US3414071A - Oriented perforate test and cement squeeze apparatus - Google Patents

Description

a D60 1968 J. B. ALBERTS 3,414,071,

ORIENTED PERFORATE TEST AND CEMENT SQUEEZE APPARATUS Filed Sept. 26, 1966 5 Sheets-Sheet 1 y V l2 ggi.Q 6 fig IL 18 4g J. B. ALBERTS 3,414,071

ORIENTED PERFORATE TEST AND CEMENT SQUEEZE APPARATUS Dec. 3, 1968 5 Sheets-Sheet 5 Filed Sept. 26, 1966 .km Q

United States Patent Oflice Patented Dec. 3, 1968 3,414,071 ORIENTED PERFORATE TEST AND CEMENT SQUEEZE APPARATUS Jack B. Alberts, Duncan, Okla, assignor to Halliburton Company, Duncan, Okla., a corporation of Delaware Filed Sept. 26, 1966, Ser. No. 581,827 11 Claims. (Cl. 1754.51)

ABSTRACT OF THE DISCLOSURE Method and apparatus for testing formations in a well bore. The apparatus includes a packer secured to the lower end of a tubing string. An opening in the Wall of the packer is provided between upper and lower packer elements which engage the wall of the well casing. The interior of the packer has an internal shoulder that forms a seat for perforating and cementing tools. A lug in the packer orients the tool rotationally with respect to the opening in the packer. The cementing tool has a cementing head connected with upper and lower portions of the tool by toggle links which project the head through the opening in the packer upon movement of the upper and lower portions of tool toward each other. The cementing tool includes an explosive device for displacing cement slurry from a chamber in the tool through the cementing ports in the cementing head.

This invention relates to well methods and apparatus, and more particularly to formation testing.

Various methods have been developed for evaluating formation productivity. One technique is known as formation or drill stem testing, in which a temporary completion of the well is carried out in order to obtain a sample of fluid from the formation. Actual production conditions are simulated in the test to determine whether oil may be produced from the formation. If the formation testing is to be carried out in a cased well, it is necessary to perforate the casing and the cement that is between the casing and the bore hole wall.

Various testing tools have been utilized in which a sample of formation fluid is collected in the tool and subsequently raised to the surface. Often the small capacity of the tool storage chamber does not allow asufiiciently large sample to be collected and thus the results of the test may be improperly evaluated.

Often there may be several formation zones in a well that appear to have favorable production characteristics as determined by logging, core analysis, or other evaluation techniques. When a series of tests is to be run at various depths in a casing, it is necessary to seal the perforations made during the previous test before proceeding with testing at other depths in the well. One method for sequential testing is to cement the packers isolating the formation zone permanently in the well casing, after each test has been completed. This procedure necessarily limits the size of the production tubing which can be run inside the packer mandrel.

Accordingly, it is an object of this invention to provide a test apparatus which yields a sufficiently large sample for reliable evaluation.

It is a further object of this invention to provide an apparatus for testing formation zones at a plurality of depths, without restricting subsequent well operations.

It is a further object of this invention to provide a test apparatus which may be conveniently assembled and operated in the field.

These objects are accomplished in accordance with a preferred embodiment of the invention by utilizing a packer with a hollow mandrel that is run in the casing on a tubing string. Resilient sleeves are spaced axially on the packer mandrel to isolate an annular space between the casing wall and the packer mandrel. An opening in the packer mandrel communicates with this isolated annular space. A perforating tool is run on a Wire line inside the tubing string until it is seated in the packer. A cam aligns the perforating tool with the opening in the packer mandrel in such a way that when the explosive charges in the tool are detonated, the casing and the cement behind the casing are perforated opposite the opening in the mandrel.

After perforating, the tool is removed from the packer and production testing is carried out through the packer and the tubing string. At the completion of the test, a cementing tool is run on a wire line inside the tubing string to seal off the perforations. The cementing tool is seated in the packer mandrel and a cam aligns the tool with the opening in the mandrel. An articulated cementing head on the tool is then displaced outwardly through the mandrel opening to engage the casing around the perforations. The cementing head has cementing ports that are aligned with the perforations and cement slurry is conducted from a storage chamber in the tool to the ports from which it is squeezed into the perforations. The mandrel and the cementing tool cooperate to position the cementing head at the same depth with respect to the mandrel, as the perforating charges are positioned. The cam arrangement also provides for rotational alignment of the cementing head with the position of the perforating charges. Thus, the ports in the cementing head are aligned with the perforations in the casing. The cementing tool confines the cement to the perforation and thus the cement does not interfere with the movements of the packer or other tools through the casing after the cementing operation. Also, only a small quantity of cement is required.

This preferred embodiment is illustated in the accompanying drawings in which:

FIG. 1 is a cross-sectional view of the packer of this invention, with the perforating tool mounted therein;

FIG. 1A is a detail view of the drag spring sleeve J-slot;

FIG. 2 is a side elevational view of the packer and perforating gun along the line 2-2 in FIG. 1;

FIG. 3 is a cross-sectional view of the lower end of the perforating tool and packer along the line 3-3 in FIG. 1;

FIG. 3A is a cross-sectional view of the perforating tool and packer along the line 3A3A in FIG. 3;

FIG. 4A is a cross-sectional view of the packer and perforating tool showing the latch assembly with the latch spring in latched position;

FIG. 4B is a cross-sectional view of the packer and the perforating tool, showing the latch assembly with the latch spring in unlatched position;

FIG. 5 is an enlarged cross-sectional view of the perforating tool along the line 5-5 in FIG. 1; 7

FIG. 6 is an enlarged cross-sectional view of the intermediate portion of the perforating tool and the packer mandrel, prior to detonating the perforating charges;

FIG. 7A is a cross-sectional view of the lower portion of the packer with the cementing tool mounted in the packer prior to displacement of the cementing head into engagement with the casing;

FIG. 7B is a cross-sectional View of the casting and tubing string and the upper portion of the cementing tool;

FIG. 8A is an enlarged cross-sectional view of the intermediate portion of the packer mandrel and the cementing tool with the cementing head displaced against the casing; and

FIG. 8B is a cross-sectional view of the upper portion of the cementing tool and the packer mandrel.

Referring to FIG. 1, acasing 2 is run in a bore hole 4 andcement 6 has been placed in the annular space between thecasing 2 and bore hole 4. A packer 8 is threadedly secured to the lower end of a string oftubing 10. The packer includes alatch collar 12 which is internally threaded at one end to receive the lower end of thetubing 10. The opposite end of thelatch collar 12 is threadedly secured to amandrel 14. A pair of swabbingcups 16 are mounted on the outside of themandrel 14 and are held in place between asleeve 18 and ashoulder 20 on the mandrel. The swabbing cups 16 are formed of a resilient material which engages thecasing 2 and prevents the flow of fluid axially through the annular space between themandrel 14 and the casing.

The intermediate portion of themandrel 14 has aradial opening 22 through the wall of the mandrel. As shown in FIG. 2, theopening 22 is in the form of an elongated slot. Below theopening 22, another pair of swabbing cups 24 is mounted on the exterior of themandrel 14. The swabbing cups are clamped between ashoulder 26 on the mandrel and the end of asleeve 28 on the mandrel. The swabbing cups 24 are similar to thecups 16 and seal against fluid flow between themandrel 14 and thecasing 2. Thus, thecups 16 and 24 isolate the annular space between them from fluid communication with the interior of thecasing 2 above and below thecups 16 and 24, respectively.

Aguide shoe 30 is threadedly secured to the lower end of themandrel 14. Theshoe 30 has adrag spring sleeve 32 mounted for sliding movement On the exterior surface of the shoe. Thesleeve 32 includes a plurality ofslips 34 which are attached to the sleeve bylongitudinal straps 36. Adrag spring 38 overlies each of thestraps 36 for urging theslips 34 against theshoe 30 and resisting movement of the slips relative to thecasing 2. Theshoe 30 has a taperedsurface 40 under theslips 34, so that downward displacement of the shoe relative to the slips causes the slips to be displaced outwardly against the casing.

Movement of thesleeve 32 relative to theshoe 30 is controlled by a J-slot in a conventional manner. Thesleeve 32 has a pin or lug 42 which projects into the J-slot 44 in the outer surface of theshoe 30. The I-slot is shown schematically in FIG. 1A. While themandrel 14 is being lowered through the casing, thepin 42 is in the position shown in full lines in FIG. 1A and thus theslips 34 remain in the position shown in FIG. 1, although the drag springs 38 engage thecasing 2. When the desired depth is reached, thepin 42 is displaced from the short leg of the J-slot 44 by lifting up on thetubing string 10 and rotating the tubing string clockwise. This moves thepin 42 into the long leg of the J-slot 44, thus allowing thesleeve 32 to slide longitudinally along theshoe 30, and thereby causing theslips 34 to be displaced outwardly against the casing by the taperedsurface 40. By setting down the weight of the tubing on theslips 34, the slips are tightly wedged against the casing and themandrel 14 is secured against downward movement relative to the casing. The approximate position of thepin 42 when the slips are set is shown in dotted lines in FIG. 1A. Theslips 34 may be retracted by picking up on the tubing string. In order to move the mandrel downward, it is necessary to rotate the tubing string in a counterclockwise direction after lifting the mandrel to return thepin 42 to the position shown in full lines in FIG. 1A.

Theshoe 30 has acentral passage 46 which is closed at its lower end by a threadedplug 48 to form a receptacle. Thepassage 46 includes a tapered shoulder 50 (FIG. 3) which forms a seat for aring 52. Thering 52 has a plurality of longitudinally extendingribs 54. In the embodiment shown in FIG. 3A, there are four ribs arranged 90 apart around the circumference of the ring, and the longitudinal edge of each rib is spaced from the center of the ring. The upwardly facing ends of theribs 54 slope toward the center of the ring, as shown in FIGS. 1 and 3. Between the lower end of themandrel 14 and thering 52, asleeve 56 having a plurality of inwardly projectingspring portions 58 is provided for deflecting tools toward the central axis of thesleeve 56. Theribs 54 permit sand or other solid matter which may enter the mandrel through theopening 22 to pass between theribs 54 and into thepassage 46 below thering 52.

The packer 8 is adapted to receive either a perforatingtool 60, as shown in FIG. 1, or acementing tool 62, as shown in FIGS. 7A and 7B. Both the perforatingtool 60 and thecementing tool 62 are suspended by substantially identical connectors to the end of a wire line 64 (FIG. 7B). Thewire line 64 is secured to aconnector body 66 and a pair ofbars 68 extends between theconnector body 66 and a latch spring sleeve 70 (FIG. 7A). The connector body supporting the perforating tool is attached to a similarlatch spring sleeve 72 on the perforating tool by a pair ofbars 74, as shown in FIG. 1. Thesleeve 72 is mounted on aguide 76. Theguide 76 has grooves on opposite sides for receiving thebars 74, as shown in FIG. 5. Since the wire line is connected with thesleeve 72 by thebars 74, the weight of the tool causes theguide 76 to move downwardly relative to thesleeve 72.

As shown in FIG. 4B, thesleeve 72 is retained on theguide 76 by ashoulder 78. Alatch spring assembly 80 is positioned between thesleeve 72 and the surface of theguide 76. Thespring assembly 80 is secured at its base to theguide 76 and includes a plurality ofelongated spring elements 82 which are biased outwardly toward the position shown in FIG. 4A. When thesleeve 72 is displaced upwardly, however, as shown in FIG. 4B, thespring elements 82 are displaced inwardly by the sleeve and lie against thetube 76. Thesleeve 72 is provided withopenings 84 in alignment with theelements 82 to permit the spring elements to swing outwardly when the sleeve is displaced downwardly. Downward travel of the sleeve is limited by ashoulder 86 on atubular portion 88 of the perforating tool.

Thecollar 12 on the packer 8 includes an outwardly taperinginterior portion 90 and a downwardly facingshoulder 92 against which the ends of theelements 82 may abut when the elements are displaced outwardly to the position shown in FIG. 4A. Thespring elements 82 prevent upward movement of thetool 60 relative to the packer 8, when theelements 82 are in engagement with theshoulder 92.

The remainder of thetool 60 includes atubular portion 94 and ashaft portion 96. Theportions 88, 94 and 96 are rigidly secured together by screw threads. Theshaft portion 96 includes an axial cam 93 (FIG. 3) which cooperates with a lug projecting inwardly from the interior wall of thepacker mandrel 14. Thecam 98 includes alongitudinal groove portion 102. When the perforatingtool 60 is lowered into the packer 8, the cam, '98 strikes thelug 100 and applies a torque to the perforating tool as it is being lowered to direct thelug 100 into thegroove 102. Thus, the lug and the groove cooperate to orient the perforating tool in a predetermined rotational relation with respect to thepacker mandrel 14.

The lower end of theshaft 96 has a bluntedpoint 104 which rests on theribs 54 of thering 52. Thelug 100 does not engage the closed end of thegroove 102 when the point rests on theribs 54 and therefore the axial position of the perforating tool is determined by the engagement of thepoint 104 with theribs 54, rather than by thelug 100. Furthermore, the distance between thepoint 104 and theelements 82 corresponds to the distance between theribs 54 and theshoulder 92. Accordingly, when thepoint 104 engages theribs 54, the free ends of thespring elements 82 are in position to engage theshoulder 92, when thespring sleeve 72 is displaced downwardly, as shown in FIG. 4A.

Referring to FIG. 6, thetubular portion 94 includes a pair ofexplosive charges 106 which are aligned withopenings 108 in thetubular portion 94. Theopenings 108 are temporarily sealed bycaps 110. Theexplosive charges 106 may be of the conventional projectile type that is ordinarily used for perforating well casings. Thecharges 106 are rigidly mounted in a frame 112, so that they are not displaced out of position while the perforating tool is being lowered through the production tubing. The explosive charges are detonated by electric filaments and current is supplied to the filaments bylead wires 114 and 116. The lead wires are connected in circuit with a switch at the surface of the ground for detonating thecharges 106 at the .appropriate time.

The cementingtool 62 is shown in FIGS. 7A, 7B, 8A and 8B. Thesleeve 70 that is suspended by thebars 68 from thewire line connector 66 is mounted on atube 118. Alatch spring assembly 120 similar to theassembly 80 on the perforating tool is mounted on thetube 118 and it includesspring elements 122 corresponding to thespring elements 82. Thetube 118 includes shoulders corresponding to theshoulders 78 and 86 (FIG. 4B) for limiting the upward and downward movement, respectively, of thesleeve 70 relative to thetube 118.

Acartridge 124 containing a slow burning power type charge is mounted at the upper end of thetube 118, as shown in FIG. 8B. Electric current for igniting the cartridge is supplied through alead wire 125. The cartridge is clamped between ashoulder 126 in atubular extension 128 and ashoulder 130 in thetube 118. Afree piston 132 is mounted in the bore of thetube 118 and has a plurality of sealing rings 133. Spaced axially downward from thepiston 132 is aplug 134. Thepiston 132 and theplug 134 cooperate with the bore of thetube 118 to form a fluid chamber. Asecond plug 136 is mounted in thetube 118 to form a cement slurry chamber between theplug 134 and theplug 136.

Asleeve 138 is threadedly secured to the lower end of thetube 118 and amandrel 140 extends through thesleeve 138 in telescoping relation, as shown in FIGS. 8A and BB. Thesleeve 138 has a plurality ofelongated slots 142 and jar pins 144 which are secured in themandrel 140 extend outwardly through theslots 142. Theslots 142 permit limited axial movement of thesleeve 138 relative to themandrel 140. The sleeve 13-8 is biased upwardly relative to themandrel 140 by aspring 146 which is compressed between oipposed shoulders on the sleeve and mandrel.

A cementing head 148 is mounted in thecementing tool 62 below themandrel 140. A pair oftoggle links 150 connect the cementing head 148 with themandrel 140. One end of eachlink 150 is hingedly mounted on a pin projecting outwardly from themandrel 140 and thelinks 150 extend in parallel relation on opposite sides of the cementing head 148. Another pair ofparallel toggle links 154 are pivotally mounted on a bearing at the top of theshaft 156 which corresponds to theshaft 96 on the perforatingtool 60, .as shown in FIG. 1. The lower end of eachlink 154 is pivotally mounted on apin 158 at the top of theshaft 156. The opposite end of eachlink 154 is supported on apin 160 projecting outwardly on opposite sides of the cementing head 148. Thepin 160 also supports the ends of thelinks 154 in overlapping relation, as shown in FIG. 8A. The cementing head 148 is biased radially outward by aleaf spring 162 which is secured at one end in themandrel 140 and at the opposite end in theshaft 156. The cementing head, the toggle links, and the spring .are enclosed in a flexibletubular cover 166.

The cementing head 1'48 includes a pair ofports 168 which are spaced apart approximately the same distance as theexplosive charges 106 in the perforatingtool 60.Wide flanges 170 are provided .around thebores 168 to form a seat which bears against theperforated casing 2, as shown in FIG. 8A. Aconduit 172 in the cementing head 148 communicates with thebores 168. Aflexible hose 174 is attached at one end to the cementing head in fluid communication with theconduit 172 and at the opposite end the hose communicates with apassage 176 in themandrel 140.

Theshaft 156 on the lower end of the cementingtool 62 is substantially the same as theshaft 96 on the perforatingtool 60. Theshaft 156 includes a blunt point 104' and acam 98 which correspond to thepoint 104 andcam 98, respectively, of thetool 60.

In operation, the packer 8 is made up on the end of a string of production tubing and run in thecasing 2 to the depth of the lowest proposed test formation. The tubing string is rotated to cause thepin 42 in the drag spring sleeve 32 (FIG. 1) to move into the long portion of the J-slot 44. The drag springs 38 engage thecasing 2 .and resist movement of thesleeve 32 relative to thecasing 2. Lowering the tubing string then causes theslips 34 to be displaced outwardly by the taperedsurface 40 until they grip the casing. In this manner, theslips 34 secure themandrel 14 against downward movement relative to the casing. Surface slips may then be applied to the tubing string to take up the remaining tubing weight.

The perforatingtool 60 is then attached to the end of the wire line by means of theconnector 66 and lowered through the production tubing until it reaches themandrel 14. The weight of the tool causes thesleeve 72 to be raised relative to thetube 76 and therefore thespring elements 82 are retracted against the surface of thetube 76, as shown in FIG. 4B. When thepoint 104 at the bottom of the perforating tool has come to rest on theribs 54 of thering 52, the perforating tool is at the desired depth relative to themandrel 14. The lug cooperates with thecam 98 to turn the perforating tool, if necessary, to align theexplosive charges 106 with theopening 22, as shown in FIG. 2. When the wire line is lowered further, the downward movement of thebars 74 permits thesleeve 72 to move downward relative to thetube 76, thus exposing thespring elements 82, which swings outwardly to engage theshoulder 92. Thus, the perforating tool is rigidly secured in the mandrel and cannot move either upwardly or downwardly relative to the mandrel. The latching of thespring elements 82 can be perceived at the surface. The perforating charges 60 are then fired by electric current conducted through theconduits 114 and 116 to perforate the casing directly opposite theopening 22.

After the casing has been perforated, an upward pull is applied to the wire line to draw thesleeve 72 over thespring elements 82 and thus retract them into the position shown in FIG. 4B. Further upward movement of the wire line raises the perforating tool to the surface. Fluid flows from the formation through the perforations into the interior of the mandrel and upwardly through the production tubing to the surface. If desired, an acid wash may be made to clear drilling mud from the test perforations. After a predetermined interval, the well is shut in.

The cementingtool 62 is then filled by unscrewing thetubular extension 128 from thetube 118. Thecartridge 124, theplug 134, and thepiston 132 are removed. A slurry of quick setting cement of sufficient volume to fill the perforations is poured into thetube 118. Thelower plug 136 prevents the slurry from passing into theman drel 140. Theplug 134 is then inserted in the open end of thetube 118 and water is poured on top of theplug 134, after which thepiston 132 is inserted to confine the water in the chamber between the piston and theplug 134. Theexplosive cartridge 124 is then inserted in the end of thetube 118 and thetubular extension 128 is screwed into place.

The cementing tool is lowered on the end of thewire line 64. As the tool passes into the packer 8, theleaf spring 162 urges the cementing head 148 outwardly. As the head 148 approaches the depth of theopening 22, thelug 100 engages thecam 98 to rotate the pool, if necessary, until the head is aligned with theopening 22. Thespring 162 then displaces opening 22 and the pointed end 104' of theshaft 156 engages theribs 54. The mandrel continues to move downward until the flanges on the cementing head engage thecasing 2. Thesleeve 70 slides downwardly relative to thetube 118 to allow thespring elements 122 to engage theshoulder 92.

When the tool is latched by thespring elements 122, current is supplied through theconduit 125 to the car- 7tridge 124. Ignition of the cartridge drives thepiston 132 downwardly and the pressure transmitted through the water in the chamber through theplug 134, and through the cement slurry breaks theplug 136. Fluid pressure behind theplug 134 moves theplug 134 downwardly to displace the cement slurry into thepassage 176. The cement slurry passes through thepassage 176 and through thehose 174 to the cementing head 148, where it is displaced outwardly through thebores 168 into the perforations in thecasing 2. The plug 1334 continues to move downward until theplug 134 seats on theplug 136, The pressure transmitted through the water chamber breaks theplug 134 and displaces the water down thepassage 176 directly behind the cement slurry. The water follows the cement through thepassage 176 and thetube 174. Preferably, the cement is confined in the perforations in thecasing 2 and penetrates only a short distance into thecement 6 behind the casing. Thus, only a small amount of cement slurry is used. Thepiston 132 continues to move downward due to the fluid pressure behind the piston, until the piston seats on theplugs 134 and 136. The pressure behind the piston then serves to hold the cementing head 148 against the casing.

After a sufiicient interval of time to allow the cement to set, the tool is unlatched by rasing the wire line and thus retracting thespring elements 122. At the same time that the spring elements are unlatched, the gas pressure in the interior of thetube 118 displaces thesleeve 138 upwardly relative to themandrel 140 and the jar lugs 144 engage the top of theslots 142 to jar the cementing head 148 loose from the cement in the casing perforations. Thus, the tool does not hang against the casing wall. The cementingtool 62 may then be raised through the production tubing. If desired, the tubing may be swabbed dry to pressure test the perforation cementing.

The packer 8 may be removed or raised to another zone by raising thetubing 10, and thus retracting theslips 34 along the tapered portion of theshoe 30. When the packer has been raised to a second zone, the tubing string may be lowered again to set theslips 34 and the procedure may be repeated for perforating, testing and cementin g at the second zone.

If more than one zone is tested, the wire line tools may be reloaded at the site, while the other stages of the test are being carried out. Furthermore, the production test through the packer 8 may be carried out for an extended length of time and the perforations may be cemented long after the completion of the test. Since the cement is placed directly in the perforations, large quantities of cement are not required. Therefore, cementing equipment that is required for cementing off perforated zones in the conventional manner after the test is eliminated.

While this invention has been illustrated and described in one embodiment, it is recognized that variations and changes may be made therein without departing from the invention as set forth in the claims.

I claim.

1. Apparatus for testing formations in a well comprismg a packer, means for securing the packer in a tubing string, said packer including a hollow mandrel having a closed end and packer elements on said mandrel, said mandrel having a radial opening therein between said packer elements, means in said mandrel forming a seat,

an elongated tool adapted to be inserted in said mandrel, said tool having a transverse locating surface thereon in position to engage said seat means upon insertion of said tool axially into said packer mandrel, a reference point on said tool being spaced axially from said tool locating surface approximately the same distance as said mandrel opening is spaced from said seat means,

means in said mandrel forming a receptacle adjacent said mandrel seat, said receptacle extending axially of said mandrel away from said seat means, said seat means being positioned between said receptacle and said mandrel opening, said seat means including a plurality of ribs projecting toward the center of said mandrel, and

means for selectively latching said tool in said mandrel against movement away from said seat means, whereby said packer accurately locates said tool reference point with respect to said mandrel openmg.

2. Apparatus for testing formations according to claim 1 wherein said ribs are below said mandrel opening, said tool including a perforating charge directed radially of said tool, said charge being located at said tool reference point.

3. Apparatus for testing formations according to claim 1, said latching means including downwardly facing shoulder means on said mandrel, latch elements on said tool, said latch elements being movable into position to engage said shoulder means to resist upward movement of said tool relative to said mandrel, and means on said tool for selectively disengaging said elements from said shoulder means, whereby said ribs and said shoulder means cooperate to locate the tool reference point at a predetermined axial position in said mandrel.

4. Apparatus for testing formations in a well comprisa packer, means for securing the packer in a tubing string, said packer including a mandrel and packer elements on said mandrel, said mandrel having a radial opening therein between said packer elements means in said mandrel forming a seat,

an elongated tool adapted to be inserted in said mandrel, said tool having a transverse locating surface thereon in position to engage said seat means upon insertion of asid tool axially into said packer mandrel, a cementing head on said tool being spaced axially from said tool locating surface approximately the same distance as said mandrel opening is spaced from said seat means,

means for selectively latching said tool against movement away from said seat means, means for rotationally orienting said tool cementing head with respect to said mandrel opening, said packer mandrel seat means including a plurality of ribs projecting toward the center of said mandrel,

said ribs being below said mandrel opening, said cementing head having mounting means including toggle links projecting upwardly and downwardly from said head, said toggle links interconnecting upper and lower portions of said tool and being arranged to displace said head radially of said tool upon movement of said upper and lower portions toward each other, whereby said ribs resist downward movement of the lower portion of said tool while said upper portion moves downwardly to displace said head outwardly through said opening.

5. Apparatus for testing formations according to claim 4 wherein said cementing head has a cementing port therein.

6. A cementing tool comprising an elongated body including an upper portion and a lower portion, said upper portion including a tube and a mandrel, said tube and mandrel being mounted in telescoping relation, means on said tube for temporarily engaging an adjacent body, means for limiting relative axial movement in one direction of said tube and mandrel,

a cementing head, a pair of toggle links, said links conmeeting said cementing head with said upper and lower portions, said toggle links being arranged to displace said head radially outward from said body upon relative axial displacement of said upper portion toward said lower portion, said limiting means including opposed abutments between said tube and said mandrel, said relative axial displacement of said upper portion being in a direction opposite to said one direction,

said cementing head having a cementing port therein, and means for selectively conducting cement slurry to said port, and means on said tube responsive to fluid pressure in said conducting means for displacing said tube in said one direction whereby releasing said body engaging means displaces said tube in said one direction relative to said mandrel in response to fluid pressure in said conducting means and engagement of said opposed abutments provides a jar for separating said cementing head from a cas- 7. A cementing tool comprising an elongated body including an upper portion and a lower portion,

a cementing head, means mounting said head in said body, said mounting means including means for displacing said head radially outward from said body upon relative axial displacement of said upper and lower portions,

said cementing head having a cementing port therein, and means for selectively conducting cement slurry to said port,

said conducting means including a fluid chamber in said body for containing cement slurry, an explosive device in a cavity in said body in pressure communication with said chamber, said chamber being between said device and said port, and means for conducting cement from said chamber to said port, whereby cement may be injected into casing perforations upon detonation of said explosive device.

8. The cementing tool according to claim 7 including a piston between said device cavity and said chamber for displacing fluid from said chamber.

9. The cementing tool according to claim 8 wherein said body includes a tube and a mandrel, said fluid chamber being in said tube, said tube and mandrel being mounted in telescoping relation, means on said tube for temporarily engaging an adjacent body, and means for limiting relative axial movement of said tube and mandrel, said mandrel having means for limiting displacement of said piston away from said device, said tube being urged in an opposite direction from said piston displacement in response to fluid pressure in said cavity, whereby a jar is provided when said engaging means is released while a fluid pressure is present in the cavity.

10. The cementing tool according to claim 9 wherein said head displacing means includes toggle links connecting said cementing head with said upper and lower portions, said toggle links being arranged to displace said head radially outward from said body upon axial displacement of said portions toward each other, said mandrel being secured to one of said links, whereby a jar is applied to said cementing head.

11. The cementing tool according to claim 8 wherein said body includes a tube and a mandrel mounted in telescoping relation, said head displacing means including toggle links connecting said cementing head with said upper and lower portions, said toggle links being arranged to displace said head radially outward from said body upon axial displacement of said portions toward each other, said fluid chamber being in said tube, means on said tube for temporarily engaging an adjacent body, said mandrel having means forming a seat limiting displacement of said piston away from said device, said tube having a pressure responsive surface urging said tube in an opposite direction from said piston displacement in response to fluid pressure in said cavity, said mandrel being secured to one of said links, whereby gas pressure in said cavity urges said cementing head against said casing perforations when said piston is in engagement with said mandrel seat means.

References Cited UNITED STATES PATENTS 3,361,204 1/1968 Howard et a1. 166-35 2,262,655 11/1941 Scale 166-100 2,301,624 11/1942 Holt 166-100 2,500,754 3/1950 Huber 175-451 2,526,695 10/1950 Schlumberger 166-100 X 2,652,000 9/1953 Woolsey 166-136 X 2,662,601 12/1953 Bagnell 166-136 2,872,983 2/1959 Renouf 166-154 X 2,915,123 12/1959 Lebourg 166-100 X 3,032,108 5/1962 Bielstein 175-452 3,153,449 10/1964 Lebourg 166-63 X 3,182,726 5/1965 Stone 166-186 X CHARLES E. OCONNELL, Primary Examiner.

I. A. CALVERT, Assistant Examiner.

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