RU2509254C2 - Internal tube stencil - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: internal tube stencil comprises two sections hingedly connected to each other. The first section includes a tubular body with flanges. The following components are installed on the tubular body: plate collars at the opposite sides, a bumper for reeving of the stencil, a transmitter for a scraper, a conical collar, imitators of odometres, a spring for removal of electrostatic charges. The second section comprises a tubular body, plate springs at the opposite ends, a spider, a unit for measurement of throughput section of the pipeline, placed in the body cavity. The bumper, the transmitter for the scraper and the plate collar are connected to each other and installed at the end of the tubular body by means of a gasket made in the form of a bushing with flanges. The unit for measurement of throughput section of the pipeline includes a pusher communicated with levers of the spider, interacting with the piston installed in the cavity of the tubular body of the section section, and the piston is made as capable of reciprocal motion for determination, according to this movement, of the value of the throughput section of the pipeline.

EFFECT: invention will make it possible to simplify design and to increase reliability of its operation.

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Description

The invention relates to devices for monitoring and control of pipeline equipment, and in particular to devices for examining the flow area of the linear part of pipelines, mainly field and main oil and gas product pipelines, and can be used to determine the minimum flow area of the pipeline before the use of in-line inspection devices .

A device for a similar purpose is known - an in-tube projectile, which allows for inspection of pipelines, which consists of two sections interconnected by means of a cardan joint, contains cuffs, at least one belt of sensitive levers mounted on the housing around the perimeter in the cross section of the pipeline, rotation angle sensors sensitive levers, measuring instruments, processing and storage of measurement data, a power source connected to measuring instruments, processing and storage of measurement data (RU 25218 U1, 09.20.2002).

The disadvantage of this known device is the design complexity and low reliability of its operation.

The technical result of the proposed invention is to simplify the design and increase the reliability of the device.

The specified technical result is achieved due to the fact that the in-tube template consists of two sections interconnected by means of a swivel joint, the first of which includes a tubular body, bumpers mounted on it for storing the template, a transmitter for the scraper, and cup-shaped cuffs mounted from opposite ends of the tubular body, a conical cuff, odometer simulators, a spring for removing electrostatic charges, and the second section includes a tubular casing with opposite mounted on it its ends with cup springs and a spider and a block for measuring the flow cross section of the pipeline located in its cavity, the tubular body of the first section is made in the form of a sleeve with flanges at its ends, while a conical cuff is mounted on one end of the tubular body on its flange, a bumper, a transmitter for the scraper and one of the dish-shaped cuffs are interconnected and mounted on one of the ends of the tubular body by means of a gasket made in the form of a sleeve with flanges, and a unit for measuring the pipe bore and includes communication with the spider arms pusher capable of cooperating with the cavity mounted in the second section of the tubular body a piston adapted for reciprocating movement in the tubular body cavity to measure the magnitude of its displacement and determining the magnitude of this movement the flow cross section of the pipeline.

The invention is illustrated by drawings, where figure 1 shows a template in-tube, General view; figure 2 is the same, the second section.

The device consists of two sections I and II interconnected by means of articulation.

Section I includes a tubular body 1, a bumper 2 mounted on it for storing the in-tube template, a transmitter 3 for the scraper, a conical cuff 4, a simulator 5 odometers, a spring 6 for removing electrostatic charges.

At the opposite ends of the tubular body 1, disk-shaped cuffs 7 are installed.

Section II includes a tubular body 8 with disk springs 9 and spider 10 mounted on it from opposite ends and a block placed in its cavity for measuring the bore of the pipeline.

The tubular housing of section I is made in the form of a sleeve 11 with flanges 12 at its ends.

The conical cuff 4 is fixed at one end of the tubular body 1 on its flange 12, the bumper 2, the transmitter 3 for the scraper and one of the disk cuffs 7 are interconnected and installed on one end of the tubular body 1 by means of a gasket made in the form of a sleeve 14 with flanges 15.

The spider 10 has a flange 16, which is its supporting part and on which levers 17 are attached using brackets (not shown). Rollers 18 with rubber rings 19 along their perimeter are mounted on the free ends of the levers 17.

Each of the levers 17 through a hinge is connected to the disk 20.

The spider contains springs 21 connected to the disk 20 to ensure that the rollers 18 are pressed against the walls of the pipeline.

The block for measuring the bore of the pipeline includes a pusher 22 communicated with the levers 17 of the spider 10, configured to interact by means of a stop 23 with a piston 24 installed in the cavity of the tubular body 8 of the second section.

The piston 24 is made with the possibility of reciprocating movement in the cavity of the tubular body 8.

The piston 24 using the studs 25 through the rubber washers 26 and nuts 27 is pulled to the housing 8.

A certain tightening force of the nuts 27 on the studs 25 ensures the absence of spontaneous movement of the piston 24 and a fixed force when it moves under the action of the pusher 22 forward, where it stops after the termination of the pusher 22.

Rulers 28 with a millimeter scale are fixed on the housing 8; pointers in the form of arrows (not shown) are fixed on the studs 25.

The pusher 22 is installed in the holes of the end flanges 29 of the housing 8 freely with a small gap.

The bumper 2 for storing the in-tube template is a cone-shaped metal basket and is designed to store the template in the pipeline and protect the transmitter 3 for the scraper from possible impacts when the template collides with obstacles in the studied pipeline.

Sections I and II are interconnected by a hinge unit 30.

The device operates as follows.

Moving in the pipeline, under the influence of the flow of the transported product, the rollers 18 with rubber rings 19 are pressed against the inner wall of the pipeline due to the action of the springs 21 on the disk 20 and then through the swivel on the levers 17. When passing the dents, the rollers 18, rolling through the dents, reject the levers 17 to the axis of the pipeline. The movement is transmitted to the disk 20 and to the pusher 22, which acts on the piston 24 through the stop 23 and moves it inside the housing 8 along it, fixing the value of its movement with the arrow and using the calibration graph, determine the minimum flow cross section of the pipeline after the template is passed.

The hinge unit 30 sections I and II changes the mutual angular position and overcomes, thus, the bends of pipelines with small radii of rotation of the construction axis.

5 odometer simulators repeat the design of odometers used in profilers to measure the distance traveled, and are used in the templates only to find out the effects of pipeline defects and partially torn underlay rings on the profilers odometers. When encountering an obstacle in the pipeline, the lever of the odometer 5 simulator deviates, enveloping the obstacle. The lever is returned to its original position due to the spring.

A spring 6 for removing electrostatic charges prevents the accumulation of electrostatic charges on the metal structure of the device, thereby preventing dangerous sparking.

The dish-shaped cuffs can be made of polyurethane and provide centering of the template in the pipeline. The cuffs of the II section have bypass holes designed to align in the front and rear of the second section to prevent folding and angular oscillations of the template when it moves through the pipeline.

The conical cuff allows you to freely pass through the bends available in the pipeline, tees without gratings.

The size of the cuffs, their design, and the material from which they are made are such that they can bear the weight of the in-tube template, while undergoing minor abrasion, and their elasticity makes it possible to adapt to the pipeline profile and ensure smooth movement of the template.

The invention will simplify the design and increase the reliability of its work, in particular, due to the simplification of the design of the measurement unit, the absence of electronic equipment in the template.

Using the in-pipe template before passing the profilers or other in-pipe inspection devices will allow you to measure the minimum flow cross-section of pipelines, as well as to assess the possibility of their subsequent passage without damage.

Claims (1)

In-tube template, consisting of two sections interconnected by means of a hinge joint, the first of which includes a tubular body, a bumper installed on it for storing the template, a transmitter for the scraper, disk cups mounted on opposite ends of the tubular body, conical cuff, odometer simulators, spring for removal of electrostatic charges, and the second section includes a tubular body with disk springs and a spider mounted on it from opposite ends and placed in its cavity, the unit for measuring the flow cross section of the pipeline, the tubular casing of the first section is made in the form of a sleeve with flanges at its ends, while a conical cuff is fixed at one end of the tubular casing on its flange, a bumper, a transmitter for the scraper and one of the cup cuffs are connected between and mounted on one of the ends of the tubular body by means of a gasket made in the form of a sleeve with flanges, and the unit for measuring the bore of the pipeline includes a pusher communicated with the levers of the spider, enny to cooperate with a cavity mounted in the second section of the tubular body a piston adapted for reciprocating movement in the tubular body cavity to measure the magnitude of its displacement and determining the magnitude of this movement the flow cross section of the pipeline.

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