RU2532050C2 - Gas and gas condensate well analysis unit - Google Patents

Abstract

FIELD: oil-and-gas industry.

SUBSTANCE: invention relates to analysis of gas and gas condensate deposits under various operating conditions. Proposed unit comprises gas-fluid mix separator and the device that follow: restrictor, separation product meter, pressure, temperature, gas flow and impurities meters and shutoff valves. This unit is arranged in carcass sized to carriers. Note here that separators and above mentioned devices are connected by pipes and include additional supersonic separator. Gas-fluid mix separator outlet is connected with supersonic separator outlet(s) while its purified gas outlet is connected with gas-fluid mix separator or purified gas discharge pipe.

EFFECT: decreased weight and sizes, accelerated preparation for measurements.

6 cl, 2 dwg

Description

The invention relates to the field of gas engineering, in particular to devices for the study of gas and gas condensate fields in different technological modes.

A well-known installation for researching wells (patent No. 2070965, IPC 6 ЕВВ 47/00, ЕВВ 43/24 - analogue), including separators for separating liquids and solids from gas, nodes for measuring gas flow, pressure and temperature, recuperative heat exchangers and vortex cooling chambers gas, low pressure gas compression ejectors.

The disadvantages of this installation are:

- the presence of a large number of units of technological equipment;

- significant metal consumption;

- significant dimensions;

- not transportability, especially for increased gas production (mln. m ³ per day or more);

- the inability to perform in a mobile version.

A device for the study of gas and gas condensate wells (RF patent No. 2070289, IPC 6 ЕВВ 47/00 - prototype), including gas cleaning units (centrifugal separation and filtration) installed in the housing, gas flow meter with diaphragm, pressure and temperature measuring units, an outlet pipe, in which the disadvantages of the analogue are partially eliminated, namely, the number of units of technological equipment is reduced, therefore, the metal consumption is reduced and installation and dismantling of the device is facilitated.

However, the overall length of the device has been increased due to the longitudinal sequential arrangement of inlet nodes, which are a continuation of the gas pipeline, which complicates the transportation of such a device and excludes the possibility of assembly on a car trailer or road transport, that is, eliminates the possibility of the device being performed in a mobile version, especially for higher industrial capacities (mln. m ^{3 of} gas per day, as it requires dismantling by flange connectors). Another disadvantage of this device is the need to conduct a leak test after each assembly before use, that is, the need for a hydraulic or pneumatic test before testing.

The technical result of the proposed technical solution is to reduce the overall dimensions of the device, to make it portable, for transportation and placement on a motor vehicle or trailer without preliminary disassembly and subsequent assembly, and eliminating the need for hydrotesting before conducting research, which significantly reduces the time of preparatory work before measurement.

The technical result is achieved by the fact that the unit for researching gas and gas condensate wells, including a gas-liquid mixture separator connected by pipelines, devices: constricting, measuring separation products, measuring pressure, temperature and gas flow, collecting liquids and solids and shut-off and control valves, is located in a frame with dimensions that fit into the dimensions of the vehicles, while the gas-liquid mixture separator, and devices that are part of the unit, including The supersonic separator is connected by pipelines, the gas-liquid mixture separator is inlet connected to the outlet (s) of the supersonic separator, and the purified gas outlet of the supersonic separator is connected to the gas-liquid mixture separator or to the purified gas outlet pipe.

A supersonic separator is located in the inlet fitting of the gas-liquid mixture separator.

The supersonic separator is equipped with inlet valves.

The gas-liquid mixture separator is equipped with vertical volumetric structured nozzles installed against the gas-liquid mixture inlet fittings.

The frame is made with ribs from profiles in such a way that it is convenient for transportation and the block placed in it for the study of gas and gas condensate wells is constantly available for servicing shut-off and control valves.

The inlet fitting of the fluid collector is equipped with a filter for collecting solids.

The location of the unit for the study of gas and gas condensate wells in a frame with dimensions that fit into the dimensions of the vehicles, the piping of the gas-liquid mixture separator and the devices that make up the unit, which also include an ultrasonic separator, pipelines, the connection of the gas-liquid mixture separator at the input to the output ( ami) of a supersonic separator, and a purified gas outlet of a supersonic separator with a gas-liquid mixture separator or with a purified gas outlet pipe, allowed:

- make the unit compact, within the railway and automobile dimensions, place it for transportation by car or car trailer fully assembled;

- protect technological equipment, valves and fittings, instrumentation and automation devices from damage during transportation;

- significantly reduce weight and size characteristics.

The location of the supersonic separator in the inlet fitting of the separator for gas-liquid mixtures made it possible to reduce the dimensions of the unit for studying gas and gas condensate wells, and to reduce the number of shutoff valves.

The inclusion of an additional supersonic separator in the gas and gas condensate well research unit, and the gas-liquid mixture separator being equipped with an additional gas-liquid mixture inlet, made it possible to conduct advanced studies of gas and gas condensate wells, not only with narrowing devices, such as diaphragms, but also with preliminary supersonic a separator.

Supply of a supersonic separator at the inlet with shutoff valves made it possible to conduct well studies with and without a supersonic separator.

The supply of the gas-liquid mixture separator with vertical volumetric structured nozzles made it possible to increase the separation efficiency of the gas-liquid mixture in comparison with horizontally located direct-flow centrifugal elements and to increase the productivity of the installation.

The implementation of the frame with ribs of flat profiles and setting them in such a way that the block placed therein for the study of gas and gas condensate wells is constantly available for servicing shut-off and control valves, made it possible to transport the block both in a vertical position when supporting on the base and in a horizontal position when located on one of the faces and constant access for servicing shut-off and control valves.

The authors are not aware of blocks for studying gas and gas condensate wells, the technical result of which would be to reduce the weight and size characteristics of the device, make it convenient for transportation and placement fully assembled in automobile transport or trailer and ready for use directly upon delivery.

Figure 1 shows the layout of the study unit of gas and gas condensate wells.

Figure 2 shows the process diagram of the piping of separators and devices for measuring and switching to various modes of the unit for the study of gas and gas condensate wells, as well as the layout of control and automation devices.

The research unit of gas and gas condensate wells 1 (Fig. 1) contains a frame 2 with a base 3. Inside the frame 2, on a base 3 there are: a vertically mounted gas-liquid mixture separator 4 with a fluid and solids collector 5 in its lower part (Fig. 2) and vertical volumetric structured nozzles 6; capacity for measuring separation products 7 (Fig.1, 2).

The separator of the gas-liquid mixture 4 (inside the frame 2) is connected to the devices:

- measuring the flow rate of gas separated from impurities 8;

- measuring fluid level 9;

- measuring pressure 10, 11 and temperatures 12, 13 (figure 2).

On the tank for measuring separation products 7 (1, 2) are devices:

- measuring the flow rate of gas separated from impurities 8;

- measuring fluid level 9;

- temperature measurement 14.

On the inlet pipe 15 (Fig. 1, 2) of the piping of the gas-liquid mixture supply to the gas and gas condensate well research unit 1, there is a shut-off valve 16, a methanol tank 17, a device for measuring pressure 10, temperature 12, and a heat exchanger 18 can also be placed (Fig. .2).

The inlet pipe 15 (FIGS. 1, 2) is connected to the constriction device 19, in which interchangeable diaphragms can be installed, by a pipe 20 with shutoff valves 16. The inlet pipe 15 is also connected to a supersonic separator 21 by a pipe 22 with shutoff valves 16. A supersonic separator 21 (Fig.2) has two exits to the separator of the gas-liquid mixture 4: liquid with a part of the gas nozzle 23 and the purified gas nozzle 24. The outlet of the purified gas 24 can be connected by a pipe 25 to the separator gas outlet 26 from the separat ra liquid mixture 4, bypassing the vertical bulk structured packings 6 (in Figure 2 a schematic embodiment of a supersonic separator arrangement 21 in fitting entry separator liquid mixture 4). The outlet pipe of the purified gas 24 can be connected by a pipe 25 to the pipe of the outlet of the separated gas 26, bypassing the separator of the gas-liquid mixture 4. The pipe of the outlet of the separated gas 26 (Fig.1, 2), with installed device for measuring the flow of gas separated from impurities 8, a control valve 27 and shutoff valves 16 are connected to the pipeline of the outlet 28 of the purified gas from the study unit of gas and gas condensate wells 1.

The separator of the gas-liquid mixture 4 at the outlet of the liquid through the shut-off valve 16 is connected by a pipe 29 with a container for measuring the separation products 7 (Figs. 1, 2) and a pipe 30 with a shut-off valve 16 with a pipe for the outlet of the purified gas 28 from the gas and gas condensate well study unit 1 (figures 1, 2). The tank for measuring the separation products 7 is equipped with a pipe for removing weathered gas 31 and a pipe for dumping the separated liquid 32, on which shutoff valves 16 are placed (Figs. 1, 2). The frame 2 of the research unit of gas and gas condensate wells 1 is made with ribs 33 of the profiles (figure 1).

The study unit of gas and gas condensate wells 1 operates as follows:

Mode 1.

The gas-liquid mixture is fed into the inlet pipe 15 (Fig. 2) of the gas and gas condensate well study unit 1 located inside the frame 2, and then into the pipe 20 and through the constriction device 19 without pressure relief (i.e., without installing a diaphragm in the device 19) in a gas-liquid mixture separator 4, while the shutoff valves 16 on the pipelines 15 and 20 are installed in the "open" position, and on the pipe 22 - in the "closed" position. The pressure and temperature of the gas-liquid mixture is measured in devices for measuring pressure 10 and temperature 12.

In the separator of the gas-liquid mixture 4 on the vertical volumetric structured nozzles 6, the hydrocarbon, aqueous phases and mechanical impurities are separated from the gas. The purified gas through the pipeline of the separated gas 26 is sent to measure the technological parameters: to the device 11 for measuring pressure, to the device 13 for measuring temperature and to the device for measuring the flow of gas 8 separated from impurities, for measuring the flow. From the device for measuring the flow rate of gas 8 separated from impurities, the purified gas is sent through a control valve 27 and shut-off valves 16, which are in the "open" position, to the purified gas outlet pipe 28 from the gas and gas condensate wells research unit 1.

After passing through the research unit of gas and gas condensate wells 1 in the steady state a certain amount of gas in the pipelines 20 and the separated gas 26, the shutoff valves 16 are closed, and the liquid in the gas-liquid mixture separator 4 is kept until the hydrocarbon and water phases are separated, detecting the time of separation, the amount of saturated aqueous , hydrocarbon phases on the device for measuring the level of liquid 9 in the separator of the gas-liquid mixture 4.

After measuring the volume of the saturated liquid phase, the shut-off valve 16 (Figs. 1, 2) is opened on the pipe 29 and the liquid phase is fed, mechanically, into the container for measuring the separation products 7, where the liquid is weathered through the weathered gas removal pipe 31. Measure the temperature (T) on the temperature measuring device 14, the amount of weathered gas on the device for measuring the flow rate of gas 8 separated from impurities installed in the weathered gas removal pipe 31. The amount of weathered aqueous, hydrocarbon phase and the amount of mechanical impurities, the time of separation of the hydrocarbon and aqueous phases are measured on a device for measuring the level of liquid 9 installed on the tank for measuring separation products 7.

Mode 2.

This operating mode of the gas and gas condensate wells research unit 1 is similar to mode 1 and differs in that a diaphragm is installed in the narrowing device 19, depending on the diameter of which, the pressure is released, for example, to 7.5 or 5.5 MPa. In this case, the gas-liquid mixture is cooled during expansion and sent to the separator of the gas-liquid mixture 4. In order to prevent hydrate formation in the piping and equipment, together with the gas-liquid mixture, an inhibitor, for example, a methanol solution, is measured in the pipeline 15 from the methanol tank 17. Further, the process of researching wells in the unit for researching gas and gas condensate wells 1 is similar to mode 1.

Mode 3.

In operation mode 3 of the gas and gas condensate wells research unit 1 using a supersonic separator 21, the shutoff valves 16 installed in the pipeline 20 are closed and the shutoff valves 16 are opened in the pipeline 22. Moreover, as in mode 2, into the pipeline 15 from the methanol tank 17 a methanol solution is supplied to prevent hydrate formation.

The gas-liquid mixture through the pipe 22 (Fig.1, 2) through the stop valves 16 is sent to a supersonic separator 21, where the flow is twisted, adiabatically isentropically expanded, cooled and divided into two streams: the liquid with a part of the gas is sent to the pipe 23 and the purified gas stream is into the nozzle 24 of the supersonic separator 21, which are then sent to the separator of the gas-liquid mixture 4. The cleaned gas stream from the nozzle 24 of the supersonic separator 21 can be sent directly through the pipeline 25 to the pipeline is separated 26 of gas bypassing the gas-liquid separator 4 mixture.

When installing a supersonic separator 21 in the inlet nozzle of the gas-liquid mixture separator 4, purified gas from the nozzle 24 and liquid with a part of the gas from the nozzle 23 are fed to the vertical volumetric structured nozzles 6, to separate hydrocarbon, water phases and mechanical impurities from the gas. Further, the operation of the unit is similar to mode 1.

Thus, the location of the unit for the study of gas and gas condensate wells in a frame with dimensions that fit into the dimensions of the vehicles, the piping of the gas-liquid mixture separator and devices that make up the unit, which also include an ultrasonic separator, pipelines, the connection of the gas-liquid mixture separator at the input with the outlet (s) of the supersonic separator, and the outlet of the purified gas of the supersonic separator with a gas-liquid mixture separator or with the outlet pipe of the purified gas, made it possible to provide a technical result consisting in reducing the overall dimensions of the device, making it portable, for transportation and placement on a motor vehicle or trailer without preliminary disassembly and subsequent assembly and without hydraulic testing before conducting research, thereby reducing the time of preparatory work.

Claims (6)

1. The unit for the study of gas and gas condensate wells, including a gas-liquid mixture separator, devices: constricting, measuring separation products, measuring pressure, temperature and gas flow, collecting liquids and solids and shut-off and control valves, characterized in that the block is located in the frame with dimensions that fit into the dimensions of the vehicles, while the separators and devices that make up the unit, which also include an ultrasonic separator, are tied with pipelines, a gas separator the inlet liquid mixture is connected to the outlet (s) of the supersonic separator, and the purified gas outlet of the supersonic separator is connected to the gas-liquid mixture separator or to the purified gas outlet pipe. 2. The block for the study of gas and gas condensate wells according to claim 1 is made with a supersonic separator located in the inlet fitting of the separator of the gas-liquid mixture. 3. The unit for the study of gas and gas condensate wells according to claim 1, characterized in that the supersonic separator is equipped with an inlet stop valve. 4. The unit for the study of gas and gas condensate wells according to claim 1, characterized in that the gas-liquid mixture separator is equipped with vertical volumetric structured nozzles installed against the gas-liquid mixture inlet fittings. 5. The block for the study of gas and gas condensate wells according to claim 1, characterized in that the frame is made with ribs from profiles, so that it is convenient for transportation, and the block placed in it is constantly available for servicing shut-off and control valves. 6. Block for the study of gas and gas condensate wells according to claim 1, characterized in that the inlet fitting of the fluid collector is equipped with a filter for collecting mechanical impurities.

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