RU2402693C1 - One-screw hydraulic machine - Google Patents

Abstract

FIELD: oil and gas production.

SUBSTANCE: one screw hydraulic machine consists of stator with internal screw teeth 2 and of rotor 3 with external screw teeth 4. The stator has hollow case 5 with end threaded transition sections 6 and 7. Sleeve 8 is installed in the stator with a gap. The sleeve has internal screw teeth and facing 10 secured in it and repeating the shape of its internal surface; the facing is made out of elastomer. External surface of sleeve 8 and internal surface of hollow case 5 have irregularities. Irregularities are enveloped with alloy 14 fixing sleeve 8 relative to case 5 and filling the gap between internal surface of hollow case 5 and external surface of sleeve 8.

EFFECT: raised reliability of one-screw hydraulic machine at operation, simplified design and process of fabrication.

8 cl, 13 dwg

Description

The invention relates to the oil and gas industry, in particular to single-rotor hydraulic machines in the form of downhole screw motors for drilling oil and gas wells, screw pumps for oil production and pumping liquids and also general purpose screw motors.

Known single-screw hydraulic machine in the form of a downhole motor (see the book "Downhole motors", pp. 16-28. M: Nedra, 1999, authors DF Baldenko, FD Baldenko, A.N. Pus), containing a stator with internal helical teeth made of an elastic material, such as rubber, and a rotor with external helical teeth, the number of which is one less than the number of stator teeth. The rotor axis of the motor is offset relative to the stator axis by an eccentricity equal to half the radial height of the teeth, the profiles of the outer teeth of the rotor and the internal teeth of the stator in the end section are mutually enveloped, and the moves of the helical teeth of the rotor and stator are proportional to their number of teeth.

The disadvantage of this single-rotor hydraulic machine is the uneven thickness of the elastomeric stator lining with an increase in elastomer thickness in the protrusions of the stator teeth relative to the stator troughs. This leads to a non-uniform thermal expansion of the stator elastomeric tooth with respect to the stator cavity and increased heating of the deep layers of the elastomer in the stator protrusions during operation of the machine due to the low coefficient of thermal conductivity of the elastomer. In the heated inner layers of the teeth, the process of vulcanization of the elastomer continues, changing its physical properties, the elasticity becomes brittle. In the end, the difference in properties causes cracks and subsequent destruction of the elastomer, which significantly reduces the life of the machine.

In modern designs of stators, the inner side of the stator steel casing is faced with an uneven thickness layer of elastomer. This uneven thickness of the elastomer makes it difficult to remove heat, leads to uneven expansion of the elastomer in the stator with a violation of the geometry of engagement. The working load on the stator teeth leads to bending of the elastomeric teeth and violation of the tooth profile during machine operation, jamming of the rotor teeth relative to the elastomeric stator teeth with increasing working moment, while the efficiency of a single-screw hydraulic machine is significantly reduced.

Also known is the design of a single-rotor hydraulic machine in the form of a downhole motor containing the so-called "metal" stator with a constant thickness of the elastomeric casing (see the book "Downhole motors", page 200. M .: Nedra, 1999, authors D.F. .Baldenko, F.D. Baldenko, A.N. Gnoyev). In this engine, the inner surface of the stator housing is profiled by machining, and the bonded elastomeric lining is uniform in thickness. However, these downhole screw motors were not widely used due to the high technological cost of manufacturing the internal metal teeth of the stator.

The closest in technical essence to the proposed invention is known (patent No. 2320838, published 03/27/2008, priority 07.10.2006, authors V.G. Vorobyov, Yu.V. Zakharov, A.L. Popov and others. ) a single-screw hydraulic machine, the stator of which includes a hollow cylindrical body with end transitions, a sleeve installed in it with internal helical teeth and a lining fixed in it, repeating the shape of its inner surface and made of elastomer, the hollow cylindrical body and sleeve are made integral, the sleeve is equipped with holes in the area of the hollows of the helical teeth, is mounted in the housing on screws with an annular gap, which is filled with an elastomer through the holes in the sleeve, while in both end transitions of the housing there is a stepped sleeve, the shoulder of which abuts against the end of the sleeve and provided with a seal, and the outer surface of the other step smaller diameter compresses the end section of the lining to the inner surface of the sleeve. The disadvantage of this single-rotor hydraulic machine is the use of screws to install the sleeves in the hollow body, which requires threaded holes in the hollow stator housing to accommodate the screws. The holes in the hollow stator housing are stress concentrators for periodic elastic bends of the stator housing during the passage of curved sections of the well. Sometimes, with a small service life, the formation of a fatigue crack in the area of the threaded holes of the stator housing is possible, causing subsequent destruction of the housing and failure of the single-screw hydraulic machine. Holes in the hollow housing of the stator can also cause drilling fluid leakage through these holes, their subsequent erosion and failure of the single-screw hydraulic machine during leakage of the drilling fluid. This leads to the necessity of using stepped bushings with seals in this design installed in the end transitions of the housing, which leads to a rise in price and a decrease in the reliability of a single-screw hydraulic machine.

The present invention solves the problem of increasing the reliability of a single-rotor hydraulic machine, simplifying manufacturing technology, increasing the working moment and efficiency of a single-rotor hydraulic machine.

This technical result is achieved in that the single-screw hydraulic machine contains a stator with internal helical teeth and a rotor with external helical teeth, the number of which is one less than the number of stator teeth, and the rotor axis is offset relative to the stator axis by an eccentricity equal to half the radial height of the teeth, profiles the outer teeth of the rotor and the internal teeth of the stator in the end section are mutually enveloped, and the moves of the helical teeth of the rotor and stator are proportional to their number of teeth, while the ator comprises a hollow body with end threaded transitions, a sleeve installed therein with internal helical teeth and a lining fixed therein, repeating the shape of its inner surface and made of elastomer, in a single-screw hydraulic machine, the outer surface of the sleeve and the inner surface of the hollow body have irregularities of depth or a height of at least 0.1 millimeters, while the bumps are encircled by an alloy that secures the sleeve relative to the body and fills the gap between the inner surface of the floor of the housing and the outer surface of the sleeve, the alloy has a melting point of 0.05-0.75 the melting temperature of the material of the hollow housing of the stator, for example, as an alloy based on tin, zinc, aluminum or copper.

The technical result is preserved when irregularities on the outer surface of the stator sleeve and irregularities on the inner surface of the hollow stator housing are made in the form of protrusions and (or) recesses of a triangular or other shape.

The technical result is also preserved when irregularities on the outer surface of the stator sleeve and irregularities on the inner surface of the hollow stator housing are made in the form of grooves.

The technical result is also preserved when irregularities on the outer surface of the stator sleeve and irregularities on the inner surface of the hollow stator housing are made in the form of intersecting grooves.

The technical result is retained when irregularities on the outer surface of the stator sleeve and irregularities on the inner surface of the hollow stator housing are made in the form of a combination of surfaces with deviations of the relative position of the surfaces.

The technical result is also preserved when irregularities on the outer surface of the stator sleeve and irregularities on the inner surface of the hollow stator housing are made in the form of a combination of surfaces with mutual deviations of the shape of the surfaces.

The technical result is also preserved when irregularities on the outer surface of the stator sleeve and irregularities on the inner surface of the hollow stator housing are made in the form of a combination of surfaces with mutual deviations of the surface sizes.

The technical result is preserved when the screw gerotor machine is made in accordance with the above, while the transition surfaces of the irregularities on the outer surface of the stator sleeve and the transition surfaces of the irregularities on the inner surface of the hollow stator housing are rounded.

Distinctive features of the proposed single-screw hydraulic machine from the above, closest to it, are the following.

Firstly, a single-screw hydraulic machine contains a stator with internal helical teeth and a rotor with external helical teeth, the number of which is one less than the number of stator teeth, the rotor axis being offset relative to the stator axis by an eccentricity equal to half the radial height of the teeth, the profiles of the outer rotor teeth and the internal teeth of the stator in the end section are mutually enveloped, and the moves of the helical teeth of the rotor and stator are proportional to their number of teeth, while the stator contains a hollow body with an end threaded transitions, a sleeve installed in it with a gap with internal helical teeth and a lining fixed in it, repeating the shape of its inner surface and made of elastomer, in a single-screw hydraulic machine, the outer surface of the sleeve and the inner surface of the hollow body have irregularities of depth or height, at least 0.1 mm, with irregularities surrounding the alloy, fixing the sleeve relative to the body and filling the gap between the inner surface of the hollow body and the outer surface of lzy, the alloy has a melting point of 0.05-0.75 melting temperature of the material of the hollow stator housing, such as an alloy based on tin, zinc, aluminum or copper.

This embodiment of a single-screw hydraulic machine allows hermetically and more securely fasten the sleeve with internal helical teeth inside the hollow body. When using an alloy having a melting point of 0.05-0.85 the melting temperature of the material of the hollow housing of the stator, filling the gap with the alloy between the inner surface of the hollow housing and the outer surface of the sleeve, while the alloy encircling the bumps on the outer surface of the sleeve and the inner surface of the hollow body, durable one-piece connection of the sleeve with the housing at operating temperatures of a single-screw hydraulic machine. When using a sleeve with internal helical teeth and a lining fixed in it, repeating the shape of its inner surface and made of elastomer, the working moment and the efficiency of a single-screw hydraulic machine also increase. The design of the machine and manufacturing technology are simplified in the absence of the need for the use of stepped bushings with seals in the end transitions of the housing and the use of screws for installing the sleeve.

Secondly, when irregularities on the outer surface of the stator sleeve and irregularities on the inner surface of the hollow stator housing are made in the form of protrusions and (or) recesses of a triangular or other shape, the reliability of fixing the stator sleeve with internal teeth in the hollow stator housing also increases.

Thirdly, when irregularities on the outer surface of the stator sleeve and irregularities on the inner surface of the hollow stator housing are made in the form of grooves, the reliability of fixing the stator sleeve with internal helical teeth in the hollow stator housing also increases.

Fourth, when irregularities on the outer surface of the stator sleeve and irregularities on the inner surface of the hollow stator housing are made in the form of intersecting grooves, the reliability of fixing the stator sleeve with internal helical teeth in the hollow stator housing also increases.

Fifthly, when irregularities on the outer surface of the stator sleeve and irregularities on the inner surface of the hollow stator housing are made in the form of a combination of surfaces with deviations of the relative position of the surfaces, the reliability of fixing the stator sleeve with internal helical teeth in the hollow stator housing also increases.

Sixthly, when irregularities on the outer surface of the stator sleeve and irregularities on the inner surface of the hollow stator housing are made in the form of a combination of surfaces with mutual deviations of the surface shape, the reliability of fixing the stator sleeve with internal helical teeth in the hollow stator housing also increases.

Seventh, when irregularities on the outer surface of the stator sleeve and irregularities on the inner surface of the hollow stator housing are made in the form of a combination of surfaces with mutual deviations of the surface sizes, the reliability of fixing the stator sleeve with internal helical teeth in the hollow stator housing also increases.

Eighth, when the transition surfaces of the irregularities on the outer surface of the stator sleeve and the transition surfaces of the irregularities on the inner surface of the hollow stator housing are rounded, the reliability of fixing the stator sleeve with internal helical teeth in the hollow stator housing also increases.

Single-screw hydraulic machine is illustrated by the drawings shown in figures 1-13.

Figure 1 shows a General view of a single-screw hydraulic machine.

Figure 2 shows a section aa of a General view of a single-screw hydraulic machine.

Figure 3 shows a perspective view of the stator and rotor of a single-screw hydraulic machine.

Figure 4 shows the deepening irregularities made on the inner surface of the hollow stator housing, with a depth S.

Figure 5 shows the protrusions of irregularities made on the inner surface of the hollow stator housing, with a height F.

Figure 6 shows the irregularities in the form of intersecting grooves made on the inner surface of the hollow stator housing.

Figure 7 shows the rounded transition surfaces of the irregularities on the inner surface of the hollow stator housing.

On Fig shows irregularities on the inner surface of the hollow stator housing, made in the form of a combination of surfaces with deviations of the relative position of the surfaces.

Figure 9 shows the irregularities on the outer surface of the stator liner, made in the form of a combination of surfaces with deviations of the relative positions of the surfaces.

Figure 10 shows the irregularities on the inner surface of the hollow stator housing, made in the form of a combination of surfaces with mutual deviations of the shape of the surfaces.

Figure 11 shows the irregularities on the outer surface of the stator liner, made in the form of a combination of surfaces with mutual deviations of the shape of the surfaces.

On Fig shows irregularities on the inner surface of the hollow stator housing, made in the form of a combination of surfaces with mutual deviations of the dimensions of the surfaces.

On Fig shows irregularities on the outer surface of the stator liner, made in the form of a combination of surfaces with mutual deviations of the dimensions of the surfaces.

Single-screw hydraulic machine (figure 1), contains a stator 1 with internal helical teeth 2 and a rotor 3 with external helical teeth 4, the number of which is one less than the number of teeth 2 of the stator 1, and the axis O ₁ -O _{1 of the} rotor 3 is offset relative to the axis O _2- O _{2 of} stator 1 by the eccentricity value E (Fig. 2) equal to half the radial height h of teeth 2, 4, the profiles of the external teeth 4 of the rotor 3 and the internal teeth 2 of the stator 1 in the end section are mutually enveloped, and the passages (Fig. 1) Tr and Tst of helical teeth 4 and 2 of the rotor 3 and stator 1 are proportional to their number of teeth 4 and 2, wherein the stator 1 comprises a hollow body 5 with end threaded transitions 6 and 7, a sleeve 8 with internal helical teeth 9 and a lining 10 fixed therein, repeating the shape of its inner surface and made of elastomer, installed therein in a single-rotor hydraulic machine, the outer surface 11 of the sleeve 8 and the inner surface 12 of the hollow body 5 have irregularities 13 with a depth or height of at least 0.1 millimeters, while the irregularities 13 are surrounded by an alloy 14, fixing the sleeve 8 relative to the housing 5 and filling azor 15 between the inner surface 12 of the hollow body 5 and the outer surface 11 of the sleeve 8, the alloy 14 has a melting temperature of 0.05-0.75 the melting temperature of the material of the hollow body 5 of the stator 1, for example, as an alloy based on tin, zinc, aluminum or copper.

Irregularities 13 on the outer surface 11 of the sleeve 8 of the stator 1 and irregularities 13 on the inner surface 12 of the hollow body 5 of the stator 1 are made in the form of protrusions 16 and (or) recesses 17 of a triangular or other shape (figure 4 and figure 5).

Irregularities 13 on the outer surface 11 of the sleeve 8 of the stator 1 and irregularities 13 on the inner surface 12 of the hollow body 5 of the stator 1 are made in the form of grooves 18 (Fig.6).

Irregularities 13 on the outer surface 11 of the sleeve 8 of the stator 1 and irregularities 13 on the inner surface 12 of the hollow body 5 of the stator 1 are made in the form of intersecting grooves 18 (Fig.6).

Irregularities 13 on the outer surface 11 of the sleeve 8 of the stator 1 and irregularities 13 on the inner surface 12 of the hollow body 5 of the stator 1 are made in the form of a combination of surfaces with deviations of the relative position of the surfaces (Fig. 8 and Fig. 9).

Irregularities 13 on the outer surface 11 of the sleeve 8 of the stator 1 and irregularities 13 on the inner surface 12 of the hollow body 5 of the stator 1 are made in the form of a combination of surfaces with mutual deviations of the shape of the surfaces (Fig. 10 and Fig. 11).

Irregularities 13 on the outer surface 11 of the sleeve 8 of the stator 1 and irregularities 13 on the inner surface 12 of the hollow body 5 of the stator 1 are made in the form of a combination of surfaces with mutual deviations of the dimensions of the surfaces (Fig. 12 and Fig. 13).

The transition surfaces 19 of the bumps 13 on the outer surface 11 of the sleeve 8 of the stator 1 and the transition surfaces 19 of the bumps 13 on the inner surface 12 of the hollow body 5 of the stator 1 are rounded (Fig. 7).

Single-screw hydraulic machine in the downhole motor mode operates as follows.

The working fluid supplied under pressure from the day surface through the drill pipe string (not shown) enters the upper part of the single-screw hydraulic machine, and as a result of the helical direction of the teeth 2 and 4 of the stator 1 and rotor 3 under the influence of unbalanced hydraulic forces, the rotor 3 is rotated while its axis O ₁ -O ₁ rotates around the axis O ₂ -O _{2 of the} stator 1 counterclockwise around a circle of radius E, and the rotor 3 itself rotates about its axis O ₁ -O ₁ clockwise. The hollow body 5 of the stator 1 perceives bending loads from the walls of the borehole, as well as compression and tensile loads from the drill pipe string and the bottom hole. The circumferential force, proportional to the developed torque of the rotor 3, is perceived by the internal helical teeth 9 of the sleeve 8 through the elastomeric lining 10, bonded to the internal screw teeth 9 of the sleeve 8. The peripheral force closes on the hollow body 5 of the stator 1, mounted on the drill pipe string (not shown) through the alloy 14, surrounding the bumps 13 and filling the gap 15 between the inner surface 12 of the hollow body 5 and the outer surface 11 of the sleeve 8 and securing the sleeve 8 relative to the housing 5. When using alloy 14 having a melting point of 0.05-0.85 melting temperature of the material of the hollow body 5 of the stator 1, filling with alloy 14 of the gap 15 between the inner surface 12 of the hollow body 5 and the outer surface 11 of the sleeve 8 and at the same time, the alloy 14 surrounds the irregularities 13 of the outer surface 11 of the sleeve 8 and the inner surface 12 of the hollow body 5 creates a strong integral connection of the sleeve 8 with housing 5 at operating temperatures of a single-screw hydraulic machine. When using a sleeve 8 with internal helical teeth 9 and a lining 10 fixed in it, repeating the shape of its inner surface and made of elastomer, the working moment and efficiency of a single-screw hydraulic machine also increase. Simplified machine design and manufacturing technology.

Claims (8)

1. A single-screw hydraulic machine containing a stator with internal helical teeth and a rotor with external helical teeth, the number of which is one less than the number of stator teeth, the rotor axis being offset relative to the stator axis by an eccentricity equal to half the radial height of the teeth, the profiles of the outer teeth of the rotor and the internal stator teeth in the end section are mutually enveloped, and the moves of the helical teeth of the rotor and stator are proportional to their number of teeth, while the stator contains a hollow body with end threads transitions installed in it with a gap sleeve with internal helical teeth and a lining fixed in it, repeating the shape of its inner surface and made of elastomer, characterized in that the outer surface of the sleeve and the inner surface of the hollow body have irregularities of depth or height, at least 0 , 1 mm, while the irregularities are encircled by the alloy, fixing the sleeve relative to the body and filling the gap between the inner surface of the hollow body and the outer surface of the sleeve, the alloy has a pace rature melting component 0.05-0.75 melting temperature of the material of the hollow stator housing, such as an alloy based on tin, zinc, aluminum or copper. 2. The single-screw hydraulic machine according to claim 1, characterized in that the irregularities on the outer surface of the stator sleeve and the irregularities on the inner surface of the hollow stator housing are made in the form of protrusions and (or) recesses of a triangular or other shape. 3. The single-screw hydraulic machine according to claim 1, characterized in that the bumps on the outer surface of the stator sleeve and the bumps on the inner surface of the hollow stator housing are made in the form of grooves. 4. The single-screw hydraulic machine according to claim 1, characterized in that the irregularities on the outer surface of the stator sleeve and the irregularities on the inner surface of the hollow stator housing are made in the form of intersecting grooves. 5. The single-screw hydraulic machine according to claim 1, characterized in that the irregularities on the outer surface of the stator sleeve and the irregularities on the inner surface of the hollow stator housing are made in the form of a combination of surfaces with deviations of the relative positions of the surfaces. 6. The single-screw hydraulic machine according to claim 1, characterized in that the bumps on the outer surface of the stator sleeve and the bumps on the inner surface of the hollow stator housing are made in the form of a combination of surfaces with mutual deviations of the surface shape. 7. The single-screw hydraulic machine according to claim 1, characterized in that the bumps on the outer surface of the stator sleeve and the bumps on the inner surface of the hollow stator housing are made in the form of a combination of surfaces with mutual deviations of the surface sizes. 8. A single-screw hydraulic machine according to claims 1 to 7, characterized in that the transitional surfaces of the irregularities on the outer surface of the stator sleeve and the transitional surfaces of the irregularities on the inner surface of the hollow stator housing are rounded.

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