RU162335U1 - STAND FOR THERMAL DRUG TESTS OF WELL-WELL DEVICES - Google Patents

Abstract

1. Stand for thermal testing of downhole tools, comprising a test chamber with three pipelines, two valves connected through pipelines to the test chamber, and a pressure sensor, characterized in that four valves, a compressor, a separation vessel, a booster pump, a water tank are introduced into it , installation of a hydraulic pump and an alarm and automatic control unit for controlled parameters, temperature sensors, heating elements, a lifting device and support for the swing element, moreover, in the body temperature sensors are placed on the test chamber, and heating elements are located on its surface, the test chamber is placed in a blown insulated casing, is equipped with a swing element and is placed on a support for the swing element, a lifting device is placed under the front end of the test chamber, the pressure sensor is connected to the output of the second valve, to which the pumping unit is connected via a fourth valve and a separation vessel, through a fifth valve - a water tank inlet, through a sixth valve - cc of the water tank through the booster pump, a compressor is connected to the third pipeline through the third valve, the outputs of the temperature and pressure sensors are connected to the inputs of the alarm unit and automatic control of the controlled parameters, and the heating elements are connected to its outputs, the second output of the alarm unit and the automatic control of the controlled parameters connected to the emergency stop input of the hydraulic pumping unit. 2. A stand for thermal bar tests of downhole tools according to claim 1, characterized in that they are thermally insulated

Description

The utility model relates to systems for hydraulic and thermal testing of downhole tools designed to control downhole parameters during well drilling.

Known heat chamber of a metrological installation for simultaneous calibration of temperature and pressure channels of complex downhole equipment, the body of the heat chamber is made of stainless steel with thermal insulation on the outside, the reference thermometer is located in the calibration zone of the heat chamber located in its upper cavity, in the immediate vicinity of the sensors of thermometers of calibrated downhole tools heaters are located in the lower part of the annular heat chamber as far as possible from the temperature measurement zone , the reference pressure gauge provides a high-pressure line through the tubes directly to the channels of the pressure gauges of downhole tools (RF Patent for invention No. 2306534 IPC G01K15 / 00, priority 23.05.2005).

However, it does not allow hydraulic testing of downhole tools.

A known pressure chamber containing a thermally insulated cylindrical body, a casing located inside it, forming an internal test compartment, an air cavity between the inner surface of the casing and the casing, as well as air inlet and outlet pipes, the casing is made in the form of adjacent to each other and alternately located throughout the length of the pressure chamber of two groups of belts, which consist of an equal number of segment-shaped links attached to the inner surface of the housing and forming in combination with it znye communicating cavities oriented in one group of belts parallel to the axis thermal vacuum chamber, and the other group of belts - on circumference of the cylindrical body (USSR Author's Certificate for invention №699417 IPC G01N 29/00, priority 10.12.1977 F25D 13/00).

However, it does not allow testing of downhole tools at elevated pressures.

The closest in technical essence to the proposed technical solution is a stand for hydraulic testing of downhole equipment (utility model of the Russian Federation 35899 IPC G01R 31/02 priority 07/22/2002), containing a test chamber, a fluid supply and discharge system, a pressure generation system and sensors for diagnosed parameters, including a pressure sensor, the pressure generation system is made in the form of a cylinder with a piston, the cavity of which is hydraulically connected to the cavity of the test chamber, and a screw connected to the piston.

However, this stand does not allow hydraulic testing of downhole tools at pressures exceeding several tens of atmospheres.

The objective of the utility model is to expand the pressure range during hydraulic testing of downhole equipment and increase the operational properties of the bench.

The problem is solved due to the fact that the stand for thermal testing of borehole equipment contains a test chamber in a blown heat-insulated casing with a swing element and a lifting device, temperature sensors are located in the body of the test chamber, and on its surface there are sections of heating elements, a support for the swing element, six valves, a compressor, a separation vessel, a booster pump, a water tank, a hydraulic pump unit, an alarm and automatic control unit are controlled parameters and a pressure sensor, the first and second valves are connected through pipelines to the test chamber, the pressure sensor is connected to the output of the second valve, which is also connected through the fourth valve and the separation vessel to the pumping unit, through the fifth valve - the inlet of the tank with water, through the sixth valve - the release of the water tank through the booster pump, a compressor is connected to the third pipeline through the third valve, the outputs of the temperature sensors and the pressure sensor are connected to the inputs of the alarm unit and the machine control of the controlled parameters, and the heating elements with its outputs, the second output is connected to the input of the hydraulic pump unit.

The heat-insulated casing is made sectional of sandwich panels and placed on belts of segment-shaped links connected by a flexible heat-resistant tape.

The essence of the utility model is illustrated in the drawings of FIG. 1-4.

In FIG. 1 shows a general diagram of the stand, in FIG. 2 is a block diagram of a control unit; FIG. 3 - design of a separation vessel, in FIG. 4 - connection of the test chamber and the heat-insulated casing.

The stand contains a support for the swing element 1, a test chamber 2 with a shutter 3 in a thermally insulated casing 4, a lifting device 5, temperature sensors 6, heating elements 7, couplings 8 for air circulation under the thermally insulated casing, the first, second, and third pipelines, respectively, 9- 11, the information bus of the temperature sensors 12, the control bus of the heating elements 13, the control unit 14, the first, second, third, fourth, fifth and sixth valves, respectively, 15-20, the compressor 21, the alarm unit and automatic control Hovhan controlled parameters 22, pressure sensor 23, separation vessel 24, the hydraulic pump unit 25, booster pump 26, the container 27 with water.

The separation vessel 24 provides the transfer of oil pressure to the water and back by moving in a cylindrical cavity inside the housing 28 of the built-in piston 29 with a sealing ring. The cavity 30 is filled with water, the cavity 31 with oil. The supply of oil and water to the separation vessel is carried out respectively through fittings 32 and 33.

The connection of the test chamber 2 and the insulated casing 4 is carried out using segmented links 34 connected by a flexible heat-resistant tape 35.

The work of the stand is as follows. The valves 15-20 are initially in the closed position. The downhole tool is loaded into the test chamber 2, the working space of the test chamber 2 is sealed with the shutter 3. Using the lifting device 6, the test chamber 2 is brought into an inclined position. Open the first 15, second 16, fourth 18 and sixth 20 valves, start the pump 26, while the working space of the test chamber 2 through the pipe 11 is filled with water from the tank 27, displacing the air from the working space of the test chamber 2 through the pipe 9. At the same time it is filled with water the working space of the separation vessel 24. After all air has been expelled from the working space of the test chamber 2, the first valve 15 is closed, using the lifting device 4, the test chamber 2 is driven t in a horizontal position, the pressure rises to the limit values of the booster pump 26 (approximately 100 kg / cm ² ). The sixth valve 20 is closed to protect the booster pump 26 from overpressure. The hydraulic pumping unit 25 is started, the increase in oil pressure in the installation is transmitted by means of a piston 29 located in the separation vessel 24 to the water located in the working space of the test chamber 2. After reaching the set test pressure, the hydraulic pumping unit 25 is turned off. The pressure in the working space of the test chamber 2 is controlled by a pressure sensor 23. In emergency situations (depressurization or bursting of protective covers), a pressure drop is recorded by the pressure sensor 23, in which case the alarm and automatic control unit for the controlled parameters 22 generates a control signal for emergency stop of the pump hydraulic 22 and turns off the heating elements 7. After the end of the test, the control elements of the pump hydraulic installation 25 there is a pressure relief, the piston 29 of the separation vessel 24 returns to its original state, the fifth valve 19 opens, the pressure is released to atmospheric and part of the water is drained into the water tank 27. The third valve 17 opens, the compressor 21 is turned on, freeing the working space of the test chamber 2 from residual water through the pipe 11. After releasing the working space of the test chamber 2 from water, the third valve 17 closes and the second valve 15 opens to relieve excess air pressure. The shutter 3 opens and the downhole tool is removed from the working space of the test chamber 2.

Heating of the test chamber and the water inside it can be performed automatically if necessary at any stage of the tests in accordance with the program embedded in the alarm and automatic control unit for the monitored parameters 22. In this case, the temperature is controlled by several temperature sensors 6, and heating is carried out heating elements 7. Cooling and uniformity of heating are provided by air circulation inside the heat-insulated casing 4 through couplings 8, placed on Counterface its sides.

The signaling and automatic control unit for the monitored parameters 22 can be performed on the basis of the TM-5103 () multi-channel temperature meter with power switches at the control outputs.

The hydraulic pumping units currently installed (UNGR) allow creating pressures in the working space of up to 3000 kg / cm ² (), which significantly exceeds the pressure in the wells currently being drilled.

The use of a water tank allows to add additives to the water, allowing to exclude corrosion of downhole tools and pipelines.

When testing stand-alone downhole tools, the recorded parameters are stored in the internal memory and after removing the downhole tool are read using the appropriate registration units.

Application of the utility model allows:

1. To expand the pressure range during hydraulic testing of downhole equipment through the use of a hydraulic pumping unit.

2. To increase the operational properties of the bench by using the horizontal position of the test chamber.

3. To test the strength of the protective shells and shells of the downhole equipment.

4. To bring the test conditions closer to the actual ones for the downhole equipment during the drilling process.

5. To verify the operability of downhole tools and monitor the change in their characteristics at elevated pressure and elevated temperature.

Claims (2)

1. Stand for thermal testing of downhole tools, comprising a test chamber with three pipelines, two valves connected through pipelines to the test chamber, and a pressure sensor, characterized in that four valves, a compressor, a separation vessel, a booster pump, a water tank are introduced into it , installation of a hydraulic pump and an alarm and automatic control unit for controlled parameters, temperature sensors, heating elements, a lifting device and support for the swing element, moreover, in the body temperature sensors are placed on the test chamber, and heating elements are located on its surface, the test chamber is placed in a blown insulated casing, is equipped with a swing element and is placed on a support for the swing element, a lifting device is placed under the front end of the test chamber, the pressure sensor is connected to the output of the second valve, to which the pumping unit is connected via a fourth valve and a separation vessel, through a fifth valve - a water tank inlet, through a sixth valve - cc of the water tank through the booster pump, a compressor is connected to the third pipeline through the third valve, the outputs of the temperature and pressure sensors are connected to the inputs of the alarm unit and automatic control of the controlled parameters, and the heating elements are connected to its outputs, the second output of the alarm unit and the automatic control of the controlled parameters connected to the emergency stop input of the hydraulic pump unit. 2. A stand for thermal bar testing of downhole tools according to claim 1, characterized in that the insulated casing is made sectional of sandwich panels and placed on belts made of segment-shaped links connected by a flexible heat-resistant tape.

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