RU2297513C1 - Core sampling tool - Google Patents

Abstract

FIELD: oil and gas industry, particularly drilling and sample taking devices.

SUBSTANCE: core sampling tool comprises body with upper sub, crown with boring, core receiver made as pipe provided with rotary support and adjustable suspension bracket in upper part thereof. The suspension bracket has retaining ring, adjusting screw connected to axis of rotary support and nut cooperating with the adjusting screw. Circulation orifices are made in the nut. Additional pipe is installed in the core receiver so that the pipe may slide in longitudinal direction. The additional pipe is provided with partition, which cooperates with core coming into the pipe. Core releasing unit comprises shoe connected to core receiver and lever-type core cutter arranged in the shoe. The core cutter comprises body and spring-loaded short and long rotary levers installed in the diametrical body plane. Core releasing unit has sleeve installed in the core cutter body and performing longitudinal movement. Lower sleeve part is made as resilient split collet provided with ledges made on outer surface thereof. The ledges cooperate with lower end of core cutter. Upper sleeve part has ledge on outer surface thereof, is connected to lower part of additional pipe and cooperates with upper end of core cutter body by ledge. Core cutter levers are located in different diametric planes, wherein short levers are over long ones. Upper sub has gate assembly, which indexes core wedging and comprises fixed bush with side and central circulation orifices. Movable bush is slidably installed in upper sub boring. Core receiver is provided with core wedging prevention mechanism made as one or several wedge-like projections arranged on lower end of core receiver suspension bracket nut and located around a circle and as one or several mating similar wedge-like projections formed on upper end of rotary support body and cooperating with them. Rotary support axis is made as stepped bush installed on adjusting screw and sliding in longitudinal direction. The rotary support axis is provided with compression spring having spring force smaller than that of compression spring included in the gate assembly. Distance between lower end of core receiver suspension bracket nut and upper end of rotary support exceeds doubled wedge-like projection height.

EFFECT: improved core removal and reliability of core separation from hole face.

9 dwg

Description

The invention relates to mining, and in particular to devices for drilling with coring and preserving the reservoir environment.

Known coring shell SK-190/80 (Knyazev IK Drillers on coring. M., Nedra, 1981, 102 S. See p.40, Fig. 27), containing:

- a housing with an upper sub for connecting to a pipe string,

- a crown with a bore,

- core receiver, made in the form of a pipe and equipped in the upper part with a rotation support connected to an adjustable suspension;

- node separation of the core from the bottom, containing a collet core explorer installed in the sub connected to the core receiver and interacting with the crown boring.

A disadvantage of the known projectile is the limited operational capabilities due to the impossibility of core removal from well sections represented by weakly cemented, loose and crumbling rocks.

This is due to the fact that in the known projectile, in the node of core separation from the bottom, only a collet core explorer is installed, designed to separate from the bottom and hold it in the core receiver when lifting the core surface, which is represented by sufficiently cemented, strong and dense rocks. Such rocks, being low porosity and low permeability, for the most part are not oil and gas reservoirs and are confined mainly to bridges between productive formations, represented by highly porous and well permeable reservoirs, usually composed of weakly cemented, loose and crumbling rocks.

Therefore, a collet core explorer (see Knyazev I.K. to Drillers on core sampling. M., Nedra, 1981, 102 pp. 38, fig. 25 and page 42, fig. 29), which practically does not overlap the cross section of the inlet the core receiver, even if the core is successfully separated from the bottom, which is represented by weakly cemented, loose and crumbling rocks, it will not be able to reliably hold the core column in the core receiver when lifting the projectile to the surface due to the possibility of core pouring out of the core receiver due to the high dynamics of tripping and lifting operations.

Known core sampling projectile "Nedra" KD 11-190 / 80 (Knyazev IK Drillers on core sampling. M., Nedra, 1981, 102 S. See p. 33-35, Fig. 17), containing:

- a housing with an upper sub for connecting to a pipe string,

- a crown with a bore,

- core receiver, made in the form of a pipe and equipped in the upper part with a rotation support connected to an adjustable suspension;

- a node for separating the core from the bottom, containing a collet core explorer installed in the lower sub connected to the core receiver, and a lever core explorer installed in the shoe connected to the lower sub.

A disadvantage of the known projectile is the low core removal, especially when it is taken from sections of wells represented by weakly cemented, loose and crumbling rocks, as well as fractured rocks.

This is due to the fact that the levers of the lever core core R18L-80 installed in the core unit of the known projectile (see Knyazev IK Drillers for core sampling. M., Nedra, 1981, 102 pp. 39, Fig. 26) , overlap the cross section of the inlet of the core receiver by no more than 30%, which is insufficient for reliable retention of core in the core receiver, represented by weakly cemented, loose and crumbling rocks, when the projectile rises to the surface. The high dynamics of tripping operations associated with lifting the drill string with the projectile, stopping it from being installed on the elevator or in the wedges of the rotor and then unscrewing the spark plug, cause shock loads and vibrations to the drill string, which will be transmitted to the core drill and, accordingly, on the core, contributing to the occurrence of additional cracks in it and breaking the bonds between particles of weakly cemented, loose and crumbling rocks. As a result, the core will spill out between the levers of the core breaker into the wellbore, which reduces its extension.

In the case of using a lever core cutter with levers that almost completely overlap the cross section of the inlet of the core receiver (see Knyazev I.K. to Drillers on Coring. M., Nedra, 1981, 102 pp. 42, Fig. 30), low core removal will be due to the fact that the core drill working elements are spring-loaded levers that constantly contact during the rotation of the projectile during drilling with the outer cylindrical surface of the rock column being formed, in the event of jamming of the core support of the core receiver intensive abrasive wear due to the high abrasive properties of rocks and the duration of the drilling process. Abrasion and subsequent breakdown of the core explorer working elements can lead to the core detonator failing to fulfill its functional purpose when the core is torn off the bottom after the sinking trip, and the core will either not be separated from the bottom or it will spill out when a known projectile rises to the surface, as a result which will be reduced its removal. This drawback is inherent in any core drill, whose working elements are constantly in contact with the core during drilling.

In addition, the location of the short and long levers of the aforementioned lever-type core detectors (see Knyazev I.K. to Drillers for core sampling. M., Nedra, 1981, 102 pp. Page 39, fig. 26 and page 42, fig. 30) in one diametrical plane it does not provide reliable core retention in the core receiver when raising a known projectile to the surface at the end of a drilling trip with coring. This is due to the fact that in the process of drilling the core, entering the core receiver, wring out the spring-loaded levers into the corresponding grooves of the core explorer body. In this case, the angle between the generatrix of the cylindrical core column and the lever at the point of contact of the short lever will be larger than that of the long lever, which, when pressed by the core into the groove of the core core body, becomes almost parallel to the generatrix of the cylindrical core column. Thus, the capture of the core at the separation of the known projectile from the face to separate the core will be carried out primarily by short levers. At the same time, with the same stiffness of the springs, providing the levers to be pressed to the surface of the core column, the force of pressing the short lever to the core due to the smaller shoulder from the axis of rotation to the point of contact will be greater in comparison with the long lever. As a result of this, at the moment of a known projectile detaching from the face to capture the core, the core will be captured and separated from the face by short levers, rather than long ones, which can remain in the depressed position, without preventing the core from falling out of the core receiver during the lifting of the known projectile to the surface, which will core removal is reduced.

And, finally, the constant contact of the core levers with core, represented by weakly cemented, loose and crumbling rocks, will contribute to the fact that rock particles separated by the core levers from the core column being drilled will gradually accumulate in the area of the core separation unit, more and more preventing free passage of the drill core in core receiver. The stepping of internal surfaces (lack of a smooth unobstructed passage) at the joints of the hull parts of the core separation unit from the bottom can also contribute to this. The cumulative effect of these factors that will increase in time will cause the core column to be fixedly stuck in the area of the core separation unit, after which the drilling will continue with a continuous slaughter, since the newly drilled core, represented by weak mechanical strength, loose and crumbling rocks, will collapse by rubbing on the face with a dense plug formed by rock particles in the through hole of the core separation unit from the bottom, and erode with mud streams, turning into cuttings, into as a result, core removal will be reduced.

At the same time, on the surface, the core stuck process in the core receiver of a known projectile and subsequent core fracture at the bottom will not be recorded, because when core sampling from well sections represented by weakly cemented, loose and crumbling rocks, the mechanical drilling speed will practically not decrease and the driller will continue drilling for the whole the length of the core receiver, destroying the core drilled again after jamming.

In the case of core sampling from directional wells or steeply falling strata represented by stratified and cavernous rocks with multidirectional fracturing and the presence of sliding mirrors, it is possible to jam the core column in the core receiver. After this, drilling will continue with a continuous face, since the newly drilled core will be destroyed by rubbing on the face with a dense plug formed by rock particles in the through hole of the core separation unit from the face, and will be washed out by the mud streams, turning into cuttings, resulting in core removal is reduced.

The objective of the invention is the creation of a coring shell devoid of the above disadvantages.

The technical results of solving this problem by the claimed coring shell are:

- increased core removal due to its more reliable separation from the face and subsequent retention in the core receiver when climbing to the surface,

- increase in core removal, represented by weakly cemented, loose and crumbling rocks, by preventing it from jamming in the core separation unit from the bottom by isolating the working elements of the lever core core from the core during drilling and ensuring a smooth passage along the entire core path from the burgole head to the core receiver;

- increase in core removal, represented by layered and cavernous rocks, prone to crack formation, due to the elimination of jamming of the core column in the core receiver;

- increase core removal by registering on the surface the moment of the core spell in the core receiver.

To ensure these results in a known coring shell containing:

- a housing with an upper sub for connecting to a pipe string,

- a crown with a bore,

- a core receiver made in the form of a pipe and provided in the upper part with a rotation support, comprising a housing with bearings and an axis, and an adjustable suspension, including a locking ring, an adjustment screw connected to the axis of the rotation support, and a nut that interacts with the adjustment screw and is installed without the possibility rotation in the bore of the upper sub to the upper end of the housing, with circulation holes made in the nut;

- a node for separating the core from the bottom, including a shoe connected to the core receiver, and a lever core explorer installed in the shoe and containing a body and spring-loaded short and long levers mounted rotatably in the diametrical plane of the core explorer body.

ACCORDING TO THE INVENTION

- an additional pipe is installed in the core receiver with the possibility of longitudinal movement, in the upper part of which there is a jumper with which the core entering the pipe interacts;

- the core separation unit is additionally equipped with a sleeve installed in the core core body with the possibility of longitudinal movement, the lower part of which is made in the form of an elastically deformable split collet with ledges on its outer surface interacting with the lower end of the core core body, and the upper part is made with a ledge on its outer the surface interacting with the upper end of the core core body and is connected to the lower part of the additional pipe;

- core levers interacting with the outer surface of the liner are located in different diametrical planes, with short levers located above the long levers;

- the core receiver suspension nut is installed in the bore of the upper sub with the possibility of longitudinal movement;

- the upper sub is additionally equipped with a core jam registration valve containing a fixed sleeve in which the lateral and central circulation holes are made, and a movable sleeve with circulation holes equipped with a compression spring, mounted in the bore of the upper sub with the possibility of longitudinal movement and interacting with the lower end with the upper end of the nut suspension, and the upper part is detachably connected to the stationary sleeve with the possibility of longitudinal movement, and detachable connection The junction is made in the form of a smooth cylindrical contact surface;

- the core receiver is additionally equipped with a core anti-jamming mechanism made in the form of one or several wedge-shaped protrusions located around the circumference on the lower end of the core receiver suspension nut, and interacting with them similar response of one or several wedge-shaped protrusions containing bevels and ledges, and located around the circumference on the upper end of the housing of the support of rotation, and the axis of the support of rotation is made in the form of a stepped sleeve mounted on an adjusting screw with the possibility of selling it is equipped with a compression spring, the rigidity of which is less than the rigidity of the compression spring of the core spindle registration valve, and the distance between the lower end of the core receiver suspension nut and the upper end of the rotation support body is more than twice the height of the ledges of the wedge-shaped protrusions.

Figure 1 shows a General view of the inventive core sampling projectile - the initial position before lowering into the well;

figure 2 in a perspective view in enlarged view shows the interacting elements of the mechanism of anti-jamming of the core in the initial position, arrow B shows the direction of rotation;

figure 3 shows a General view of a core sampling projectile - the working position of the mechanism of anti-jamming of the core at the time it begins to jam;

figure 4 shows a General view of a core sample - the operating position of the valve registration jamming of the core after it is jammed,

figure 5 shows a General view of the lower part of the core shell after separation of the core from the bottom,

Fig.6 in section aa in Fig.5 shows the upper row of short levers of the core cutter in the working position,

in Fig. 7 in a section bB in Fig. 5 shows the bottom row of the long levers of the core core in the working position,

Fig. 8 in an enlarged view in the initial position shows the interaction of the sleeve of the separation unit with the core core body, in which the levers are separated from the interaction with the core being drilled,

figure 9 in an enlarged view shows the moment of detachment of the sleeve from the core core body and the release of core core levers that came into contact with the core.

The core sampling shell (Fig. 1) contains a body 1 in the form of a pipe equipped with a sub 2 in the upper part and a crown 3 in the bottom, in which a bore 4 and flushing holes 5 are made. A core receiver 7 in the form of a pipe is placed in the cavity 6 of the body 1 the end of which is equipped with a rotation support 8, which includes a housing 9, bearings 10 and an axis 11, made in the form of a stepped sleeve. An adjustable suspension 12 of the core receiver 7 is connected to the rotation support 8, including an adjustment screw 13 connected to a nut 14 mounted on the end of the housing 1 with the possibility of longitudinal movement in the sub 2 and fixed in the initial position by an annular stopper 15. Circulating holes are made in the nut 14 of the suspension 12 16, and the axial channel 17 of the adjusting screw 13, communicating with the cavity of the core receiver 7, is blocked by a ball valve 18 installed in the eyebolt 19, designed to sling the core receiver 7 with a lifting hook a winch (not shown) when it is removed from the housing 1. The axis 11 of the rotation support 8 is mounted on the adjusting screw 13 with the possibility of longitudinal movement, is equipped with a compression spring 20 and is fixed in the initial position on the adjusting screw 13 by the threaded sleeve 21.

Between the rotation support 8 and the nut 14 of the suspension 12 there is a mechanism of anti-jamming of the core 22 (Figs. 1 and 2), containing interacting elements made in the form of one or more protrusions 23 of a wedge-shaped shape located around the circumference at the lower end 24 of the nut 14, and in the form reciprocal of one or more protrusions 25 of a wedge-shaped shape located circumferentially on the upper end 26 of the housing 9. Bevels 27 and ledges 28 are made on the protrusions 23 and 25.

In the sub 2, a core jam registration valve 29 is installed, comprising a sleeve 30 fixedly installed in the upper part of the sub 2, in which circulation holes are made: side 31 and central 32. A movable sleeve 33 is detachably connected to the stationary sleeve 30 with the possibility of longitudinal movement, and detachable connection is made in the form of a smooth cylindrical contact surface and contains an o-ring 34 mounted in a groove made on the outer surface of the stationary sleeve 3 0. In the initial position, the lateral circulation holes 31 of the stationary sleeve 30 are open. The lower part of the movable sleeve 33 is mounted with the possibility of moving in the bore of the sub 2 and in the initial position it is fixed with a ring nut 35, interacting with a step with the compression spring 36, and with the lower end with the upper end of the nut 14. The rigidity of the compression spring 20 of the anti-jamming mechanism 22 is less than the spring stiffness compression 36 valve registration 29 core jamming. Holes 37 are made for the circulation of the solution in the movable sleeve 33, and for fixing the nut 14 from rotation, a keyway 38 is made in it, interacting with the key 39 installed in the ring nut 35.

In the lower part of the core receiver 7 there is a node for separating the core 40 from the bottom and its subsequent retention in the core receiver 7 when the projectile is raised to the surface. The compartment assembly 40 includes a shoe 41 fixedly connected to the core receiver 7 and a lever core arrester 42 mounted in the shoe 41, in the case 43 of which short 44 and long 45 levers are mounted in different diametric planes with the possibility of rotation, and the short levers 44 are located above the long levers 45 ( 5, 6 and 7). In the initial position, the levers 44 and 45 are located vertically in the grooves of the body 43, are fixed from rotation and separated from contact with the core core bore 46 drilled by the outer surface, the lower part of which is made in the form of an elastically deformable split collet 47. In the initial position, the sleeve 46 interacts with the steps 48 made on the outer surface of the collet 47, with the lower end of the core 43 case, and the upper part interacts with a step 49 made on the outer surface of the upper part of the sleeve 46 with the upper end of the core 43 case 43 2.

In the core receiver 7, an additional pipe 50 is installed with the possibility of longitudinal movement, made, for example, of a fibrous composite material, in the upper part of which a jumper 51 is installed, with which the core 52 entering the pipe 50 interacts (Fig. 2). The lower part of the pipe 50 is fixedly connected to the sleeve 46, and the inner diameters of the sleeve 46 and the pipe 50 are equal and their connection at the junction is smooth passage, without ledges and gaps.

The inventive coring shell works as follows.

Before descent into the well, preparation of the projectile is carried out, for which the housing 1, assembled with a crown 3 (Fig. 1), is installed on the mouth of the elevator or in the wedges of the rotor (not shown). Next, the assembly of the core separation unit 27 is carried out, for which the sleeve 46 is connected to the core drill 42, previously turning the levers 44 and 45 into a vertical position and leading into the corresponding grooves of the case 43, after which the sleeve 46 is inserted from the top into the case 43 with the steps 48 forward (Fig. 8 ) Due to the elastically deformable properties of the split collet 47, the ledges 48 are closed, and the sleeve 46 is freely installed in the housing 43 until the stop of the ledge 49 in the upper end of the housing 43. Moreover, the ledges 48, being closed when passing through the housing 43, at the end of the movement of the sleeve 46 due to the elastic the deformable properties of the split collet 47 open and interacting with the lower end of the housing 43, the sleeve 46 is fixedly fixed relative to the core core 42.

Next, an additional pipe 50 is screwed to the upper part of the sleeve 46, in which, depending on the expected length of the flight with coring 52, a jumper 51 is installed in the required place in the upper part (Fig. 1).

The bearings 10 with the axis 11 installed in the housing 9 form a rotation support 8, which is connected to the adjusting screw 13, for which a compression spring 20 is installed inside the axis 11 and the axis 11 is connected to the adjusting screw 13 by the threaded sleeve 21, additionally compressing the spring 20. On the adjusting screw 13 screw the nut 14 to the position at which the distance between the lower end 24 of the nut 14 and the upper end 26 of the housing 9 will be more than two height values of the ledges 28 of the protrusions 23 and 25.

The core receiver 7 is connected to a rotation support 8 and an adjustable suspension 12, after which a pipe 50 with a separation unit 40 is inserted into the lower end of the core receiver 7, which are fixed in the core receiver 7 with a shoe 41. The core core 42 is fixed in the shoe 41 from longitudinal movement by the lower end of the core receiver pipe 7 , with which the upper end of the housing 43 of the core core 42 interacts.

After assembling the upper part of the adjusting screw 13 with the valve 18 and the eyebolt 19, the assembled core receiver 7 is lifted by an auxiliary winch hook (not shown) and inserted into the housing 1 until the nut 14 is installed on the end of the housing 1. Adjustment of the suspended position of the core receiver 7 in the housing 1, with which shoe 41 with gaps (radial and end) will be located in the bore 4 of the crown 3, is produced by rotating the adjusting screw 13 in the nut 14, after which the required position of the core receiver 7 in the housing 1 is fixed by an annular stopper 15.

Assembly valve registration 29 jamming core 52 in sub 2 is as follows. The fixed sleeve 30, picked up with the sealing ring 34, is screwed into the upper part of the sub 2, then the compression spring 36 and the movable sleeve 33, which are fixed in the bore of the sub 2 with a ring nut 35, are installed in the bore of the sub 2 from the bottom. In this case, the spring 36 will be additionally preloaded and the upper part of the movable sleeve 33 is detachably, on a smooth cylindrical contact surface, connected to the lower part of the stationary sleeve 30, leaving the circulation side holes 31 open. 29 and 52 sub-jamming core 2 is screwed to the housing 1 by fixing the end of the movable sleeve 33, the nut 11 on the end of the body 1.

In the initial position shown in figure 1, the projectile on the drill string (not shown) is lowered into the well. In this case, the pipe string is filled with drilling fluid from the well through openings 5, cavity 6, openings 16, cavities of fixed 30 and movable 33 bushings, a bore of the sub 2 and openings 37, 31 and 32. Filling the cavity of the core receiver 7 with drilling fluid as it descends into the well it is carried out by pressing the ball valve 18 by increasing the pressure in the cavity of the core receiver 7, after which the air in it will be forced out through the channel 17 by the drilling fluid into the drill pipe string.

Drilling with coring 52 is carried out by turning on the drill, flushing the well with a drilling fluid pumped from the surface to the bottom of the well along the drill string through holes 31, 32 and 37, the cavity of the bore of the sub 2, the stationary sleeve 30, the movable sleeve 33, the holes 16 , cavity 6 and holes 5. The circulation of the drilling fluid through the cavity of the core receiver 7 will be impossible, thanks to the ball valve 18, which prevents the access of drilling fluid through the channel 17 to the core receiver 7, thereby eliminating the countercurrent of the drilling fluid chu incoming core receiver 7 to drill out cores 52. This prevents erosion of the core, in particular of weakly cemented loose rocks and provided increasing its removal. A similar effect is achieved by regulating the fit of the shoe 41 into the bore 4, thereby minimizing the access of the solution towards the incoming core 52.

As the core is drilled, 52 enters the area of the separation unit 40, where the sleeve 46 eliminates the contact of the levers 44 and 45 of the core explorer 42 with the core 52, as a result of which the levers 44 and 45 will not resist the movement of the core 52, which prevents the destruction of the latter, which is especially loose crumbling and weakly cemented rocks. Next, the core 52 enters the pipe 50, where due to the equality of the diameters of the sleeve 46 and the pipe 50, as well as making the junction point smoothly, without ledges and gaps, jamming of the core 52 is also eliminated, which contributes to an increase in its removal.

At the end of the sinking trip, the upper end of the core column 52 will reach the jumper 51 installed in the pipe 50 (figure 3). As the core continues to deepen and core 52 is drilled, its pressure on the bridge 51 will increase, as a result of which this force will be transmitted through the pipe 50 to the sleeve 46. The steps 48, elastically closing, will disengage from the lower end of the core body 43 and unlock the sleeve 46, which, when further moved upward inside the housing 43, will first sequentially release the long levers 45, and at the end of the stroke, short levers 44 (Fig. 7), which will come into contact with the cylindrical surface of the core column 52.

At the end of the sinking trip 52, the core 52 is detached from the bottom and the core 52 is separated by the core 42. In this case, the core 42 will move upward relative to the stationary core 52 connected to the bottom and the short levers 44 located to the generatrix of the cylindrical core column 52 at a much larger angle than the long levers 45, first of all they will mesh with the cylindrical surface of the core 52 and, turning to a horizontal position, will penetrate into the core 52 and separate it from the bottom (Figs. 5 and 6). With the same stiffness of the springs of the levers 44 and 45, the much greater effort of pressing the short levers 44 to the surface of the core 52 contributes to the smaller shoulder from the axis of rotation of the lever 44 to the point of contact with the core 52. Thus, the core column 52 separated from the bottom by its lower the end will be located on the short levers 44, and the long levers 45, due to the lack of core 52 in their diametrical plane of arrangement in the housing 43, being spring-loaded, will freely rotate to a horizontal position, almost completely opening the opening section of the node of the compartment 40 core 52 (Fig.7).

When the projectile rises to the surface due to the high dynamics of the tripping process, it is possible to destroy and precipitate the core 52, represented in particular by loose, crumbling and weakly cemented rocks, through short levers 44 (Fig. 5). However, below the long levers 45, which completely overlap the passage section of the opening of the separation unit 40, will prevent the core 52 from falling into the well, thereby preventing its removal.

When coring 52 from directional wells or steeply falling strata, represented by cavernous-clastic rocks with multidirectional fracturing and sliding mirrors, due to the impact of working elements of crown 3 on core 52 and manifestation of rock pressure, core column 52 may crack and fracture immediately after of its formation with subsequent jamming already in the zone of the separation unit 40. This is fraught with the destruction of core 52 at the bottom by a dense plug formed by rock particles in the passage opening of the separation unit 40. In this case, due to friction forces, the force of core 52 advancement inside the core receiver 7 will increase, as a result of which the latter will move upward relative to the housing 1, reducing the distance between the lower end 24 of the nut 14 and the upper end 26 of the housing 9 and at the same time compressing the anti-jamming spring 20 22. At a certain amount of movement of the core receiver 7, the rotating protrusions 23 will interact with the longitudinally moving upwards protrusions 25, involving the latter in rotation. And since the protrusions 25 are connected with the housing 9 of the rotation support 8, the latter, being connected to the core receiver 7 and the separation unit 40, will also begin to rotate relative to the stationary core 52 stuck in the core receiver 7. Thereby, it is possible to release the core column 52 from jamming, after whereby the action of the force from the compressed spring 20 and the mass of the core receiver 7, the latter will return to its original state, disconnecting the protrusions 25 from engagement with the protrusions 23.

If the core receiver 7 does not rotate relative to the core 52 fixed and connected to the bottom of the well due to the impossibility of overcoming the friction force of the core 52 stuck in the core receiver 7, then the protrusions 23, rotating relative to the stationary protrusions 25 and interacting with each other by bevels 27, will push them down overcoming the resistance of the compressed spring 20 and the friction force of the core 52 stuck in the core receiver 7. In this case, the core receiver 7 will also move downward relative to the core that is stationary and connected with the bottom of the well 52, and after the bevels 27 come out of the interaction, the core receiver 7 from the action of the compressed spring 20 and the axial load on the crown 3 will move upward relative to the core 52 by twice the height of the ledges 28. Thus, for each revolution of the body 1 with the core receiver 7, depending on the number of protrusions 23 and 25 will make several reciprocating longitudinal movements relative to the core 52, which, in combination with the rotation of the core receiver 7, can eliminate the jamming of the core 52 and will ensure further drilling for the entire field nirovannuyu flight length.

When drilling with coring, situations are possible when, when a projectile is raised to the surface and preparing it for the next voyage for core sampling, rock fragments that exceed the strength of loose and weakly cemented rocks in the interval of coring can fall out of the overburden into the well borehole to the bottom. Then, after the projectile is lowered to the face, such fragments of rock that are not associated with the face and being pressed by the end face of the crown 3 to the face will begin to rotate with it, gradually deforming and entering into the core-receiving hole of the crown 3, shoe 41 and further into the sleeve 46. It will be simultaneously there is a process of grinding of the rock located under these fragments, the destroyed remains of which without gaps will fill the inlet of the crown 3 and then the passage section of the shoe 41 and sleeve 46. Thus, core 52 is jammed amom beginning of the process of its drilling out and entering the separation unit 40 and there will be a sharp decline in ROP.

As the axial load increases, the force from moving this wedged mass of fragments and frayed rock upward will increase and be transmitted to the sleeve 46, which due to the elastically deformable properties of the collet 47 will lock the ledges 48 and release the sleeve 46 from engagement with the core 43 case 43. Subsequent movement of the sleeve 46 up will release the levers 44 and 45, which will engage with the jammed mass of debris and frayed rock.

At the same time, the effort from moving the wedged mass of debris and frayed rock upward will be transmitted through the shoe 41 and core explorer 42 to the core receiver 7, and from it through the nut 14 to the details of the registration valve 29 for core jamming 52, i.e. on the movable sleeve 33 interacting with the nut 14 and on the spring 36, which will begin to compress. In this case, the nut 14 and the movable sleeve 33 will begin to move up into the bore of the sub 2, and the upper part of the movable sleeve 33, being detachably connected to the upper sleeve 30 with the possibility of longitudinal movement, due to the sealing ring 34 will block the side holes 31 of the stationary sleeve 30. Pumped from the surface at the bottom, the drilling fluid can circulate through the projectile only through the central hole 32, the area of which is less than the total area of the side holes 31 and the central hole 32 and, as a result, I am a local hydraulic resistance of the discharge pressure of drilling mud to rise immediately. On the surface, the overlap of the holes 31 by moving the sleeve 33 will be recorded by a manometer in the form of a pressure jump, which, in combination with a drop in the mechanical drilling speed, will indicate that core 52 is stuck in the lower part of the projectile and the need to stop the drilling process with the projectile being raised to the surface. Thus, timely information about the beginning of the core spell 52, received on the surface from the registration valve 29, will prevent further drilling with the destruction of core 52 at the bottom and will increase its removal.

The subsequent detachment of the projectile from the bottom for lifting to the surface will separate and hold the core 52 with the released levers 44 and 45 of the core explorer 42.

When the projectile rises to the surface, the solution is drained from the pipe string into the well through the hole 32, the stationary cavity 30 and the movable 33 bushings, holes 37, cavity 6 and holes 5.

On the surface, the projectile is installed in the rotor wedges, the sub 2 with the registration valve 29 is disconnected, and the core receiver 7 is removed from the housing 1 by inserting the lifting winch hook (not shown) into the eye bolt 7. Next, the shoe 41 with the core drill 42 is disconnected from the core receiver 7 and removed a pipe 50 with a core 52 and a sleeve 46. After disconnecting the sleeve 46, the pipe 50 together with the core is cut into meter sections, a description and measurement of the linear core removal 52 are performed.

Thus, the set of distinguishing features of the claimed core projectile allows you to get a positive result when selecting coring, namely:

- the use of a thin-walled sleeve that separates the core drill levers from the core during drilling, provides:

a) preventing the possible destruction of the core by the levers of the core explorer, which increases the removal and preservation of the core;

b) the prevention of abrasive wear of the core levers on the surface of the core being drilled and their subsequent breakage, which helps to increase the reliability of the core explorer when separating the core from the bottom and subsequent retention in the core receiver when lifting to the surface, and therefore increases core removal;

- due to the location of the long and short levers of the core explorer in different diametric planes, the core is not spilled from the core receiver, represented by loose and crumbling rocks, and therefore provides an increase in core removal;

- thanks to the use of an additional pipe inserted into the core receiver with the possibility of movement and equipped with a jumper in the upper part interacting with the core drilled, and the lower part connected with the sleeve fixed relative to the core core body by elastically deformable stops, the core core levers are released and their interaction with the core core drilled only at the end of the drilling process, which in combination with the arrangement of short and long levers in various diametrical planes of the core drill body The atelier ensures the reliability of core separation and subsequent retention in the core receiver when lifting to the surface, and therefore, the increase in core removal is ensured;

- thanks to equipping the upper sub with the core spell registration valve, information on the moment of the core spell in the core separation unit is quickly, in real time provided, which prevents further drilling with a continuous face and, therefore, increases the core removal;

- due to equipping the core receiver with the anti-jamming mechanism at the very beginning of the core jamming process, rotary and reciprocal longitudinal movements of the core receiver relative to the core are provided, which allows to eliminate core jamming and to ensure further drilling for the entire planned flight length, reducing time spent on tripping.

Claims (1)

A core sample containing a housing with an upper sub for connecting to a pipe string, a crown with a bore, a core receiver made in the form of a pipe and provided in the upper part with a rotation support containing a housing with bearings and an axis and an adjustable suspension including a retaining ring, an adjusting screw, connected to the axis of the rotation support, and a nut that interacts with the adjusting screw and is mounted without the possibility of rotation in the bore of the upper sub on the upper end of the housing, and the nut is circulated openings, a node for separating the core from the bottom, including a shoe connected to the core receiver, and a lever core arrester installed in the shoe and comprising a body and spring-loaded short and long levers mounted rotatably in the diametrical plane of the core core body, characterized in that the core receiver is installed with the possibility of longitudinal movement, an additional pipe, in the upper part of which a jumper is installed, with which the core coming into the pipe interacts, supplement the core separation unit the flax is equipped with a sleeve installed in the core-shell body with the possibility of longitudinal movement, the lower part of which is made in the form of an elastic deformable split collet with ledges on its outer surface interacting with the lower end of the core-shell body, and the upper part is made with a step on its outer surface interacting with the upper end core core body and connected to the bottom of the additional pipe, core core levers interacting with the outer surface of the sleeve are located in different diameters planes, with short levers located above long levers, the core receiver suspension nut is mounted in the bore of the upper sub with the possibility of longitudinal movement, the upper sub is additionally equipped with a core jam registration valve containing a fixed sleeve in which the lateral and central circulation holes are made, and equipped with a compression spring movable sleeve with circulation holes installed in the bore of the upper sub with the possibility of longitudinal movement I and interacting with the lower end with the upper end of the suspension nut, and with the upper part detachably connected to the stationary sleeve with the possibility of longitudinal movement, moreover, the detachable connection is made in the form of a smooth cylindrical contact surface, the upper part of the core receiver is equipped with a core anti-jamming mechanism made in the form of one or several protrusions wedge-shaped, located around the circumference on the lower end of the core receiver suspension nut, and interacting with them similar response of one sludge and several wedge-shaped protrusions containing bevels and ledges and circumferentially located on the upper end of the rotation support housing, the rotation support axis being made in the form of a stepped sleeve mounted on the adjusting screw with the possibility of longitudinal movement and equipped with a compression spring, the rigidity of which is less than the spring stiffness compression of the core spindle registration valve, and the distance between the lower end of the core receiver suspension nut and the upper end of the rotation support housing is greater than twice the height of the ledges in wedge-shaped form.

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