Abstract:
A well tool, such as a packer apparatus, is adaptable for insertion on a conduit within a subterranean well having casing therein. The well tool comprises a cylindrical mandrel which is communicable to the conduit. Slip means are carried exteriorly around the mandrel and are movable into expanded position for anchoring the apparatus to the casing whereby subsequent longitudinal movement of the apparatus in at least one direction is prevented. Seal means are circumferentially extending exteriorly around the mandrel and are urgable into sealing relation with the casing to prevent fluid communication thereacross, the seal means comprising at least one section of transversely compressible seamless, knitted elements generally defined by a continuous series of interlocking ductile metal-containing loop members.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The invention relates to a tool insertable within a subterranean well comprising a seal means defined by a continuous series of transversely compressible interlocking ductile metal-containing loop members. 
     2. Description of the Prior Art 
     During certain operations in a subterranean oil or gas well, such as during a completion or workover procedure, it is common practice to utilize a packer assembly, bridge plug or other isolation tool to separate one section or zone of a well from another section or zone. Such apparatuses typically employ elastomeric sealing members, utilized alone or in combination with other sealing elements, such as virgin tetrafluoroethylene and/or glass-filled tetrafluoroethylene components (sometimes referred to under the tradename &#34;Teflon&#34;), as the primary means for isolating the section or zone, the seal means, upon manipulation of the tool, sealing against the internal wall of the casing. In extremely hostile well environments, such as those wherein the bottom hole temperature is in excess of about 350° F. and/or exposed to considerably high concentrations of H 2  S and or CO 2 , an acrylonitrile-type elastomeric substance has been utilized in the seal means of the tool, to provide somewhat effective working life for the tool. The use of such acrylonitrile-type elastomers is not entirely satisfactory because this material can, with time, chemically degrade to the extent that its elastomeric properties are lost in the hostile environment, described above, Other materials, such as tetrafluoroethylene have the desired chemical inertness, but tend to extrude under high temperature and pressure. Additionally, when metallic back-up rings are utilized in such seal systems, wherein a gap is defined in the metallic ring upon expansion thereof into engagement with the casing, &#34;gaps&#34; or &#34;voids&#34; will be necessarily defined at one or more points thereon which require sealing with respect to the casing in order to insure the integrity of the entire seal system. 
     The present invention is directed to a seal means for use in a well tool, such as a well packer, which prevents extrusion of such inert sealing elements, described above, and which will fill &#34;gaps&#34; and &#34;voids&#34; within metallic back-up rings within the seal system. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a longitudinally extending sectional view, the left hand side showing the exterior, and the right hand side being a cut-away view showing the interior, of a well packer apparatus employing the present invention, prior to setting in a well having casing therein. 
     FIG. 2 is a view similar to that illustrated in FIG. 1 showing the component parts of the apparatus subsequent to setting of the apparatus, the seal means being illustrated in sealing relation to the casing, the slips being in anchored position. 
     FIG. 3 is an enlarged perspective view of the seal assembly illustrated in FIGS. 1 and 2. 
     FIG. 3A is a cross-sectional view taken along line 3A--3A of FIG. 3 illustrating, in pre-crushed state the continuous series of interlocking ductile metal-containing loop members utilized in the seal means of the present invention. 
     FIG. 4 is a perspective view of the seal means subsequent to the setting of the apparatus in the well. 
    
    
     SUMMARY OF THE INVENTION 
     The present invention is directed to a well tool, such as a well packer, bridge plug, or other sealing means which is adaptable for insertion in a conduit within a subterranean well and for selective sealing engagement with a second conduit, such as a casing. The well tool comprises a cylindrical mandrel communicable to the first conduit, such as the tubular work or production string. Slip means are carried exteriorly around the mandrel and are moveable into expanded position for anchoring the apparatus to the second conduit, or casing, whereby subsequent longitudinal movement of the apparatus in at least one direction is prevented. Seal means circumferentially extend exteriorly of the mandrel and are urged into sealing relation with the second conduit to prevent fluid transmission thereacross, the seal means comprising at least one section of transversely compressible seamless, knitted elements generally defined by a continuous series of interlocking ductile metal-containing loop members. In a preferred form, the seal means may further comprise as asbestos-laden material innerwoven among the loop members. In still another preferred form, the seal means may additionally comprise upper and lower sections of the seamless elements, together with a seal member comprising one of tetrafluoroethylene and flourinated ethylene propylene. Metal extrusion barriers or secondary supports, together with glass-filled seal members, also may be incorporated within the seal means. 
      DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Now referring to FIG. 1, the apparatus A which is illustrated as a well packer, is carried on a tubular conduit TC and is inserted within a well W extending to a production zone Z, the well W having a string of casing C extending from the zone Z to the top of the well, the casing C having perforations P therethrough communicating from the zone Z to within the annulus AL. 
     The apparatus A is run on the tubular conduit TC within the well W below and in operational communication with a setting tool ST having an internal setting tool activator STA affixed by threads 10A to a longitudinally extending cylindrical mandrel in the apparatus A, the setting tool ST also having a setting tool sleeve STS formed on the exterior of the setting tool ST. Together, the setting tool sleeve STS and the setting tool activator STA provide a &#34;push-pull&#34; action upon the apparatus A during the setting thereof. 
     The setting tool may be one of a number of conventionally and commercially known setting tools, and the particular setting tool or mechanism utilized does not form a part of the present invention. Typical of such setting tools is that as shown in the Technical Data Manual Unit No. 2717 of the Baker Packers Division, Baker International Corporation and the Baker Packers Model &#34;J&#34; Hydraulic Setting Assembly, Product No. 413-71. However, any setting tool which is adaptable to provide a &#34;push-pull&#34; action, as described above, may be used in conjunction with the apparatus A for the setting thereof. 
     The mandrel 10 has defined thereon a series of exteriorly defined circumferentially extending wicker elements 11 which, together with engageable wickers 18 on a body lock ring 17 carried exteriorly around the mandrel 10 are utilized in the setting of the apparatus A. A hole 12 is defined in the mandrel 10 for receipt of one end of a shear screw 24 protruding therein and out of an upper cone element 23 for initial securement of the upper cone element 23 around the mandrel 10. A similar hole 13 holds the exterior inwardly protruding end of a lower shear screw 40 insertable therein and extending interiorly from a lower cone element 39. The mandrel 10 is terminated at its lower end by a series of threads 14 for affixation of a ported bottom sub element 43. 
     The wickered lock ring 17 is secured at threads 16 to a lock ring protector 15 having an upper end 15A receiving the lower end of the setting tool sleeve STS, prior to the setting of the apparatus A. The lower end 19 of the lock ring protector abuts upon the upper face of a circumferentially extending series of slotted upper slips 20 having exteriorly protruding teeth 21 thereon which, upon setting of the apparatus A, will break up along longitudinal grooves and then contact and grasp the inner wall of the casing C for anchoring of the apparatus A relative to the casing C. An upper cone element 23 is carried below the upper slips 20 and circumferentially around the exterior of the mandrel 10, the upper cone 23 having a slanted guide surface 22 for guiding and urging the upper slips 20 outwardly into anchored position. The upper shear screws 24 is carried within a bore of the upper cone 23 and has its innermost end protruding outwardly of the cone 23 and into the hole 12 fo initial securement of the upper cone 23 to the mandrel 10. 
     An upper triangularly shaped cone ring element 25 is carried circumferentially around the mandrel 10 and below the upper cone 23 and is initially shouldered against said upper cone 23. This upper cone ring 25 typically is of a metallic substance and, when urged outwardly into engagement with the casing C, provides a metal back-up bridging means to prevent extrusion of other components of the seal means and further provide support to the sealing means. The cone ring 25 contains a groove 27 profiled on its lower face for receipt of a companion tongue 28 of a similarly constructed element ring 26, of triangular configuration. It should be noted that each of the rings 25 and 26 contain a gap, such as 29 shown in FIG. 3 which is enlarged (as shown in FIG. 4) upon activation of the apparatus A into sealing engagement with the casing C, the &#34;gap&#34; in the cone ring 25 being spaced 180°  from the &#34;gap&#34; in the element ring 26. Such a gap is a construction detail of the rings 25-26 enabling each of the said rings to radially expand into engagement with the internal wall of the casing C. 
     Below the element ring 26 and extending circumferentially around the mandrel 10 is a section of transversely compressible seamless, knitted elements generally defined by a continuous series of interlocking ductile, metal-containing loop members. Such an element is described in U.S. Pat. No. 2,761,203, entitled &#34;Resilient Gasket Forming Material And Method Of Reducing Same&#34;, and No. b 3,033,722, entitled &#34;Compressible Metal Gasket And Method Of Making Same&#34;, each being assigned to Metex Corporation of Edison, N.J., from which such a product can be readily obtained. 
     Now referring specifically to FIG. 3A, this element consists of continuous series 30A, 30B, 30C, etc., of interlocking loops knitted in a tubular form, allowing two-way movement in the wire plane, affording unusual flexibility and resiliency, even under heavy compression loads and exposure to extreme temperatures. It has been found that knitted wire yields to applied force, yet maintains its compressive stress. Since there are no ribs, seams or other weak areas in this construction, the seal has a uniform strength over its entire area. When used in combination with other basic sealing material, such as asbestos-laden cords 30D, 30E, 30F, etc., interwoven betweeen one or more of the loops 30A, 30B, 30C, etc., the knitted wire serves as a &#34;backbone&#34; sleeve or expander, imparting its resiliency to the combined element. This seamless, knitted element is compressed to contour to the general requirements of contour of the apparatus and may be fabricated from almost any material or combination of materials that may be drawn or filament form, such as stainless steel wire, or other ductile metals, such as aluminum, copper and special alloys, in combination with the asbestos-laden material, other synthetic fibers, polymers and yarns. Such a knitted element is further disclosed in Bulletin No. Ml-50 of the Metex Thermal-Mechanical Group, Metex Corporation. 
     Referring to FIG. 3, below the upper knitted wire mesh element 30 and communicating therewith is a secondary seal element 31, which may be typically a teflon or glass-filled teflon ring element. The main sealing component of the seal means in the apparatus A is defined as a virgin teflon ring element 32, preferably having grooved internally spaced circumferentially extending rib elements 32A thereon to permit flexing of the seal 32 during setting. 
     Below the main seal element 32 is provided a lower, preferably glass-filled teflon secondary seal element 33 which, in turn, contacts a second or lower knitted wire mesh element 34 of the same or similar construction as the upper knitted wire mesh element 30. Similarly, the seal means is terminated at its lowermost end by the companion lower cone 39 and lower element rings 35 and 38, respectively, of similar construction and design as the rings 25 and 26. A groove and tongue configuration 36 and 37, respectively, is defined between the rings 38 and 35 for interengagement thereof. 
     Carried circumferentially around the exterior of the mandrel 10 and below the lower element ring 38 is a lower cone element 39 receiving a lower shear screw element 40 therethrough having its innermost interior end received within the hole 13 in the mandrel 10 for securing the lower cone 39 to the mandrel 10 prior to the setting of the apparatus A. The lower cone 39 has a guide 39A for directing a series of slotted lower slip elements 41 having teeth 42 into radially extended positioning for securing the teeth 42 into the inner wall of the casing C to assist in anchoring the apparatus A unto the inner wall of the casing C. 
     OPERATION 
     The apparatus A is run into the well on a tubular conduit TC, such as the tubing string or the like, and is located above perforations P within the zone Z. The setting tool ST typically will be activated by pumping or gravitating a ball element through the tubular conduit TC until it lands upon a seat (not shown) in the setting tool ST. Thereafter, pressure is applied within the tubular conduit TC and against the ball and seat for transmission of hydraulic force through setting tool ST. The setting tool sleeve STS typically will be urged downwardly while the setting tool activator STA is stabilized or urged upwardly. This &#34;push-pull&#34; force is transmitted between the mandrel 10 and the components of the apparatus A extending therearound, and, because of the innerengagement of the bottom sub 43 to the mandrel 10 at threads 14, such action will cause the lock ring 17 to shift relative to the mandrel 10 upon innerengagement of the wickers 11-18, thereby urging the lock ring protector 15 against the upper slips 20 which are moved along the guide 22 of the upper cone 23 until the teeth 21 contact and engage the inner wall of the casing C. Concurrently, the force is transmitted from the upper slips 20 through the cone 23 and, subsequent to shearing of the shear screw 24, through the upper cone ring 25 and element ring 26, whereby the rings 25-26 expand radially outwardly, extending the length of the gap 29, until the rings 25 and 26 contact the inner wall of the casing C. The setting force continues to be transmitted to the upper knitted wire mesh element 30 which is urged outwardly into contact with the casing C to prevent extrusion of the ring 31 therebelow and to fill the gap defined in the element ring 26. The setting force continues to be transmitted through the apparatus A for outward urging of the virgin teflon ring 32, the lower glass-filled ring 33, the lower knitted wire mesh element 34, the lower cone ring 35 and the lower element ring 38. 
     It should be noted that as the lower knitted wire mesh element 34 extends outwardly, it will fill the extended &#34;gap&#34; or &#34;void&#34; in the lower cone ring 35 as it extends radially outwardly into sealing engagement with the casing C. The force continues to be transmitted to the lower cone members 39 which, by means of the guide 39A, urge the lower slip members 41 outwardly away from the apparatus A, such that the teeth 42 grasp the casing C, subsequent to shearing of the lower shear screw 40 from position on the mandrel 10. 
     The complete setting position of the apparatus A is shown in FIG. 2 with the upper and lower slip elements 20 and 41 respectively engaging in the wall of the casing C and the seal means being in sealed relationship with the casing C. The relative position of the components of the seal means in their expanded mode are as shown in FIG. 4. 
     Although the invention has been described in terms of specified embodiments which has been set forth in detail, it should be understood that this is by illustration only and that the invention is not necessarily limited thereto, since alternative embodiments and operating techniques will become apparent to those skilled in the art in view of the disclosure. Accordingly, modifications are contemplated which can be made without departing from the spirit of the described invention.