Abstract:
The present invention provides an apparatus for cementing a liner string in a well bore. The apparatus comprises an operating string having a smaller diameter than the internal diameter of the liner string which is insertable therein. The operating string is connected within the internal diameter of the liner string and may be operated by rotation of the operating string to release the string from the liner. A plug is connected to the lower end of the operating string and has a top plug which is releasably supported from the plug carrying body together with a longitudinally spaced bottom plug which is releasably supported from the top plug. The top plug is pressure releasable relative to the plug carrying body, as is the bottom plug to the top plug, and a retainer on the bottom plug, respectively. A shift is provided for locking the top plug to the plug carrying body until the bottom plug is released by application of pressure. A mechanical lock is provided to secure the retainer means relative to the bottom plug to prevent inadvertent release prior to release by application of pressure.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates generally to equipment for cementing liners in well bores and specifically to a well bore liner cementing apparatus having multiple liner wiper plugs for wiping the interior surfaces of the operating string and liner during cementing operations. 
     2. Description of the Prior Art 
     A liner is a section of casing or tubing which is suspended in a well without normally extending to the surface. Cemented liners are used for many purposes including well control and reducing the initial cost of casing. Liners may be installed entirely within outer casing strings or partially within the casing and partially within an open hole. 
     Conventionally, a liner is set and cemented by first lowering the liner and a setting tool connected to an operating string into the well bore. The liner is hung, usually on slips, and the setting tool is usually, but not always released from the liner. Cement is then pumped through the operating string, into the liner, and displaced from the liner, usually through a foot valve, into the annular space between the liner and the surrounding casing or well bore. 
     In most cases, a pump down plug is introduced into the liner string immediately behind the cement in order to separate the cement from the displacing fluid and to wipe the cement from the operating string and liner surface as the cement is pushed out of the liner into the surrounding annular space. Typically, the pump down plug which is to wipe the operating string and liner is pumped behind the cement until it engages a liner wiper plug and then the liner wiper plug and pump down plug are forced downwardly together in the liner string so as to displace the cement therefrom and to wipe the liner walls. 
     U S. Pat. No. 3,910,349 to Joe R. Brown et al, entitled &#34;APPARATUS AND METHOD FOR CEMENTING WELL LINERS&#34;, issued Oct. 7, 1975, shows a liner cementing apparatus which includes a setting tool having a tubular mandrel connected in a pipe string for extension through the liner. A liner wiper plug is releasably disposed within the liner near one end of the mandrel. After the liner is hung in position in the well bore, the setting tool is unlatched and moved axially a few feet to indicate to the operator at the surface that disengagement of the setting tool has occurred. A pump down plug engages the liner wiper plug to wipe the interior of the operating string and liner behind the cement column. 
     It is an advantage in well cementing operations to provide a cementing apparatus which utilizes multiple plugs to completely isolate the column of cement being pumped through the operating string and liner. U.S. Pat. No. 3,364,996, to C. C. Brown, entitled &#34;APPARATUS FOR CEMENTING WELL LINERS&#34;, issued Jan. 23, 1968, shows a cementing apparatus utilizing a total of four plugs to isolate the column of cement being pumped from the well bore fluids both in front of and behind the column of cement. The present invention is an improvement to the device shown in U.S. Pat. No. 3,364,996, in that the top liner wiper plug is positively locked to the plug carrying body of the setting tool until the bottom wiper plug has been released. Both the top and bottom liner wiper plugs are positively locked to each other and to the setting tool until the pump down plugs land in their respective seats. Because of the positive lock features of the design, premature shear of either the top or bottom liner wiper plugs is prevented. 
     In co-pending U.S. patent application Ser. No. 7/147,699, filed Jan. 25, 1988, entitled &#34;APPARATUS AND METHOD FOR CEMENTING A LINER IN A WELL BORE&#34;, there is shown and disclosed and apparatus and method for cementing a liner in a well bore utilizing a unique cement wiping plug system. While such system is unique for the reasons set forth therein, it has recently been discovered that said device may not be completely hydraulically balanced with respect to all of its shear releasing mechanisms in that for example with respect to the device shown in FIG. 1B of said application, the retainer ring 151 is held in place by a shear pin mechanism 155 which could be exposed to premature shearing as the bottom plug assembly travels downwardly within the liner subsequent to release from the upper plug, as described in said patent application by means of the encountering of the shoulder 147 of the sleeve 125 and a direct downward force being applied at the upper end 149 of the retainer ring 151 to thereby cause a premature load on the pin 155 and cause same to prematurely shear. 
     The present invention overcomes this possible problem by assuring that the sleeve mechanism never applies a direct load to the retaining member for the collet mechanism. 
     SUMMARY OF THE INVENTION 
     The present invention provides an apparatus for cementing a liner string in a well bore. The apparatus comprises an operating string having a smaller diameter than the internal diameter of a liner string and which is insertable therein. Means connect the operating string within the internal diameter of the liner string and are operable by rotation of the operating string to release the operating string from the liner. A plug carrying body is connected to the lowermost extent of the operating string. A top plug is releasably supported from the plug carrying body and a longitudinally spaced bottom plug is releasably supported from the top plug. Pressure-releasable means secure the top plug to the plug carrying body, the bottom plug to the top plug, and retainer means on the bottom plug, respectively. Shifting means are provided for locking the top plug to the plug carrying body until the pressure-releasable means securing the bottom plug are released. Means for hydraulically balancing the pressure-releasable means are provided and secure the retainer means on the bottom plug. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1a is a cross-sectional view of the upper portion of a plug assembly of the type which is connected to an operating string for use in the present invention. 
     FIG. 1b is a downward continuation of the assembly of FIG. 1a. 
     FIG. 2a shows the upper portion of a liner with the operating string of the invention in place within the liner and a pump down plug preceding a column of cement. 
     FIG. 2b is a downward continuation of the operating string and liner of the invention showing the plug assembly attached to the operating string. 
     FIG. 2c a downward continuation of a liner of FIG. 2b showing the slips used to land the liner within the surrounding well casing. 
     FIG. 2d is a downward continuation of the liner of FIG. 2c showing the foot valve thereof. 
     FIG. 3a is a view similar to FIG. 2a showing the second pump down plug which follows the column of cement. 
     FIG. 3b is a view similar to FIG. 2b showing the plug assembly without the bottom plug. 
     FIG. 3c is a downward continuation of FIG. 3b. 
     FIG. 3d is s downward continuation of FIG. 3c showing the bottom plug and first pump down plug seated within the landing collar of the liner. 
     FIG. 4a shows the retrieval of the operating string from the cemented liner. 
     FIG. 4b is a downward continuation of FIG. 4a. 
     FIG. 4c is a downward continuation of FIG. 4b. 
     FIG. 4d is a downward continuation of FIG. 4c showing the top plug seated within the bottom plug at the conclusion of the cementing operation. 
     FIG. 4e is a downward continuation of FIG. 4d showing the first pump down plug having been sheared out from the bottom plug. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Referring to FIGS. 2a and 2b there is shown a liner string 11 disposed near the bottom of a well bore. The well bore can be lined by a casing string 13, which can extend to the surface of the well. An annular space 15 is formed between the liner string 11 and the surrounding well bore defined by the casing 13. 
     The liner string 11 includes a setting mechanism 17 (FIG. 2c), and a setting sleeve 19 joined by a coupling 20 to a setting sleeve extension 21 (FIG. 2a). At the lower end of the liner string 11 there is provided a standard landing collar 23 and a cementing shoe 25. 
     The liner setting mechanism 17 includes slips 27 and setting cones 29 by which the liner string is supported in the well bore. Such construction is well known in the industry and will not be described in detail here. The landing collar 23 is adapted to receive a liner wiper plug as will be more fully described. The cementing shoe 25 is provided with back pressure check valves 31, 33 which permit passage of cement from within the internal diameter 35 of the liner into the annular space 37 via the ports 39. 
     As shown in FIG. 2b, the liner string 11 is initially attached by means of a rotatably releasable connector 41 to the operating string 43 which extends to the well surface. The rotatable connector 41 comprises a left-handed threaded nut which engages course left-handed threads 42 on the interior of the longitudinal slots for engaging corresponding splines 45 on the setting tool 47. Thus, rotation of the operating string 43 and the associated setting tool 47 in the right-hand direction will cause the nut 41 to move upwardly on the splines 45 to eventually disengage the threads 42 and the setting sleeve 49, effectively releasing the setting tool from the liner string. Setting tools of the type described are known in the art and are shown, for instance, in U.S. Pat. No. 4,441,560, issued to Baugh et al, entitled &#34;SETTING TOOL&#34;, Apr. 10, 1984. 
     As shown in FIG. 2b, the lowermost extent 49 of the setting tool 47 has an internally threaded surface 51 for engaging a mating externally threaded surface of a plug carrying tubular body 53. The plug carrying body 53 forms the uppermost portion of the plug assembly used in the apparatus of the invention and shown in greater detail in FIGS. 1a and 1b. 
     As shown in FIG. 1a, the plug carrying body 53 include an upper extent 55 with an externally threaded portion 57 for engaging the running tool threads and an internal bore 59 which communicates with the bore of the setting tool 47 and, in turn, with the bore 61 of the operating string 43. The plug carrying body 53 is provided with an internal recess, such as annular groove 63, for receiving the lugs 65 of upwardly extending collet fingers 67. The collet fingers 67 are used to releasably secure a top plug 69 to the plug carrying body 53. The top plug 69 includes an upper body portion 71, a lower body portion 73, and an intermediate connecting portion 75. The body portions are connected by means of mating threaded surfaces 77, 79 and 81, respectively. The intermediate portion 75 and upper body portion 71 carry a circumferential sealing element 83 which is used to wipe the interior of the liner during cementing operations. The intermediate portion 75 also includes a lower extent 85 having a serrated external surface for later engagement with an internal landing profile 87 (FIG. 1a) provided in the upper body portion 89 of a bottom plug 91. The bottom plug 91 has an intermediate body portion 93, a lower body portion 95 and an associated sealing element 97 similar to the arrangement of the top plug 69. 
     As shown in FIGS. 1a and 1b, the bottom plug 91 has an internal recess, such as annular groove 99 for receiving the lugs 101 of downwardly extending collet finger 103. The collet fingers 103 depend from the lower body portion 73 of the top plug and provide a pressure releasable means for securing the bottom plug to the top plug. 
     The top plug 69 is mechanically locked to the plug carrying body 53 prior to the release of the bottom plug 91 by means of a longitudinally shiftable top sleeve 105. The top sleeve 105 has an upper extent 107 which abuts an internal shoulder 109 provided in the plug carrying body 53 and has a lower extent 111. The exterior surface 106 of the upper extent 107 initially underlies the lugs 65 of upwardly extending collet fingers 67 to lock the top plug 69 to the plug carrying body 53. The lower extent 111 is provided with a down plug, as will be described. The lower extent 111 of the top sleeve 105 includes a shoulder region 115 for contacting a mating shoulder 117 provided in the lower body portion 73 of the top plug 69. The top sleeve 105 is initially retained in the position shown in FIG. 1a by means of shear screws 119 and a snap ring 121. 
     The snap ring 121 has an external profile which mates with the shoulder 117 and is retained in the expanded position shown in FIG. 1a by contact with the upper extent 123 of a longitudinally shiftable bottom sleeve 125. The bottom sleeve 125 has a region of increased external diameter 127 which joins a region of decreased external diameter 129 to form an external shoulder 131. The region of increased diameter 127 initially underlies the lugs 101 of the bottom plug 91 to thereby releasably secure the bottom plug 91 to the top plug 69. An O-ring 133 carried in a groove on the bottom sleeve 125 seals within the bore 135 of the bottom plug 91. Similarly, O-rings 136 and 137 seal between the top plug and top sleeve 105 and O-ring 139 seals between the top sleeve 105 and plug carrying body 53. 
     The bottom sleeve 125 has a lowermost extent 141 provided with an external shoulder 143 which initially abuts a mating shoulder provided in the portion 145 of the bottom plug 91. The lowermost extent 141 also has an oppositely arranged external shoulder 147 which is adapted to engage the upper surface 149 of a collet finger 157 which extends from a collet extention 95 threadably secured to the body portion 93. A collet retainer ring 151 is located around the extension 153 of the collet extension 157. The retaining ring 151 is supported in the position shown by means of shear screws 155. The bottom sleeve 125 has a serrated interior surface 161 which is similar to surface 113 of the top sleeve 105 but of a smaller relative internal diameter. 
     The operation of the apparatus of the invention will now be described. FIGS. 1a and 2b show the device of the invention as it would appear at the initial stage of the cementing operations. The setting mechanism 17 has been actuated (FIG. 2c) so that the cones 29 cause the associated slips 27 to grip the surrounding casing 13 to anchor its liner into position. After the liner has been hung in the conventional manner, circulation is established by pumping circulating fluid through the operating string 43, through the setting tool 47, through the liner string 11, and through the shoe 25 into the annular space 37 surrounding the liner. 
     After circulation has been established, the setting tool 47 can be released from the liner string 11 by rotating the operating string in the right-hand direction to release the splined nut 41. The operating string is then typically lifted a few feet to insure that release has been effected. A first pump down plug 163 is then pumped behind the circulating fluid and in front of a properly measured amount of cement 165. The conventional pump down plug 163 is adapted to slide and seal within the bore 61 of the operating string 43. The pump down plug 163 includes a nose portion 167 with a frictional engagement surface thereon sized and adapted to engage the serrated interior surface 161 of the bottom sleeve 125 to latch the pump down plug within the bottom sleeve. A pump pressure increase of approximately 1,000 psi will then shear the first set of shear screws 169 which connect the bottom sleeve 125 to the top plug. The bottom sleeve 125 then moves downwardly until shoulder 147 contacts the upper surface 149 of the collet extension 157. In this position, it will be appreciated that the tool now is hydraulically balanced in that there is no load applied to any shear pin and particularly that there is no load on pin 155 since downward load on the sleeve 125 is carried on the upper surface 149 and, in turn, is transmitted to the lower body portion 95 which is secured to the intermediate body portion 93 and thence through the portion 145. This movement brings the region of decreased external diameter 129 beneath the collet lugs 101, thereby allowing the collet to collapse and release the bottom liner wiper plug 93. Bottom plug 91 then travels down the interior of the liner string until externally serrated surface 171 (FIG. 1b) latches within the internally serrated surface 173 (FIG. 2d) of the landing collar 23. FIG. 3d shows the bottom plug 93 and the associated first pump down plug 163 latched within the landing collar 23. As shown in FIG. 3b, the top plug 69 is still connected to the plug carrying body 53. 
     Another pump pressure increase of approximately 1,000 psi will now shear the second set of shear screws 155 which holds the retaining ring 151. This action causes the collet extension 157 to become disengaged from the ring 151 and allows the bottom sleeve 125 and first pump down plug 163 to be released and fall to the bottom of the liner, thereby allowing circulation of the cement through the bottom liner wiper plug 93, out the cementing ports 39 and into the annular space 37 as shown in FIG. 4e. 
     As shown in FIG. 3a, a second pump down plug 175 is now dropped and pumped behind the column of cement 165. The second pump down plug 175 is pumped down by circulating fluid until the serrated surface 177 on the nose region thereof engages the serrated interior surface 113 of the top sleeve 105 (FIG. 3b). A 1,000 psi pump increase will then shear the third set of shear screws (119 in FIG. 1a) to release the top sleeve 105. Top sleeve 105 moves downwardly until the shoulder 115 contacts the mating shoulder 117, displacing the snap ring 121 and allowing the collet lugs 65 to spring free of the groove 63 in the plug carrying body 53. The top liner wiper plug 69, top sleeve 105 and second pumped down plug 175 are then free to move down the liner string until the serrated surface (85 in FIG. 1a) of the top plug latches within the internal landing profile 87 provided in the bottom plug. FIG. 4d shows the second pump down plug 175 top sleeve 105 and top plug 69 latched within the landing profile of the bottom plug 91. 
     An invention has been provided with several advantages. The four plug cementing system of the invention completely isolates a column of cement from outside drilling mud and other contaminates. This is accomplished by having a plug both below and above the column of cement. The top liner wiper plug is positively locked to the plug carrying body of the setting tool until the bottom wiper plug has been sheared off the assembly. The positive lock provided by the longitudinally shiftable internal sleeve prevents premature shear of the top liner wiper plug. Both the top and bottom wiper plugs are positively locked to each other and to the setting tool until the pump down plugs land within their respective setas. As a result, premature shear of either the top or bottom wiper plugs is prevented during loading of the plug assembly at the well surface or during the release of the setting tool from the liner string during the first stages of the cement operation. It will also be seen that the device maintains complete pressure integrity in that there is no premature loading of any shear pin or shearing mechanism. 
     Although the invention has been described in terms of the specified embodiments which are 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.