background technology.

The utility model provides a heating power pipeline push pipe impels stress automation monitoring device, includes the base, be provided with a plurality of rectangle hole on the upper end surface of base, the first electromagnetic track of upper end one side fixedly connected with on the surface, just fixedly connected with second electromagnetic track on the upper end opposite side surface of base, second electromagnetic track, impel monitoring component is installed to the orbital upper end of second electromagnetic, impel monitoring component's one side and install fixed monitoring component, just impel monitoring component's one side and install first circular connecting block, one side fixedly connected with heating power pipeline of first circular connecting block, the second circular connecting block is installed to one side of heating power pipeline.

Preferably, the propulsion monitoring assembly comprises an electromagnetic slide block, the upper end of the electromagnetic slide block is fixedly connected with a movable vehicle body, a hydraulic rod is fixedly installed in the movable vehicle body, one end of the hydraulic rod is connected with a U-shaped connecting block, and a cylinder connecting block is fixedly connected to the outer surface of one end of the U-shaped connecting block. The cylinder connecting block is characterized in that a first infrared sensor is fixedly connected to the outer side surface of one end of the cylinder connecting block, and a plurality of connecting blocks are fixedly connected to the outer side surface of the other end of the cylinder connecting block.

Preferably, the electromagnetic sliding blocks are mounted on two sides of the lower end of the movable vehicle body, the electromagnetic sliding blocks mounted on one side of the lower end of the movable vehicle body are matched with the first electromagnetic track, the electromagnetic sliding blocks mounted on the other side of the lower end of the movable vehicle body are matched with the second electromagnetic track, a plurality of circular holes are formed in the outer side surface of the first circular connecting block, and the circular holes formed in the outer side surface of the cylindrical connecting block, which penetrates through the first circular connecting block, are connected with the heating pipeline.

Preferably, the fixed monitoring assembly comprises a driving motor, a rectangular connecting block is arranged at the lower end of the driving motor, a threaded rod is arranged in the rectangular connecting block, a conical fixing block is connected to the outer side surface of the threaded rod, and a second infrared sensor is fixedly connected to the outer side surface of one end of the conical fixing block.

Preferably, the outer side surface of one end of the rectangular connecting block is fixedly connected to the outer side surface of the movable vehicle body, one side output end of the driving motor is connected with the threaded rod by penetrating through the rectangular connecting block, and the conical fixing block is matched with the rectangular hole.

Preferably, the output signal end of the second infrared sensor is connected with the input signal end of the hydraulic rod, and the output signal end of the first infrared sensor is connected with the input signal end of the driving motor.

Compared with the prior art, the utility model has the advantages that:

1) According to the utility model, when the lower end of the second infrared sensor in the fixed monitoring assembly monitors that the lower end is level with the upper surface of the base, the hydraulic rod is started and drives the U-shaped connecting block to move forwards, so that the connecting block is driven to move forwards, the heating pipeline is driven to generate thrust at the moment, when the first infrared sensor monitors that the U-shaped connecting block moves to a set distance, the hydraulic rod stops moving, so that the push pipe pushing operation is finished, the push pipe pushing operation of the heating pipeline is prevented from being performed by manually controlling the pushing device, the situation that the push distance of the heating pipeline is caused by visual interference caused by manual operation of the pushing device is avoided, and the situation that the push distance of the heating pipeline is required to be finely adjusted by the pushing device when the push distance of the heating pipeline is caused by the visual interference is avoided, so that time is consumed, and the progress of the whole engineering is influenced is avoided.

2) According to the utility model, the threaded rod is driven to rotate by the driving motor, and the conical fixing block is driven to move downwards along the threaded rod along with the rotation of the threaded rod and penetrates through the rectangular hole formed in the surface of the base, so that the propulsion monitoring assembly is fixed, the situation that the moving vehicle body moves backwards due to the fact that the hydraulic rod generates a backward thrust to the moving vehicle body in the process of propelling the thermal pipeline is avoided, and meanwhile, the situation that errors occur in the forward distance of the propulsion monitoring assembly in propelling the thermal pipeline due to the fact that the moving vehicle body moves backwards is avoided.

Drawings

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

FIG. 2 is a schematic diagram of a propulsion monitoring assembly according to the present utility model;

fig. 3 is a schematic structural diagram of a fixed monitoring component according to the present utility model.

The reference numerals in the figures illustrate: 1. a base; 2. rectangular holes; 3. a first electromagnetic track; 4. a second electromagnetic track; 5. a propulsion monitoring assembly; 501. an electromagnetic slide block; 502. moving the vehicle body; 503. a hydraulic rod; 504. a U-shaped connecting block; 505. a cylinder connecting block; 506. a first infrared sensor; 507. a connecting block; 6. fixing the monitoring assembly; 601. a driving motor; 602. a rectangular connecting block; 603. a threaded rod; 604. a conical fixed block; 605. a second infrared sensor; 7. a first circular connection block; 8. a thermodynamic conduit; 9. and a second circular connecting block.

Detailed Description

Examples: referring to fig. 1-3, an automatic monitoring device for pushing stress of a heat distribution pipeline jacking pipe comprises a base 1, wherein a plurality of rectangular holes 2 are formed in the upper end surface of the base 1, a first electromagnetic track 3 is fixedly connected to one side surface of the upper end of the base 1, a second electromagnetic track 4 is fixedly connected to the other side surface of the upper end of the base 1, a pushing monitoring assembly 5 is installed at the upper end of the second electromagnetic track 4, a fixed monitoring assembly 6 is installed on one side of the pushing monitoring assembly 5, a first circular connecting block 7 is installed on one side of the pushing monitoring assembly 5, a heat distribution pipeline 8 is fixedly connected to one side of the first circular connecting block 7, and a second circular connecting block 9 is installed on one side of the heat distribution pipeline 8.

The propulsion monitoring assembly 5 comprises an electromagnetic sliding block 501, wherein the upper end of the electromagnetic sliding block 501 is fixedly connected with a movable vehicle body 502, a hydraulic rod 503 is fixedly installed inside the movable vehicle body 502, one end of the hydraulic rod 503 is connected with a U-shaped connecting block 504, a cylinder connecting block 505 is fixedly connected to the outer side surface of one end of the U-shaped connecting block 504, a first infrared sensor 506 is fixedly connected to the outer side surface of one end of the cylinder connecting block 505, and a plurality of connecting blocks 507 are fixedly connected to the outer side surface of the other end of the cylinder connecting block 505.

The electromagnetic slide blocks 501 are installed on two sides of the lower end of the moving body 502, the electromagnetic slide blocks 501 installed on one side of the lower end of the moving body 502 are matched with the first electromagnetic track 3, the electromagnetic slide blocks 501 installed on the other side of the lower end of the moving body 502 are matched with the second electromagnetic track 4, a plurality of circular holes are formed in the outer side surface of the first circular connecting block 7, and the cylindrical connecting block 505 penetrates through the circular holes formed in the outer side surface of the first circular connecting block 7 through the connecting block 507 and is connected with the heating pipeline 8.

The fixed monitoring assembly 6 comprises a driving motor 601, a rectangular connecting block 602 is mounted at the lower end of the driving motor 601, a threaded rod 603 is mounted in the rectangular connecting block 602, a conical fixing block 604 is connected to the outer side surface of the threaded rod 603, and a second infrared sensor 605 is fixedly connected to the outer side surface of one end of the conical fixing block 604.

One end outer side surface of the rectangular connecting block 602 is fixedly connected to the outer side surface of the movable car body 502, one side output end of the driving motor 601 is connected with the threaded rod 603 by penetrating the rectangular connecting block 602, and the conical fixing block 604 is matched with the rectangular hole 2.

The output signal end of the second infrared sensor 605 is connected with the input signal end of the hydraulic rod 503, and the output signal end of the first infrared sensor 506 is connected with the input signal end of the driving motor 601.

Working principle: first, the first electromagnetic track 3 and the second electromagnetic track 4 are started, the propulsion monitoring assembly 5 moves forwards along the first electromagnetic track 3 and the second electromagnetic track 4 until the connecting block 507 in the propulsion monitoring assembly 5 penetrates through the circular hole formed in the surface of the first circular connecting block 7 to be connected with the heating pipeline 8, when the electromagnetic sliding block 501 in the propulsion monitoring assembly 5 needs resistance in the process of driving the propulsion monitoring assembly 5 to move forwards, the driving motor 601 stops moving, at the moment, the driving motor 601 starts rotating, the threaded rod 603 is driven to rotate, the conical fixing block 604 is driven to move downwards along the threaded rod 603 and penetrate through the rectangular hole 2 formed in the surface of the base 1 along with the rotation of the threaded rod 603, when the lower end of the second infrared sensor 605 detects that the lower end of the second infrared sensor 605 is level with the upper surface of the base 1, the driving motor 601 stops rotating, and the hydraulic rod 503 is started, along with the starting of the hydraulic rod 503, the U-shaped connecting block 504 is driven to move forward, the cylindrical connecting block 505 is driven to move forward, the connecting block 507 generates thrust to the thermal pipeline 8 at the moment, the thermal pipeline 8 is driven to move forward, when the second infrared sensor 605 monitors that the U-shaped connecting block 504 moves to a set distance, the hydraulic rod 503 stops moving, the push pipe pushing operation is finished, thus the push pipe pushing operation of the thermal pipeline 8 is prevented from being carried out by manually controlling the pushing device, the situation that the push pipe pushing distance of the thermal pipeline 8 is caused to have errors due to visual interference caused by manually operating the pushing device is avoided, the push distance of the thermal pipeline 8 needs to be finely adjusted by utilizing the pushing device when the push pipe pushing distance of the thermal pipeline 8 is caused to have errors is avoided, this takes time and affects the progress of the whole project.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present utility model, and are not intended to limit the utility model, and that various changes and modifications may be made therein without departing from the spirit and scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a heating power pipeline push pipe impels stress automation monitoring devices, includes base (1), its characterized in that: be provided with a plurality of rectangle hole (2) on the upper end surface of base (1), first electromagnetism track (3) of fixedly connected with on the upper end one side surface of base (1), just fixedly connected with second electromagnetism track (4) on the upper end opposite side surface of base (1), second electromagnetism track (4), propulsion monitoring component (5) are installed to the upper end of second electromagnetism track (4), fixed monitoring component (6) are installed to one side of propulsion monitoring component (5), just first circular connecting block (7) are installed to one side of propulsion monitoring component (5), one side fixedly connected with heating power pipeline (8) of first circular connecting block (7), second circular connecting block (9) are installed to one side of heating power pipeline (8).

2. The automatic monitoring device for push pipe pushing stress of thermal pipeline according to claim 1, wherein: the propulsion monitoring assembly (5) comprises an electromagnetic sliding block (501), wherein the upper end of the electromagnetic sliding block (501) is fixedly connected with a mobile vehicle body (502), a hydraulic rod (503) is fixedly installed inside the mobile vehicle body (502), one end of the hydraulic rod (503) is connected with a U-shaped connecting block (504), a cylinder connecting block (505) is fixedly connected on the outer surface of one end of the U-shaped connecting block (504), a first infrared sensor (506) is fixedly connected on the outer surface of one end of the cylinder connecting block (505), and a plurality of connecting blocks (507) are fixedly connected on the outer surface of the other end of the cylinder connecting block (505).

3. The automatic monitoring device for push pipe pushing stress of thermal pipeline according to claim 2, wherein: electromagnetic sliding blocks (501) are arranged on two sides of the lower end of the moving car body (502), the electromagnetic sliding blocks (501) arranged on one side of the lower end of the moving car body (502) are matched with the first electromagnetic track (3), the electromagnetic sliding blocks (501) arranged on the other side of the lower end of the moving car body (502) are matched with the second electromagnetic track (4), a plurality of circular holes are formed in the outer side surface of the first circular connecting block (7), and the circular holes formed in the outer side surface of the first circular connecting block (7) in a penetrating mode are connected with the thermal pipeline (8) through connecting blocks (507).

4. A thermodynamic pipeline jacking stress automatic monitoring device according to claim 3, characterized in that: fixed monitoring component (6) is including driving motor (601), rectangular connection block (602) are installed to driving motor (601) lower extreme, rectangular connection block (602) internally mounted has threaded rod (603), be connected with toper fixed block (604) on the outside surface of threaded rod (603), fixedly connected with second infrared inductor (605) on the one end outside surface of toper fixed block (604).

5. The automatic monitoring device for push pipe pushing stress of thermal pipeline according to claim 4, wherein: the outer side surface of one end of the rectangular connecting block (602) is fixedly connected to the outer side surface of the movable car body (502), one side output end of the driving motor (601) is connected with the threaded rod (603) by penetrating the rectangular connecting block (602), and the conical fixing block (604) is matched with the rectangular hole (2).

6. The automatic monitoring device for push pipe pushing stress of thermal pipeline according to claim 5, wherein: the output signal end of the second infrared sensor (605) is connected with the input signal end of the hydraulic rod (503), and the output signal end of the first infrared sensor (506) is connected with the input signal end of the driving motor (601).