RU25599U1 - STAND FOR PIPES TESTED BY INTERNAL PRESSURE AND BENDING AND HYDRAULIC SYSTEM OF THE STAND - Google Patents

Abstract

1. Stand for testing pipes with internal pressure and bending, consisting of a device for loading the test pipe with a bend and a hydraulic system, the device for loading the test pipe with a bend contains a plate with supports, hydraulic cylinders, rods, support and load traverses with profiled lodges in contact with the test pipe characterized in that the hydraulic cylinders are pivotally mounted on the plate and, using rods, pivotally connected to the load traverses. 2. The stand according to claim 1, characterized in that the supports are connected to the supporting traverses by means of elastic rods. The stand according to claim 1 or 2, characterized in that it is equipped with a control system for the device for loading the test pipe by bending and a hydraulic system in the form of electronic equipment equipped with a computer. A stand according to any one of claims 1 to 3, characterized in that the control system of the device for loading the test pipe by bending and the hydraulic system includes force sensors for measuring forces on the hydraulic cylinder rods, pressure sensors for measuring pressure in the tested pipe, displacement sensors for measuring movements of the hydraulic cylinder rods .5. The hydraulic system of the bench for testing pipes with internal pressure and bending, consisting of circuits for supplying oil to hydraulic cylinders and the medium in the test pipe, characterized in that it contains a dual-circuit pressure transducer, one of the circuits of which is filled with water to create internal pressure in the test pipe, and the other - hydraulic oil for controlling the pressure transducer together with the hydraulic cylinders of the device for loading the pipe under bending. 6. The system according to claim 5, �

Description

  ° ° G01M3 / 02, G 01 N3 / 10, 3/36

Bench for testing pipes with internal pressure and bending and hydraulic system of the stand

A group of utility models relates to test equipment and relates to the creation of a test bench for testing steel pipes of oil trunk pipelines with a diameter of 1220 mm, 1020 mm, 820 mm, 720 mm, 530 mm for static and low-cycle strength under joint loading by internal pressure and bending moment, operating under real conditions operation of main oil pipelines during rises and depressures of pumped oil, soil shifts, temperature extremes within the climatic conditions, pipeline lifting during overhaul onte, etc.

A device for testing pipes for bending under internal pressure (USSR author's certificate .f 1145271, publ. 15.10.75), containing two sliding supports, mounted on them tubular holders for mounting the test pipe, connected to them the system for supplying and outputting the test medium and attached to the holders symmetrically located relative to the supports loading devices made in the form of hinged loads, between which are mounted supports of adjustable height to limit the deflection of the test pipe.

This device provides testing the pipe for cyclic bending during periodic lifting and depressurization using a high-pressure pump, simulating an external load on the pipe with a constant constant bending moment.

The disadvantage of this device is the inability to simulate variable bending moments caused by external effects on the oil pipeline of soil, water (underwater crossings) and temperature differences with a periodicity different from the frequency of pressure changes in the pipeline.

A known installation for testing tubular samples under the simultaneous influence of internal pressure and bending moment created by means of loading devices, which include hydraulic cylinders (USSR author's certificate No. 162992, publ. 05.27.1964). However, the hydraulic cylinders used in this installation are not equipped with a control system in terms of force, and therefore, with periodic lifting and depressurization inside the tubular sample, it does not provide a given value of bending forces: when the pressure rises with the hydraulic cylinder piston fixed, the loading device, preventing the sample from moving,

additionally loads it, and with freely moving tailgate

the volume of the cavity of the hydraulic cylinder above the piston and, consequently, the load on the sample changes.

Closest to the proposed stand is the installation for testing welded joints of tubular samples (see USSR author's certificate No. 170720 of 04/23/1965), which allows the test samples to be loaded with internal pressure and a clean bend. The specified installation contains a device for the infusion of two tubular samples by bending and a hydraulic system, and the loading device includes a power plate (bed) with supports, hydraulic cylinders (hydraulic presses), rods (support columns), support and load traverses with profiled lodgements (yokes), contacting with the tested pipes, the curvature of the contact surfaces of which is similar to the curvature of the surface of the tested pipes.

The simulation of pure pipe bending using this device, which is structurally designed so that the support columns and two test specimens form a closed hinge frame, is carried out using the reactive forces arising from loading with the help of hydraulic presses of one sample to load through the support columns of the second sample. In connection with this, a disadvantage

of this device is the excessive bulkiness of its design when testing pipes of large oil pipelines of large diameters (1020 mm and 1220 mm).

The technical result, the first useful model is aimed at, is to create a compact (for testing one pipe) bending device, which immerses the pipe under test with a clean bend and requires minimal technical and time costs for installing pipes of various diameters.

The specified result is achieved by the fact that in the stand for testing pipes with internal pressure and bending, containing the above nodes

devices for loading two tubular samples by bending, elastic rods are used to fasten support traverses to the supports and articulated joints in hydraulic cylinder mounts to the power plate and through traction to load traverses.

The well-known hydraulic system for testing welded joints of tubular samples (ed. St. No. 170720) contains two independent circuits that differ in both technical design and control, one of which is designed to supply oil to the hydraulic cylinders in a given sequence, providing bending of the samples by bending and the other for supplying the medium, creating internal pressure in the samples.

In this regard, in order to ensure the simultaneous loading of the test samples with variable internal pressure and variable bending moment with given amplitudes and periodicity of change in their values corresponding to the conditions of the actual operation of the main oil pipelines, it would be necessary to develop a special system for joint control of these circuits, which would greatly complicate this installation.

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A useful model is to equip the hydraulic system of the bench with a special hydraulic device with a design and control similar to hydraulic cylinders, which reproduces the internal pressure in the pipe at the same time as the hydraulic cylinders load it with a bending moment with amplitudes and periodicity of change corresponding to the conditions of the actual operation of main oil pipelines.

The indicated result is achieved by using, as part of the hydraulic system of the bench, for testing pipes with internal pressure and for bending a double-circuit pressure transducer in the form of a hydraulic cylinder consisting of two cavities, one of whose circuits

filled with water to create internal pressure in the test pipe, and the other with hydraulic oil to control the pressure transducer together with hydraulic cylinders, a low pressure water pump to fill the test pipe with water and the primary circuit of the pressure transducer and high pressure pump for supplying hydraulic oil through the control valve block to hydraulic cylinders and the second circuit of the pressure transducer.

The essence of the utility model is illustrated by drawings, where:

in FIG. 1 shows a General view of the stand for testing pipes with internal pressure and bending with a tube sample;

in FIG. 2 and Fig. 3 - views of the stand with a tube sample from the end, respectively, of the support node and the load node.

The pipe sample consists of the test pipe 1, connected by welding with two cylindrical holders 2 and 3, hermetically sealed by elliptical bottoms, in one of which (3) nipples 4 and 5 are welded for filling the sample with water and air outlet, equipped with shutoff valves.

The stand for testing pipes with internal pressure and bending (hereinafter referred to as the stand) consists of a bending device and a hydraulic installation.

The bending device comprises a rectangular power plate 6 with longitudinal longitudinal grooves, the supports of which are bolted at the corners of the pole 7. Symmetrically relative to the supports 7, four hydraulic cylinders 8 are mounted in pairs along the plate and are mounted on the power plate by articulated joints 9. T-shaped longitudinal grooves are made in the power plate 6 to move the supports 7 and hydraulic cylinders 8 along the power plate 6 at a predetermined distance from each other.

For each pair of supports 7 located on the edge of the power plate 6, with

with the help of rods 10, a support beam And is suspended with a profiled lodgement 12, on which the end part of the holder of the tube sample is supported.

The design of the rods 10 made of spring steel is such that their elastic bending ensures the movement of the supporting traverse 11, and, consequently, the movement of the ends of the pipe sample when bending the test pipe 1.

Each pair of hydraulic cylinders 8 is connected by means of rods 10 to a loading beam 13 equipped with a profiled tool tray 12, with which the beam 13 is mounted on the holder of the tube sample. The load beam 13 is docked with rods 10 with a swivel joint 14.

The use of articulated joints 9 and 14 in the assembly of hydraulic cylinders with a power plate 6 and through rods 10 with load traverses 13 in combination with the use of elastic rods 10 for fastening the support traverses 11 to the supports 7 provides unhindered bending of the tested pipe 1 during loading, eliminating the occurrence of longitudinal ( shear) forces and the appearance of swaying of the tube sample.

To prevent bursting and destruction of the steel holders 2 and 3 of the tube sample in the contact zones with the tool holders, each tool bed 12 is structurally made of two profiled segments interconnected by screws and made of aluminum alloy with a surface curvature for contact with the tube sample, similar to the curvature of the surface of the sample. In this case, the nomenclature of the profiled segments corresponds to the nomenclature of the tested pipes 1.

Each hydraulic cylinder 8 is equipped with a servo-hydraulic unit 15 with valves for controlling the movement of the hydraulic cylinder rod, a force sensor 16 for measuring the force on the rod and a displacement sensor 17 for measuring the movement of the rod.

The hydraulic installation contains a dual-circuit (oil-water) pressure transducer made in the form of a hydraulic cylinder 18, which creates water pressure inside the pipe sample, a low pressure water pump 19 to fill the pipe sample and the water cavity of the hydraulic cylinder 18 with water from the tank 20, a high pressure pump 21 with a system air-water cooling for supplying hydraulic oil to the hydraulic cylinders 8 and 18 through the block of control valves 22.

The double-circuit hydraulic cylinder 18 is made with a single rod and two pistons, one in each cavity, in the upper water cavity of the hydraulic cylinder 18, connected by pipelines to the pipe sample and the low pressure water pump 19 through a check valve 23, a pressure sensor 24 is installed. In the lower cavity of the hydraulic cylinder 18 filled with high-pressure hydraulic oil, a servo-hydraulic unit 15 with valves for controlling the movement of the rod and a displacement sensor 17 for measuring the movement of the rod are installed. Operated in the lower cavity of the cylinder 18

ji i y / m the movement of the rod leads to the creation of water pressure in the upper water cavity and in the tube sample. The stand is equipped with the necessary equipment for controlling electronic equipment located in the control cabinet 25. When controlling the stand, a computer 26 is used (setting, starting and stopping loading modes, recording readings of force, pressure and mixing sensors) and remote controls installed on the front panel of the control cabinet 25 (turning on and turning off the hydraulic oil supply from the high pressure pump 21 to the hydraulic cylinders 8 and 18). The stand works as follows. On the power plate 6, the supports 7 are mounted and bolted with support traverses 11 and symmetrically with respect to the support traverses at a distance that ensures the test pipe 1 is infused with a given bending moment, two pairs of hydraulic cylinders 8. The pipe sample is supported by the ends of the holders 2 and 3 on the profiled lodges 12 of the support traverse 11. On the same holders set profiled lodgements 12 load traverses 13, which through the rods 10 screw connections are attached to the rods of the hydraulic cylinders 8. Next, using a water pump 19 low-pressure tank is filled with water from the upper cavity 20 of the hydraulic cylinder 18 and the sample tube through the nozzle 4 with the release of air through the nozzle 5, stop valves which close after filling with water. By switching on the control panels on the control cabinet 25, hydraulic oil is pumped by a high pressure pump 21 through the block of control valves 22 to the hydraulic cylinders 8 and into the lower cavity of the hydraulic cylinder 18. Using the computer software 26, static (load value, loading speed, holding time under load, unloading time ) and cyclic (load values for triangular, rectangular, trapezoidal, sinusoidal cycles, loading frequency and number of cycles) loading modes of the test pipes. When the loading mode of the tested pipe is started on the computer 26, the electronic equipment 25, recording the readings of the pressure sensors 24, forces 16 and displacements 17, controls the movement of the rods of hydraulic cylinders 8 and 18 using servo-hydraulic blocks 15 with valves. By an incoming electrical signal in the servo-hydraulic unit, the flow of hydraulic oil entering at high pressure into the hydraulic cylinder 8 or 18 is directed either into the cavity in front of the piston, which leads to the movement of the rod from the hydraulic cylinder, or into the cavity behind the piston, which causes the rod to move inside the hydraulic cylinder while the forces and pressure are monitored according to the readings of the respective sensors. When the rods are moved inside the hydraulic cylinders 8, the load traverses 13 are pressed through the profiled lodges 12 onto the surface of the holders of the pipe sample, creating the required transverse load bending the tested pipe 1. When the rod moves upward in the lower cavity of the hydraulic cylinder 18, the required water pressure is created in its upper cavity and pipe sample . Periodic movements of the hydraulic cylinder rods 8 and 18 make it possible to simulate low-cycle loading of the tested pipe with variable bending and variable internal pressure, acting in the conditions of actual operation of main oil pipelines. The result of the application of the group of utility models is to increase the reliability of the experimental assessment of the static and low-cycle strength of steel pipes of oil trunk pipelines by testing the pipes by loading with variable internal pressure and variable bending moment with amplitudes and periodicity of change simulating the loads acting in the conditions of real operation of the main oil pipelines.

Claims (7)

1. Stand for testing pipes with internal pressure and bending, consisting of a device for loading the test pipe with a bend and a hydraulic system, the device for loading the test pipe with a bend contains a plate with supports, hydraulic cylinders, rods, support and load traverses with profiled lodges in contact with the test pipe characterized in that the hydraulic cylinders are pivotally mounted on the plate and by means of rods pivotally connected to load traverses.  2. The stand according to claim 1, characterized in that the supports are connected to the supporting traverses by means of elastic rods.  3. The stand according to claim 1 or 2, characterized in that it is equipped with a control system for a device for loading the test pipe by bending and a hydraulic system in the form of electronic equipment equipped with a computer.  4. A bench according to any one of claims 1 to 3, characterized in that the control system of the device for loading the test pipe by bending and the hydraulic system includes force sensors for measuring forces on the hydraulic cylinder rods, pressure sensors for measuring pressure in the tested pipe, displacement sensors for measuring displacements rods of hydraulic cylinders.  5. The hydraulic system of the bench for testing pipes with internal pressure and bending, consisting of circuits for supplying oil to hydraulic cylinders and the medium in the test pipe, characterized in that it contains a dual-circuit pressure transducer, one of the circuits of which is filled with water to create internal pressure in the test pipe, and the other with hydraulic oil to control the pressure transducer in conjunction with the hydraulic cylinders of the bending device for loading the pipe under test.  6. The system according to claim 5, characterized in that the low-pressure water pump for filling the test pipe and the primary circuit of the dual-circuit pressure transducer and a high-pressure pump for supplying hydraulic oil through the distribution valve block to the hydraulic cylinders of the test pipe loading device by bending and the second bypass circuit pressure transmitter. 7. The system according to claim 5 or 6, characterized in that the dual-circuit pressure transducer is made in the form of a hydraulic cylinder, consisting of two cavities - water and oil, with a single rod and two pistons, one in each cavity.