SU1404858A1 - Device for testing pipe joints for leak-proofness at temperature effects - Google Patents

Abstract

The invention relates to devices for monitoring the tightness of pipe joints and allows for independent adjustment of temperature and force effects. The cylindrical cryo-thermocamera 1 has a partition 22, which divides it into two coaxial cavities 2 and 5. A coolant is supplied to the external cavity 2. In the inner cavity 5 there is a loader, made in the form of a cup 9 with thermal insulation 10 and a heater 11. The pipe with the test joints 8 is fixed on the outside of the cup 9 by means of ring stops 13 placed in the upper part of the cup 9 and on its bottom. The test tube is cooled through a heat-conducting element, which can be made in the form of a fraction 6. Selecting the material of the tenlo-conductive element, control the cooling rate. The load temperature determines the tensile force. 2 h. item f-ly, 1 ill.

Description

YU

Nj

О 4 ОО 01

OO

9 20

The invention relates to a testing technique, in particular, to devices for monitoring all-in-one pipe joints under the combined effect of temperature and tensile forces.

The aim of the invention is to expand the operational capabilities by providing independent adjustment of temperature and force effects.

The drawing shows a diagram of a device for testing pipe joints for leak tightness at temperature effects.

The device contains a cryo-thermocamera 1, the external cavity 2 of which is connected by a pipe 3 to a source of coolant (not shown), and a pipe 4 to a drain line (not shown). In its internal cavity 5 a heat-conducting element is installed in the form of fine heat-conducting shot 6, encompasses, she shell 7 with the test subjects placed between her cup 9 and shell 7, through pipe 15 to the leak detector, for example, helium. The indicator gas from an external source is fed into the internal cavity 5 of the heat chamber 1 through the nozzle 16 and discharged through the nozzle 17 into the drainage main. At the same time, the tightness of the tested compounds is preliminarily monitored, then refrigerant 10 from an external source is fed into the internal cavity 2 of the cryothermal chamber through pipe 3 and discharged through pipe 4 to the drain line.

The refrigerant is supplied continuously during static tests or alternately with hot air during cyclic tests. In this case, the temperature of the tested compounds 8 changes at a given speed to a given temperature during heat transfer through heat-conducting fraction 6 with tracer gas in the gaps, performing the functions of a thermal bridge.

15

thirty

8, as well as a loader in the form of 20 The resulting temperature deformations of a rigid glass 9, on the outer surface of which thermal insulation 10 is fixed, having a heater 11 inside. The hard glass 9 is located inside the shell 7 and, thanks to the bottom 12 and the ring lugs 13, forms a gap 14 connected by a nozzle 15 to a leak detector (not shown), and the internal cavity 5 is connected by a nozzle 16 to an indicator gas source (not shown) and a nozzle 17 to a drain line (not shown). The heater 11 is connected to an external power supply system (not shown) through a pressure input 18. Covers 19 and 20 are coaxially mounted on the walls of the cavity 5 and the cryo-thermocamera 1. The cryo-thermal chamber 1 is mounted on the ring stops 13 by means of a sealed plug flange 21 and has a partition 22, dividing it into cavities 2 and 5.

The device works as follows.

The test connections 8 are made on the shell 7, for example, by welding, and attached around the perimeter also by welding to the annular stops 13 of the cup 9. By means of a sealed detachable flange connection 21, the cryothercamera 1 is attached to the cup 9 after its removal covers 19 and 20

The shells 7 through the annular stops 13 are completely perceived by the rigid glass 9, the thermally insulated cavity 14 and the insulation 10. As a result, the necessary power voltages arise in the tested 25 compounds, the functions of which are performed by the glass 9, having an adequate margin of rigidity and stability. These voltages, controlled, for example, by strain gauges mounted on a glass, are increased if necessary by increasing the length of the glass 9 by heating it with a heater 11 or decreasing by decreasing the length of the glass 9 by cooling it, for example, by filling it with the required amount of refrigerant. Alternately cooling and heating the cup 9, create cyclic power voltages in the tested compounds 8, independent of their test temperature conditions. At the same time, the tightness of the joints 8 is continuously monitored.

The use of a rigid cup 9 as a load bar allows you to create a predetermined force loading of the tested compounds during long test cycles without the use of a testing machine. Cup 9 performs function35

40

they are filled with fine heat-conducting hard pulling, perceived by a temper of such a fraction that provides the specified cooling speed and temperature of the tested compounds, for example, in the form of copper balls with a diameter of 0.2-0.5 mm.

When the inner cavity 5 is filled, some of its volume is left free to ensure free flow of shot 6 during the test, for example, during shaking, of the device, in order to eliminate the possible overlap of defects in the test compounds. Sealing the caps 19 and 20 in the initial position, connect the gap 14 formed

50

Regional deformations of the tested compounds. Its own temperature distortions are also used to create loading forces. When the cup 9 is filled with the required amount of refrigerant, its length is reduced, and additional power stresses arise in the heated compounds under test 8, to which the deformation of the cup 9 is transferred.

Thermal insulation 10 on the outer surface of the loading cup 9 excludes heat exchange with the test compounds 8 surrounding it, which are at the test temperature. Owing to this, a glass 9 and a shell 7 will be sedimentary, through the pipe 15 to the leak detector, for example, helium one. The indicator gas from an external source is fed into the internal cavity 5 of the heat chamber 1 through the nozzle 16 and discharged through the nozzle 17 into the drainage main. At the same time, the tightness of the tested compounds is preliminarily monitored, then refrigerant 0 from an external source is fed into the internal cavity 2 of the cryothermal chamber through pipe 3 and discharged through pipe 4 to the drain line.

The refrigerant is supplied continuously during static tests or alternately with hot air during cyclic tests. In this case, the temperature of the tested compounds 8 changes at a given speed to a given temperature during heat transfer through heat-conducting fraction 6 with tracer gas in the gaps, performing the functions of a thermal bridge.

five

0 Emerging temperature deformations

thermal deformations

The cages 7 through the ring stops 13 are completely perceived by the rigid glass 9, the insulated cavity 14 and the insulation 10. As a result, the necessary power voltages arise in the test joints, the functions of which are performed by the glass 9, having an adequate margin of rigidity and stability. These voltages, controlled, for example, by strain gauges mounted on a glass, are increased if necessary by increasing the length of the glass 9 by heating it with a heater 11 or decreasing by decreasing the length of the glass 9 by cooling it, for example, by filling it with the required amount of refrigerant. Alternately cooling and heating the cup 9, create cyclic power voltages in the tested compounds 8, independent of their test temperature conditions. At the same time, the tightness of the joints 8 is continuously monitored.

The use of a rigid cup 9 as a load bar allows you to create a predetermined force loading of the tested compounds during long test cycles without the use of a testing machine. Cup 9 performs the function

hard ti gi perceptions

Regional deformations of the tested compounds. Its own temperature distortions are also used to create loading forces. When the cup 9 is filled with the required amount of refrigerant, its length is reduced, and additional power stresses arise in the heated compounds under test 8, to which the deformation of the cup 9 is transferred.

Thermal insulation 10 on the external surface of the loading cup 9 excludes heat exchange with the test compounds 8 surrounding it, which are at the test temperature. Due to this, power vapor is carried out; connection 8 is independent of their thermal conditions.

The heater 11 inside the heat insulator 10 allows to heat the loading glass 9 and thereby regulate the voltages in the test compounds 8 by changing the length of the glass 9 clamped by the shell 7 with the connections 8. The location of the hard glass 9 inside both gulls 7 with the test connections 8 provides a compactness of the device and simplifies assembly and disassembly operations associated with the installation and removal of the shell 7.

The connection of the cavity 5 between the loading cup and the shell to the leak detector makes it possible to monitor the tightness of the tested compounds 8 continuously while regulating the temperature and force effects during the testing process. The vacuum created in the cavity provides additional heat insulation for the loading cup 9.

The fine heat-conducting fraction 6 of a given fraction, filling the cavity 5 of the cryothermocamera 1, performs the functions of a thermal bridge and provides the necessary heat transfer conditions between the cryo-thermal chamber 1 and the tested compounds 7 in order to provide the necessary rate of change in the temperature of the compounds and the temperature limit reached. Regulation of the cooling rate of test compounds 8 is provided by changing the fraction of heat-conducting shot 6 used. Cooling compounds 8 through fraction 6 excludes direct contact with the refrigerant, which is a necessary condition for testing without thermal shock of a number of compounds, for example, metal-ceramic. Insulating test compounds 8 from atmospheric air also improves the quality of testing by eliminating leakage from atmospheric moisture. Connecting the cavity 5 of the cryothermocamera 1 filled with shotgun 6 to the indicator gas source allows creating an indicator medium around the tested compounds 8 and monitoring their tightness

0

continuously throughout the cycle of test and temperature effects.

The device allows testing of compounds 8 at high temperatures, for which instead of the refrigerant into the cavity of the cryo-thermocamera 1, hot air is supplied continuously or cyclically in combination with cooling.

The use of the invention makes it possible to improve the quality of the leaktightness test of various compounds of structural elements in the process of working out technical solutions, as well as in the manufacture of compounds and in the course of routine maintenance.

Claims (3)

1. A device for testing pipe joints for leak tightness at temperature effects, containing a cylindrical cryo-thermocamera with a partition partitioning 0 it into two coaxial cavities, a source of thermal agent connected to the external cavity, a heat-conducting element, made in the form of a hollow cylinder in contact with the partition, a loading device. The annular stops located on the butt-chamber of the chamber and the connecting rod tying them, and the leak detector, are installed in the butt-chamber. characterized in that, in order to expand the operational capabilities by providing independent adjustment of temperature and power effects, the ha is made in the form of a glass and installed on its outer surface of the heater and heat insulation, located inside the heat-conducting E. 1msite n placed coaxially with a gap of h of the test compound. 2. The device according to claim 1, characterized in that it is provided with a source of test gas connected to a gas-permeable heat-conducting element, and a leak detector is connected to the cavity of the gap between the thermal insulation 0 and heat-conducting element. 3. The device according to claim 1, characterized in that the heat-conducting element is made in the form of a fine fraction.