RU2515627C1 - Hydraulic downhole motor - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: device contains a hollow body with a gerotor screw mechanism inside that includes a stator placed in the body coaxially and a rotor installed inside the stator and the rotor rotation is carried out by fluid delivered by the pump, a transmission section that includes a shaft mounted at the axial bearing made as a multirow thrust and radial bearing and at the upper and lower radial skid bases consisting of the outer and inner sleeves placed in the transmission section body and respectively at the transmission section shaft; the transmission section shaft is fixed at the input by a drive shaft with a rotor and at the output it is fixed with a chisel; the motor is equipped with the upper collar grab consisting of a shaft, a thrust and a nut and the lower collar grab made as a fishing collar with the outer fishing clamp, a thrust collar and the lower threaded crossover with an inner fishing clamp; the upper collar grab is fixed to the upper part of the gerotor screw mechanism while the lower collar grab in mounted at the transmission section shaft between the inner sleeve of the lower radial bearing and the axial bearing made as a multirow thrust and radial bearing. The transmission section shaft and the fishing collar of the lower collar grab with the outer fishing clamp are fixed rigidly with each other by means of a common thread thus providing tightness at butt ends of the thrust collar placed between butt ends of the fishing collar and the inner collar of the lower radial skid base. Cross-threading direction of the transmission section shaft and the fishing collar of the lower collar grab coincide with the direction of drill string rotation during tripping out.

EFFECT: improving accident-free operation, service life and reliability of motors, accuracy of hole making and the rate of parameters set for the hole curvature and passing ability.

5 cl, 2 dwg

Description

The invention relates to hydraulic actuators for rotary drilling, placed in wells, and can be used for rotary drilling of horizontal horizontal oil well shafts with screw gerotor hydraulic motors.

A hydraulic downhole motor is known, comprising a hollow body, a drive with a rotor located inside it, and a spindle mounted inside the spindle body on axial and radial bearings, equipped with a chisel and connected by a drive shaft with a rotor, the motor and spindle bodies are connected by curved threaded adapters, and the rotor and the spindle are connected to the drive shaft, equipped with a leading and driven hinge assemblies with axial sliding bearings by means of threaded adapters, the spindle housing is made with a transverse connector between the axial and radial bearings on the bit side, the spindle is made with an annular groove in the plane of the transverse connector of the spindle housing, a split ring is installed in the groove, the diameter of which exceeds the diameter of the spindle, a support sleeve and a catcher ring are fixed inside the spindle housing, and a radial support of the spindle housing on the bit side, it is made in the form of an elastic-elastic sliding support mounted on a removable sleeve and fixed inside the spindle housing, while the distance between the axial bearings of the drive shaft is not pre yshaet axial length of the support spindle (RU 2232859, 20.07.2004).

A disadvantage of the known engine is the execution of the spindle shaft 6 with an annular groove 23 located between the lower radial support 9 and the axial support 10, which weakens its cross section, increases the maximum values of the transverse stresses arising from the action of bending moments of the bit on the spindle shaft when using the motor in controlled layout of the bottom of the drill string in areas of change in the curvature of the wells.

The disadvantages of the known engine are also the deterioration of the cooling of the lower radial slide bearings by the pumped drilling fluid, the incomplete possibility of increasing the resource and reliability of the engine spindle, reducing the accident rate when raising the downhole motor from the wells when drilling directional and horizontal wells, as well as the incomplete possibility of improving the accuracy of well drilling and the pace of a set of parameters of the curvature of the wells, increasing patency, i.e. reducing the resistance and stresses in the layout of the bottom of the drill string when using the engine in the controlled layout of the bottom of the drill string in areas of change in the curvature of the wells.

A known hydraulic rotor motor containing a hollow housing, a multi-start rotor mechanism located inside it, including a coaxially mounted stator and a rotor installed inside the stator, as well as a spindle, including a spindle shaft located in rotation bearings in the spindle housing and connected to the input shaft with a rotor by an input shaft, and at the exit, with a chisel, the motor and spindle housings being connected by a curved sub with threads at its edges (RU 2162132, 01.20.2001).

A disadvantage of the known design is the incomplete possibility of using lateral horizontal oil well shafts during rotary drilling due to the fact that the "spindle body from the side of its end facing the bit has a circumferential rib covering the spindle shaft with a clearance, and the spindle shaft has a circumferential collar located between the rotation support and the circumferential rib, while the circumferential collar on the spindle shaft and the circumferential rib in the spindle housing are made as continuous, mating threads, the direction of inchivaniya spindle shaft and the housing is opposite the direction of rotation of the spindle shaft. "

The disadvantage of the known design is due to the "unscrewing" of the destroyed (cut) part of the hollow shaft 4 of the spindle with the adapter sleeve 8 and a bit (not shown) on the thread 17 from the thread 18 in the peripheral rib 15 in the spindle housing 6 when the shaft 4 of the spindle is destroyed above the end face 16 due to that the drill strings are rotated to the right by the rotor of the drilling rig, for example, 5000EU relative to the rotor table when lifting from the wells at drilling rigs in the Russian Federation, while the bit and spindle shaft are irretrievably lost in the well.

Another disadvantage of the known design is the incomplete ability to reduce the distance from the bit to the lower radial sliding support ("outreach" of the bit), which does not provide the possibility of increasing the resource and reliability of the spindle section, as well as improving the accuracy of well drilling.

A hydraulic downhole motor is known, comprising a housing with a rotor located inside it, rotatable by pumping fluid, a spindle housing with a spindle shaft located inside it, mounted on an axial support, made in the form of an axial-radial multi-row bearing, and also upper and lower radial sliding bearings, a threaded sub attached to the motor and spindle housings, the spindle shaft containing a fishing collar, connected to a rotor by a drive shaft ohm and fastened with a chisel, and a nut made with a fishing belt is fixed on the thread of the spindle body, while the spindle shaft is made with a centering belt and a thread located between the lower radial sliding support and the output part of the shaft intended for fastening the bit, the fishing collar is made in a fishing ring mounted on the centering belt of the spindle shaft, a threaded sleeve is installed on the spindle shaft that secures the fishing ring, the nut fishing belt is made with grooves whose width and diameter exceed the corresponding etstvenno cross-sectional thickness and diameter of the picker ring nut inside an annular cavity communicating with the slots picker belt, and the diameter of the annular cavity exceeds the diameter of the picker in the picker shoulder ring (RU 2367761, 20.09.2009).

A disadvantage of the known design is the incomplete ability to reduce the distance from the bit to the lower radial sliding support ("outreach" of the bit), which negatively affects the resource of the support unit, as well as the incomplete ability to reduce accident rate when lifting a downhole motor with a string of drill pipes from horizontal horizontal oil well bores , improving the accuracy of penetration and the pace of a set of parameters of well curvature, as well as improving patency, i.e. reducing the resistance and stresses in the layout of the bottom of the drill string when using the engine in a horizontal controlled layout of the bottom of the drill string in areas of change in the curvature of the wells.

A hydraulic downhole motor with a diamond sliding support is known, comprising a motor housing with a rotor located inside it, as well as a spindle housing with a shaft located inside it mounted on radial and axial sliding bearings, the spindle shaft is connected by a drive shaft to the motor rotor and fastened to the bit, part fluid is pumped through radial and axial sliding bearings, and the axial bearing is made in the form of two pairs of rotor and stator rings with an annular row of thrust modules fixed in each of them, the torus rings are bonded to the spindle housing, the rotor rings are bonded to the spindle shaft, and each thrust module contains a layer of polycrystalline diamonds at the end facing the ends of adjacent modules and alternately contacts one or two ends of adjacent modules (US 4620601, Nov.4, 1986 )

A disadvantage of the known design is the execution of the spindle shaft without a fishing collar, and the nipple without a fishing belt, which eliminates the possibility of lifting with a string of drill pipes from the horizontal lateral oil shafts when the spindle shaft is destroyed.

Closest to the claimed design is a downhole motor containing a hollow body, a gerotor mechanism located inside it, including a stator coaxially located in the body and a rotor installed inside the stator, as well as a spindle section, including a shaft with an axial bearing, located in the upper and lower radial bearings consisting of outer and inner bushings and housed in the housing of the spindle section, connected at the input by a drive shaft with a rotor, and at the output - a lower sub with a chisel, adjustable a movable sub mounted between the gerotor mechanism and the housing of the spindle section, while the engine is equipped with an upper emergency device consisting of a shaft, a stop and a nut, and a lower emergency device made in the form of a figured sleeve, the upper emergency device is connected to the rotor of the gerotor mechanism, and the lower an emergency device is mounted on the shaft of the spindle section and is located between the inner sleeve of the lower radial support and the axial bearing, the shaft of the spindle section has circumferential collar, and the figured sleeve - the inner and outer circumferential collars, while the circumferential collar of the spindle shaft shaft and the inner collar of the curly sleeve are made in the form of a screw thread with a direction opposite to the rotation of the spindle section shaft, with the possibility of stopping the circular collar of the spindle section shaft in the inner collar of the figured sleeve, and the outer shoulder of the figured sleeve abuts against the thrust end of the lower sub, while the outer sleeve of the lower radial support is attached to the case of the lower sub so that the extreme torus The core surfaces of the radial support and the lower sub body are the same (RU 2299302, 05.20.2007).

The disadvantages of the known downhole hydraulic motor are the incomplete ability to reduce accidents during rotary drilling of horizontal lateral oil shafts, essentially when lifting with rotation of the drill string with a bit when breaking the shaft of the spindle section, the incomplete possibility of increasing the resource and reliability of the engine, improving the accuracy of well drilling and pace a set of parameters of well curvature, as well as increasing patency, i.e. reduce resistance and stress in the layout of the bottom of the drill string.

The main disadvantage of the known construction is explained by the fact that "the circumferential collar of the shaft of the spindle section and the inner collar of the figured sleeve are made in the form of a screw thread with the direction opposite to the rotation of the shaft of the spindle section", as a result of which the direction of the screw thread of the outer collar of the figured sleeve of the lower anti-emergency device mounted on the shaft spindle section and located between the inner sleeve of the lower radial support and the axial bearing, does not coincide with the direction of rotation of the drill string with two a digger and a chisel when lifting from a well.

Drill strings when lifting from wells at drilling rigs in the Russian Federation during rotary drilling of oil wells with rotary gerotor hydraulic motors rotate the rotor of the drill rig, for example, 5000EU to the right (the right threads of the drill string), as a result of this, in the known construction, the damaged part of the hollow shaft 4 is turned away spindle section with a transition sleeve 8 and a bit (not shown) on the thread 17 of the thread 18 in the peripheral rib 15 in the housing 6 of the spindle section when the shaft 4 of the spindle is destroyed sections above the end face 16, and the destroyed part of the shaft of the spindle section and the bit are irretrievably lost in the well.

Another disadvantage of the known design is the location of the thread and the annular groove (stress concentrators) on the shaft of the spindle section (on a diameter smaller than the diameter of the inner sleeve of the lower radial support) between the axial and lower radial bearings (in a dangerous section), which weaken the shaft of the spindle section, reduce strength and fatigue endurance of the shaft from the action of the maximum values of transverse stresses arising from the bending moments of the bit on the shaft of the spindle section when passing through the radius borehole shaft, as well as when the bearings of the axial support are worn (axial play of the shaft of the spindle section is allowed, for example, up to 5.5 mm).

This embodiment of the emergency device increases the bending stress coefficient (Stress ratio, the ratio of the changing voltage amplitude to the average voltage), increases the likelihood of destruction of the shaft of the spindle section between the axial and lower radial bearings, and when the shaft of the spindle section is destroyed in the annular belt "a" the bit and shaft irretrievably lost in the well.

Another disadvantage of the known design is the implementation of the figured sleeve 24 with the inner 27 and outer 28 circumferential fishing collars, which increases the diameter of the spindle section or reduces the strength of the fishing collars and the dangerous section of the shaft of the spindle section when the emergency device is located between the inner sleeve of the lower radial support and the axial bearing: ring the belt "a" between the belt "in" and the lower radial sliding support 9.

This is explained by the need for double "overlapping" (minimum overlap of 4 ÷ 5 mm is required) of fishing collars: a circular collar "in" the spindle shaft shaft and inner collar 27 of the figured sleeve 24, as well as "overlapping" circumferential collar 28 of the figured sleeve 24 relative to end 29 and the inner diameter of the lower sub housing 30.

The life and reliability of the spindle section are determined by the wear of the axial support of the shaft of the spindle section, made in the form of a thrust-radial multi-row bearing, (axial play of the shaft of the spindle section, for example, up to 5.5 mm is allowed), as well as the wear of the lower radial sliding support, (radial is allowed backlash of the shaft of the spindle section, for example, not more than 1.55 mm), and if the radial backlash of the shaft of the spindle section in the lower radial support is exceeded, drilling of horizontal lateral oil shafts is not allowed.

The disadvantages of the known design are also explained by the large value of the stress coefficient in the radial sliding bearings and in the thrust-radial multi-row bearing of the shaft of the spindle section (Stress ratio, the ratio of the changing voltage amplitude to the average voltage), essentially equal to (5.4 ÷ 7.8), as well as the high probability of resonance vibrations and “sticking” under the action of maximum axial and radial loads (from the bit) in a curved drill pipe string, when the sign of the axial load acting on the thrust dially multi-row bearing.

The technical result of the invention is to reduce the accident rate when using a downhole hydraulic motor in the layout of the bottom of the drill string for rotary drilling of horizontal lateral oil wells, increasing the resource and reliability of the engine, increasing the accuracy of well penetration and the rate of set of parameters of the curvature of the wells, as well as increasing patency, i.e. . reducing the resistance and stresses in the layout of the bottom of the drill string due to the rigid fastening of the shaft of the spindle section and the fishing sleeve of the lower fishing device to each other using a common thread, ensuring an interference fit at the ends of the thrust ring located between the ends of the fishing sleeve and the inner sleeve of the lower radial sliding support, and also due to the fact that the direction of make-up of the thread of the shaft of the spindle section and the fishing sleeve of the lower fishing device coincides with the direction of rotation of the drill Lonna during lifting of the well.

This technical result is achieved in that in a hydraulic downhole motor, which during operation can be used in a rotary drill string containing a hollow body, a gerotor screw mechanism located inside it, including a stator coaxially located in the body and a rotor installed inside the stator, the rotation of which is carried out by pumping a fluid medium, a spindle section including a shaft mounted on an axial support, made in the form of a radial thrust bearing and on the upper and lower radial sliding bearings, consisting of the outer and inner bushings located in the housing of the spindle section, and accordingly, on the shaft of the spindle section, the spindle section shaft is fastened at the inlet by a drive shaft with a rotor, and at the output is fastened with a bit , the engine is equipped with an upper fishing device, consisting of a shaft, a stop and a nut, and a lower fishing device, made in the form of a fishing sleeve with an external fishing collar, a thrust ring and a lower threaded sub with an internal fishing m collar, the upper fishing device is attached to the upper part of the rotor of the gerotor screw mechanism, and the lower fishing device is mounted on the shaft of the spindle section between the inner sleeve of the lower radial support and the axial support, made in the form of a thrust-radial multi-row bearing, according to the invention, the shaft of the spindle section and fishing the sleeve of the lower fishing device with an external fishing collar is rigidly fastened together using a common thread with the possibility of providing an interference fit at the ends of the thrust ring Disposed between the ends of a fishing sleeve and the inner sleeve bottom radial sliding bearing, wherein the screwing direction of the shaft section and the thread of the spindle sleeve of the lower a fishing picker coincides with the direction of rotation of the drill string from the borehole while lifting.

The diameter D of the inner fishing belt in the lower threaded sub and the outer diameter D _{1 of the} fishing collar of the fishing sleeve of the lower fishing device are related by the ratio: D = D ₁ - (0.03 ÷ 0.05) D.

The thrust ring of the lower radial sliding support is made with an outer collar in contact with the inner sleeve of the lower radial sliding support, while the diameter of the outer collar of the thrust ring does not exceed the outer diameter of the inner sleeve of the lower radial sliding support.

The outer sleeve of the lower radial sliding support and the lower threaded sub are made in the form of a single design with hard alloy plates, while the hard alloy plates are installed in the inner bore of the lower threaded sub and fastened together by impregnation of the hard alloy with solder-binder components.

The molten ligament-solder powder for fixing carbide plates in the lower threaded sub contains components in the following ratio, wt.%: Ni 32 ÷ 47, Fe 2, Cr 7 ÷ 14, Si 2, WC, the rest.

The execution of the hydraulic downhole motor in such a way that the shaft of the spindle section and the fishing sleeve of the lower fishing device with the external fishing collar are rigidly fastened together using a common thread with the possibility of tightness at the ends of the thrust ring located between the ends of the fishing sleeve and the inner sleeve of the lower radial sliding support while the direction of screwing the threads of the shaft of the spindle section and the fishing sleeve of the lower fishing device coincides with the direction of rotation of the drill of the casing when lifting from the well, reduces the accident rate when using the hydraulic downhole motor when lifting with rotation of the drill string with a bit from the side of the well bore when the spindle shaft is destroyed, increases the resource and reliability of the engine, the accuracy of the penetration of the wells and the rate of set of parameters of the curvature of the wells, and provides increased cross-country ability, i.e. reduces the resistance and stress during rotary drilling of horizontal lateral oil well bores when the bearings of the axial support of the spindle section wear, made in the form of an axial-radial multi-row bearing, for which axial play of the shaft of the spindle section is allowed, for example, to 5.5 mm.

This embodiment of the spindle section of the hydraulic downhole motor reduces the stress coefficient in the radial sliding bearings and in the thrust radial multi-row bearing of the shaft of the spindle section (Stress ratio, the ratio of the changing voltage amplitude to the average voltage), essentially equal to (3.1 ÷ 4.5 ), reduces the likelihood of resonant vibrations, “sticking” under the action of maximum axial and radial loads (from the bit) in a curved drill pipe string, when the sign of the axial load changes, the current th on a thrust-radial multi-row bearing, during rotary drilling of horizontal lateral oil shafts, and when the shaft of the spindle section is destroyed, the bit and shaft of the spindle section freely rise from the well with the right rotation of the drill pipe string.

The performance of the hydraulic downhole motor in such a way that the diameter D of the inner fishing belt fixed in the housing of the spindle section of the lower threaded sub and the outer diameter D _{1 of the} fishing collar of the fishing sleeve of the lower fishing device are related by the ratio: D = D ₁ - (0.03 ÷ 0, 05) D, provides minimal "overlap" of the fishing belt in the fishing sleeve above the fishing collar of the lower threaded sub, reliable retention of the ragged shaft of the spindle section with a chisel at given external diameters of the threads compound of the spindle housing and the lower section of the threaded sub, slice and prevents collapse of the picker in a fishing collar sleeve.

The execution of the hydraulic downhole motor in such a way that the thrust ring is made with an outer collar in contact with the inner sleeve of the lower radial sliding support, while the maximum diameter of the outer collar of the thrust ring does not exceed the outer diameter of the inner sleeve of the lower radial sliding support, simplifies the replacement and repair of axial bearing assemblies and radial bearings during the development of the resource, reduces the maximum values of transverse stresses arising from the bending of the shaft of the spindle section with a bit, and yatnost fracture shaft spindle section in the zone between the center and bottom radial supports the spindle section and also increases the strength and fatigue endurance common shaft threaded joint spindle section with a fishing sleeve when passing through the radius portions of the borehole in a friction and rotation in the wellbore.

The execution of the hydraulic downhole motor in such a way that the outer sleeve of the lower radial sliding support and the lower threaded sub is made in the form of a single design with hard alloy plates, while the hard alloy plates are installed in the inner bore of the lower threaded sub and fastened together by impregnation of the hard alloy with components ligament-solder, while the molten powder of the ligament-solder for mounting plates of hard alloy in the lower threaded sub contains components in the following ratio, wt.%: Ni 32 ÷ 47, Fe 2, Cr 7 ÷ 14, Si 2, WC, the rest increases the resource and reliability of the engine, the accuracy of well penetration and the pace of the set of parameters of the curvature of the wells, and also provides increased throughput, t. e. reduces the resistance and stress during rotary drilling of horizontal lateral oil wellbores, essentially when the lower radial sliding bearing is worn, for which radial play of the shaft of the spindle section is allowed, for example, not more than 1.55 mm, and when the radial play of the shaft of the spindle section is exceeded in lower radial support is not allowed to drill horizontal lateral oil shafts.

This technical result also provides the use of a bit of the same diameter in two adjacent sizes of the layout of the bottom of the drill string, although increasing the outer diameter of the housing in the lower part of the spindle requires a transition to a larger diameter of the bit.

The following is a DRU1-73RS gerotor screw hydraulic motor with a shortened spindle section, angle adjuster, chisel, upper and lower borehole catchers, used for rotary drilling of horizontal lateral oil shafts.

Figure 1 shows a longitudinal section of a gerotor screw hydraulic motor with a spindle section, an angle adjuster, upper and lower downhole catchers and a chisel.

Figure 2 shows the element I in figure 1 of the lower fishing device of the spindle section.

The downhole hydraulic motor comprises a hollow housing 1 with an elastomer cover 2 fixed inside it and a multi-helical rotor rotor 3 located in the housing cover 2, the planetary-rotor rotation of the rotor 3 is carried out by pumping fluid 4, the housing 5 of the spindle section 6 with a shaft located inside it 7 of the spindle section 6 mounted on an axial support 8, made in the form of a thrust-radial multi-row ball bearing 9, as well as on the upper 10 and lower 11 radial sliding bearings, consisting of an outer the sleeves 12 and the inner sleeve 13 of the upper radial slide bearing 10, and respectively, from the lower threaded sub 14 and the inner sleeve 15 of the lower radial slide 11 located respectively in the housing 5 of the spindle section 6, in the lower threaded adapter 14 and on the shaft 7 of the spindle section 6, shown in figures 1, 2.

The shaft 7 of the spindle section 6 is fastened at the inlet 16 by a drive (cardan) shaft 17 with the rotor 3 by means of a threaded connection 18 to the output housing 19 of the cardan shaft 17, and by means of a threaded connection 20, the input housing 21 of the cardan shaft 17 is fastened to the output part 22 of the rotor 3 , while the output 23 of the shaft 7 of the spindle section 6 is fastened with a bit 24 using a threaded connection 25, shown in Fig.1, 2.

The engine is equipped with an upper fishing device 26, consisting of a shaft 27, a stop 28 and a nut 29 and is equipped with a lower fishing device 30, made in the form of a fishing sleeve 31 with a fishing collar 32 and a thrust ring 33, while the upper fishing device 26 is rigidly fastened with threads 34 with the upper part 35 of the rotor 3 of the gerotor screw mechanism, and the lower fishing device 30 is mounted on the shaft 7 of the spindle section 6 between the inner sleeve 15 of the lower radial support 11 and the axial support 8, made in the form of a persistent-radial multi-row bearing 9, shown in figures 1, 2.

In addition, figure 1, 2 shows: pos.36 - additional thrust ring located between the end face 37 of the inner sleeve 15 of the lower radial bearings 11 and the end face 38 of the shaft 7 of the spindle section 6; Pos. 39 - carbide plates fastened by impregnation of the hard alloy with the components of the solder bond in the lower threaded sub 14, while the outer sleeve of the lower radial sliding support and the lower threaded sub 14 are made in the form of a single design with carbide plates; Pos.40 - plates made of hard alloy fastened by impregnation of the hard alloy with components of the ligament-solder in the inner sleeve 15 of the lower radial sliding support 11.

The hardness of the plates 39, 40, for example, from a tungsten-cobalt carbide carbide, is (89 ÷ 92) HRA, the thickness of the plates is (2.5 ± 0.5) mm, the molten binder-solder powder for fastening the plates 39, 40 of the hard alloy contains components in the following ratio, wt.%: Ni 32 ÷ 47, Fe 2, Cr 7 ÷ 14, Si 2, WC the rest, the hardness of the material formed by impregnation of the hard alloy with components of the solder binder is (52 ÷ 65) HRC shown in figures 1, 2.

The shaft 7 of the spindle section 6 and the fishing sleeve 31 with a fishing collar 32 of the lower fishing device 30 are rigidly fastened together by a common thread 41 with the possibility of providing an interference fit of 0.13 ÷ 0.33 mm at the ends 42, 43 of the thrust ring 33 located between the end 44 of the fishing sleeve 31 and the end face 45 of the inner sleeve 15 of the lower radial sliding support 11, while the screwing direction of the thread 41 of the shaft 7 of the spindle section 6 and the fishing sleeve 31 of the lower fishing device 30 coincides with the rotation direction of the drill string (not shown in FIG. ) At the rise of the wells 1, 2.

The thrust ring 33 is made with an outer collar 46 in contact with the end 42 of the outer collar 46 with the end face 45 of the inner sleeve 15 of the lower radial bearing 11, while the maximum diameter 47 of the outer collar 46 of the thrust ring 33 is equal to the outer diameter 48 of the inner sleeve 15 of the lower radial bearing 11 slip, shown in figure 2.

The diameter 49, D of the inner fishing belt fixed in the housing 5 of the spindle section 6 of the lower threaded sub 14, and the outer diameter 50, D _{1 of the} fishing collar 32 of the fishing collar 31 of the lower fishing device 30 are connected by the ratio: D = D ₁ - (0.03 ÷ 0.05) D, shown in Fig.2.

In addition, item 51 is a skew angle regulator of a gerotor screw hydraulic motor, comprising a hollow curved shaft 52 with external splines and threads at its edges, a gear coupling 53 with internal longitudinal spline grooves and internal rectangular teeth mounted on the end face mounted on the external longitudinal splines of the hollow a curved shaft 52, a straight sub 54 and a curve sub 55, misaligned between each other (at an angle of skew of up to 3 °), shown in figure 1.

The downhole hydraulic motor operates as follows: the mud flow 4 under pressure through the drill pipe string is pumped by the drilling rig pump into the multi-start screw (lock) chambers between the teeth of the multi-start rotor screw 3 and the helical teeth of the elastomer plate 2 (the cross section of the teeth and lining is not shown) while the flow of drilling fluid 4 forms a region of high pressure and a moment from hydraulic forces, which leads to planetary rotor rotation of the rotor 3 inside the elastomeric plate 2, closed insulated in the housing 1.

Multiple helical chambers between the helical teeth of the rotor 3 and the helical teeth of the elastomeric plate 2 have a variable volume and periodically move along the flow of the drilling fluid 4, which has a density of up to 1500 kg / m ³ , contains up to 1% sand and up to 10% of oil products.

The planetary-rotor rotation of the screw rotor 3 inside the plate 2, mounted in the housing 1, transmits torque (in the opposite direction) through the driveshaft 17, the shaft 7 of the spindle section 6 to the bit 24, while drilling, while to prevent sticking, rotate simultaneously drill string in the well by the rotor of the drilling machine, for example, 5000EU to the right, the rotational speed of the drill string 10 ÷ 20 rpm

In the maximum power mode, the rotational speed of the shaft 7 of the spindle section 6 and the bit 24 is 110 ÷ 310 rpm, the moment of force on the shaft 7 of the spindle section 6 is 65 kgf · m, the pressure drop (inter-turn, on the teeth of the elastomeric lining 2) is in maximum power is 64 kgf / cm ² , the maximum allowable axial load on the bit 24 is 5000 kgf.

In the fields of Western and Eastern Siberia, using DRU1-73RS, DRU2-172RS, DRU2-172RS, DRU2-195RS, DRU2-195RS and 5000EU drilling rigs with gerotor screw hydraulic motors, dozens of complex wells were drilled with a depth of 3,500 ÷ 4,500 meters, then windows were cut into casing strings with the help of milling ribs and lateral horizontal shafts 350–450 meters long were drilled through windows in casing strings for oil production.

The value of the stress coefficient in bending (Stress ratio, the ratio of the changing amplitude of the voltage to the average voltage) when passing sections of curvature during rotary drilling of a horizontal lateral oil wellbore with a screw gerotor hydraulic engine, in which shaft 7 of the spindle section 6 and fishing sleeve 31 with fishing collar 32 lower fishing device 30 are rigidly fastened together using a common thread 41 with the possibility of providing an interference fit on the ends 42, 43 of the thrust ring 33 located between the torus ohm 44 of the fishing sleeve 31 and the end face 45 of the inner sleeve 15 of the lower radial sliding support 11, and the screwing direction of the thread 41 of the shaft 7 of the spindle section 6 and the fishing sleeve 31 of the lower fishing device 30 coincides with the direction of rotation of the drill string when rising from the well, decreases and is equal to essentially (2.2 ÷ 3.5), this increases the rigidity of the lower radial bearings, as close as possible to the bit, simplifies the assembly and repair of the spindle section when running out of bearings.

The execution of the spindle section 6 with the shaft 7 placed inside it, mounted on an axial support 8, made in the form of a thrust-radial multi-row ball bearing 9, as well as on the upper 10 and lower 11 radial sliding bearings so that the thrust ring 33 is made with an outer collar 46 in contact with the end 42 of the outer collar 46 with the end 45 of the inner sleeve 15 of the lower radial bearing 11, while the maximum diameter 47 of the outer collar 46 of the thrust ring 33 is equal to the outer diameter 48 of the inner sleeve 15 of the lower radial bearings 11 of the slide, and the diameter 49, D of the internal fishing belt fixed in the housing 5 of the spindle section 6 of the lower threaded sub 14, and the outer diameter 50, D _{1 of the} fishing collar 32 of the fishing sleeve 31 of the lower fishing device 30 are connected by the ratio: D = D ₁ - (0.03 ÷ 0.05) D, the outer sleeve of the lower radial sliding bearing and the lower threaded sub 14 are made in the form of a single design with hard alloy plates 39 fastened by impregnation of the hard alloy with the components of the solder bond in the lower threaded sub 14, and the hardness of the carbide plates 39, for example, tungsten-cobalt carbide, is (89 ÷ 92) HRA, reduces the accident rate when using a hydraulic downhole motor when lifting with rotation of the drill string with a bit from the side well bore when the spindle shaft is destroyed, increases the life and engine reliability, well penetration accuracy and the rate of set of well curvature parameters, and also provides increased throughput, i.e. reduces resistance and stress in the layout of the bottom of the drill string.

Claims (5)

1. Hydraulic downhole motor, which during operation can be used in a drill string for rotary drilling, containing a hollow body, a gerotor screw mechanism located inside it, including a stator coaxially located in the body and a rotor installed inside the stator, the rotation of which is carried out by pumping fluid, spindle section, including a shaft mounted on an axial support made in the form of a thrust-radial multi-row bearing, as well as on the upper and lower radial bearings x sliding, consisting of the outer and inner bushings located in the housing of the spindle section, and accordingly, on the shaft of the spindle section, the shaft of the spindle section is fastened at the inlet by a drive shaft with a rotor, and at the output is fastened with a chisel, the engine is equipped with an upper fishing device consisting of shaft, stop and nut, and a lower fishing device made in the form of a fishing sleeve with an external fishing collar, a thrust ring and a lower threaded sub with an internal fishing collar, the upper fishing device is fastened about with the upper part of the rotor of the gerotor screw mechanism, and the lower fishing device is mounted on the shaft of the spindle section between the inner sleeve of the lower radial support and the axial support, made in the form of a thrust-radial multi-row bearing, characterized in that the shaft of the spindle section and the fishing sleeve of the lower fishing device with an external fishing collar are rigidly fastened together using a common thread with the possibility of providing an interference fit on the ends of the thrust ring located between the ends of the fishing sleeve and the inner sleeve of the lower radial sliding support, while the direction of screwing the threads of the shaft of the spindle section and the fishing sleeve of the lower fishing device coincides with the direction of rotation of the drill string when lifting from the well. 2. The downhole hydraulic motor according to claim 1, characterized in that the diameter D of the inner fishing belt in the lower threaded sub and the outer diameter D _{1 of the} fishing collar of the fishing sleeve of the lower fishing device are related by the ratio: D = D ₁ - (0.03 ÷ 0, 05) D. 3. The downhole hydraulic motor according to claim 1, characterized in that the thrust ring of the lower radial sliding support is made with an outer collar in contact with the inner sleeve of the lower radial sliding support, while the diameter of the outer collar of the thrust ring does not exceed the outer diameter of the inner sleeve of the lower radial support slip. 4. The downhole hydraulic motor according to claim 1, characterized in that the outer sleeve of the lower radial sliding support and the lower threaded sub are made in the form of a single structure with hard alloy plates, while the hard alloy plates are installed in the inner bore of the lower threaded sub and fastened between themselves by impregnation of the hard alloy with components of the solder binder. 5. The downhole hydraulic motor according to claim 4, characterized in that the molten ligament-solder powder for fixing carbide plates in the lower threaded sub contains components in the following ratio, wt.%: Ni 32 ÷ 47, Fe 2, Cr 7 ÷ 14, Si 2, WC the rest.

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