RU179850U1 - Submersible linear motor - Google Patents

Abstract

The utility model relates to designs of submersible linear magnetoelectric motors used mainly in rodless deep-well pumping units. The technical result consists in increasing the reliability of the engine and increasing the pressure, while ensuring its maintainability. SUBSTANCE: linear electric motor (LED) (2) contains a stator (4) and a reciprocating action head (slider) (8). The stator (4) (Fig. 3) consists of a cylinder (5), of induction coils (IR) (7) of phases A, B, C and steel cores (6) periodically installed on the cylinder (5), as well as additionally installed between them thin ring insulating gaskets (22). IR (7) are distributed along the entire length of the stator, forming three phase windings A, B, C, which are connected in a "star". Cores (6) are made in the form of round plates (23) of electrical steel (Fig. 4) with functional technological cuttings (37-40). Annular packages of plates (21) are attached to the cores (6) around the perimeter, which form the yoke of the magnetic circuit. The teeth plates (6) and the yoke of the magnetic circuit are installed oriented along the direction of the lines of force of the IR magnetic flux (7). IR (7) and cores (6) are distributed along the length of the stator (4) into groups of modules (24). Modules (24) at the ends are closed by end caps (25). Between the end caps (25) of the adjacent modules (24) and the connection with the end caps (25), steel pipes (26) are mounted on which the support bushings (27) are coaxially mounted, which form the bearing sliding surfaces of the slider. The slider (8) (Fig. 2) contains axially magnetized permanent magnets (11) and magnetically conductive cores (12) sequentially mounted on the hollow shaft (9). Metallic washers (28) of highly conductive metal are additionally periodically mounted on the slider shaft. Magnets (11) and cores (12) are fixed on the shaft (9) by end couplings (31) and (32). To the body (3) of the LED (2) a threaded connection is connected to the current lead head (13) with a nipple (35) for suspending the pumping unit to the tubing string. A channel (14) is made in the current lead head (13) of the electric motor for supplying the produced fluid from the plunger pump (1) through the hollow shaft (9) of the slider (8) to the tubing and a sealed connector (15) for connecting the ends of the phase windings (16) with the coupling cable input of the supply cable, and also made the upper oil valve (17) for pumping transformer oil into the intermodular cavity (33) of the stator (4). A lower oil bleed valve (19) is installed in the lower part of the stator (4). 6 c.p. f-ly, 4 ill.

Description

The utility model relates to the designs of submersible linear magnetoelectric motors used mainly in rodless deep-well pumping units for reciprocating motion, intended for the production of formation fluids in oil production, in particular, in low-yield deep wells with a depth of up to 3000 m.

More than 50 years ago, it became clear that the prospect of increasing the efficiency of plunger pumps can be linear electric motors used as drives of plunger pumps. This gave impetus to the development of specialized submersible linear electric motors for plunger pumps.

Known for a number of submersible rodless pumping units containing a linear motor with a reciprocating moving working body (slider). An example is an asynchronous multiphase cylindrical motor (linear motor), the stator of which is enclosed in a sealed enclosure and consists of a magnetic circuit and windings made up of coils. A working piston (plunger) with a discharge valve is installed on the hollow working body (slider) of the engine. During operation, the piston moves back and forth in the chamber body, in which the suction valves are installed, and pumps the liquid into the tubing, on which the pump unit is suspended (author's certificate of the USSR No. 491793).

Also known is a rodless pump unit for working in deep wells, which includes a linear electric motor with a reciprocating moving hollow working body (slider) made with the possibility of connection with a hollow pump plunger, while a guide cone is made in the motor stator to center the pump casing (Author's certificate of the USSR No. 538153).

A common drawback of the above technical solutions is the lack of reliability and insufficient pressure when working in deep wells with complicated operating conditions.

Known cylindrical linear induction motor for driving submersible plunger pumps, containing a cylindrical inductor with a multiphase winding, made with the possibility of axial movement and mounted inside a steel secondary element, the steel secondary element is an electric motor housing, the inner surface of which has a highly conductive copper layer coating, and The cylindrical inductor is made of several modules, recruited from phase coils and interconnected by a flexible in ligature, the number of modules of the cylindrical inductor is a multiple of the number of phases of the winding, and when moving from one module to another, the phase coils are stacked with alternating changes in the location of the individual phases (RF Patent No. 2266607). However, its disadvantage is the inability to achieve the pressure required to drive the plunger pump in a deep well.

Also known is a submersible linear electric motor containing a cylindrical housing with an end plug, a stator and a reciprocating head are placed inside the housing, the head contains a shaft with permanent magnets and magnetically conducting cores mounted on it, and the cavities formed inside the housing and separated by a stator and a head reciprocating action, filled with reservoir fluid in the operating position of the electric motor (RF Patent No. 2489600). In this electric motor, the shaft of the reciprocating head is hollow with radial holes, through the radial holes the shaft communicates with each other the cavities formed inside the housing, at least one of the cavities communicating with the annulus through the filter element.

The disadvantages of this linear electric motor is a low efficiency, insufficient pressure and low reliability.

A known design of a submersible linear magnetoelectric motor used in conjunction with a submersible pump in rodless deep-well pumping units for reciprocating motion for the production of formation fluids in oil production (RF Patent No. 2549381). The electric motor in this installation contains a sealed stator with cores installed in it with coils, current lead and head for connection to the pump. A movable rod is located in the stator, including a connecting rod with a thread for connecting the rod to the pump plunger and an active tight slider connected to the rod by a threaded connection made in the connecting sleeve. The slider contains axially magnetized magnets and poles made of structural steel sequentially mounted on the pipe. Magnets and poles are divided into technological packages, which are interconnected by couplings. The stem is located in an inner tube made of stainless steel with a honed surface, between which a clearance is formed between the surface of the stem. The head is connected to the stator housing by a threaded connection through sealed spacers having channels. A compensator with an elastic diaphragm is attached to the base of the stator, which is made in the form of a bubble having a diameter in the middle part greater than the diameter of each of its end parts, with one end of the diaphragm connected to the stator base and its other end connected to a coupling connecting the electric motor to the compensator.

The disadvantages of this linear electric motor is also low efficiency, insufficient pressure, low reliability, as well as the complexity of the design.

The closest in technical essence to the claimed utility model is a linear electric motor for a submersible pumping device reciprocating with numerical control (Patent EAPO No. 009268). The specified well-known submersible linear electric motor consists of a cylindrical body, inside which a stator is placed with steel cores periodically mounted on thin-walled stainless steel bushings and interconnected by induction coils forming a group of windings. Supporting guides and a reciprocating head are installed between the windings - a slider consisting of a shaft made with the possibility of connection with the pump plunger and with permanent magnets and magnetically conducting cores installed on it, while the output of the stator windings is connected to the digital program control unit located on the surface.

The disadvantage of this technical solution is the lack of reliability due to the following:

firstly, insufficient cooling of the linear motor at high power, since cooling in it occurs only one-sided from the outside of the linear motor;

secondly, due to the presence of shock contacts during operation of the protruding stator support guides with protruding steel cores of the reciprocating head;

thirdly, the fact that the isolation of the phase stator windings (coils) installed close to each other and under linear voltage, which is 1.73 times the phase voltage, is made without taking this argument into account insufficiently reliable.

Another disadvantage of the known design of the electric motor is the limited pressure required when working in deep wells, since the magnetic circuit of the stator of the motor enters saturation mode with an increase in the supply current.

A significant disadvantage of this known design of the electric motor is the lack of maintainability, because many elements in it are connected by welding, and the stator cavities are filled with a compound.

The technical result achieved by the claimed utility model is to increase the reliability of the engine and increase the pressure, while ensuring its maintainability.

The specified technical result is achieved by the proposed submersible linear electric motor, including a cylindrical housing, inside which a stator is placed with steel cores periodically mounted on thin-walled stainless steel bushings and interconnected by induction coils, forming groups of windings between which support rails are installed, and a reciprocating head - a slider consisting of a shaft made with the possibility of connection with the plunger of a submersible pump, permanent magnets and magnet-core cores installed on it, characterized in that the linear electric motor is additionally equipped with a current lead head, in which a channel for supplying produced fluid through the hollow shaft of the slider to the tubing and a sealed connector for connecting the phase windings of the linear motor with the cable entry coupling supply cable, and also made a channel with an upper valve for pumping transformer oil into gaps and cavities free from coils and cores stator, while in the lower part of the linear motor housing a channel is made with a lower valve for bleeding air from the stator cavities when they are filled with transformer oil.

In an advantageous embodiment:

- each magnetically conducting stator core is made of pairs of monolithic packages of plates of electrotechnical iron, rigidly fastened together to form a magnetic circuit with the formation of teeth and grooves of the stator, while the radially located packages are the teeth of the magnetic circuit, and the axially located packages are the yoke of the magnetic circuit, with the possibility of creating directivity magnetic field lines generated by the stator induction coils, only along the laminated plates .

- induction coils located between the teeth of the magnetic circuit are additionally isolated from the teeth by thin ring dielectric spacers.

- on a slider consisting of a shaft with permanent magnets and magnetically conductive cores installed on it, metal washers of high conductivity metal are additionally periodically installed, made with a diameter equal to the diameter of the permanent magnets and magnetically conductive cores.

- as a metal of high conductivity, for example, aluminum or copper is used.

- permanent magnets mounted on the slider shaft are protected from abrasion around the perimeter by stainless steel bandages.

induction coils and magnetically conductive cores distributed along equal length of the stator into equal groups and bounded by end caps into modules are rigidly interconnected along the entire length of the stator by steel pipes, while stainless steel support bushings are coaxially mounted on the steel pipes with an inner diameter slightly smaller than the inner diameter thin-walled stator bushings for the formation of the bearing sliding surfaces of the slider.

The essence of the utility model is illustrated by drawings:

FIG. 1 - A linear electric motor in cross section in conjunction with a submersible pump (to describe the operation of the engine in field conditions).

FIG. 2 - Slider - the head of the reciprocating action of a linear electric motor.

FIG. 3-Fragment of a cross section of a linear motor.

FIG. 4 - Plate of electrical steel of the tooth of the magnetic circuit of the engine.

The inventive submersible linear electric motor (2) contains a stator (4) and a reciprocating action head (slider) (8). The stator (4) (Fig. 3) is installed inside the cylindrical body (3) and consists of a cylinder (5) of the stator (4) made of stainless steel; from periodically installed on the cylinder (5) of the stator (4) induction coils (7) of phases A, B, C and steel cores (6) forming the teeth of the magnetic circuit, as well as additional thin ring insulating spacers (22) additionally installed between them.

Induction coils (7) of phases A, B, C are distributed along the entire length of the stator, forming three phase windings A, B, C, which are connected to a "star" at the end of the stator (4).

Steel cores (teeth) (6) are made in the form of round plates (23) of electrical steel (Fig. 4) with the necessary functional technological cuts (20, 37-40). In this case, cutting (37) is intended for connecting induction coils into phase lines, cutting (38) - for opening eddy currents in the teeth; cutting down (39) - for laying mounting tightening tires; cutting down (40) - for installing the slider.

To the steel cores (teeth) (6) around the perimeter are attached annular packets of plates (21) of electrical steel, forming the yoke of the magnetic circuit. In this case, the plates of the electrical steel of the teeth (6) and the yoke of the magnetic circuit are installed oriented along the direction of the lines of magnetic flux of the induction coils (7). Induction coils (7) and steel cores (teeth) (6) for ease of assembly are distributed along the length of the stator (4) into groups (modules) (24). Modules (24) at the ends are closed by end caps (25) installed by a threaded or welding connection on the ends of the cylinders (5) of the stator (4). Between the end caps (25) of the adjacent modules (24) and the threaded or welding connection with the end caps (25), steel pipes (26) are mounted on which stainless steel support bushings (27) are concentrically (coaxially) with an inner diameter slightly smaller than the inner diameter the diameter of the thin-walled stator bushings forming the supporting sliding surfaces of the slider.

To fill transformer oil and place a splice (34) of the phase windings of the modules (24), intermodular cavities (33) are formed.

The reciprocating head (slider) (8) (Fig. 2) contains axially magnetized permanent magnets (11) and magnetically conductive steel cores (12) sequentially mounted on the hollow steel shaft (9). On the head of the reciprocating action (slider), consisting of a shaft (9), with permanent magnets (11) mounted on it and magnetically conducting cores (12), metal washers (28) of highly conductive metal (for example, aluminum, copper) are additionally periodically inserted with a diameter equal to the diameter of said permanent magnets and magnetically conductive cores. Permanent magnets (11) and steel cores (12) are fixed on the steel shaft (9) by end couplings (31) and (32). The lower end sleeve (32) is threaded for possible connection of the slider shaft (8) with the plunger (10) of the plunger pump (1), and the upper end sleeve (31) with a thread is made for fastening the discharge pipe (18). A threaded connection is attached to the cylindrical body (3) of the linear electric motor (2) by a current lead head (13) with a nipple (35) for suspending the pumping unit to the tubing string.

A channel (14) is made in the current lead head (13) of the electric motor for supplying the produced fluid from the plunger pump (1) through the hollow shaft (9) of the slider (8) to the tubing (not shown in the drawing) and a sealed connector (15) for connecting the phase ends windings (16) of a linear electric motor (2) with a cable entry sleeve for the supply cable (not indicated in the drawing), and also an upper oil valve (17) is made for pumping transformer oil into the intermodular cavity (33) of the stator (4). A lower oil bleed valve (19) is installed in the lower part of the stator (4).

The proposed linear motor operates as follows.

In field conditions, an electric motor installed in the well is connected to a submersible plunger pump (1) for reciprocating motion, containing a plunger (10), a suction valve (29), and a discharge valve (30). At the intake of the plunger pump (1), a filter (36) can be installed to protect against mechanical impurities.

The principle of operation is based on the fact that in a linear electric motor (2), when the windings of induction coils (7) of the stator (4) are powered by alternating three-phase current, the reciprocating head (slider) (8) under the influence of electromagnetic forces makes reciprocating movements, which transfers to the plunger (10) of the pump (1) rigidly connected to the slider. In this case, the produced fluid through the filter (36), suction (29), discharge (30) valves, a hollow plunger (9) and the channel (14) of the motor current lead (13) is pumped into the tubing (not shown).

The essence of the physics of the phenomena that determine the operation of the proposed electric motor can be explained as follows.

The electromagnetic forces that occur in a linear electric motor are due to several reasons:

firstly, with the passage of electric current through the coils (7) of the stator (4), the current conductors (turns of induction coils) are affected by the magnetic field created by the permanent magnets (11) of the slider (8), and this creates a force action Ampere Law;

secondly, the electric current in the stator (4) creates a running magnetic field, which induces loop currents in the slider (8). A traveling magnetic field, interacting with a current induced in a closed circuit, also creates axial-direction electromagnetic forces. To increase the contour currents and traction of the linear motor, ring gaskets (28) made of copper or aluminum are provided in the design of the slider (8). The total electromagnetic forces cause axial movement of the slider (8) and, accordingly, the plunger (10) relative to the stator (4) and the plunger pump housing (1).

In this case, with a direct alternation of the current phases set by the control station (not shown in the drawing), the system: a slider-plunger, move in one direction, with a reverse phase rotation - move in the other direction, ensuring stationary operation of the pump unit.

When the plunger pump is operating between the plunger (10) and the pump cylinder (1), the so-called “leakage fluid” is always pushed in the annular gap. It enters the gap between the slider (8) and the support sleeves (27) of the stator (4), while performing the function of lubricating and cooling the friction surfaces, which eliminates their overheating, and therefore ensures reliable operation of the electric motor.

When the proposed motor is operating under the influence of alternating current flowing in the stator coils (7) (4), active power is released and the stator (4) is heated. In the proposed design, additional cooling of the stator (4) is achieved due to the filling of the sealed cavities (33) of the stator (4) with transformer oil, which is heated from the coils (7) and removes heat both through the external housing (3) of the engine (2) and inside of the hollow shaft (9) of the slider (8) into the produced fluid exiting into the tubing through the channel (35) formed in the current lead head (13). An additional effect during the passage of the fluid flow through the hollow shaft (9) of the slider is its magnetization by the permanent magnets (11) of the slider (8) and, as a result, the reduction of paraffin deposits and the corrosivity of the liquid, which also ensures reliable operation of the engine as a whole.

To reduce the magnetic resistance, each magnetically conducting core (tooth) (6) of the stator (4) is made of a pair of monolithic packages of plates of electrotechnical iron, and the direction of the lines of force of the magnetic field created by induction coils (7) along the indicated charge plates provides the maximum value of the magnetic induction and maximum value of electromagnetic force.

When insulating induction coils (7), additional insulating gaskets (22) can be provided between adjacent adjacent coils of different phases, since it is taken into account that the voltage between the coils of different phases is linear, which is 1.73 times higher than the phase voltage between the coils and stator housing. This ensures a higher reliability of the electrical insulation of induction coils (7).

The design of the inventive submersible linear electric motor is made of structurally interconnected, as well as between the pump, which will be equipped with the specified engine when working in the well, structural units: cable - nipple (35) of the current lead head (13); current lead head (13) - linear motor housing (3) (2); linear motor housing (3) (2) - plunger pump housing (1); slider (8) of the linear motor (2) - plunger (10) of the plunger pump (1); induction coils (7) and stator cores (6) are divided into identical groups (modules) (24), which are connected in series along the length of the stator.

Thanks to this connection, maintainability of the engine is ensured.

Pilot-industrial and workshop tests of the proposed linear electric motor as part of submersible rodless pumping units were carried out at the oil fields of Perm Prikamye.

Based on the tests, the following area of optimal application of the inventive electric motor as a part of submersible rodless pump units has been determined:

- wells of an oil production fund with a design flow rate of 4 to 30 cubic meters / day .;

- wells with a depth of descent of the pump from 1500 m to 2500 m;

- wells with a complex design of the production string;

- wells that respond to seasonal injection, where the flow rate is periodically required;

- wells of the periodic stock;

- wells located at well sites with limited electric power;

- wells directional and horizontal.

As a result of experimental and field tests and workshop tests confirmed:

- increased traction of the proposed electric motor per unit length of a linear motor compared with analogues;

- improving the reliability of the electric motor compared to analogues, due to the strengthening of the electrical insulation of the stator coils, optimizing the thermal conditions of the linear motor, reducing friction and vibration when the slider moves;

- maintenance maintainability.

Claims (7)

1. Submersible linear electric motor, including a cylindrical housing, inside which a stator is placed with steel cores periodically mounted on thin-walled stainless steel bushings and interconnected by induction coils, forming groups of windings, between which support rails are installed, and a reciprocating action head - slider, consisting of a shaft made with the possibility of connection with the plunger of a submersible pump, with permanent magnets mounted on it and a magnet driving cores, characterized in that the linear electric motor is additionally equipped with a current lead head, in which a channel for supplying the produced fluid through the hollow shaft of the slider to the tubing and a sealed connector for connecting the phase windings of the linear electric motor with the cable entry coupling of the supply cable is made, and is also made a channel with an upper valve for pumping transformer oil into the gaps and stator cavities free of coils and cores, while in the lower part of the linear electro vigatelya channel configured with bottom valve for venting air from the cavities of the stator at their filling with transformer oil. 2. The linear electric motor according to claim 1, characterized in that each magnetically conducting stator core is made of pairs of monolithic packages of plates of electrotechnical iron, rigidly fastened together to form a magnetic circuit with the formation of teeth and grooves of the stator, while the radially located packages are teeth of the magnetic circuit, and axially located packets are the yoke of the magnetic circuit, with the possibility of creating the directivity of the magnetic field lines created by induction coils with tator, only along the lined plates of the magnetic circuit. 3. The linear electric motor according to claim 2, characterized in that the induction coils located between the teeth of the magnetic circuit are further isolated from the teeth by thin ring dielectric spacers. 4. The linear electric motor according to claim 1, characterized in that on a slider consisting of a shaft with permanent magnets and magnetically conductive cores mounted thereon, metal washers of high conductivity metal are additionally periodically installed, made with a diameter equal to the diameter of the permanent magnets and magnetically conductive cores . 5. The linear electric motor according to claim 4, characterized in that, for example, aluminum or copper is used as a metal of high conductivity. 6. The linear electric motor according to claim 1, characterized in that the permanent magnets mounted on the slider shaft are protected from abrasion around the perimeter by stainless steel bandages. 7. The linear electric motor according to claim 1 or 2, characterized in that the induction coils and magnetically conductive cores distributed along the length of the stator into equal groups and bounded by end caps into modules are rigidly interconnected along the entire length of the stator with steel pipes, while on steel stainless steel support bushings with an inner diameter slightly smaller than the inner diameter of the thin-walled stator bushings are coaxially mounted to form the supporting sliding surfaces of the slider.

Images