RU2201503C2 - Gear to investigate formation fluids - Google Patents

Abstract

FIELD: oil and gas industry. SUBSTANCE: gear can be employed to take samples across well-head and from oil and gas pipe-lines, to study physical properties of well-head and formation fluids, to determine pressure-to-temperature ratio and to establish content of free water in taken sample of hydrocarbon fluid. Technical result of invention lies in provision for selection of representative sample of formation fluid from well-head equipment not allowing violation of relations of phases and of their phase state, in analysis of these relations without transfer into special hardware, in examination of deep samples of formation fluids after their transfer from samplers into given gear. Proposed gear includes measurement high-pressure chamber with lower and upper covers fitted with gland assembly and shut-off valves installed in thermostatting enclosure with distribution unit and manometer. Measurement high-pressure chamber houses separating piston with hydraulic drive carrying meter in the form of scale with limb anchored on rod and mechanical drive coming in the form of screw with nut for rod displacement. Body of separating piston houses mixer made in the form of rod passing through gland assembly, collapsing spring linked to separating piston, drive implemented with cooler of gland assembly in the form of water jacket and electric motor with variable rotational speed tied up to rod. Upper cover of measurement highpressure chamber carries electronic temperature and pressure transducers which are connected through shut-off valves to computer. Slide-wire which current collecting part is connected to limb of meter is placed in parallel to meter on lower cover of measurement high- pressure chamber. Lower end of separating piston has through hole and rod of hydraulic drive is attached to piston through rubber seal. EFFECT: provision for taking representative samples of formation fluids without violation of relations of phases and their phase state. 1 dwg

Description

 The invention relates to the oil and gas industry and can be used for sampling at the wellhead and oil and gas pipelines and to study the physical properties of wellhead and formation fluids and to determine pressure-temperature ratios (PVT), as well as to determine the free water content in a selected sample of a hydrocarbon fluid.

 A device for studying formation fluids is known, including a high-pressure measuring chamber with a distribution unit and a pressure gauge and placed in a thermostatically controlled casing, while in the measuring chamber there is a dividing piston with a hydraulic actuator, in which the meter is made in the form of a scale with a limb and a mechanical actuator for moving the rod in in the form of a screw with a nut [1].

 The disadvantage of the device for the study of reservoir fluids, taken as a prototype, is the inability to study high viscosity oils due to insufficient mixing of the known device with a ball, as well as ensuring the selection of a representative sample of reservoir fluid from the wellhead equipment, avoiding the violation of the phase ratio and their phase state.

 The objective of the invention is to ensure the selection of a representative sample of reservoir fluid from the wellhead equipment, avoiding violation of the phase ratio and their phase state, as well as the study of these ratios without subsequent transfer to special equipment and the study of deep samples of reservoir fluids after transferring them from samplers to this device.

 The task in the device for the study of reservoir fluids, including a high-pressure measuring chamber with a lower and upper cover, equipped with a gland unit and shut-off valves, installed in a thermostatic casing with a separation unit and a pressure gauge, a separation piston with a hydraulic actuator located in the high-pressure measuring chamber, in which a meter is placed in the form of a scale with a limb fixed on the rod, and a mechanical drive made in the form of a screw with a nut to move the rod, t m, that the separation piston is additionally equipped with a stirrer located in its housing, made in the form of a rod passing through the stuffing box, a folding spring connected to the separation piston, a drive made with cooling of the stuffing box in the form of a water jacket, and connected with a variable-speed electric motor rod number of revolutions. Electronic pressure and temperature sensors are installed on the top cover of the measuring chamber and connected through a corresponding shut-off valve to a computer; a rechord is installed on the bottom cover of the measuring chamber in parallel with the meter, the current-collecting part of which is connected to the meter’s dial, and the lower end of the separation piston is provided with a through hole to which the hydraulic stem is connected through a rubber seal.

Distinctive, essential features of the claimed invention
The separation piston is additionally equipped with a stirrer located in its housing, made in the form of a rod passing through the stuffing box.

 The folding spring is connected to the separation piston.

 The lower end of the separation piston is made with a through hole to which a hydraulic actuator rod is connected through a rubber seal.

 The drive is made with cooling of the stuffing box in the form of a water jacket.

 The drive is connected to a variable speed motor rod.

 A rechord is installed on the top cover of the measuring chamber, the collector part of which is connected to the meter limb.

 The above essential, distinctive features were not known to us from the patent and scientific and technical information and in this regard meet the criterion of "novelty."

 The claimed invention is not obvious to the average person skilled in the art and, therefore, meets the criterion of "inventive step".

 In addition, the claimed invention has successfully passed field trials and therefore meets the criterion of "industrial applicability".

 The drawing shows a diagram of a device for the study of reservoir fluids, where the measuring chamber 1 is placed in a thermostatic casing 2 with a thermocouple and a control thermometer (not shown).

 The top cover 3 of the measuring chamber 1 is equipped with shut-off needle valves 4 and 5, an stuffing box consisting of a rubber-fluoroplastic seal 6, granbuks 7 and a nut 8, through which the rod of the mixer 9 passes, and a folding spring 10.

 The stuffing box is cooled during operation by a water jacket 11. The stirrer rod 9 is connected through a rubber-metal coupling 12 to a variable-speed electric motor 13. A folding spring 10 is connected to the separation piston 17 by means of a screw 14, rivets 15 and washer 16. The lower end of the separation piston 17 made with a through hole to which a hydraulic actuator rod 19 with an internal hole of ⌀ 2 mm is connected through a rubber seal 18. The lower cover 20 of the measuring chamber 1 is equipped with a rubber-fluoroplastic gasket 21 through which the hydraulic actuator rod 19 passes and a needle shut-off valve 22. A meter 23 is installed on the lower cover 20, the limb of which is fixed to the hydraulic actuator rod 19. In parallel with the meter 23, the lower chamber of the measuring chamber 1 is installed reochord 24, the collector part 25 of which is connected to the meter dial 23. At the lower end of the hydraulic actuator rod 19, a shut-off valve 26 is installed through a detachable connection 27, which is sealed with a nuts 28. A mechanical drive is installed in the lower part of the hydraulic actuator rod 19, made in the form of a screw with a nut 29. The body 30 of the thermostatic casing 2 is connected to it by a screw 31 and at the same time is a tripod of the device.

 The pressure value is counted according to the exemplary pressure gauge 32, which is mounted on the top cover 3 of the measuring chamber 1 through the valve 5. On the same valve 5, an electronic pressure sensor is installed, which is connected to a computer (not shown). The temperature value is taken from a thermometer (not shown) and an electronic temperature sensor 33 mounted on the top cover 3 of the measuring chamber 1, which is also connected to a computer (not shown).

 The volume measurement is read on a linear scale and the dial of the meter 23 located on the hydraulic actuator rod 19, as well as on a computer (not shown) to which the reochord 24 is connected. The separation piston 17 is controlled hydraulically through the nozzle 34 and the shut-off valve 22.

Device operation
In the study, the device shown in the drawing is installed in a thermostatic casing 2 on a rack 35 with a rotary assembly 36 through a detachable connection 37. A manual or mechanical hydraulic pump 38 with an oil tank 39, the level of which is controlled using a measuring ruler with a float, is installed on the rack 35 40.

 Thermostating of the measuring chamber 1 is carried out using a liquid ultra-thermostat 41 serial production. Mixing of the sample is carried out using a folding spring 10. The temperature of the sample is controlled by a thermometer (not shown) on the thermostat 41 and an electronic temperature sensor 33, built into the top cover of the measuring chamber 1.

 The pressure is measured using an exemplary pressure gauge 32 and an integrated electronic pressure sensor (not shown) through the shut-off valve 5. Before starting the sample, the separation piston 17 is set to its highest position using the hydraulic pump 38, the distribution valve 42 and the shut-off valve 22. Under the dividing piston 17, a pressure is set 10% higher than the pressure at which the sample is taken, after which the control valve 42 is closed. The pressure under the piston is controlled by a pressure gauge 43. The test sample through the shut-off valve 4 is introduced into the displaced volume of the measuring chamber 1 and the connecting line and washed with a triple displaced sample volume through the shut-off valve 26 at the sampling pressure.

 After washing, the shut-off valve 26 is closed, the distribution valve 42 is opened, and at the sampling pressure controlled by the pressure gauge 32 and the pressure gauge 43 of the measuring chamber 1, the sample is filled. After sedimentation of the sample and separation of water from oil, water is removed through the shutoff valve 26, maintaining the sampling pressure in the measuring chamber 1 by the hydraulic pump 38 through the shutoff valve 22. The operation is repeated if necessary.

 In the case of a high content of bound water in oil, a demulsifier is added through a shut-off valve 4 to the measuring chamber 1 through a shut-off valve 4, the sample is mixed with a folding spring 10 and settled, after which the water is removed through the shut-off valve 26 while maintaining the sampling pressure in the chamber. The sample is thermostated by means of a thermostatic casing 2 to the reservoir temperature or the sampling temperature. The reservoir pressure or sampling pressure in the measuring chamber 1 is set by a hydraulic pump 38 through a distribution valve 42 and a shut-off valve 22 with the shut-off valve 4 closed by a pressure gauge 32. The pressure is stabilized by bringing the sample into a single-phase state by stirring it with a folding spring 10 while cooling the rubber-fluoroplastic seal 6 with a water jacket eleven.

After the PVT is brought to reservoir conditions, a high pressure pycnometer (not shown) for measuring the oil density and a high pressure viscometer (not shown) for measuring the oil viscosity are connected to the shutoff valve 26. The reservoir pressure or the sampling pressure in the chamber is maintained by a hydraulic pump 38 through a distribution valve 42. The PVT ratio at the reservoir temperature, sampling temperature and normal (20 ^° C) temperature is studied by repeatedly compressing or expanding the sample volume by increasing or decreasing the pressure in the measuring chamber 1 high pressure.

 The volume measurement is considered on the linear scale of the meter 23 and its dial with an accuracy of hundredths and thousandths of a millimeter. An electric signal from reochord 24 is sent to a computer (not shown), where the dependences of the PVT ratios, compressibility coefficient, temperature coefficients, and gas saturation pressure are obtained.

 At low operating pressures, for example, during sample degassing, comparable with the friction forces of the moving part of the device’s hydraulic system, the PVT ratios are studied by a mechanical drive 29.

 The measurement of the viscosity of high-viscosity oils is carried out by measuring the differential pressure on a pressure gauge 32 and a pressure gauge connected through a manifold to a shut-off valve 26 (not shown).

 The density of oil is also determined by the results of standard oil separation according to the generally accepted method. The reference volume of oil is taken on a scale meter 23.

 The claimed device for fluid research allows, in comparison with the prototype, to study the parameters of density, viscosity, PVT ratios, water content, gas content of high-viscosity oils (non-Newtonian fluids) due to intensive forced mixing of the sample at pressures up to 80 MPa.

 This device can be used as a selection tool and a measuring tool at the same time and, in addition, it allows the processing of measurement results automatically on a personal computer, since it is equipped with electronic sensors for measuring pressure and temperature.

Sources of information taken into account
1. RF patent 2127363 IPC E 21 V 49/00. Publ. 03/10/99, prototype.

Claims (1)

 A device for studying reservoir fluids, including a high-pressure measuring chamber with a lower and upper cover, equipped with an stuffing box and shut-off valves, installed in a thermostatic casing with a distribution unit and a pressure gauge, a dividing piston with a hydraulic actuator located in the high-pressure measuring chamber, in which the meter is located in in the form of a scale with a limb mounted on the rod, and a mechanical drive made in the form of a screw with a nut to move the rod, characterized in that it is stripped The integral piston is additionally equipped with a stirrer located in its housing, made in the form of a rod passing through the stuffing box, a folding spring connected to the separation piston, a drive made with cooling of the stuffing box in the form of a water jacket, and connected to a rod of a variable speed motor, electronic pressure and temperature sensors are installed on the top cover of the measuring chamber and are connected through a corresponding shut-off valve to a computer, parallel to the meter on the bottom The rechord is installed on the measuring chamber lid, the collector part of which is connected to the meter’s dial, the lower end of the separation piston having a through hole, to which the hydraulic actuator rod is connected through a rubber seal.