RU2438015C1 - Well surveying facility - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: well surveying facility includes product receiving line of the surveyed well and is equipped with pressure controls, pressure and temperature measurement devices, vertical gravitational separator for separation of gas from liquid. Gravitational separator is equipped with condensate and water extraction lines, as well as interconnected by means of pressure controls, automatic valves and check valves with condensate collector provided with liquid level gauges. Facility is also equipped with heat exchanger installed upstream of vertical gravitational separator. In addition, well surveying facility is equipped with high pressure gas supply line connected with small-size wave expansion machine. Compressor part of wave expansion machine is connected to heat exchanger installed downstream of vertical gravitational separator. In addition, heat exchanger is connected to heat exchanger the outlet of which is connected to gas extraction line to industrial chromatograph, and through the protection capacity of chromatograph with float liquid level sensor. At that, industrial chromatograph is connected to controller and personal computer.

EFFECT: improving accuracy and reliability of field gas-condensate well surveys owing to separation gas temperature reduction; excluding gas and condensate losses due to combustion on flames; considerable increase of scopes of surveys owing to reducing the labour intensity.

4 cl, 1 dwg

Description

The invention relates to the gas industry and can be used in conducting gas condensate research of wells in the process of developing gas condensate fields in order to determine their gas condensate characteristics by measuring in an automated mode the separation pressures, separation temperatures, barometric pressures, differential pressures on the measuring diaphragm, determining the component composition of the separation gas investigated wells and separation rates.

Known mobile separation unit U-900 for the study of gas condensate wells, including units for measuring gas flow, pressure and temperature, a heat exchanger, fluid collectors connected to separators [1].

A well-known installation for the study of gas condensate wells "Porta Test" company PORTA-TEST manufakturing LTD "(Canada) [2]. The installation includes a receiving line of gas condensate mixture, equipped with a shut-off valve and a pressure regulating valve. A series-mounted heater and a three-phase separator connected With gas, water and condensate drainage lines, as well as flow meters for the phases of the well’s production. to the required temperature stipulated by the research program. Next, the gas-liquid mixture is sent to the separator to separate the liquid phase from the gaseous. The test gas is sent to the vortex tube and then to the gas exhaust line, the gas flow rate of the separation is determined by the flow meter. At the bottom of the separator is a liquid storage, where There is a separation of water and condensate due to gravitational forces.The discharge of liquids in the drainage line of water and condensate is carried out with a simultaneous measurement of flow. The Porta-Test installation has a higher accuracy in determining the condensate content in the gas of separation of the investigated well compared to other well-known technical solutions of a similar purpose due to a more complete separation of the liquid phase from the gaseous and separate measurement of the volumes of water and liquid hydrocarbons.

The main disadvantage of these plants is that they are designed for research at the wellhead using the industrial production method with the separation of all the production of the well, and this is due to the burning of large quantities of gas and condensate in flares. In addition, they are cumbersome and research on them is associated with the great complexity of the work in connection with the need to perform them continuously for several days. These circumstances seriously limit their application in practice. In large fields, only 2-5% of the wells from the total stock are studied annually, and at some stages of field development, especially in conditions of industrial implementation of condensate enhancement technologies, it is necessary to conduct studies of the entire stock of wells, and for some wells, 2-4 times a year. In addition, it is necessary to take into account the fact that when conducting studies with a separation temperature above 10 ° C, reliable gas sampling is not provided due to the two-phase gas flow. This excludes the possibility of using them at a late stage of development, when, due to a decrease in reservoir pressure, high separation temperatures (more than 10 ° C) will be observed.

Known installation "separation small" for the study of gas condensate wells [3]. The installation contains a mixer, a heat exchanger, a gravity separator, a float level gauge for measuring condensate in a measuring cylinder.

The well-known "low-temperature condensate device NT-PKP-5" for the study of gas condensate wells, containing a pollution chipper, methanol tank, heat exchanger, thermostatically controlled condensate meters [4].

Both units are designed for field research by taking part of a gas-liquid stream using isokinetic probes, separating it into gas and liquid phases in a low-temperature separator, measuring gas separation and crude condensate, sampling and their chemical-analytical studies. In studies at these facilities, it is difficult to ensure, as well as verify the uniform distribution of the liquid phase over the flow cross section.

Therefore, Gazprom’s corporate regulatory documents do not recommend the implementation of field gas condensate studies using small-sized separation plants.

The closest to the claimed combination of essential features to the achieved result is the well-known installation for field research of gas condensate wells located at the gas treatment facility and including: a gas condensate mixture receiving line equipped with a shut-off valve and a control valve and connected to separators for separating gas from liquid , one of which is connected in series with a heat exchanger, as well as with degassing and stabilization tanks of hydrocarbons [5]. The disadvantage of this installation for researching wells is that in the process of developing gas condensate fields at a late stage at low reservoir pressures, the temperature of the separation gas at the outlet is more than 10 ° C, which leads to non-representative sampling of gas after separation and, as a result, does not allow reliable conduct gas condensate studies.

The technical task of the claimed solution is to ensure the required quality of field gas condensate field studies by reducing the temperature of the separation gas, eliminating gas and condensate losses from flaring, and significantly increasing the volume of research by reducing the complexity of the work.

The task in the installation for the study of wells, including the production line of the studied well, equipped with a pressure regulator, pressure measuring devices, temperature measuring devices, a vertical gravity separator for separating gas from the liquid, equipped with liquid level meters, is solved by the fact that the installation is additionally equipped a heat exchanger installed before the gravity separator, while the installation for researching wells is additionally equipped with a feed line and high-pressure gas connected to a small-sized wave expander, the compressor part of which is connected to a heat exchanger installed after the gravitational separator, the heat exchanger being additionally connected to a heat exchanger, the outlet of which is connected to a gas extraction line to an industrial chromatograph through a chromatograph protection tank with a liquid level float sensor while an industrial chromatograph is connected to the controller and a personal computer. The problem is also solved by the fact that the gas sampling line for an industrial chromatograph is equipped with a chromatographic analysis system for the separation gas, consisting of a probe, a chromatograph protection tank, and an industrial chromatograph.

The task is also solved by the fact that the output line of the vertical gravity separator is equipped with an intelligent separation gas pressure sensor, separation gas temperature sensor, differential pressure sensor on the measuring diaphragm.

The salient features of the claimed technical solution are:

- the installation is additionally equipped with a heat exchanger installed up to a vertical gravity separator;

- the installation is additionally equipped with a high pressure gas supply line connected to a small-sized wave expander, the compressor part of which is connected to a heat exchanger installed after the vertical gravity separator;

- the heat exchanger installed after the vertical gravity separator is additionally connected to the heat exchanger, the output of which is connected to the gas extraction line to the industrial chromatograph via a chromatograph protection tank with a float liquid level sensor, while the industrial chromatograph is connected to the controller and a personal computer;

- the gas sampling line for an industrial chromatograph is equipped with a probe;

- the gas sampling line for an industrial chromatograph is equipped with an intelligent gas temperature sensor for separation;

- the output line of the vertical gravity separator is equipped with an intelligent separation gas pressure sensor, a separation gas temperature sensor, a differential pressure sensor on the measuring diaphragm.

The claimed significant distinguishing features were not known to us from the patent and scientific and technical information and, therefore, meet the criterion of "novelty."

The claimed significant distinguishing features are not obvious to the average specialist in this industry, and were not found in the analysis of the technical level.

In connection with the foregoing, we believe that the claimed technical solution meets the criterion of "inventive step".

We justify the criterion of “industrial applicability” by the fact that almost all the components of the research facility — the wave expander, separator, condensate collector, heat exchangers, shutoff valves, connecting pipelines, chromatograph protection capacitance, valves, nozzle, level gauges, cables, and sampling lines — are produced by domestic industry.

The declared installation for researching wells is presented in the drawing.

The installation includes a production line for the products of the investigated well 1, equipped with pressure regulators 2, a device for measuring inlet pressure 3, a device for measuring inlet temperature (not shown), a heat exchanger 4 connected to a vertical gravity separator 5 for separating gas from the liquid. The heat exchanger 4 of the design "pipe in pipe" is designed to cool the test gas using gas cooled to minus 20 ° C entering the annulus of the heat exchanger 4. The vertical gravity separator 5 is equipped with liquid level meters 6, the output line 7 of the gravity separator 5 through the measuring diaphragm differential pressure 8, pressure regulators 9 connected to the annulus of the heat exchanger 10, the pipe part of which through the pressure regulator 11 is connected to the compressor part of small waves a new expander 12 for cooling the test gas. The lower part of the vertical gravity separator 5 is connected through a system of pressure regulators 13, valves 14, a non-return valve 15 to a condensate collector 16 equipped with liquid level meters 17 and connected to a high-pressure gas line (HPG) to transfer condensate through a system of pressure regulators 18, a non-return valve 19 into the tank for transferring liquid 20. In the upper part of the condensate collector 16, a gas vent line is provided for weathering 21 through the check valve 22 to the ejector. High-pressure gas (HPG) through a system of pressure regulators 23, diaphragm 24, fitting 25 enters the expander part 26 of a small-sized wave expander. The heat exchanger 10 is connected to the heat exchanger 27 for better transfer to the gaseous state of the droplet condensate in the event of its entrainment from the vertical gravity separator 5.

The outlet of the tubular part of the heat exchanger 27 is equipped with a gas sampling line to an industrial chromatograph 28 through a chromatograph protection vessel 29 with a liquid level float sensor 30, a gas sampling line is connected to an industrial chromatograph 31. The gas sampling line to an industrial chromatograph 31 is equipped with a probe 32 for representative sampling of the test sample and an intelligent temperature sensor 33, and is also connected via cable communication with the controller 34 and a personal computer 35. The output line of the vertical gravity separator 5 o naschena intelligent separation gas temperature sensor 36, the separation gas pressure sensor 37, differential pressure sensor 38 gas separation.

The work of the installation for well research is carried out in the following sequence. The products of the well under investigation enter the tube space of the heat exchanger 4, where it is cooled by the “cold”, to minus 20 ° С, gas entering the annulus of the heat exchanger 4 from the small-sized wave expander 12. After passing the heat exchanger 4, the cooled products of the well under investigation enter the vertical gravity separator 5, where it is divided into liquid and gaseous phases. The gaseous phase of the well’s production, having passed the measuring diaphragm of the differential pressure 8, enters the annulus of the heat exchanger 10, where it is heated by “hot” gas circulating along the closed circuit of the compressor part of the small-sized wave expander through the tube space of the heat exchanger 10, while the gas itself, passing the heat exchanger 10, cooled. This cooling is technologically necessary for the operation of a small-sized wave expander. After passing the heat exchanger 10, the warmed-up gaseous phase of the well production enters the pipe space of the heat exchanger 27, where it is additionally heated by gas from the inlet manifold entering the annular space of the heat exchanger 27. After passing the heat exchanger 27, the gaseous phase of the production of the studied well enters the gas pipeline. The necessity of installing a heat exchanger 27 in the research line was dictated by the fact that the test gas in the heat exchanger 10 was practically not heated. Its temperature increased by 2-5 ° C due to insignificant gas consumption (2-2.5 thousand m ³ / day according to the technical data of a small-sized wave expander) circulating in a closed circle of the compressor part. Therefore, another heat exchanger 27 was added to the installation for researching wells in a single-stage separation with cooling gas of wells using a small-sized wave expander, so that the test gas partially heated in the heat exchanger 10, entering the heat exchanger 27, was heated to higher temperatures (at 10 ° С and more) with an oncoming flow of “warm” gas coming from the inlet manifold. In the case of mechanical removal of condensate from a vertical gravity separator 5, the flow of the test gas when it is heated in heat exchangers 10 and 27 will be single-phase, since the phase liquid will evaporate into the gaseous phase. Therefore, on the gas supply line to the industrial chromatograph 28, a sampling of the separation gas is provided for its subsequent investigation after the heat exchanger 27.

The liquid phase released in the vertical gravity separator 5 (crude condensate and water) is measured by the accumulation time in a fixed volume of the vertical gravity separator 5 or condensate collector 16 using liquid level meters 6 and 17 installed in the body of the vertical gravity separator 5 and condensate collector 16. For for more accurate measurements of small amounts of water, a special tank E _zzh is _provided - a tank for measuring liquid (not shown). After measuring the water in the tank E _{, the} last one is discharged into the fluid collection manifold (CSF) (not shown).

On the condensate collector 16 also provides for the discharge of low-pressure gas to the ejector through the check valve 22 using automation. After the heat exchanger 27, the gas sampling line to the industrial chromatograph 28 is equipped with a probe 32 for sampling the separation gas from the middle of the stream for its subsequent analysis on the industrial chromatograph 31 in automatic mode.

The claimed technical solution in comparison with the prototype allows us to provide the necessary quality of research of gas and gas condensate wells by reducing the temperature of the separation gas, eliminating the loss of gas and condensate from flaring, a significant increase in the volume of research by reducing the complexity of the work.

Information sources

1. Instructions for the study of gas condensate fields for condensation. M .: Nedra, 1975.

2. Low-temperature mobile condensate device NT-PKP-5. Pavilion "Gas Industry" VDNH, USSR, M., 1969.

3. Korotaev Yu.P. and other exploitation of gas fields. M .: Nedra, 1975.

4. Gritsenko A.I., Aliev Z.S., Ermilov O.M., Remizov VV, Zotov G.A. Well Research Guide. M .: Nauka, 1995.

5. Dolgushin N.V., Gurlenov E.M. Technology of gas condensate research through gas treatment facility (for example, Vuktylskoye field). Collection of scientific works of VNIIGAZ, M., 1985, p.137-152.

Claims (4)

1. Installation for researching wells, including the production line of the studied well, is equipped with pressure regulators, devices for measuring pressure, temperature, a vertical gravity separator for separating gas from liquid, equipped with condensate and water extraction lines, and also communicated using pressure regulators, automated valves, check valves with a condensate tank equipped with liquid level meters, characterized in that the installation is additionally equipped with a heat exchanger, tuned to a vertical gravity separator, while the well study is additionally equipped with a high-pressure gas supply line connected to a small-sized wave expander, the compressor part of which is connected to a heat exchanger installed after the vertical gravity separator, and the heat exchanger is additionally connected to a heat exchanger, the output of which is connected to gas sampling line to an industrial chromatograph, through a chromatograph protection tank with a float level sensor liquid, while an industrial chromatograph is connected to the controller and a personal computer. 2. Installation for researching wells according to claim 1, characterized in that the gas sampling line for an industrial chromatograph is equipped with a chromatographic analysis system for separation gas, consisting of a probe, a chromatograph protection tank, and an industrial chromatograph. 3. Installation for researching wells according to claim 1, characterized in that the gas sampling line to an industrial chromatograph is equipped with an intelligent sensor for separating gas temperature. 4. Installation for researching wells according to claim 1, characterized in that the output line of the vertical gravity separator is equipped with an intelligent separation gas pressure sensor, a separation gas temperature sensor, a differential pressure sensor on the measuring diaphragm.

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