RU13910U1 - INSTALLING A WELL RESEARCH - Google Patents

Abstract

INSTALLING A WELL RESEARCH

The utility model relates to the oil and gas industry and is intended for use in conducting complex gas-hydrodynamic studies of the products of one or more wells of oil and gas condensate fields during exploration, during trial operation or at the initial stage of development of fields, including products that contain aggressive components in order to determine the flow rate for liquid hydrocarbons, natural and associated gas, bed water and other gas hydrates odinamicheskih characteristics work well or group of wells with the simultaneous preparation of liquid hydrocarbons for transport and disposal of gas and formation water.

The inventive utility model solves the problem of improving the accuracy of measuring the flow rate of the components of the production of wells and expanding the functionality of the installation.

The Lada well research installation includes a gas condensate mixture receiving line equipped with a shutoff valve and a pressure regulating valve and connected to a three-phase separator connected to condensate, gas and water drain lines equipped with flow meters, an oil separation unit connected to the gas drain lines and water, including an oil intake line equipped with a shutoff valve and a pressure regulating valve, and a heater, a two-phase separator and a water sludge separator connected in series enny with lines interblock communication, and power stabilization of liquid hydrocarbons, comprising hydrocarbons degassing and stabilization of the vessel. In addition, the Lada well research installation further comprises a storage and dispensing unit for commercial products containing storage tanks and an automated liquid hydrocarbon filling station, and an auxiliary unit unit, including a boiler room for heating the coolant, a substation, and a backup power diesel engine.

The use of the installation provides an increase in the accuracy of measuring the flow rate of gas condensate and produced water in the study of gas condensate wells, the ability to conduct research of gas condensate and oil wells with the implementation of liquid hydrocarbons prepared to the level of marketable products; the proposed installation can be used not only in the study of equipped wells, but also in the absence of developed engineering services.

ESSAY

Description

INSTALLING A WELL RESEARCH

The utility model relates to the oil and gas industry and is intended for use in conducting complex gas-hydrodynamic studies of the products of one or more wells of oil and gas condensate fields during exploration, during trial operation or at the initial stage of development of fields, including products that contain aggressive components in order to determine the flow rate for liquid hydrocarbons, natural and associated gas, produced water and other gas hydrates odinamicheskih characteristics work well or group of wells with the simultaneous preparation of liquid hydrocarbons for transport and disposal of gas and formation water.

A well-known automated group metering device Sputnik in various modifications (Sputnik-A, Sputnik-B, Sputnik-B40), designed for automatic metering with separation of the liquid and gas phases of oil wells 1. The installation includes a hydrocyclone separator, gas and liquid meters, collectors gas and liquid, differential pressure regulator between the separator and the gas manifold.

The disadvantages of the known metering installation are the decrease in the accuracy of measuring fluid flow at high flow rates of the investigated well or at a high gas factor due to poor separation of gas from the liquid, as well as limited functionality. This is due to the lack of the ability to determine the oil and water flow rates during the study of waterlogged wells, the complications of working with heavy paraffin oil and the inability to use the installation for the study of unfinished wells.

There is also known a device for measuring and researching oil well production, containing a separator-stabilizer with a tangential supply of a gas-liquid mixture, a unit for preparing a gas-liquid mixture, consisting of separators and a tank with a demulsifier, flow, pressure and temperature meters 2. The well-known installation has higher accuracy in comparison with the above, because provides a more complete separation of gas from

IPC Е21В 47/10 Е21В 49/00

liquids (oil and water).

The disadvantages of the known installation are the lack of the possibility of a separate measurement of the volumes of oil and water and the use of gas condensate wells, as well as undeveloped wells; in addition, the use of this installation causes complications in the study of wells whose products contain heavy oil.

The closest to the claimed utility model in terms of the set of essential features is the Porta-Test installation for the study of gas condensate wells, including products which contain aggressive components, from PORTA-TEST Tuning LTD (Canada) 3. The installation includes a line for receiving a gas-condensate mixture, equipped with a shutoff valve and a valve - pressure regulator, and a heater and a three-phase separator connected in series to the gas, water and condensate drain lines with flow rate meters for the production of the well. The well-known installation works as follows: the gas-condensate mixture from the wells enters the heater, where it is heated to the required temperature provided for by the research program. Next, the gas-liquid mixture is sent to a separator to separate the liquid phase from the gas phase. The gas is sent to the vortex tube and then to the gas exhaust line, the flow rate of the separation gas is determined by the flow meter. In the lower part of the separator is a liquid storage, where there is a separation of water and condensate due to the difference in their densities. The discharge of liquids from the water and condensate drain lines is carried out with a simultaneous flow measurement. The Porta-test installation has higher accuracy compared to other well-known technical solutions of a similar purpose due to more complete gas separation and separate measurement of water and liquid hydrocarbon volumes.

A disadvantage of the known installation for the study of gas condensate wells is the low reliability of determining the flow rates of condensate and water due to incomplete separation. In addition, the installation has limited functionality due to the impossibility of its use in oil wells and in wells without a developed engineering communications network, which does not allow the study of unfinished wells.

The inventive utility model solves the problem of improving the accuracy of measuring the flow rate of the components of the production of wells and expanding the functionality of the installation.

To solve this problem, the Lada well research installation, including a gas condensate mixture receiving line equipped with a shutoff valve and a pressure regulating valve and connected to a three-phase separator connected to condensate, gas and water drainage lines equipped with flow meters, additionally contains an oil separation unit, connected to gas and water drainage lines, including an oil intake line, equipped with a valve - shutoff valve and a valve - pressure regulator and connected in series to the heater b, a two-phase separator and sludge water separator connected to the communication lines interconnect and stabilize the liquid hydrocarbons unit comprising the degassing vessel stabilization and hydrocarbons.

Another difference of the claimed utility model is that the Lada well research unit further comprises a storage and supply unit for commercial products containing storage tanks and an automated liquid hydrocarbon filling station, and an auxiliary unit unit including a boiler room for heating a heat carrier, a substation and a diesel power backup power station.

The technical result achieved in this case is as follows:

- the presence of an oil separation unit (an oil reception line, a two-phase separator and a water sludge separator with inter-unit communications) allows the study of oil wells, as well as improving the quality of separation of water from condensate in the study of gas condensate wells, which provides improved accuracy in measuring the flow rate of condensate and water;

- the presence of a block of stabilization of liquid hydrocarbons (degassing and stabilization of liquid hydrocarbons - oil and gas condensate by heat treatment to remove hydrogen sulfide, light hydrocarbons and the destruction of oil-water emulsions) provides the opportunity to study oil and gas condensate wells with the simultaneous preparation of liquid hydrocarbons to the level of marketable products (if available engineering communications products can be sent to the consumer through pipelines.

when exploring unfinished wells, commodity products can be taken out by tank trucks, as the installation provides a level of preparation of liquid hydrocarbons in accordance with the requirements of GOST 9965-76);

- the presence of a unit for storage and dispensing of commodity products (storage capacities of commodity products - liquid hydrocarbons and an automatic filling station) and a block of auxiliary facilities {boiler room for heating a coolant providing temperature stabilization of oil, a substation for supplying electricity to power units, a diesel power station for backup power) provides the ability to use the installation in wells that are not equipped with developed engineering services.

Thus, the use in the proposed installation of additional units used for their intended purpose, gives a new technical result: improving the accuracy of measuring the flow rate of gas condensate and produced water in the study of gas condensate wells, the possibility of studying gas condensate and oil wells with the implementation of liquid hydrocarbons prepared to the level commercial products, as well as ensuring the operation of the installation not only in the study of equipped wells, but also in the absence of developed engineering communications.

The drawing shows a block diagram of an installation for the study of wells Lada.

The installation contains a block (I) of a gas separator, including a line 1 for receiving raw materials, equipped with a shut-off valve 2 and a pressure regulating valve 3 and connected to a gas three-phase separator 4 connected to a gas discharge line 5 to the horizontal installation 6, a water discharge line 7 and condensate drain line 8; block (II) of the oil separator, including a line 9 for receiving raw materials, equipped with a shut-off valve 10 and a pressure regulating valve 11 and connected to a series-mounted oil heater 12, a two-phase separator 13 and a water sludge separator 14, while the two-phase separator 13 is connected to the line 15 of the gas outlet to the horizontal flare unit 6 and with a water-oil emulsion outlet line 16, and the water sludge separator 14 is connected to the outlet line 8

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- 4 condensate from the separator 4 (relative to the separator 14, line 8 is a condensate supply line for sludge), a drainage line 17 and a liquid hydrocarbon discharge line 18; gas discharge lines 5 and 15, condensate drain line 8 and a water-oil emulsion drain line 16, water drain lines 7 and 17 are provided with flow meters 19; liquid hydrocarbon stabilization unit (III) including a degassing vessel 20 connected to a degassing gas exhaust line 21 and a liquid hydrocarbon exhaust line 22, a heat exchanger 23, a stabilization tank 24 connected to a stabilization gas exhaust line 25 and a liquid hydrocarbon exhaust line 26, pumps 27 pumping liquid hydrocarbons; a unit (IV) for storing and dispensing marketable products — liquid hydrocarbons, including liquid hydrocarbon storage tanks 28 and an automated liquid hydrocarbon filling system 29; block (V) of auxiliary objects, including substation 30, diesel power station 31, air compressor 32, boiler room 33; in addition, the installation includes a block 34 of chemicals and a control unit 35.

Installation works as follows.

The gas condensate mixture from gas wells with a pressure of up to 35 MPa is supplied via a loop (not shown in the drawing) to the gas separator block (I). Having passed along the line for receiving raw material i through a shut-off valve 2, a pressure regulating valve 3, the mixture enters a three-phase separator 4, where, under the influence of gravitational forces, changes in speed and direction of flow are separated into gas, gas condensate and produced water. The gas stream from the separator 4 is directed to the gas exhaust line 5 and then through the flow meter 19 to the horizontal b flare unit for neutralization by burning. The produced water from the separator 4 enters the water discharge line 7, passes the flow meter 19 and enters the torch of the horizontal installation 6 for evaporation. Gas condensate from the separator 4 is sent to line 8, passes the flow meter 19 and enters the separator 14 of the water sludge block (II) of the oil separator.

Oil and gas mixture from oil wells with a pressure of up to 16 MPa and a temperature of 0 to 30 degrees. C enters the block (II) of the oil separator. Having passed along the line 9 for receiving raw materials sequentially through the shutoff valve 10, the valve is a pressure regulator 11, a heater 12, an oil and gas mixture with a pressure of up to 3.6 MPa with a temperature of up to 40 degrees. C enters the two-phase separator 13, where it is separated due to gravity, changes in the direction and velocity of the flow into gas and liquid phases. All free associated gas released from the oil at the operating parameters of the separator 13 enters the gas phase. The gas phase from the separator 13 is directed to the gas exhaust line 15 and then through the flow meter 19 and enters the horizontal flare unit for thermal neutralization. The liquid phase partially degassed water-oil emulsion passes into line 16 and through a flow meter 19 enters a separator 14 for separating formation water mixed with gas condensate from a three-phase separator 4. In the separator 14, water is sedimented due to gravitational forces. Produced water from the separator 14 through line 17 through the flow meter 19 is supplied for evaporation into the flare of a horizontal flare plant. Liquid hydrocarbons (oil and gas condensate) from the separator 14 are sent via line 18 to the block (III) of stabilization of liquid hydrocarbons, they enter the degassing tank 20 to remove gas. From the tank 20, liquid hydrocarbons are pumped out by a pump 27 through a heat exchanger 23, where they are heated to a temperature of 60 degrees. C, into the stabilization tank 24, in which residual gases, including hydrogen sulfide, are released. Stable liquid hydrocarbons from the tank 24 by the pump 27 are pumped to the block (IV) storage and distribution of commercial products. The degassing and stabilization gases from the tanks 20 and 24 of the stabilization unit are discharged along lines 21 and 25 to a horizontal flare unit for thermal neutralization. Stable liquid hydrocarbons through line 26 enter the tank 28 for storage of commodity products, from where they are taken by the pump of the automated filling station 29 and pumped through tank volumetric meters (not shown) into tankers for sale. The air compressor 32 compresses the atmospheric air up to 0. MPa and feeds it through pipelines to the control valves of the installation and pneumatic devices of the control unit 35. In the boiler room 33, the circulating stream of softened iodine is heated, which enters the heater 12 as a coolant for heating the working hydrocarbon medium and heat exchanger 23. Substation 30 supplies electricity to the electric motors of the pumps 27, to the lighting. Diesel power station 31 is used for backup power supply and supplies electricity in case of disconnection of the main source. From the block 34 of chemical reagents, the necessary reagents are fed into the technological process (demulsifier at the inputs of the block (I) of the gas separator and block (II) of the oil separator, corrosion inhibitor in the upper part of the separators 4, 13 and 14). The control unit 35 using the devices Kia controls the process in automatic mode.

Experimental and industrial tests of the proposed installation at the 1-N well of the Nagumanovskoye oil condensate field were carried out in May - July 1999. A prototype of the proposed installation demonstrated high accuracy in measuring the production rate of the components of the wells and reliability, the use of the installation made it possible to obtain an additional useful product - stable hydrocarbons.

The proposed installation in comparison with the prototype has a higher accuracy and wider functionality, because It can be applied in oil wells and in wells without developed engineering communications.

Sources of information,

taken into account

when applying for a utility model.

1. Reference book on oil production, edited by Sh.K. Gimatudinova. Moscow, Nedra, 1974, p. 487.

2. RF patent N 2100596, IPC b Е21В 47/10, publ. 12/27/97, bull. N 36.

3.Gritsenko A.I., Aliev Z.S., Ermilov O.M., Remizov V.V., Zotov G.A. Well Research Guide. Moscow, Science, 1995, p. 364 (prototype).

Claims (2)

1. Installation of well research, including a gas condensate mixture receiving line equipped with a shut-off valve and a pressure regulating valve and connected to a three-phase separator connected to condensate, gas and water drain lines equipped with flow meters, characterized in that it further comprises an oil separation unit associated with gas and water drainage lines, including an oil receiving line equipped with a shut-off valve and a pressure regulating valve, and a two-phase heater connected in series eparator and sludge water separator, coupled to interconnect communication lines, and unit stabilization of liquid hydrocarbons, comprising hydrocarbons degassing and stabilization of the vessel. 2. The installation according to claim 1, characterized in that it further comprises a storage and dispensing unit for marketable products containing storage tanks and an automated liquid hydrocarbon filling station, and an auxiliary unit unit including a boiler room for heating a heat carrier, a substation and a diesel power backup power supply.