RU165136U1 - CHEMICAL REAGENT SUBMERSIBLE DISPENSER - Google Patents

Abstract

1. A submersible chemical reagent dispenser comprising a cylindrical body, on one side of which a sealed module with an intelligent unit is installed, on the other hand, a base is installed with a mixing chamber, with a controlled valve, and with an output channel communicated with the mixing chamber, while the intelligent unit is connected an electric conductor in an insulating shell located in a sealed pipe with a controlled valve, characterized in that the inner cavity of the cylindrical body is sealed with water the ability to fill with reservoir fluid and a chemical reagent, and hermetically separated by a piston, the hermetic tube is a guide for the piston and is located on the axis of the cylindrical body, in the base of the dispenser there is additionally made an inlet channel of the chemical reagent with a valve, an electromagnetic valve is installed as a controlled valve, made to open / closing by a control signal, the electromagnetic valve is installed in the output channel, while the dispenser additionally contains a compensator, adjoint body cavity filled with a liquid reservoir, wherein the inner cavity of the compensator is connected to the hermetic vessel cavity through a channel formed in the nipple sealed emkosti.2. The dispenser according to claim 1, characterized in that the intelligent unit is connected by a neutral wire of a three-phase electric drive of a submersible pump. 3. The dispenser according to claim 1, characterized in that the cylindrical body is made of a corrosion-resistant material, for example stainless steel. The dispenser according to claim 1, characterized in that the cylindrical body is made of

Description

The technical field to which the utility model relates.

The utility model relates to the oil industry, in particular to submersible devices for supplying reagent to the well, to the surface of submersible electric motors and the inlet of electric centrifugal pumps, and can be used to prevent corrosion, deposits of salts and paraffins in oil production equipment to increase the reliability of the ESP.

State of the art

A device for dosed supply of reagent into the well is known, including a container with a chemical reagent and a plunger pump-dispenser placed between it and a sucker rod pump. The metering pump plunger is attached to the stem, driven by the differential pressure of the fluid during operation of the sucker rod pump (RF patent 1617198, MKI F04B 47/00; Е21В 43/00, 1990).

The disadvantages of the device include the impossibility of using it with other types of oil-producing pumps (centrifugal, axial, etc.) and the uneven supply of the reagent due to its gradual dilution with well fluid during operation, the lack of control over the output of the reagent, and the location of the container with chemistry under the dosing the pump makes it difficult to remove the chemical agent, and the lack of a device for equalizing the pressure between the external reservoir and inside the container with chemistry creates additional increased requirements for sealing chemical chemistry, leads to increased metal consumption due to the need to use increased wall thickness of the container.

A device for the dosed supply of reagent to the well, a reagent tank and a metering pump connected with it with its own drive and control system, which are placed inside the well below the oil production equipment, the drive power of the metering pump is supplied by a battery of galvanic cells located in the sealed cavity of the device . (RF patent 2446272, IPC Е21В 37/06 (2006.01))

A disadvantage of the known design is that it is impossible to remotely control the flow of a chemical reagent, there is a need for hermetic isolation of the battery from the ingress of chemical reagent and formation fluid, and this container, due to the lack of a compensation system, must withstand large reservoir pressures, which is so it creates the risk of premature depressurization of the sealed cavity and the failure of the entire equipment as a whole, the disadvantages also include the fact that the chemical reagent is located wives in a separate container that is placed in an additional housing, which reduces the useful volume of the chemical reagent, and as a result, and a decrease in life of the dosage unit. It is also worth noting that it is not possible to fill the specified installation with a chemical reagent through an external casing, which makes it difficult to assemble the dispenser.

The closest in technical essence to the proposed device is an intelligent submersible dispenser, consisting of a container with a piston and a fixed membrane, filled with a dosing composition, located in a tube-shaped housing, on one side of which there is an end piece and a sealed module with an electronic unit connected by an electric a conductor in an insulating sheath located in a sealed pipe and located on the other hand controlled valve, which is installed in the base and connected to internal channels with a receiving device having a piercer of a fixed membrane, the electronic unit receives power and a control signal through the zero wire of the three-phase electric drive of the submersible pump and transfers it to the controlled valve. (RF patent 115 468 IPC G001F 13/00, ЕВВ 37/06.)

A disadvantage of the known design is that the chemical reagent is located in a separate container, which is placed in an additional housing, which leads to a decrease in the useful volume of the chemical reagent, and as a result of a reduction in the dosage period of this device, it can also be seen from the figure that the electric wire passes between the outer casing and the container body of the chemical reagent, which also increases the gap between the walls of the above buildings and, as a result, reduces the dosage period of this device -keeping. It is also worth noting that it is not possible to fill the specified installation with a chemical reagent through an external casing, which makes it difficult to assemble the dispenser.

An additional disadvantage of the known construction can be attributed to the fact that in case of depressurization of the internal cavity of the submersible metering device, which communicates with the oil-filled cavity of the submersible electric motor and, accordingly, with the oil-filled cavity of the hydraulic protection of the submersible electric motor, it can lead to the formation of fluid inside the submersible oil-filled electric motor, which will lead to a short circuit its windings and, accordingly, to the failure of all submersible equipment and its premature in recovery. Also, in the event of a break in the hydraulic protection of the submersible electric motor, a short circuit may occur on the submersible oil-filled electric motor, which can lead to failure of the electrical components in the submersible block. Also, the disadvantages of the above-mentioned design include contacting the board of the submersible block with the oil of the submersible electric motor, which has corrosive properties and can destroy the soldering and electric tracks of the board itself.

Utility Model Essence

The technical problem posed in this utility model is to increase the reliability of the submersible batcher and its protection against the ingress of formation fluid into it.

The technical result of the claimed utility model is to increase the reliability of the design.

The technical result of the claimed utility model is achieved due to the fact that the submersible chemical reagent dispenser contains a cylindrical body, on one side of which a sealed module with an intelligent unit is installed, on the other hand, there is a base with a mixing chamber, with a controlled valve, and with an output channel communicated with the mixing chamber, while the intelligent unit is connected by an electrical conductor in an insulating shell located in an airtight pipe with a controlled valve, with the cavity of the cylindrical body is sealed with the possibility of filling with formation fluid and a chemical reagent, and is hermetically separated by a piston, the sealed pipe is a guide for the piston and is located along the axis of the cylindrical body, in the base of the dispenser there is an additional filling channel of a chemical reagent with a valve as a controlled valve an electromagnetic valve is installed, made with the possibility of opening / closing by a control signal, the electromagnetic valve is installed in the output to the analyzer, the dispenser additionally contains a compensator located in the cavity of the housing filled with reservoir fluid, while the internal cavity of the compensator is connected to the cavity of the sealed container through a channel made in the nipple of the sealed container.

In the particular case of the implementation of the utility model, the intelligent unit is connected by the neutral wire of a three-phase electric drive of a submersible pump.

In the particular case of the implementation of the utility model, the cylindrical body is made of a corrosion-resistant material, for example, stainless steel.

In the particular case of the implementation of the utility model, the cylindrical body is made of a corrosion-resistant composite material, for example, fiberglass or plastic

In the particular case of the implementation of the utility model, the internal cavity of the cylindrical body is made with the application of a corrosion-resistant coating.

Brief Description of the Drawings

Details, features, as well as advantages of this utility model follow from the following description of embodiments of the claimed installation using the drawings, which show:

In FIG. 1 shows a chemical submersible dispenser

In the figure, the numbers indicate the following positions: consists of: 1 - base; 2 - the electromagnetic valve; 3 - filling channel; 4 - valve; Channel 5; 6 - tube; 7 - cable; 8 - outer casing; 9 - a piston; 10 - nipple; 11-respiratory canal; 12 - intelligent unit; 13- cavity; 14 - upper nipple; 15- zero wire; 16 - chemical reagent; 17 - reservoir fluid; 18 - mixing chamber; 19 - inlet; 20 - outlet; 21 - channel; 22 compensation cavity; 23 - compensator; 24 - sealed connector; 25 PED oil; 26 - zero wire PED; 27 - cavity; 28- sleeve compensator.

Utility Model Disclosure

Submersible chemical reagent dispenser (Fig. 1) is made in the form of a cylindrical body (8), limited on the one hand by the upper nipple (14), and on the other hand, by the base (1).

An immersion chemical dispenser with compensating protection is attached to the base of the submersible electric motor or TMS through a nipple (14) and connected to the neutral wire of the PEM (26), which is removed from the submersible electric motor or TMS and is located in the motor or TMS housing, as well as in oil PED (25), using a sealed connector (24) and through its own neutral wire (15), through which the control signal is transmitted from the ground control panel to the intelligent unit (12), where the processing signal flow and transmission of the open / close control signal via cable (7) to the electromagnetic valve (2).

The internal cavity of the housing (8) is divided into two parts by the nipple (10): with the formation of a cavity (13) between the upper nipple (14) and the nipple (10), as well as with the formation of a cavity (27) between the base (1) and the nipple (10) )

An intelligent unit (12) is located in the cavity (13).

In the cavity (27) along the axis of the cylindrical body there is a pipe (6), hermetically connecting the base (1) and the nipple (10).

The cavity (27) is hermetically divided by the piston (9) into two parts, the first part is filled with a chemical reagent and limited in volume by the piston (9) and the base (1), the second part with reservoir fluid, limited in volume by the piston (9) and nipple (10) ) The pipe (6) is a guide for the piston (9).

A breathing channel (11) is made in the nipple (10), connecting the part of the cavity (27), limited in volume by the piston (9) and the nipple (10) with the formation fluid.

An electromagnetic valve (2) is installed in the base (1) and is connected to the mixing chamber (18) on one side and connected to the chemical reagent (16) through the channel (5).

The chemical reagent is located in the cavity formed by the inner diameter of the outer casing (8) along the length, and at the ends of the piston (9) and the base (1).

In the cavity of the cylindrical body, along its axis there is a pipe (6), hermetically connecting the base (1) and the nipple (10).

The pipe is also a guide for the piston (9).

Inside the cavity, limited in volume by the piston (9) and the nipple (10), a compensator (23) is located. The compensator (23) is hermetically connected to the upper nipple (10) on the one hand, and to the compensator sleeve (28) on the other hand. In this case, the sleeve of the compensator (28) is hermetically located on the pipe (6).

Inside the compensator (23) there is a compensation cavity (22), which is connected through a channel (21) made in the nipple (10) to the cavity (13) formed by the inner diameter of the housing (8) and the ends of the upper nipple (10) and the nipple (14 ) into which the smart unit (12) is installed.

The above cavities (13, 22) are filled with a fluid that is dielectric and neutral with respect to solders and copper tracks of electric circuit boards.

The use of a sealed connector (24) allows you to make a submersible chemical dosing unit with compensating protection sealed and independent of oil PED (25), its own compensator (23), the compensation cavity (22) of which is filled with dielectric and neutral with respect to solders and copper tracks of electric circuit board liquid, such as silicone fluid.

The compensator (23) allows you to equalize the pressure of the reservoir fluid and the pressure inside the dispenser, which will allow for more stable and long-term operation of the intelligent unit (12), as well as compensate for the volumetric expansion of the dielectric and neutral with respect to solders and copper tracks of the liquid circuit boards.

The fluid, which is filled with a compensator, which is insulating and neutral with respect to solders and copper tracks of electric circuit boards, protects copper tracks and solders of electric boards from the aggressive effects of PEM oil.

The base (1) of the dispenser is made with a filler channel (3), an output channel (5) and a mixing chamber (18).

In this case, the channel (3) connects the cavity, limited in volume by the piston (9) and the base (1).

A valve (4) is installed in the filler channel (3) of the chemical reagent, which prevents the backflow of chemistry from the dispenser.

The channel (5) connects the part of the cavity (21) limited in volume by the piston (9) and the base (1) and the mixing chamber (18).

An electromagnetic valve (2) is installed in the mixing chamber (18) at the outlet of the channel (5). At the base of the dispenser (1), at least one outlet (20) and inlet (19) are open radially, which are in communication with the mixing chamber (18).

The electromagnetic valve (2) is connected through an electric cable (7) located in the pipe (6) to the smart unit (12). In the intelligent unit (12), the signal is processed and the open / close control signal is transmitted via a cable (7) located inside the tube (6), which hermetically connects the base (1) and the upper nipple (14) to the electromagnetic valve (2).

Submersible dispenser chemical reagent operates as follows.

At the manufacturer's factory or directly at the well before launching, the dispenser is filled with a chemical reagent (16) against corrosion, salt formation, and paraffin formation through the filler channel (3), in which a valve (4) is installed to prevent backflow of chemistry from the dispenser. At this moment, the piston (9) is in its lowest position and is in contact with the end face of the base (1).

In the process of filling the cavity, formed by the inner diameter of the outer casing (8), the end face of the base (1) and the end face of the piston (9), the piston (9) moves to its highest position until it contacts the compensator sleeve (28). Before the descent into the well, the neutral wire (15) is connected to the neutral wire of the submersible electric motor or TMS through a sealed connector (24) to the neutral wire of the PEM (26), and using the nipple (14) the submersible batcher is attached to the housing (27) of the submersible electric motor or to TMS base.

During the operation of the submersible batcher in the well, the pressure inside and outside the batcher is equalized with the help of the breathing channel (11) in the upper nipple, through which the reservoir fluid (17) enters the container and with the help of a compensator (23), consisting, for example, of a movable diaphragm.

Formation fluid (17) enters through the channel (11) into the cavity, limited in volume by the piston (9) and nipple (10), exerts pressure on the piston (9), which transfers this pressure to the chemical reagent (16), and also exerts the pressure on the movable walls of the compensator (23) is made, for example, from the diaphragm, which in turn transmit this pressure of the fluid enclosed in the compensation cavity (22).

Thus, equalization of pressure is carried out outside and inside the submersible batcher.

Also, the compensator (23) carries out the process of compensating for the thermal expansion of the liquid contained in the compensation volume, which inevitably occurs when the equipment is lowered into the well.

After the ground part of the smart block transmits a signal about the start of work on the neutral wire (15) to the submersible part of the smart block (12) located inside the housing (13), the submersible part of the smart block will give a signal through the wire (7) to the electromagnetic valve (2 ) about its opening / closing. The chemical reagent (16) under its own weight and under the pressure of the reservoir fluid (17) will begin to flow through the channel (5) into the electromagnetic valve (2), and in the case of its open state, into the mixing chamber (18) located in the base (1).

Formation fluid enters the mixing chamber (18) through the inlet (19), which, being mixed with the chemical reagent entering the chamber through the solenoid valve (2), is taken out of the mixing chamber through the outlet (20) and then enters the oil producing stream pump, thereby fully protecting all submersible equipment, including the submersible motor, from salt formation, paraffin formation and corrosion.

The technical solutions presented, namely, the use of a submersible installation with installed compensation protection, allows comparing the pressure inside the submersible batcher with external reservoir pressure, thereby reducing the risk of failure of electrical elements of the submersible part of the smart unit (12), the absence of a pressure drop positively affects the operation of the sealing elements which work in comfortable conditions of low differential pressure, and due to the possibility of compensating for the thermal expansion of the liquid Turning to the compensating volume (22) can also avoid excessive internal pressure, and the movable wall of the compensator (23) allow to smoothly equalize the pressure inside and outside of the dispenser during lowering / lifting operations on the well.

Also, the connection of the neutral wire of the PED (26) of the submersible motor or TMS with the zero wire (15) of the submersible batcher through a sealed connector (24), which is sealed in the nipple (14), allows the batcher to be sealed and not dependent on the compensator of the submersible motor, which allows to say that in the case of depressurization of the engine, the electrical circuits located in the submersible part of the intelligent unit (12) will remain operational, and vice versa: in the case of depressurization of the compensation volume (22) and formation fluid (17) getting into it will fail only the submersible part of the intelligent unit (12), while this will not affect the operation of the submersible electric motor, which means that the submersible pump will continue to operate.

Claims (5)

1. A submersible chemical reagent dispenser comprising a cylindrical body, on one side of which a sealed module with an intelligent unit is installed, on the other hand, a base is installed with a mixing chamber, with a controlled valve, and with an output channel communicated with the mixing chamber, while the intelligent unit is connected an electrical conductor in an insulating sheath located in a sealed pipe with a controlled valve, characterized in that the internal cavity of the cylindrical body is sealed with the possibility of filling with reservoir fluid and a chemical reagent, and is hermetically separated by a piston, sealed pipe is a guide for the piston and is located along the axis of the cylindrical body, at the base of the dispenser, an additional inlet channel of a chemical reagent with a valve is made, as a controlled valve, an electromagnetic valve is installed, made with the possibility of opening / closing by a control signal, an electromagnetic valve is installed in the outlet channel, wherein the dispenser further comprises a compensator located in the body cavity filled with formation fluid, while the internal cavity of the compensator is connected to the cavity of the sealed container through a channel made in the nipple of the sealed container. 2. The dispenser according to claim 1, characterized in that the intelligent unit is connected by a neutral wire of a three-phase electric drive of a submersible pump. 3. The dispenser according to claim 1, characterized in that the cylindrical body is made of a corrosion-resistant material, for example stainless steel. 4. The dispenser according to claim 1, characterized in that the cylindrical body is made of a corrosion-resistant composite material, for example fiberglass or plastic. 5. The dispenser according to claim 1, characterized in that the inner cavity of the cylindrical body is made with a corrosion-resistant coating.

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