BR112021008002B1 - ORIENTATION SLEEVE GUIDE SET - Google Patents

Abstract

ORIENTATION SLEEVE GUIDE SET, GUIDANCE SLEEVE SET, AND, GUIDE SET FOR PASSING COLUMN TO A WELL HOLE. A column guide comprising an upper mandrel, a lower guide sleeve guide concentric with a lower portion of the upper mandrel, and an annular fastener internal to the lower guide sleeve guide that secures the lower guide sleeve guide to the upper mandrel. When the guide encounters an obstruction (e.g., a packer hole or liner top), the weight of the equipment above the lower guiding sleeve guide elastically deforms the annular fastener that drives the lower guiding sleeve guide up the chuck. higher. As the lower guidance sleeve guide travels through the upper mandrel, the internal lugs of the guidance sleeve guide rest in a spiral groove in the upper mandrel to rotate the lower guidance sleeve guide around the upper mandrel.

Description

TECHNICAL FIELD

[001] The disclosure generally refers to the field of earth or rock drilling (mining) and, more particularly, to well equipment or well maintenance.

FUNDAMENTALS

[002] Traditional well construction, such as drilling an oil or gas well, consists of three phases: drilling, casing and production with tubing. In the drilling phase, rock is cut until a deposit is reached. This establishes a wellbore or shaft through a series of formations. Each formation through which the well passes must be sealed to prevent undesirable passage of fluids, gases or formation materials out of the formation and into the well or from the well into the formation. Furthermore, it is often desired to isolate both producing and non-producing formations from each other to avoid contaminating one formation with fluids from another formation.

[003] Lining the wellbore with casing protects the formation layers and stabilizes the wellbore. Packers and liners are often used in wellbore casing to separate types of fluids. Packers are tools used to form an annular seal between two concentric strings of pipe or between the pipe and the wall of the open hole and are usually set just above the production zone to isolate the production range from the casing annulus or production zones. elsewhere in the wellbore. Sometimes it is not desired for the casing to extend to the surface of the wellbore, in which case a liner is used. A liner is a casing string that does not extend to the top of the wellbore, but instead is anchored or suspended from within the bottom of the previous casing string.

[004] Production piping is passed into a drilled well after the casing is passed and set in place. Production tubing protects the wellbore casing from wear and corrosion, whilst providing a continuous borehole from the production zone to the wellhead. When sections of production piping are run into a wellbore, they often pass through a packer or liner top to interconnect them. However, packer holes and liner tops are substantially centered in the wellbore. If the wellbore is diverted, the production tubing will tend to engage the edge of the packer hole or the top of the liner instead of entering it. In order to correct this problem, the production piping is maneuvered to enter the packer hole or the top of the liner. A guide is attached to the lower end of production tubing to facilitate entry into a packer hole or maneuver through downhole obstructions. The guide typically includes a guide sleeve geometry such that rotation of the guide sleeve will allow the end of the guide to clear the top of a packer or obstruction. This rotation can be accomplished by rotating the entire production pipeline from the surface. However, when passing the production tubing string into a wellbore, the ability to rotate the tubing string to enter packer holes or liner tops may be impeded due to control lines attached to the tubing and/or angles. of extreme holes. When rotation of production tubing is not feasible, there are self-aligning orienting sleeve guides available that will rotate as the weight of the production tubing string applied to the guide increases due to the guide seating in a packer hole or liner top . A guide with a guiding sleeve geometry will enter the packer hole or liner top after sufficient rotation. After the guide enters the packer or liner top, the lower end of the guide will typically move back to the original position with the assistance of a spring. Additionally, the spring designed for use in the guide is designed for the harsh downhole environment, which incurs significant cost in material and design.

BRIEF DESCRIPTION OF THE DRAWINGS

[005] Modalities of disclosure can be better understood by referring to the attached drawings.

[006] FIG. 1 depicts a schematic diagram of a well system making use of a single-acting snap ring guide in accordance with some embodiments.

[007] FIG. 2 illustrates an embodiment of a single-acting snap ring guide.

[008] FIG. 3 illustrates a cross-sectional side view of a single-acting snap ring guide.

[009] FIG. 4 represents a cross-sectional view of the pressure ring in a groove in the upper mandrel.

[0010] FIGS. 4A-B represent a cross-sectional sectional view of the snap ring in a groove in the upper mandrel and an embodiment of a snap ring for use in the springless orienting sleeve guide assembly.

[0011] FIG. 5 is an enlarged cross-sectional side view of the snap ring having jumped from the first groove to the next groove in the mandrel.

DESCRIPTION OF MODALITIES

[0012] The following description includes example systems that incorporate embodiments of the disclosure. However, it is understood that this disclosure may be made without these specific details. For example, this disclosure relates to a single-acting snap ring guide for entering a packer hole or liner top in a wellbore for subsurface drilling operations in illustrative examples. Embodiments of this disclosure may also be applied to subsea drilling operations. In other cases, well-known instruction instances, protocols, structures, and techniques were not shown in detail so as not to obfuscate the description.

Overview

[0013] When passing the string of production tubing into a wellbore, a guide is often used at the lower end of the string to assist in maneuvering down the hole. Guides are used to keep the production tubing centered within the wellbore, thereby minimizing problems associated with obstructions striking the tubing (e.g., rock edges or objects) in the wellbore as the tubing is lowered into the wellbore. A guide has been designed that can rotate without a spring. This springless guide is designed with a helical or spiral groove to guide the orientation of the guide shoe and with a constant section retaining ring (“snap ring”) and at least one circumferential groove for the snap ring to rest and retain. guide shoe in position. When the guide shoe encounters an obstruction, the weight of at least the guide itself drives a chuck from the guide to the guide shoe. As the chuck is driven downward, internal lugs of the guide shoe mount into the spiral groove in the chuck and cause the guide shoe to rotate. If the guide shoe is still in contact with the edge and the weight is still providing a force on the guide, the snap ring will move out of the current circumferential groove through a beveled edge of the current circumferential groove and fit into a next groove , allowing the guide to continue its rotation as the snap ring moves between circumferential grooves. Once the guide shoe enters the packer or liner top, the guide shoe can remain in position for future operations. Keeping the guide shoe in the same orientation that allowed it to enter a packer or liner top can increase operational efficiency because it is more likely to be in the correct alignment for the next packer hole or liner top encountered in the wellbore. This removes the need for multiple applications of weight to be applied to the guide to index the guide around the desired orientation. No springs or other mechanisms are required to return the guide to a previous position.

Example Illustrations

[0014] In the following description of a single-acting snap ring guide assembly and other apparatus and methods described herein, directional terms such as “top”, “bottom”, “upper”, “lower”, etc. , are used only for convenience when referring to the accompanying drawings. Specifically, top and bottom are used to refer to different regions, parts, portions, or components of an assembly or equipment when oriented vertically. Additionally, it will be understood that the various embodiments of the inventive subject matter described in this document can be used in various orientations, such as inclined, inverted, horizontal, vertical, etc., and in various configurations, without departing from the principles of the embodiments.

[0015] FIG. 1 depicts a schematic diagram of a well system making use of a single-acting snap ring guide to pass a string of production tubing into the wellbore. FIG. 1 depicts an example of a well system after a vertical wellbore 114 has been drilled. The well system includes a platform 106 positioned on the surface of the earth 104 and extending over and around the wellbore 114. The wellbore 114 extends vertically from the surface of the earth 104.

[0016] In particular, FIG. 1 represents the wellbore 114 in which a packer 110 has been inserted downhole. The packer 110 closes a space between the open hole and a wellbore casing 116 before a string of production tubing 112 is passed. The packer 110 contains a hole through which the production tubing string can be passed. The production tubing string 112 is passed into the wellbore 114 with the aid of a guide 108. The guide 108 is a springless guiding sleeve guide attached to the lower end of the production tubing string 112. The guide 108 is designed to rotate, if necessary, to enter the packer 110 without rotating the production piping string 112 and without cycling (i.e., raising and lowering the string).

[0017] FIG. 2 depicts one embodiment of a single-acting snap ring guide assembly 200. The single-acting snap ring guide assembly 200 consists of a concentric lower guiding sleeve guide 201 with an upper mandrel 202. A mandrel, as defined herein, may refer to a shaft or tube around which other components are arranged or mounted. The lower guidance sleeve guide 201 is tapered to allow guidance around obstructions (e.g., entry into packer holes and liner tops). The tapered lower end of the lower guide sleeve guide 201 has an angled segment 205 and a flat segment 206. The angled segment 205 is cut from one side of the lower portion of the lower guide sleeve guide 201 while the rest remains flat. The lower guiding sleeve guide 201 is secured to the mandrel 202 by a snap ring 204. The snap ring 204 is housed within the lower guiding sleeve guide 201 (as indicated by the dashed lines) and in contact with the outer surface of the upper mandrel 202. The illustrated longitudinal location of the snap ring 204 on the springless guidance sleeve guide assembly 200 is only to illustrate the existence of the snap ring and not a necessary initial location or rest location. Snap ring 204 is a circular ring that expands and contracts in response to applied forces. The snap ring 204 acts as a wedge, holding the lower orienting sleeve guide 201 in place relative to the upper mandrel 202. The upper mandrel 202 consists of two sets of grooves (203, 205). The grooves 203 are a set of grooves that spiral around the upper mandrel 202, while the grooves 205 are a set of circumferential grooves orthogonal to a central axis of the upper mandrel 202. The grooves 205 are chamfered to allow the pressure ring 204 move between the slots. Snap ring 204 engages grooves 205 to lock the lower guiding sleeve guide 201 in place relative to the upper mandrel 202. The snap ring 204 is inside the lower guiding sleeve guide 201 and outside the upper mandrel 202 securing the two pieces. The grooves 203 spiral around the upper mandrel 202 and allow the lower orienting sleeve guide 201 to rotate and move up the upper mandrel 202 when the pressure ring 204 is expanded due to an applied force from the loading of components above the single acting snap ring guide assembly 200 weighing down on the single acting snap ring guide assembly 200 when the flat segment 206 encounters or contacts an obstruction.

[0018] When the single-acting snap ring guide assembly 200 encounters an obstruction (e.g., a packer or liner top) in a wellbore, the flat segment 206 rests on the liner top. This causes a force due to the weight of the single-acting snap ring guide assembly 200 and a column fixed above the guide equipment 200 to act on the slewing sleeve guide 201. This force causes the snap ring 204 expand and slide out of the grooves 205. With the snap ring 204 disengaged from the grooves 205 the lower guiding sleeve guide 201 rotates upward relative to the upper mandrel 202 following the grooves 203. If the lower part of the guide is still seating on the edge after the snap ring 204 engages a first of the orthogonal grooves 205 and contracts, the snap ring 204 will slide out of the current beveled orthogonal groove and expand to continue its rotation and upward movement. Once the angled segment 205 is aligned in an orientation that allows the guide assembly 200 to enter the packer hole or liner top, the single-acting snap ring guide assembly 200 will drop, removing the force acting on it. on the lower guiding sleeve guide 201. Thus, the snap ring 204 will once again engage with the grooves 205 and the lower guiding sleeve guide 201 will remain in that position for future operations. In some cases, the snap ring 204 may not have moved into one of the grooves 205 when the lower guide sleeve guide 201 orients to a position that allows the guide assembly 200 to pass through an obstruction. In some embodiments, inertia will allow the snap ring 204 to continue moving along the upper mandrel 202 until the snap ring 204 engages with the next groove 205. In some embodiments, friction between the snap ring 204 and the outer surface of the upper mandrel 202 between the grooves 205 will be sufficient to retain the lower orienting sleeve guide 201 in position without the snap ring 204 engaging a groove 205.

[0019] FIG. 3 depicts a cross-sectional side view of the single-acting snap ring guide assembly 200 of FIG. 2. The cross-sectional view further shows enlarged view 320. Enlarged view 320 illustrates the beveled edge of the snap ring 204 and its position between the upper mandrel 202 and the lower orienting sleeve guide 201 when engaged in one of the circumferential grooves 205. Snap ring 204 has an inner edge chamfer from an approximate midpoint of a top (i.e., toward the upper mandrel and away from the shoe) at 45 degrees to an interior of snap ring 204 to align with the beveled edge of the circumferential grooves 205. Aligning the beveled edges makes it easier to match the snap ring 204 to the beveled edges of the circumferential grooves 205. This reduces the likelihood that the snap ring 204 will catch on an edge of the circumferential grooves 205 or another part of the upper mandrel 202 and maintains a predictable pressing action. The lower orienting sleeve guide 201 consists of a recessed internal channel or a cutout 307 that houses the snap ring 204 when the snap ring 204 is in an expanded position. The cutout 307 is circumferential around the inner diameter of the lower guide sleeve guide 201. When the snap ring 204 expands, the snap ring 204 slides out of the grooves 205 and into the cutout 307. The snap ring travels through the upper mandrel 202 in cutout 307 to the next groove 205. This sequence of expansion out of groove 205 into cutout 307, traveling through the upper mandrel 202 and reengaging with the next sequential groove 205 continues until the lower guide sleeve 201 orients to pass through an obstruction (e.g. enter packer hole). In some cases, the snap ring 204 may not have moved into one of the grooves 205 when the lower guide sleeve guide 201 orients to a position that allows the guide assembly 200 to pass through an obstruction. In some embodiments, the snap ring 204 will remain in position when the guide assembly 200 can pass through the obstruction and retain the lower guiding sleeve guide 201 in place due to tension of the snap ring 204 and/or intersurface adhesion between the surface of the pressure ring 204 and the outer surface between the grooves 205 of the mandrel 202.

[0020] FIG. 3 depicts a set of eyes 306 internal to the lower guide sleeve guide 201 ("inner eyes") on the upper portion of the lower guide sleeve guide 201. The eyes 306 connect the top end of the lower guide sleeve guide 201 to the bottom of the upper mandrel 202. In some embodiments, the eyes 306 are comprised of individual projections spaced along the upper portion of the lower guide sleeve guide 201. In other embodiments, the eyes 306 are comprised of a spiral projection. The spiral protrusion aligns with the spacing and angular configuration of the grooves 203 in the upper mandrel 202. The eyes 306 in the lower guide sleeve guide 201 are in the spiral grooves 203 in the upper mandrel 202. When the lower guide sleeve guide 201 is pushed upward by the force acting on the guide assembly 200, the lower guiding sleeve guide 201 rotates due to the lugs 306 being in the spiral groove 203 in the upper mandrel 202.

[0021] FIG. 4 depicts a cross-sectional, cross-sectional view of the snap ring 204 in a groove 205 in the upper mandrel of the springless orienting sleeve guide assembly 200 of FIG. 2. FIG. 4A shows the total circumference of a snap ring 400 when positioned in a groove 205 in the upper mandrel 202. A portion of the lower orienting sleeve guide 201 is removed to show the entire snap ring 400. The snap ring 400 is positioned between the inner surface of the lower guiding sleeve guide 201 and the outer surface of the upper mandrel 202. The upper mandrel 202 has a set of ring grooves 205 that are circumferential to the upper mandrel 202 and are positioned orthogonal to the central axis of the mandrel 202 The grooves 205 have edges (208, 209) to allow the snap ring 400 to move out of the grooves 205 when a force is applied to the lower guide sleeve guide 201 in an upward direction (i.e., when the guide guide sleeve 201 engages with an obstruction) and holds the lower guide sleeve 201 in place when it does not encounter an obstruction. The lip 208 is shaped to prevent the snap ring 400 from moving out of the groove 205 when the lower guide sleeve guide 201 does not encounter an obstruction. For example, border 208 may be a square border. The lip 209 is shaped to allow the snap ring 400 to move out of the groove 205 when the lower orienting sleeve guide 201 engages an obstruction. Thus, the edge 209 may be an angled or beveled edge that allows the snap ring 400 to slide out of the groove 205 when the lower guiding sleeve guide 201 encounters an obstruction.

[0022] FIG. 4B depicts the snap ring for use in the single-acting snap ring guide assembly 200 of FIG. 4A. Snap ring 400 is an annular fastener with an opening. The snap ring 400 acts as a wedge, holding the lower orienting sleeve guide 201 in place relative to the mandrel 202. The snap ring 400 consists of a retaining ring 411 and two ends (410A, 410B). When a force is applied to the lower guide sleeve guide 201 of FIG. 4A, ring 411 assumes an elliptical deformation. Due to deformation, ring 411 contacts groove 205 of FIG. 4A at three or more isolated points along the groove 205, but not continuously around the circumference. The elliptical deformation causes the ends (410A, 410B) to separate, allowing the snap ring to disengage from the groove 205. When the force is removed, the ends (410A, 410B) return to the original position and engage the next groove 205 .

[0023] FIG. 5 depicts an enlarged cross-sectional view of the overlap portions of the single-acting snap ring guide assembly 200 of FIG. 2. FIG. 5 illustrates the position of the snap ring 204 after jumping from one circumferential groove to the next. The snap ring 204 engages the grooves 205A or 205B when a force is not applied to the guide 200. When the lower guide sleeve guide 201 encounters an obstruction, the corresponding force causes the snap ring 204 to slide from a groove to the next, sequentially, since the pressure ring 204 is attached to the lower orienting sleeve guide 201 upon which the force is applied. Before the weight is seated on the guide, the snap ring 204 is engaged in the groove 205A. When weight is applied to the guide assembly 200, the pressure ring 204 elastically deforms and disengages from the groove 205A. The weight causes the orienting sleeve guide 201 to rotate upward around the spiral groove 203. For each groove 205 the snap ring 204 jumps, the lower orienting sleeve guide 201 will rotate an angular distance defined by the longitudinal distance between the grooves 205 and the angle of the spiral grooves 203. In some embodiments, each groove 205 will correspond to a 60-degree rotation of the lower orienting sleeve guide 201 around the upper mandrel 202. As an example, the mandrel 202 may be made with six of the grooves 205 at a distance apart corresponding to the groove 203 spiraling at an adapted angle to allow the lower orienting sleeve guide 201 to complete a full 360 degree rotation. This angular rotation rotates the lower orientation sleeve guide 201 until aligned in an orientation for passing an obstruction. When the lower orienting sleeve guide 201 passes the obstruction, force is no longer applied and the snap ring 204 will engage the next groove 205B. This action holds the lower guidance sleeve guide 201 in position.

[0024] Although the previous example refers to a design with 6 ring grooves to allow for a single 360 degree rotation of the lower guide sleeve guide, a guide assembly design will vary depending on a specified maximum degree of rotation or rotations complete. Design attributes of the guide assembly that can influence the amount of rotation include top mandrel length, number of ring grooves, and helix pitch or helix angle. The length of the upper mandrel limits the longitudinal distance that can be traveled by the lower guiding sleeve guide. With the maximum longitudinal distance that can be traveled by the lower guide sleeve guide and a specified total number of complete rotations to be allowed, the number of ring grooves and any of the helix pitch or helix angle can be specified in the groove design. helical.

[0025] Although the illustrations above refer to a snap ring, embodiments are not limited to a snap ring. Embodiments use an annular fastener that elastically deforms to exit a ring groove to then travel along a portion of an inter-groove mandrel.

[0026] The embodiments described in this document use a single action, caused by an application of force applied due to contact with a packer or liner top, to place the guide in the desired position to enter a packer hole or liner top. Single action is the ability to perform work in only one direction. Single action, as used herein, refers to the rotation of the lower orienting sleeve guide being only in an upward direction relative to the upper chuck. The snap ring allows single-acting rotation of the bottom orienting sleeve guide and removes the need for a long coil spring as used in traditional self-aligning pipe guides. By not using long coil springs, the risk of potential malfunction or introduction of debris into the bore is reduced. This reduces cost and increases reliability over current guides.

[0027] Although aspects of the disclosure are described with reference to various implementations and exploitations, it will be understood that these aspects are illustrative and that the scope of the claims is not limited thereto. Plural examples may be provided for components, operations, or structures described herein as a single example. Finally, boundaries between various components, operations, and data stores are somewhat arbitrary, and particular operations are illustrated in the context of specific illustrative configurations. Other functionality allocations are contemplated and may fall within the scope of the disclosure. In general, structures and functionality presented as separate components in example configurations can be implemented as a combined structure or component. Likewise, structures and functionalities presented as a single component can be implemented as separate components. These and other variations, modifications, additions and improvements may fall within the scope of the disclosure.

[0028] The use of the phrase “at least one of” preceding a list with the conjunction “and” should not be treated as an exclusive list and should not be interpreted as a list of categories with one item from each category, unless specifically stated otherwise.A clause that recites “at least one of A, B, and C” may be infringed with only one of the items listed, multiples of the items listed, and one or more of the items in the list and another item not listed.

Example Embodiments

[0029] Example embodiments include the following: Embodiment 1: An orientation sleeve guide assembly comprising: an upper mandrel having a first end adapted to couple to a column and having a plurality of grooves on an outer surface of the upper mandrel, wherein the plurality of grooves comprises a helical groove and a set of ring grooves; a lower guiding sleeve guide concentric with at least a lower portion of the upper mandrel; and a snap ring located within the lower guiding sleeve guide and securing the lower guiding sleeve guide to the upper mandrel.

[0030] Embodiment 2: The orientation sleeve guide assembly of Embodiment 1, wherein the ring groove assembly is substantially orthogonal to a longitudinal axis of the upper mandrel.

[0031] Embodiment 3: The orientation sleeve guide assembly of Embodiment 1 or 2, wherein the snap ring is positioned in one of the set of ring grooves when engaged in the upper mandrel.

[0032] Embodiment 4: The guidance sleeve guide assembly of one of Embodiments 1-3, wherein the snap ring is positioned in a cutout on the inner circumference of the lower guidance sleeve guide when the snap ring is disengaged of the slotted chuck.

[0033] Embodiment 5: The orienting sleeve guide assembly of any of Embodiments 1-4, wherein the lower orienting sleeve guide comprises internal eyes adapted to lie in the helical groove winding around the upper mandrel.

[0034] Embodiment 6: The guiding sleeve guide assembly of any of Embodiments 1-5, wherein at least one first of the ring groove assembly comprises a beveled edge, the beveled edge being toward the first end of the mandrel top and the pressure ring comprises a chamfer adapted to match the chamfered edge.

[0035] Embodiment 7: The guiding sleeve guide assembly of any of Embodiments 1-6, wherein a first ring groove also comprises a square edge, the square edge being toward the second end of the upper mandrel.

[0036] Embodiment 8: A guide assembly comprising: a slotted mandrel having a first end adapted to engage or connect a second end and having a spiral groove and a set of ring grooves on an outer surface of the slotted mandrel; a concentric guide shoe with at least the second end of the mandrel grooved; and an annular fastener that secures the guide shoe to the slotted mandrel.

[0037] Embodiment 9: The guide assembly of Embodiment 8, wherein the guide shoe comprises a tapered bottom portion.

[0038] Embodiment 10: The guide assembly of Embodiments 8 or 9, wherein the annular fastener is adapted to deform elastically when exiting one of the set of ring grooves.

[0039] Embodiment 11: The guide assembly of any of Embodiments 8-10, wherein each of the set of ring grooves is substantially orthogonal to a longitudinal axis of the slotted mandrel.

[0040] Embodiment 12: The guide assembly of any of Embodiments 8-11, wherein the guide shoe comprises an internal cutout adapted to accommodate the annular ring when elastically deformed.

[0041] Embodiment 13: The guide assembly of any of Embodiments 8-12, wherein the guide shoe comprises internal eyes adapted to lie in the spiral groove to allow the shoe to rotate around the slotted mandrel.

[0042] Embodiment 14: The guide assembly of any of Embodiments 8-13, wherein at least one first groove of the ring groove assembly comprises a first edge adapted to allow the annular fastener to move out of the first ring groove, the first edge being toward the first end of the slotted mandrel.

[0043] Embodiment 15: The guide assembly of any of Embodiments 8-14, wherein the first ring groove comprises a second edge adapted to prevent the fastener from exiting the first groove towards the second end of the slotted mandrel.

[0044] Embodiment 16: A guide assembly for passing string into a wellbore, the guide assembly comprising: a mandrel having a first end that is a coupling end and a second end, and having an outer set of ring and an external helical groove; an annular fastener capable of elastic deformation, the annular fastener securing a guide shoe to the mandrel; and the guide shoe comprising an internal cutout for housing the annular fastener when elastically deformed and internal lugs that lie within the outer helical groove of the mandrel when the guide shoe rotates about the mandrel, the guide shoe being concentric to at least one lower portion of the chuck.

[0045] Embodiment 17: The guide assembly of Embodiment 16, wherein the annular fastener can elastically deform to exit one of the outer set of ring grooves.

[0046] Embodiment 18: The guide assembly of any of Embodiments 16-17, wherein the annular fastener is a snap ring.

[0047] Embodiment 19: The guide assembly of any of Embodiments 16-18, wherein numerous of the outer set of ring grooves and the outer helical groove are adapted to permit at least one complete rotation of the shoe guide around the mandrel .

[0048] Embodiment 20: The guide assembly of any of Embodiments 16-19, wherein each of the set of ring grooves comprises a beveled edge and a square edge, the beveled edge toward the first end of the mandrel and the square towards the second end of the chuck.

Claims (7)

1. Orientation sleeve guide assembly (200), characterized in that it comprises: an upper mandrel (202) having a first end adapted to couple to a column and having a plurality of grooves (203, 205) on a surface external of the upper mandrel (202), wherein the plurality of grooves comprises a helical groove (203) and a set of ring grooves (205); a lower guiding sleeve guide (201) concentric with at least a lower portion of the upper mandrel (202), the lower guiding sleeve guide (201) comprising internal eyelets adapted to lie in the helical groove (203) winding around the upper chuck (202); the lower guide sleeve guide (201) further comprising a cutout (307) in an inner circumference of the lower guide sleeve guide (201); and a snap ring (204) located within the lower guiding sleeve guide (201) and securing the lower guiding sleeve guide (201) to the upper mandrel (202). 2. Orientation sleeve guide assembly (200) according to claim 1, characterized in that the assembly of ring grooves (205) is orthogonal to a longitudinal axis of the upper mandrel (202). 3. Orientation sleeve guide assembly (200) according to claim 1, characterized by the fact that the pressure ring (204) is positioned in one of the assembly of ring grooves (205) when engaged with the upper mandrel (202). 4. Orientation sleeve guide assembly (200) according to claim 1, characterized in that the pressure ring (204) is positioned in the cutout (307) on an inner circumference of the lower orientation sleeve guide (201 ) when the pressure ring (204) is disengaged from the upper mandrel (202). 5. Guiding sleeve guide assembly (200) according to claim 1, characterized in that at least one first groove of the ring groove assembly (205) comprises a beveled edge, the beveled edge being toward the first end of the upper mandrel (202), and with the pressure ring (204) comprising a chamfer adapted to match the chamfered edge. 6. Guiding sleeve guide assembly (200) according to claim 5, wherein the first ring groove also comprises a square edge, the square edge being toward a second end of the upper mandrel (202 ). 7. Orientation sleeve guide assembly (200) according to claim 1, characterized in that the lower orientation sleeve guide (201) is springless.