RU76962U1 - WELD CEMENTING DEVICE - Google Patents

Abstract

The invention relates to the construction of wells and can be used for step and cuff cementing of wells. The device includes a housing with a central passage channel, a two-way sleeve for one-way movement, a ring and a shutter. Radial circulation openings and pressure reducing valves are made in the casing, and the inner surface has annular protrusions and depressions. The sleeve is made with radial circulation holes, a check valve, a mechanical limiter of its first stroke and an autonomous pressure reducing valve. The sleeve and the ring are installed in the housing and are telescopically interconnected by a shear element, and conical stops are installed in their annular separators with the possibility of extension into the central channel or exit from it. The pressure reducing valves of the housing are disconnected from the central channel by a shutter with radially movable elements forming a seat in the central channel. The damper is made with longitudinal through grooves and equipped with balls placed in these grooves to increase the rigidity of the saddle. An additional annular depression is made in the inner surface of the housing with the possibility of moving balls into it with axial movement of the shutter. The amount of movement of the two-way sleeve at the first stroke N is determined from the relation: H≥h + R + r, where h is the amount of movement of the sleeve during the first stroke to the initial position, at which the conical stops of the ring ring separator are fully extended into the central channel; R and r are the radii of the radial circulation holes of the housing and sleeve, respectively; 1 n.a.s. f-ly, 6 ill.

Description

The invention relates to the field of well construction and can be used to perform technological processes of stepwise and cuff cementing of wells, especially deviated and with horizontal end of the trunk.

A device for cementing wells is known, including a housing with a central passage channel, an inner surface made with annular protrusions and depressions, and radial circulation holes installed in the housing and telescopically connected by a shear element to a two-way sleeve of one-way movement and a ring, in the ring separators of which are installed conical stops with the possibility of interaction with the inner surface of the housing and extension while the Central passage channel or exit from it, and the two-way sleeve is made with radial circulation holes located above the radial circulation holes of the housing and separated from them with the possibility of communication with them and re-separation, respectively, at the first and second strokes of the two-way sleeve down, and is equipped with a mechanical limiter of its first stroke, installed with the possibility of withdrawing it from its working position, and the cavity of the inner surface of the housing directly under the annular protrusion placed in the zone of the ring is made stepped, tapered from top to bottom (Patent of Russian Federation №2096585, E 21 B 33/14, 1995).

The disadvantage of this device is the lack of its technological versatility as a loop-through. It is not applicable as a passage in the conventional technology of step cementing using a practically unlimited range of grouting

mixtures. This refers to the cementing of the well in two successive stages with bringing the squeeze plug in the first stage to a separate thrust ring located near the casing shoe. It also cannot be used according to the generally accepted cuff cementing scheme, which provides for sequential control — using dividing plugs — by an annular packer and a cement clutch installed above it.

The closest technical solution, selected as a prototype, is a device for cementing wells, comprising a housing with a central passage channel, an inner surface made with annular protrusions and depressions, radial circulation holes and radially placed reduction valves, separated from the central passage channel by a shutter with radially movable elements forming a saddle in the central passage channel, a ring and a two-way sleeve of unilateral movement with p dial circulation holes, a non-return valve, a mechanical limiter of its first stroke and an autonomous pressure reducing valve, while the two-way sleeve and ring are installed in the housing and are telescopically connected to each other by a shear element, and conical stops are installed in their annular separators with the possibility of interaction with the inner surface of the housing and while extending into or out of the central passage channel, the radial circulation openings of the two-way sleeve being located above the radial x circulation openings of the housing and are disconnected from them with the possibility of communication with them and re-disconnection, respectively, at the first and second strokes of the two-way sleeve down, its check valve is placed with the possibility of overlapping pressure reducing valves of the body after the first stroke of the two-way sleeve, and the mechanical limiter of the first stroke of the two-way sleeve is installed with the ability to withdraw it from its working position, with a two-way

the sleeve is configured to form a hydraulic brake in the form of a closed annular cavity communicated with an autonomous pressure reducing valve after re-uncoupling the radial circulation holes of the two-way sleeve and the housing, the cavity of the inner surface of the housing directly under the annular protrusion located in the ring zone is made stepwise, tapering from top to bottom, and the two-way sleeve and the housing below the circulation holes are made with adjacent recesses placed with the possibility of formation of neous with hydraulic brakes the circumferential channel of the circulation holes of the sleeve to a two-way pressure relief valve body (Patent of Russian Federation №2145662, E 21 B 33/14, 1999).

The known device is technologically universal as a passage and can provide the conclusion of the remains of cement slurry from its central passage through the annulus after cementing the well with the exception of the premature actuation of the device and the possibility of back flow of cement through its channels into the cavity of the column.

The disadvantage of this device is the low reliability of its operation.

When using the known device is not guaranteed message and re-separation of the radial circulation holes of the housing and the two-way sleeve in the process of cementing the well with the first and second strokes of the two-way sleeve down.

Given the insufficient rigidity of the seat in the central passage channel formed by radially movable shutter elements, there may be a lack of axial movement of the shutter when the all-rubber dividing plug passes through it and, therefore, there may be no hydraulic communication between the central passage channel and the annulus of the borehole through pressure reducing valves necessary for landing first rubber-metal separation

plugs on the saddle formed by the stops of the two-way sleeve after the completion of the forcing of cement slurries of the first cementing stage. As a result, the radial circulation openings of the housing and the two-way sleeve will not occur at the first cementing stage.

Due to the fact that during the first stroke of the two-way sleeve with the ring down, at the very initial moment of communication of the circulation holes of the housing and the two-way sleeve, a pressure drop will occur over the cement plug in the central passage and the two-way sleeve will slow down and may stop, while the conical stops of the ring they do not extend completely into the central passage channel onto the cylindrical surface of the annular protrusion of the housing and, therefore, do not form the saddle necessary for reliable seating dki on it a second rubber-metal separation tube. In this position of the conical stops of the ring, their reliable interaction with the second rubber-metal stopper is not ensured and, therefore, the second stroke of the two-way sleeve is impossible. At the same time, the tightness of the device is not achieved, which does not provide the necessary tightness of the casing for the operation of the wells.

The problem solved by the invention is to ensure the complete reliability of the device for cementing wells.

This problem is solved by creating a guaranteed message and re-separation of the radial circulation holes of the housing and the two-way sleeve of the device during cementing of the well during the first and second moves of the two-way sleeve down.

The solution to this problem is achieved by the fact that in a device for cementing wells, including a housing with a central passage channel, an inner surface made with annular protrusions and depressions, radial circulation holes and radially placed reduction valves, disconnected from the central

the passage channel with a shutter with radially movable elements forming a saddle in the central passage channel, a ring and a two-way sleeve for one-way movement with radial circulation holes, a check valve, a mechanical limiter of its first stroke and an autonomous pressure reducing valve, while the two-way sleeve and ring are installed in the body and telescopically interconnected by a shear element, and conical stops are installed in their annular separators with the possibility of interaction with the inner surface the case of the housing and extension into the central passage channel or exit from it, the radial circulation holes of the two-way sleeve located above the radial circulation holes of the body and separated from them with the possibility of communication with them and re-separation, respectively, at the first and second strokes of the two-way sleeve downward, the check valve is placed with the possibility of overlapping pressure reducing valves of the housing after the first stroke of the two-way sleeve, and the mechanical stop of the first stroke of the two-way sleeve is installed it is mounted with the possibility of withdrawing it from its working position, while the two-way sleeve is configured to form a hydraulic brake in the form of a closed annular cavity communicated with the self-contained pressure reducing valve after repeated separation of the radial circulation holes of the two-way sleeve and the body, the cavity of the inner surface of the body directly under the annular protrusion, placed in the zone of the ring, is made stepped, tapering from top to bottom, and the two-way sleeve and housing below the circulation holes you olneny with adjacent recesses arranged to form a hydraulic brakes simultaneously with the circumferential channel of the circulation holes of the sleeve to a two-way pressure relief valve body, the flap is provided with longitudinal grooves and provided with through balls housed in longitudinal through slots to engage the inner surface

case and with radially movable elements of the damper, and in the inner surface of the housing below its pressure reducing valves, an additional annular depression is made with the possibility of radial movement of balls into it during axial movement of the damper, while the amount of movement of the two-way sleeve at the first stroke N is determined from the relation: H≥h + R + r, where h is the amount of movement of the two-way sleeve during the first stroke to the initial position, at which the conical stops of the ring ring separator are fully extended into the central passage a channel with the possibility of interaction with the annular protrusion of the inner surface of the housing; R is the radius of the radial circulation holes of the housing; r is the radius of the radial circulation holes of the two-way sleeve.

The specified set of features is not known from the scientific, technical and patent literature, which means that the proposed device for cementing the wells meets the requirements for utility models.

The invention is illustrated by graphic images.

Figure 1 shows a device for cementing wells in the initial position (during descent into the well). Figure 2 is a section bB (see figure 1). Figure 3 - the device after moving the two-way sleeve by the value of h at the first stroke to the initial position, in which the conical stops of the annular ring separator are fully extended into the Central passage channel and interact with the annular protrusion of the inner surface of the housing. Figure 4 - at the end of the first stroke of the two-way sleeve. Figure 5 - at the time of the delay of the second stroke of the two-way sleeve with a hydraulic brake. Figure 6 - at the end of the second stroke of the two-way sleeve.

The device (Fig. 1) is installed on the casing (by means of connecting threads) and includes a composite housing 1 with a central passage 2, with radial circulation holes 3

radius R and with an inner surface made with annular protrusions 4, 5 and annular cavities 6, 7, 8, an additional annular cavity 9 installed in the housing 1 and telescopically connected with a shear element 10 two-way sleeve 11 unilateral movement and the ring 12 made with ring separators in which the conical stops 13 and 14 are installed (the dotted lines show the conical stops 14 after moving them together with the ring 12 and the two-way sleeve 11 down by the value of h during the first stroke to the initial position, with the conical stops 14 of the annular separator of the ring 12 are fully extended into the Central passage channel 2 and interact with the annular protrusion 4 of the inner surface of the housing 1) with centrifugal springs 15 with the possibility of interaction with the inner surface of the housing 1 and extend in the Central passage channel 2 or exit from this channel, as well as with the possibility of interaction, respectively, with the lower and upper rubber-metal dividing plugs 16, shown in figure 3, 4 and 5. The springs 15 are performed, for example measures in the form of a ring or a curved plate. The two-way sleeve 11 is fixed in the housing 1 by a shear screw 17 and is equipped with a mechanical limiter 18 of its first stroke installed in the annular cavity 7 and configured to withdraw it from the working position by displacing the ring 12 relative to the sleeve 11. The annular cavity 7 of the inner surface of the housing 1 immediately below the annular the protrusion 4, located in the zone of the ring 12, is made stepped, tapering from top to bottom. The limiter 18 includes sector locks that are held from moving to the device axis by an annular support 19 mounted in the sleeve 11 on the shear pin. In addition, the two-way sleeve 11 is made with radial circulation holes 20 of radius r located above the radial circulation holes 3 of the housing 1 and separated from them with the possibility of communication with them and re-separation, respectively

with the first and second strokes of the two-way sleeve 11 down. The two-way sleeve 11 is equipped with an autonomous pressure reducing valve 21 and is configured to form a hydraulic brake with the housing 1 in the form of a closed annular cavity 22 shown in FIG. 5 immediately after re-separation of the circulation holes 20 and 3 of the two-way sleeve 11 and the body 1. Stand-alone pressure reducing valve 21 can be made in the form of a rubber cuff overlapping a number of radial calibrated holes of a two-way sleeve 11. Moreover, the sleeve 11 and the housing 1 are lower than the circulator The holes 20 and 3 are made with adjacent annular recesses 23 and 24, placed with the possibility of simultaneously forming the bypass channel with the said hydraulic brake around the first rubber-metal dividing plug 16 (Fig. 5) from the circulation holes 20 of the two-way sleeve 11 to the pressure reducing valves 25 radially located in the body of the housing 1 along an annular row and disengaged from the central passage channel 2 by a shear pin and a shutter 26 with longitudinal through grooves 27, in which the balls 28 are placed, interact casing with the inner surface of the housing 1 and the radially movable elements 29 of the valve 26 (Fig.2). The damper 26 protects the pressure reducing valves 25 against premature actuation upon an unforeseen increase in pressure in the column. Radially movable elements 29 of the shutter 26 with balls 28 interacting with the annular protrusion 5 of the housing 1 and radially movable elements 29 form a rigid seat in the central passage 2 with the possibility of its interaction with the all-rubber dividing plug and exit from the central passage 2 due to radial movement balls 28 into an additional annular cavity 9 and radial displacement (deformation) of said elements 29 after axial displacement of the shutter 26. Radially movable elements 29 are performed, For example, in the form of a radially deformable

petals. Case 1 is connected to the upper and lower sub. Gasket seals are provided by rubber rings.

Rubber-metal dividing plugs 16 are made with non-return valves 30, opening towards the super-cork space (Figs. 3, 4, 5).

The two-way sleeve 11 in the lower part is equipped with a check valve 31 made in the form of a rubber cuff installed in the annular groove of the outer surface of the sleeve 11 with the overlapping of the annular row of radial holes of the annular groove and placed with the possibility of overlapping pressure reducing valves 25 after the first stroke of the sleeve 11 (Fig. four). The specified overlap excludes the flow of grouting mortar into the central passage 2 from the annulus at the second cementing stage.

In figure 3, the dashed line shows the conical stops 14 in the initial position of the device.

The amount of movement of the two-way sleeve 11 at the first stroke is H (Fig. 1), ah is the amount of movement of the two-way sleeve at the first stroke to the initial position, at which the conical stops 14 of the ring separator of the ring 12 are fully extended into the central passage 2 with the possibility of interaction with the ring the protrusion 4 of the inner surface of the housing 1 (figure 3).

A device for cementing wells works as follows (for example, stepwise cementing of a well).

After injection of the grouting material for the first cementing step (minimizing the reservoir properties of the reservoir) to the casing, the whole-rubber separation plug is inserted and pressed until it fits onto the “stop” ring (located near the shoe of the string) by pumping the specified fluids into the string. These liquids may be a portion of water in a volume several (by 0.5-1.0 m ³ ) exceeding the volume of the cavity of the column between

"stop" - a ring and a device, and then a portion of the drilling fluid injected. Between these portions, the first rubber-metal separation plug is introduced into the column to accelerate its fit into the device after receiving a stop signal at the first cementing stage.

When passing through the central passageway 2 of the device, the all-rubber dividing plug sits on a rigid seat formed by radially movable elements 29 of the shutter 26 and balls 28 interacting with the annular protrusion 5 of the housing 1 and radially movable elements 29, moves the shutter 26 in the axial direction until it stops against the end And the lower sub (Figs. 1, 2, 3) radially deforms the mentioned elements 29 (by unclenching the petals), which, leaving the central passage 2, radially move the balls 28 to an additional the annular cavity 9 and then the all-rubber dividing plug is displaced in the direction of “stop” - the ring. The axial displacement of the shutter 26 provides hydraulic communication of the pressure reducing valves 25 with the central passage channel 2 (Fig. 1), i.e. provides removal of protection of pressure reducing valves 25 from premature operation. The placement of the balls 28 in the longitudinal through grooves 27 of the shutter 26 eliminates their jamming during the interaction of the all-rubber dividing plug with said saddle and the axial displacement of the shutter 26 (Figs. 1, 2, 3).

After landing the all-rubber dividing plug on the “stop” - ring (receiving the “stop” signal), increase the pressure in the casing to a value that ensures the operation of at least one pressure reducing valve 25 (Fig. 3) (extruding its shut-off element - fixed by shear by means of a plug plug into the annular space) and thereby creates a hydraulic communication between the central passage channel 2 and the annular space, sufficient for

slow punching and "soft" landing of the first rubber-metal separation plug 16 on the conical stops 13.

Thus, the communication of the radial circulation holes 3 and 20 of the housing 1 and the two-way sleeve 11 is guaranteed.

The first rubber-metal separation tube 16, interacting with the stops 13, provides a cut of the screw 17 (Fig.3) and moves the two-way sleeve 11 down. When moving the two-way sleeve 11 down, the ring 12 also moves downward, pushing the conical stops 14 into the central passage 2. On the length of the two-way sleeve 11 equal to h, the conical stops 14 move along the conical surface of the housing 1 connecting the annular cavity 6 with the annular protrusion 4, and the full extension of the stops 14 into the central passage channel 2 due to their interaction with the annular protrusion 4 of the inner surface of the housing 1, i.e. a saddle is formed to fit the second rubber-metal separation plug. In this position, the radial circulation holes 3 and 20 are not yet communicated if the device parameters are interconnected by the ratio: H≥h + R + r. The movement of the two-way sleeve 11 by h under the action of the calculated pressure drop over the first rubber-metal dividing plug 16 is reliable and guaranteed only under the condition that during this movement the radial circulation holes 3 and 20 are not hydraulically communicated, which ensures that the predetermined pressure drop over the first rubber is maintained in the central passage 2 metal dividing plug 16, necessary for the specified movement of the two-way sleeve 11 with the full extension of the conical stops 14 in the Central passage channel 2. If the hydraulic communication of the radial circulation holes 3 and 20 begins before the completion of the movement of the two-way sleeve 11 by h, then the pressure drop over the first rubber-metal dividing plug 16 may be less than specified as a result of hydraulic

communication over the rubber-metal separation plug of the annulus and annulus of the well, and the two-way sleeve 11 may not move by the value of h, i.e. the stops 14 will be located on the conical surface of the housing 1, connecting the annular cavity 6 with the annular protrusion 4, and the full extension of the conical stops 14 in the Central passage channel 2 will not occur, and therefore will not be formed from the conical stops 14, necessary to complete the second two-way stroke sleeves 11. Thus, in a device whose parameters are interconnected by the ratio H≥h + R + r, the second stroke of the two-way sleeve 11 and the re-isolation of the radial circulation holes 3 and 20 cor 1 and two-way sleeve 11, and, therefore, ensures reliable operation of the device. After moving the two-way sleeve 11 down by an amount of h, it continues its first stroke until the radial circulation holes 3 and 20 are aligned. In this case, the pressure reducing valves 25 are blocked by the check valve 31 of the two-way sleeve 11 (Fig. 4), which eliminates the possibility of back flow of grout through the holes this valve into the casing cavity. When the two-way sleeve 11 makes the first stroke by the value of H (combining the radial circulation holes 3 and 20), its movement stops due to the interaction of the mechanical stop 18 with the housing 1 (i.e., the stop of the sector clamps of the stop 18 in the conical shoulder of the housing 1). The operations carried out by means of the first rubber-metal dividing plug 16 are controlled by a predetermined increase in pressure in the casing (cut of screw 17) and a subsequent decrease in this pressure with the resumption of fluid circulation in the well through openings 3 and 20.

In the interaction of the second rubber-metal separation plug 16 with conical stops 14 (at the end of the forcing of cementing materials of the second stage of cementing through

the circulation holes 3 and 20) at the beginning, the element 10 is cut. This cut provides the displacement of the ring 12 relative to the two-way sleeve 11 (Fig. 5), as a result of which, against the sector locks of the mechanical limiter 18, instead of the ring support 19, the ring groove of the ring 12 is located, and sector lock radially shifted against the stop in the wall of this groove with the termination of their stop in the conical shoulder of the housing 1, that is, the two-way sleeve 11 is freed from axial locking.

Then (Fig. 5), the two-way sleeve 11 together with the ring 12 is shifted downward until the circulation holes 3 and 20 are re-uncoupled, accompanied by the exit of the conical stops 14 from the central passage channel 2 into the annular cavity 7 of the inner surface of the housing 1, the formation of a bypass channel around the first rubber-metal separation plugs 16 from the circulation holes 20 of the sleeve 11 through the check valve 31 to the pressure reducing valves 25 (due to the corresponding placement of the recesses 23 and 24), as well as the formation of a hydraulic brake in the form of a message constant with auxiliary relief valve 21, a closed annular cavity 22.

The second rubber-metal separation plug 16 is fully displaced into the first similar plug located on the stops 13, displacing grouting material from the annular space into the annular space through the bypass channel, non-return valve 31 and pressure reducing valve 25.

A predetermined increase in pressure in the casing cavity above the device after the second rubber-metal separation plug 16 is planted on the first one (by multiplying the pressure in the annular cavity 22), the autonomous pressure-reducing valve 21 is opened - its rubber sleeve is broken against one or more radial calibrated openings of the two-way sleeve overlapped by it 11. As a result, there is an additional displacement of the sleeve 11 and the ring 12 (Fig.6) to a tight overlap with the sleeve 11 of the reduction

valves 25, accompanied by the exit of the conical stops 13 from the central passage channel 2 into the annular cavity 8 of the inner surface of the housing 1 (while maintaining the separation of the radial circulation holes 3 and 20), i.e. the second stroke of the sleeve 11 is completed. Rubber-metal separation plugs are released for mechanical pushing towards the casing shoe.

During well development operations, rubber-metal separation plugs are displaced before they fit onto the all-rubber separation plug placed on the “stop” ring. When the rubber-metal separation plugs are displaced, the liquid displaced by them through the check valves 30 of these plugs (Fig. 5) is transferred to the super-plug space.

The advantage of the proposed device is that it has the property of technological universality as a passage (not blocking the casing channel) and has high operational reliability, which ensures guaranteed communication and re-separation of the annulus and annulus with step and cuff cementing of wells.

Pilot work confirmed the high reliability of the proposed device.

Claims (1)

A device for cementing wells, comprising a housing with a central passage channel, an inner surface made with annular protrusions and depressions, radial circulation holes and radially arranged pressure reducing valves, a shutter disconnected from the central passage channel with radially movable elements forming a saddle in the central passage channel, a ring and two-way sleeve for unilateral movement with radial circulation holes, non-return valve, mechanical restriction its first stroke and autonomous pressure reducing valve, the two-way sleeve and ring are mounted in the housing and telescopically connected to each other by a shear element, and conical stops are installed in their annular separators with the possibility of interaction with the inner surface of the housing and extension into the central passage channel or exit from it, moreover, the radial circulation holes of the two-way sleeve are located above the radial circulation holes of the housing and are separated from them with the possibility of communication them and re-uncoupling, respectively, at the first and second strokes of the two-way sleeve down, its check valve is placed with the possibility of overlapping pressure reducing valves of the housing after the first stroke of the two-way sleeve, and the mechanical limiter of the first stroke of the two-way sleeve is installed with the possibility of withdrawing it from the working position, while the two-way sleeve configured to form a hydraulic brake with the housing in the form of a closed annular cavity communicated with an autonomous pressure reducing valve after repeated disconnection I radial circulation holes of the two-way sleeve and the housing, the cavity of the inner surface of the housing directly under the annular protrusion located in the zone of the ring is made stepped, tapering from top to bottom, and the two-way sleeve and the housing below the circulation holes are made with adjacent recesses arranged to form simultaneously with the hydraulic brake the bypass channel from the circulation holes of the two-way bushings to the pressure reducing valves of the housing, characterized in that the damper is made with a longitudinal through grooves and equipped with balls placed in longitudinal through grooves with the possibility of interaction with the inner surface of the housing and with the radially movable elements of the damper, and in the inner surface of the housing below its pressure reducing valves an additional annular cavity is made with the possibility of radial movement of the balls into it during axial movement of the damper while the amount of movement of the two-way sleeve at the first stroke N is determined from the ratio H≥h + R + r, where h is the amount of movement of the two-way sleeve at the first stroke to the initial position, in which the conical stops of the annular ring separator are fully extended into the Central passage channel with the possibility of interaction with the annular protrusion of the inner surface of the housing; R is the radius of the radial circulation holes of the housing; r is the radius of the radial circulation holes of the two-way sleeve.