阅读说明：本技术 导向胀开式可溶桥塞 (Guide expansion type soluble bridge plug ) 是由 张正玉 李孟来 张新华 刘虎 郑平 李阳兵 田太华 刘兴春 孙玉刚 陈洋 刘殿清 于 2020-12-30 设计创作，主要内容包括：本发明涉及可溶桥塞技术领域,旨在解决现有桥塞在胀开时均匀性和顺利性存在缺陷的问题,提供导向胀开式可溶桥塞,其包括引鞋和卡瓦；引鞋的外周面的一端设置为锥形的第一锥面；卡瓦的内表面的一端具有与第一锥面适配的第三锥面；卡瓦包括沿周向依次间隔分布的多个第一切槽和多个第二切槽；第一切槽从卡瓦的轴向第一端切入但未延伸至其轴向第二端,第二切槽从卡瓦的轴向第二端切入但未延伸至其轴向第一端；轴向第一端靠近引鞋；引鞋上设置有沿轴向的导向筋；第二切槽为槽宽保持一致的槽,第一切槽的起始段为槽宽较大且能够与导向筋匹配的槽,以使导向筋能够可活动地配合于第一切槽的起始段。本发明的有益效果是能够提高卡瓦胀开的周向均匀性。(The invention relates to the technical field of soluble bridge plugs, aims to solve the problem that the existing bridge plug has defects in uniformity and smoothness during expansion, and provides a guide expansion type soluble bridge plug which comprises a guide shoe and a slip; one end of the peripheral surface of the guide shoe is provided with a first conical surface; one end of the inner surface of the slip is provided with a third conical surface matched with the first conical surface; the slips comprise a plurality of first cutting grooves and a plurality of second cutting grooves which are sequentially distributed at intervals along the circumferential direction; a first slot cut into but not extending to an axial first end of the slip and a second slot cut into but not extending to an axial first end of the slip; the axial first end is close to the guide shoe; the guide shoe is provided with a guide rib along the axial direction; the second cutting groove is a groove with the groove width kept consistent, and the starting section of the first cutting groove is a groove with the larger groove width and capable of being matched with the guide rib, so that the guide rib can be movably matched with the starting section of the first cutting groove. The invention has the beneficial effect that the circumferential uniformity of the expanding of the slips can be improved.)

1. A direction expanding soluble bridge plug which is characterized in that:

comprises a guide shoe and a slip;

one end of the outer peripheral surface of the guide shoe is provided with a first conical surface; one end of the inner surface of the slip is provided with a third conical surface matched with the first conical surface;

the slips comprise a plurality of first cutting grooves and a plurality of second cutting grooves which are sequentially distributed at intervals along the circumferential direction; the first slot cut into but not extending to an axial first end of the slip, the second slot cut into but not extending to an axial first end of the slip;

the axial first end is close to the guide shoe;

the guide shoe is provided with a guide rib along the axial direction;

the second cutting groove is a groove with the consistent groove width, and the starting section of the first cutting groove is a groove with the larger groove width and capable of being matched with the guide rib, so that the guide rib can be movably matched with the starting section of the first cutting groove.

2. A direction expanding soluble bridge plug which is characterized in that:

comprises a guide shoe and a slip;

one end of the outer peripheral surface of the guide shoe is provided with a first conical surface; one end of the inner surface of the slip is provided with a third conical surface matched with the first conical surface;

the slip is provided with a guide groove extending along the axial direction of the slip, and the guide shoe is provided with a guide rib capable of being in sliding fit with the guide groove.

3. The soluble bridge plug of claim 2, wherein:

the slips comprise a plurality of first cutting grooves and a plurality of second cutting grooves which are sequentially distributed at intervals along the circumferential direction; the first slot cut into but not extending to an axial first end of the slip, the second slot cut into but not extending to an axial first end of the slip;

the axial first end is close to the guide shoe;

the guide grooves are distributed on part or all of the first cutting grooves uniformly along the circumferential direction.

4. The soluble bridge plug of claim 3, wherein:

the width of the guide groove is larger than that of the first cutting groove.

5. The soluble bridge plug of claim 3, wherein:

the groove widths of the first cutting groove and the second cutting groove are 0.3-0.6 mm; the width of the guide groove is 2.6-3.4 mm.

6. The soluble bridge plug of claim 3, wherein:

the guide slot is cut into the first axial end and extends a length less than the length of the first slot.

7. The soluble bridge plug of claim 3, wherein:

the guide rib protrudes from a generatrix of the first conical surface along the normal direction of the conical surface.

8. The soluble bridge plug of claim 3, wherein:

also includes a cone and a central tube;

the guide shoe is connected to one axial end of the central tube, and the cone is matched with the other axial end of the central tube and can move towards the direction close to the guide shoe; the peripheral surface of one end of the cone close to the central tube is a conical second conical surface;

the other end of the inner peripheral surface of the slip is a fourth conical surface matched with the second conical surface.

Technical Field

The invention relates to the technical field of bridge plugs, in particular to a guide expansion type soluble bridge plug.

Background

The soluble bridge plug can block oil, gas, water, leakage and other layers according to requirements, and is mainly applied to the field of oil and gas exploitation energy.

The existing bridge plug has certain defects in uniformity and smoothness during expansion.

Disclosure of Invention

The invention aims to provide a guide expansion type soluble bridge plug to solve the problem that the existing bridge plug has certain defects in uniformity and smoothness during expansion.

The embodiment of the invention is realized by the following steps:

a guided expanding dissolvable bridge plug comprising a shoe and a slip;

one end of the outer peripheral surface of the guide shoe is provided with a first conical surface; one end of the inner surface of the slip is provided with a third conical surface matched with the first conical surface;

the slips comprise a plurality of first cutting grooves and a plurality of second cutting grooves which are sequentially distributed at intervals along the circumferential direction; the first slot cut into but not extending to an axial first end of the slip, the second slot cut into but not extending to an axial first end of the slip;

the axial first end is close to the guide shoe;

the guide shoe is provided with a guide rib along the axial direction;

the second cutting groove is a groove with the consistent groove width, and the starting section of the first cutting groove is a groove with the larger groove width and capable of being matched with the guide rib, so that the guide rib can be movably matched with the starting section of the first cutting groove.

The soluble bridging plug of direction expanding in this scheme can exert suitable guide to the slips at the slips inflation in-process, can improve the circumference homogeneity that the slips was expanded.

The embodiment of the invention also provides a guide expansion type soluble bridge plug, which comprises a guide shoe and a slip;

one end of the outer peripheral surface of the guide shoe is provided with a first conical surface; one end of the inner surface of the slip is provided with a third conical surface matched with the first conical surface;

the slip is provided with a guide groove extending along the axial direction of the slip, and the guide shoe is provided with a guide rib capable of being in sliding fit with the guide groove.

In one embodiment:

the slips comprise a plurality of first cutting grooves and a plurality of second cutting grooves which are sequentially distributed at intervals along the circumferential direction; the first slot cut into but not extending to an axial first end of the slip, the second slot cut into but not extending to an axial first end of the slip;

the axial first end is close to the guide shoe;

the guide grooves are distributed on part or all of the first cutting grooves uniformly along the circumferential direction.

In one embodiment:

the width of the guide groove is larger than that of the first cutting groove.

In one embodiment:

the groove widths of the first cutting groove and the second cutting groove are 0.3-0.6 mm; the width of the guide groove is 2.6-3.4 mm.

In one embodiment:

the guide slot is cut into the first axial end and extends a length less than the length of the first slot.

In one embodiment:

the guide rib protrudes from a generatrix of the first conical surface along the normal direction of the conical surface.

In one embodiment:

also includes a cone and a central tube;

the guide shoe is connected to one axial end of the central tube, and the cone is matched with the other axial end of the central tube and can move towards the direction close to the guide shoe; the peripheral surface of one end of the cone close to the central tube is a conical second conical surface;

the other end of the inner peripheral surface of the slip is a fourth conical surface matched with the second conical surface.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings referred to in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings may be obtained from these drawings without inventive effort.

A schematic diagram of the structure of an all-metal soluble bridge plug in an embodiment of the invention is shown in fig. 1;

FIG. 2 is a schematic diagram showing the fit of an all-metal soluble bridge plug and casing;

FIG. 3 is a three-dimensional view of slips in an embodiment of the present invention;

in figure 4 there is shown a cross-sectional view of an expander in an embodiment of the invention;

FIG. 5 is a view taken along line A of FIG. 4;

FIG. 6 is a three-dimensional view of a guide shoe in an embodiment of the present invention;

FIG. 7 is a schematic illustration of a center tube in an embodiment of the present invention;

FIG. 8 is a cross-sectional view of a base pipe in an embodiment of the present invention;

FIG. 9 is an enlarged view of FIG. 7 at B;

fig. 10 is an enlarged view of fig. 7 at C.

Icon: the full-metal soluble bridge plug 100, an expansion ring 10, a receiving groove 11, an inner annular surface 12, an outer annular surface 13, a conical base surface 14, a conical surface section 15, a groove surface section 16, a front conical surface section 17, a rear conical surface section 18, a first groove surface section 19, a second groove surface section 20, a combined surface 21, a rear annular wall 22, a cut 23, an arc piece 24, a front annular wall 25, a fillet 26, a seal ring groove 27, a center tube 40, a shoe guide 41, a cone 42, a clamping and sealing structure 43, a backstop tooth 44, a first inner hole 45, a second inner hole 46, a clamping and locking component 47, a seal component 48, a clamping and locking structure 49, a slip 50, a slip tooth 51, a first cutting groove 52, a second cutting groove 53, a slip ring 54, a seal ring 55, a hole 56, grease 57, a guide groove 58, a guide rib 59, a snap tooth 60, a cutting groove 61, an axial first end D1, an axial second end D2, a first conical surface P1, a second conical surface P2, a third conical surface P56, a fourth conical surface P4, A sixth taper surface P6, a locking position S1, a sealing and adhering position S2, a containing cavity Q1 and a sleeve 200.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Examples

Referring collectively to fig. 1, the present invention also provides an all-metal soluble bridge plug 100 comprising a center tube 40, a boot 41, a cone 42, and a retaining seal structure 43.

Wherein the guide shoe 41 is attached to one axial end of the center tube 40. The wall of the central tube has a slot 61 running through it in a direction parallel to the axis, so that the central tube is in a partially annular configuration. And the central tube can be made of elastic materials such as aluminum magnesium alloy, and after the cutting groove 61 is arranged, the central tube can be radially contracted by extrusion or radially and elastically expanded and restored when the extrusion force is removed.

The outer peripheral surface of center tube is close to guide's one end and is equipped with along being on a parallel with its axial distribution's stopping tooth 44, the guide is close to the one end of center tube and is equipped with first hole 45, the hole face of first hole is equipped with the latch 60 that can block in stopping tooth 44.

The end of the peripheral surface of the central tube, which is close to the cone, is provided with retaining teeth distributed along the axial direction of the central tube, the end of the cone, which is close to the central tube, is provided with a second inner hole 46, and the hole surface of the second inner hole is provided with a latch 60 capable of being clamped on the retaining teeth 44, so that the cone can move forwards in one direction relative to the shoe guiding direction and cannot move backwards.

Therefore, when the cone, the guide shoe and the central tube are relatively static, the clamping teeth are clamped in the stopping teeth, so that the guide shoe and the cone can be prevented from retreating relative to the central tube; and when the cone moves relatively close to the guide shoe, the cone and the guide shoe apply radial inward pressure to the central tube through the clamping teeth, so that the central tube is radially shrunk without stopping the relative advance of the cone. The backstop action is determined primarily by the orientation of the teeth and will not be described in detail herein.

In this embodiment, one end of the inner peripheral surface of the locking seal structure 43 corresponding to the guide 41 is a tapered surface that fits the first tapered surface P1, and one end of the inner peripheral surface corresponding to the taper 42 is a tapered surface that fits the second tapered surface P2. When the cone 42 moves in the direction of the guide shoe 41, the locking seal structure 43 can be expanded in the radial direction so that a part thereof is locked to the sleeve 200 and a part thereof is in sealing contact with the sleeve 200. The fully metal soluble bridge plug 100 is shown in FIG. 2 in a condition to capture and sealingly engage the sleeve 200.

The all-metal soluble bridge plug 100 in the embodiment can be pressed into the guide shoe 41 through the taper body 42, so that the clamping and sealing structure 43 expands to clamp and seal the sleeve 200 in the radial direction under the pressing and guiding of the first taper surface P1 and the second taper surface P2, and meanwhile, the all-metal soluble bridge plug 100 and the sleeve 200 are fixed and sealed, and the structure is simple and the use is convenient.

In the operating state, the latching position S1 of the latching seal structure 43 and the sleeve 200 is located below the sealing position S2 of the sleeve 200.

In the present embodiment, the stopper seal structure 43 includes a stopper member 47 and a seal member 48. One end of the inner peripheral surface of the locking member 47 is a third tapered surface P3 that fits the first tapered surface P1. The other end of the inner peripheral surface of the locking component 47 is a fourth taper surface P4 matched with the second taper surface P2; the outer peripheral surface of the locking member 47 is provided with a locking structure 49 which can be locked to the sleeve 200 when the locking member 47 is radially expanded.

In this embodiment, the locking member 47 includes a slip 50, and slip teeth 51 as locking structures 49 are provided on the outer peripheral surface of the slip 50 in a protruding manner.

Referring collectively to fig. 3, the slips 50 include a plurality of first undercut grooves 52 and a plurality of second undercut grooves 53 that are circumferentially spaced apart; the first slot 52 is cut from the axial first end D1 of the slip 50 but does not extend to its axial second end D2, and the second slot 53 is cut from the axial second end D2 of the slip 50 but does not extend to its axial first end D1. By the arrangement of the first and second slots 52, 53, the slips may be squeezed radially outward. In this embodiment, the slips 50 may further include a hole 56 between adjacent first and second notches 52, 53 for receiving the slip teeth 51.

Referring to fig. 1, in this embodiment, the slip 50 is provided with a slip ring 54 around its outer circumference at an end adjacent to the shoe 41. The axial end surface of the locking component 47 near one end of the cone 42 is a conical convex fifth conical surface P5, and the conical angle of the fifth conical surface P5 is complementary to the fourth conical surface P4.

In this embodiment, the seal assembly 48 is annular, the seal assembly 48 is disposed on the second tapered surface P2, and the inner annular surface 12 is a tapered surface adapted to the second tapered surface P2.

In this embodiment, the seal assembly 48 includes an expander 10 and a seal ring 55 coupled to the outer annular surface 13 of the expander 10. The illustrated two seal rings 55 are fitted in the two seal ring grooves 27 of the expander 10. In this embodiment, the expander 10 is made of a highly ductile material such as magnesium-aluminum alloy so that it can expand radially under the compression of the cone 42. In the scheme, the outer annular surface is expanded to form sealing with the sleeve where the all-metal soluble bridge plug is located. The sealing between the outer ring surface and the sleeve can be the direct attaching sealing between the outer ring surface and the sleeve, and can also be the sealing between the outer ring surface and the sleeve by a sealing ring arranged on the outer peripheral surface of the expansion ring. And for the situation that the outer ring surface and the sleeve are directly jointed and sealed, the outer ring surface is not required to be provided with a sealing ring groove. In practice, the all-metal soluble bridge plug for well entry is mostly sealed in a mode without a sealing ring.

With reference to fig. 4 and 5, the expander 10 for the all-metal soluble bridge plug 100 provided in the present embodiment has an annular shape, and an axial end surface of the expander 10 near one end of the latching component 47 is a sixth conical surface P6 which is conically recessed; the seal assembly 48 abuts with its conically concave sixth taper surface P6 the conically convex fifth taper surface P5 of the catch assembly 47 to exert a radially inward force on both axial ends of the slips in cooperation with the slip ring 54.

With this configuration, the slips are constrained at one end by the radially inward force of the slip ring 54 and at the other end by the radially inward component of the force exerted by the sixth tapered surface P6 of the seal assembly 48 during high swage. In this embodiment, the radial inward forces applied to the two ends of the slip may be calculated to match the radial inward forces applied to the two ends of the slip so that the two ends of the slip may expand as synchronously as possible when the slip is squeezed. The method can be realized by means of simulation or test, and the like, which is not described herein again. The taper angles are arranged in a complementary mode, so that when the cone body is extruded, the interaction force between the expansion ring and the slips is parallel to the second taper surface of the cone body, and synchronous and uniform expansion of the expansion ring and the slips is facilitated.

Continuing with fig. 4 and 5, the present embodiment provides an expander 10 for an all metal soluble bridge plug 100 having an inner annular surface 12 and an outer annular surface 13. The inner annular surface 12 has a tapered surface section 15 on a tapered base surface 14 and a groove surface section 16 recessed from the tapered base surface 14, the groove surface section 16 defining a receiving groove 11 capable of receiving lubricating or corrosion-resistant grease 57. The expander 10 is capable of being forced to expand radially to an outer annulus 13 for sealing with the all-metal dissolvable bridge plug 100.

When the expander 10 in the present scheme is assembled on the conical surface of the cone 42 of the all-metal soluble bridge plug 100, the accommodating groove 11 and the conical surface of the cone 42 together enclose an accommodating cavity Q1, and grease 57 can be filled in the accommodating cavity Q1. Before the expansion ring 10 expands, the grease 57 can be used for protecting the conical surface of the cone 42, so that corrosion of the corresponding position of the conical surface of the cone 42 can be avoided or slowed down; the outer annular surface 13 of the expander 10 forms a seal with the inner circumferential surface of the casing 200 in which the all-metal soluble bridge plug 100 is located after expansion, and the grease 57 also provides lubrication to the contact surfaces during expansion.

In this embodiment, the tapered section 15 includes a front tapered section 17 having a smaller diameter and a rear tapered section 18 having a larger diameter, and the groove section 16 is connected between the front tapered section 17 and the rear tapered section 18.

Optionally, the groove face section 16 comprises a first groove face section 19 and a second groove face section 20 connected to each other; the outer end of the first groove surface section 19 is connected with the front conical surface section 17, and the second groove surface section 20 is connected with the rear conical surface section 18. A rear annular wall 22 is defined between the combined surface 21 of the second groove surface section 20 and the rear conical surface section 18 and the corresponding part of the outer annular surface 13, and a plurality of slots 23 distributed on the rear annular wall 22 in the circumferential direction are formed in the rear annular wall 22; the slit 23 is cut forward a set distance from the rear end surface of the rear annular wall 22 in the axial direction of the rear annular wall 22 to divide the rear portion of the rear annular wall 22 into a plurality of circumferentially cut arc pieces 24. The number of the slots 23 in the embodiment is 32, and the slots are uniformly distributed on the circumference. Optionally, the intersection of the first trough-face section 19 and the front cone-face section 17 transitions through a fillet 26. In this embodiment, the width of the slit 23 is 0.1 to 0.2 mm. The slit 23 in this embodiment is only a structural slit, and is used for dividing the rear annular wall 22, and the slit width is extremely small, so that the corrosion-resistant grease 57 filled in the accommodating groove 11 does not leak out. In practice, the slit 23 may be formed by wire cutting or the like. In this embodiment, the slit 23 may extend through the entire rear annular wall 22, or may be cut into the rear portion of the rear annular wall 22 for a certain length. The present embodiment illustrates a slot 23 extending through the entire rear annular wall 22.

In this embodiment, the second groove surface segments 20 are parallel to the outer annular surface 13, and the distance between the outer annular surface 13 is 1.2-1.7mm, for example, the distance may be optionally set to 1.5 mm.

In the present embodiment, the front conical surface section 17 and the corresponding portion of the outer annular surface 13 define a front annular wall 25 therebetween; the front ends of the arc pieces 24 are connected to the front annular wall 25. The first and second groove face sections 19, 20 are perpendicular to each other so that the thickness from the rear end of the front annular wall 25 to the front end of the rear annular wall 22 decreases stepwise. In this way, the main resistance to the expansion of the expander 10 is concentrated in the front wall 25, while the resistance to the expansion of the expander 10 is very small, almost negligible, in the rear wall 22 due to the separation of the slits 23. The inventor finds in research that, for the expander 10, the circumferential uniformity of the structure at the part with small thickness is extremely sensitive, namely, for the part with small thickness of the expander 10, even small deviation of the thickness at each part in the circumferential direction can cause the non-uniformity at the expanding time; in contrast, the circumferential uniformity is less required for the portions of the expander 10 having a greater thickness, i.e., the expansion can be substantially uniform to a greater degree of non-uniformity. Thus, in the present embodiment, the resistance of the rear annular wall 22 to the expansion of the expander 10 is substantially changed to the resistance of the respective arc pieces 24 by cutting the rear annular wall 22 having a small thickness, and the respective arc pieces 24 have a small resistance, so that the expansion can be performed substantially uniformly. The back ring wall 22 of the expander 10 in this embodiment also has the effect of an effective guide for the cone 42 to be pressed in.

In this embodiment, the outer annular surface 13 is provided with a seal ring groove 27 for receiving a seal ring 55; a seal ring groove 27 is provided at the outer annular surface 13 corresponding to the front annular wall 25. Two rings of seal grooves 27 are shown.

In this embodiment, the expander 10 may be made of magnesium-aluminum alloy. The expander 10 in the embodiment is made of aluminum-magnesium alloy with good ductility, and can radially expand without breaking when being extruded, so that the sealing capacity of the expander after expansion is ensured. Of course, the expansion ring 10 can be made of other materials capable of ensuring the sealing capability after expansion.

In this embodiment, the axial end surface of the expander 10 near the end with the smaller diameter of the tapered base surface 14 is the sixth tapered surface P6, and the taper angle of the sixth tapered surface P6 is complementary to the taper angle of the tapered base surface 14.

As in the previous expander 10 for the all-metal soluble bridge plug 100, the expander 10 includes a front annular wall 25 and a rear annular wall 22, and the front annular wall 25 and the rear annular wall 22 are integrally connected in the axial direction; the inner peripheral surface of the front annular wall 25 is tapered with a small front and a large rear; the thickness of the rear annular wall 22 is smaller than that of the front annular wall 25, and the connection part from the inner circumferential surface of the front annular wall 25 to the inner circumferential surface of the rear annular wall 22 is in a step shape; the inner circumferential surface of the junction of the rear annular wall 22 and the front annular wall 25 is recessed to define a receiving groove 11 capable of receiving lubricating or corrosion-resistant grease 57.

Referring to fig. 1 again, in the present embodiment, the expander 10 is sleeved on the second taper surface P2, the tapered section of the expander 10 is fitted on the second taper surface P2, and the second taper surface P2 closes the receiving groove 11 to form a receiving cavity Q1; the receiving cavity is filled with grease 57.

In the all-metal soluble bridge plug 100 in the scheme, under the assembly state of the expansion ring 10, grease 57 in the accommodating cavity applies anti-corrosion protection to the conical surface of the cone 42; if necessary, the cone 42 is pressed axially into the expander 10, so that the expander 10 expands radially to form a seal with the casing 200 in which the all-metal soluble bridge plug 100 is located, and during the axial pressing of the cone 42, the grease 57 lubricates the contact part of the second conical surface P2 of the cone 42 and the conical section of the expander 10, and the frictional resistance to the pressing of the cone 42 is reduced.

Referring collectively to fig. 3 and 6, an all metal soluble bridge plug 100 in this embodiment is configured as a guided expanding all metal soluble bridge plug 100. as previously described, all metal soluble bridge plug 100 in this embodiment includes shoe guides 41 and slips 50. One end of the outer peripheral surface of the guide shoe 41 is provided with a first tapered surface P1; one end of the inner surface of the slip has a third taper surface P3 that mates with the first taper surface P1. The slips comprise a plurality of first cutting grooves 52 and a plurality of second cutting grooves 53 which are sequentially distributed at intervals along the circumferential direction; the first slot 52 is cut into but does not extend to the axial second end D2 from the axial first end D1 of the slip and the second slot 53 is cut into but does not extend to the axial first end D1 from the axial second end D2 of the slip.

The axial first end D1 is adjacent to the guide shoe 41. The slip is provided with a guide groove 58 extending along the axial direction of the slip, and the guide shoe 41 is provided with a guide rib 59 along the axial direction. The second cut groove 53 has a uniform groove width, and the first cut groove 52 has a larger groove width at the beginning thereof to match the guide rib 59, so that the guide rib 59 can be movably fitted to the first cut groove 52 at the beginning thereof.

In this embodiment, the guiding rib 59 on the guide shoe 41 and the initial section of the first cut groove 52 are matched to conveniently guide the expansion of the slip, so that the slip can be uniformly expanded.

Alternatively, there are a plurality of guide grooves 58, and the plurality of guide grooves 58 are uniformly distributed at part or all of the first cut grooves 52 in the circumferential direction. Alternatively, the groove width of the guide groove 58 is larger than the groove width of the first cutout groove 52.

In this embodiment, the groove widths of the first undercut 52 and the second undercut 53 are 0.3 to 0.6 mm; the width of the guide groove 58 is 2.6-3.4 mm. The guide groove 58 is cut from the axial first end D1 and extends for a length less than the length of the first cut groove 52.

In this embodiment, the guide rib 59 protrudes from a generatrix of the first taper surface P1 thereof in the taper surface normal direction.

In other embodiments, the guide slot 58 may be provided separate from the first cut-out 52. Of course, the guide grooves 58 are still used to cooperate with the guide ribs 59.

The all-metal soluble bridge plug 100 in this embodiment is designed to be all-metal soluble, and it is meant that the major components including the expander ring 10, the guide shoe 41, the cone 42, the slips 50, the slip ring 54, etc. are made of soluble metals such as magnesium aluminum alloy, etc., but it is not excluded that small components such as the slip teeth and some connecting pins, etc. are made of other insoluble metals or non-metal materials. The all-metal soluble bridge plug 100 can temporarily block oil, gas, water, leakage and other layers, high-pressure fracturing construction operation is carried out on a production layer on the upper portion of the all-metal soluble bridge plug 100, and after the fracturing construction operation is completed, main components of the all-metal soluble bridge plug 100, which are made of soluble metals such as magnesium-aluminum alloy, are automatically dissolved under the conditions of liquid and temperature in a well, so that a full channel of the production casing 200 is provided. And the undissolved slip teeth, pins and the like are small in size, so that the smoothness of the channel cannot be influenced. At present, the tool is mainly applied to shale gas well stratum reconstruction.

The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes will occur to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.