NO173836B - BROENNVERKTOEY - Google Patents

Abstract

Well tool for inserting and placing a safety valve (S) in the well, including a locking mandrel (M) for releasably locking the valve (S) at a single end nipple (160) in a wellbore and an insertion tool (R) for inserting and placing the locking mandrel (M). The locking mandrel (M) comprises a body with a locking ring (^ 5), locking lugs (32) on the body and an embodiment sleeve (33) which is movable upwards in the body for making and locking the locking lugs (32). The insertion tool includes a tubular core (135) having an end that can be engaged with the control valve (151) of the safety valve (S) and an upper locking wedge device (102) for engaging the housing of the locking mandrel (M) to connect the insertion tool (R) to the locking mandrel. (M), a lower collet device (132) for operating the lead sleeve (33) in the locking mandrel (M) for making the locking lugs (32) and a head (8) for connecting the insertion tool (R) to a line tool string. The insertion tool (R) has a locking device which exerts a force from a spring in the safety valve (S) on the locking wedges (102) to lock the insertion tool (R) to the locking mandrel (M). Safety valve is connected to the locking mandrel (M) which is connected to the insertion tool (R). The whole thing is lowered into a well to a landing nipple. A control fluid pressure applied to the safety valve (S) relieves the spring force from the core of the mi-insertion tool (R) and the insertion tool (R) is pulled upwards, whereby the locking door lugs (102) are removed and the insertion tool (R) is released from the locking door (M) .31-

Description

The present invention relates to an insertion tool for placing and locking a connected locking mandrel and well tool in a landing nipple in a well flow pipe, which locking mandrel is of the type that includes a body with side windows, an internal annular recess, a carrying shoulder for supporting the locking mandrel in a landing nipple stopper, a radially movable locking cam in each of the side windows, an annular sealing device around the body for sealing between this and a sealing surface in the landing nipple, an ejection sleeve in the body, slidable within the locking cams in a direction opposite to the direction of movement of the locking mandrel into the landing nipple for ejection and retraction of the locking lugs, an internal annular recess or cam surface in the output sleeve for maneuvering the same, as well as means for coupling to the well tool, which insertion tool includes a head device for coupling to a working tool string, an upper insertion sleeve, a tubular core which is ano arranged in the upper insertion sleeve and is limited axially movable in relation to this, a probe which is attached to the core and extends downwards to abut against the well tool's operating pipe, devices for releasable coupling to the locking mandrel's annular recess, and devices for engagement with the output sleeve's internal cam surface for maneuvering the output sleeve.

An insertion tool of this type is known from US patent 4161984. US patent 3670821 represents a further example of the state of the art.

In the well area, and particularly in relation to oil and gas wells, it is common practice to complete the wells using equipment hanging from lines and the use of methods that ensure significant cost reductions in future inspections of the well. Procedures and equipment for completion where liners are used are shown and described in detail in PETROLEUM ENGINEER INTERNATIONAL from August 1981 on pages 83-89. The now available locking dowels for underwater safety valves are of the extension hanger type, which can create a number of work problems when used together with safety valves. Extension hanger locks are set or activated with an insertion tool by applying force in the same downward direction as required to drive the safety valve into a landing nipple to which the valve is to be locked. The friction created by the seal between the safety valve and the landing nipple can require such a high downward force that the locking mandrel is set prematurely. Furthermore, it is possible for the locking mandrel to only partially engage a recess in the tool to which it is to be connected, to then build up control line pressure and then remove the insertion tool used to insert the mandrel, without any serious problem being indicated. One solution that has been used is a spring isolator device which eliminates the main problems but can still fail. A locking sleeve in the extension hanger lock must move in an opposite direction to the flow to lock the safety valve. Thus, it will be possible for this current to lift the locking sleeve, which in turn releases the lock.

One purpose of the present invention is to arrive at a new and improved introduction tool of the type mentioned at the outset.

An important purpose of the invention is to arrive at a new and improved insertion tool for a locking mandrel in well flow pipe for releasably locking devices, e.g. safety valves, to a landing nipple in the flow pipe, and which can be operated with line equipment.

The previously known insertion tools have used a shear pin to connect the insertion tool to the locking mandrel. It is desirable to avoid the use of cutting pins as the insertion tool could malfunction if the cutting pin or pins are cut off accidentally or at the wrong time and the locking mandrel cannot therefore be placed correctly in the landing nipple.

Furthermore, it has been desirable to come up with an insertion tool that is inserted with a force that is exerted in a direction opposite to the direction of force required to drive down the device, e.g. a safety valve which is connected to the locking mandrel, into the landing nipple into which the locking mandrel is inserted.

It has been desirable to arrive at an insertion tool which can drive the locking mandrel downwards with unlimited force without the possibility of the lock being set too early.

It has also been an aim of the invention to arrive at an introduction tool where release from the locking mandrel can only take place after the safety valve, which is connected to the locking mandrel, has been properly inserted into the landing nipple.

A further purpose of the invention is to arrive at an insertion tool which is such that a continuous control line for the locking mandrel and the safety valve is created before the tool can be released from the locking mandrel.

This is achieved according to the invention with an insertion tool of the kind mentioned at the outset, which is characterized by the fact that the devices for releasable connection to the locking mandrel's annular recess include an upper locking wedge device, comprising a wedge holder sleeve with windows and locking wedges which are arranged concentrically around the upper insertion sleeve and are secured to the core for movement therewith relative to the lead-in sleeve, that the means for engagement with the inner cam surface includes a lower lead-in sleeve attached to the upper lead-in sleeve and having clamping fingers with finger heads which can spring inwardly and outwardly, and that one annular recess is provided on the outside of the upper insertion sleeve and another annular recess are provided on the outside of the core, which sleeve recess and core recess are adapted to cooperate with the locking wedges and fingers respectively for releasing the insertion tool from the locking mandrel when the insertion sleeve and the sleeve are raised to align te the recess, the wedge heads and finger heads are combed into the core of the recess.

The invention will be explained in more detail in the following with reference to the drawings in which: Fig. 1 shows partly a longitudinal section and partly an elevation of the locking mandrel according to the invention; fig. 2 shows a longitudinal section through a wedge holder sleeve on the locking mandrel; fig. 3 shows a section taken along the line 3-3 in fig. 2; fig. 4 shows a longitudinal section through one of the locking sources on the locking mandrel in fig. 1; fig. 5 shows the wedge in fig. 4 seen from the outside; fig. 6 shows the wedge in fig. 4 sets from inside; fig. 7 shows the bottom of the holding wedge in fig. 6; fig. 8A and 8B together show partly a longitudinal section and partly an elevation of an insertion tool according to the invention; fig. 9 shows a section along the line 9-9 in fig. 8B; fig. 10 shows the retaining sleeve for locking lugs in the insertion tool seen from the side; fig. 11 shows a longitudinal section through the sleeve in fig. 10; fig. 12 shows a section through the sleeve taken along the line 12-12 in fig. 11; fig. 13 shows one of the retaining lugs on the insertion tool seen from the outside; fig. 14 shows a longitudinal section through the cam in fig. 13; fig. 15 shows the retaining cam in fig. 13 interior view; fig. 16 shows the retaining cam in fig. 14 seen from the female; fig. 17A and 17B together show partly a longitudinal section and partly an elevation of the insertion tool connected to the locking mandrel according to the invention, while this is connected to the upper end of a safety valve for the well, the safety valve being inserted therein; fig. 18A and 18B show together the insertion tool and locking mandrel seen partly in elevation and partly in section, with the tool and mandrel connected to the upper end of a safety valve for a well, and a broken piece of the landing nipple in section, where the safety valve and locking mandrel are inserted; and fig. 19A and 19B together show the insertion tool, locking mandrel and the upper end part of a safety valve in a landing nipple seen partly in elevation and partly in section, where the locking lugs of the locking mandrel are led out into locking recesses in the landing nipple. As shown in fig. 1, a locking mandrel M comprises a tubular body formed by a holding sleeve 30 for locking cams and a sealing mandrel 31, as well as radially movable locking cams 32, an output sleeve 33 for the locking cams and a sealing device 34. The cams 32 are radially movable in windows 35 which are found in the holding sleeve 30. The output sleeve 33 is moved inside the locking lugs between the upper locking position shown in fig. 1 and a lower position where the cams are released.

As shown in Figures 2 and 3, the retaining sleeve 30 for the locking lugs has an internal annular locking recess 40 with an upper end locking surface 41 for receiving locking wedges on the insertion tool according to the invention when this is used to insert the locking mandrel and the safety valve in the locking nipple. The sleeve 30 has a series of pin holes 41' which are spaced from each other in the circumferential direction for attaching the locking mandrel to an insertion tool. The windows 35 in the sleeve 30 are spaced from each other in the circumferential direction and each window is sized and shaped to receive and hold one of the locking lugs 32 together with the sleeve which allows the lug to move radially between an inner release position and an outer locked position. The bore in the lower part of the sleeve 30 which extends past the windows 35 is stepped and shaped to provide space for the outlet sleeve 33 for the locking lugs. A tapered stop shoulder 42 along the bore of the sleeve limits the upward movement of the delivery sleeve 33. As can be seen from Figures 2 and 3, each of the windows 35 has longitudinal internal holding recesses 43 on the side, and in these holding flanges are occupied along the side edges of the locking lugs 32 to hold the lugs in the windows in the sleeve 30. The lower end part of the sleeve 30 is internally threaded at 44 for connection to the sleeve at the upper end of the packing mandrel 31. An externally circumferential stop flange 45 is formed on the lower end portion of the sleeve 30 to limit the downward movement of the mandrel M in a landing nipple. •

The output sleeve 33 for the locking lugs is, as shown in fig. 1 a tubular part with upper and lower guide or bearing end parts 50 and 51. The upper end part 50 of the housing 33 slides in the bore in the sleeve 30 above the stop shoulder 42, while the lower guide part 51 of the sleeve slides in the bore in the packing mandrel 31. The bore in the output sleeve 33 is tapered with an extended lower end part which has a tapered operating shoulder 52 for abutment against an operating wedge on the insertion tool, so that the output sleeve is lifted when the locking lugs 32 are to be moved outwards to locking positions. The outer diameter of the central part of the output sleeve 33 is also tapered, so that an upper central part 53 and a larger lower central part 54 appear. A conical cam surface 60 is found on the sleeve 33 between the parts 53 and 54. An outer ring-shaped locking recess 61 is found on the output sleeve part 53 for releasable locking of the output sleeve in the upper locked position.

Each of the locking wedges 32 shown in Figures 4-7 is a circularly curved segment which is shaped to fit in the windows 35 in the sleeve 30 and has an outer locking profile and an inner locking profile which can engage the delivery sleeve 33 for delivery and locking of the wedges. The side edges of the locking lugs 32 are in one piece with an internal longitudinal holding flange 62 which fits in the retaining recesses 43 along the windows 35 in the sleeve 30 to hold the locking lugs 32 in the windows in the positions shown in fig. 1.

Each of the lugs 32 has an outer locking boss surface 63 which is shaped to fit into a locking recess in a landing nipple for locking the locking mandrel M to the landing nipple. The insides of the lugs 32, which are particularly shown in Figures 4 and 5, are stepped surfaces comprising an upper inside 64 and a lower inside 65. The lower end of the surface 65 has an internal cam surface 70. Between the surfaces 64 and 65, each lug has an inclined cam surface 71. The surface 64 also has a locking lip or ridge 72 which can engage with the locking recess 61 in the sleeve 33, so that when the sleeve is in the upper locked position in fig. 1, the delivery sleeve will be releasably locked in the upper position where the cams 32 have been brought out. The cams 70 and 71 on the inside of the cams 32 cooperate with cam surfaces on the output sleeve 33 to move the cams outwards to locking positions when the holding sleeve 33 is lifted upwards from a release position to the upper locked end position in fig. 1. To further lock the sleeve 33 in the upper end position, the sleeve 33 has an external annular locking flange 73 which is placed around the lower end part 51 of the sleeve, while the packing mandrel bore has an internal annular locking flange or shoulder 74. In the upper locked position of sleeve 33, the locking flange 73 is moved over the locking flange 74 in the bore in the packing mandrel to further assist in holding the output sleeve 33 in the upper locking position.

As shown in fig. 8A and 8B, the insertion tool R with the features according to the invention has a fish neck 80 having the features and details of standard line connection, so that it can be connected to a line tool string, including a reduced threaded upper end part 81 and an external annular flange 82. The fish neck has a extended lower skirt part 83 of a bore 84, where an end part 85 of reduced diameter is internally threaded. An upper insertion sleeve 90 is fixed along an externally threaded upper end part and in the threaded bore part 85 in the fish neck. The fish neck's skirt 83 and the upper end part of the sleeve 90 stand at a concentric distance from each other. The sleeve 90 has a pair of longitudinal slits 91 arranged on the opposite side of the sleeve. The lower end part of the insertion sleeve 90 is bored out at 92 and has a shear pin hole 93, as well as a set screw hole 94. Above the set screw hole, the sleeve 90 has an external annular recess 95 for releasing the lock. A holding sleeve 100 for locking springs can be moved telescopically over the lower end part of the sleeve 90 into the skirt 83 between the sleeve 90 and the skirt. The sleeve 100 has windows 101 which are spaced from each other in the circumferential direction and are shaped to receive and hold a locking wedge 102. As shown in fig. 12, each of the windows 101 in the sleeve 100 has longitudinal, opposing retaining lips or flanges 103 which hold the wedges on the side and form a longitudinal recess 104 against each longitudinal side edge of the windows. As shown in fig. 13-16, each of the locking wedges 102 is a curved circular segment with an outside 105 and an inside 110. The outside has a locking boss 111 which is provided with a recess 112 for a transverse ring spring and which extends between an upper cam surface 113 and a lower cam surface 114 The locking heads of the wedges formed by the outer bosses 111 have inner bosses 115 which extend between an inclined cam surface 120 and an inclined cam surface 121. As shown in fig. 16, each of the longitudinal side edges of the wedges 102 is provided with an internal holding flange 122 which fits in the recesses 104 at the window edges, fig. 12, and can engage together with the holding flanges 103 along the window edges of the holding sleeve 100 for the wedges, to hold these in the windows while allowing the wedges to move radially in and out. The wedges 102 are fitted in the windows and are held by an annular spring 107 which completely surrounds the wedges and sleeve 100. The annular spring runs through the outer recess 112 in the locking heads of the wedges and between the wedges through a segment of the outer annular recess 124, which is found on the outside of the sleeve 100, and crossing the lower ends of the windows 101. The spring holds the wedges within the windows while allowing the locking head ends of the wedges to move radially between engaged locking positions and retracted release positions. The wedges 102 are movable along the sleeve 100 between performed locking positions and retracted release positions. When the locking heads of the wedges are flush with the release depression 95 on the sleeve 90, the ring spring 123 will pull the locking heads of the wedges inwards to the release positions.

Continuing with reference to fig. 8A and 8B, it can be seen that a lower insertion sleeve 130 is telescopically inserted along an upper end part into the bore 92 in the upper insertion sleeve 90. A set screw 131 through the lower end part of the sleeve 90 holds the lower insertion sleeve together with the upper insertion sleeve. The lower part of the lower insertion sleeve has a series of downwardly directed longitudinal clamping sleeve fingers 132 which are spaced from each other in the circumferential direction and each of which has a locking head 133. Each of the locking heads of the clamping sleeve fingers has an upper outwardly tapering cam surface 134 for displacing the locking cams' output sleeve 54 in the mandrel M, and then to cam the locking heads 133 inwards to release positions. It should be clear from fig. 8A and 8B that the collet fingers 132 merge into the main part of the sleeve 130 at the upper ends of the fingers, while the fingers, including the locking heads 133, can freely spring inward and outward for locking and operating the locking mandrel M. A tubular core 135 can slide telescopically in relation to the upper insertion sleeve 90 through the lower insertion sleeve 130. The core has an outer annular release recess 136, which enables the locking heads 133 on the collet fingers 132 to move inwardly to release positions when the locking heads are aligned with the recess 136. When the locking heads are not aligned towards the recess 136 and thus lies along the larger diameter of the core above the recess, the outside of the core will hold the locking heads 133 outwardly in operative positions. The upper end parts of the retaining sleeve 100 for the locking wedges and the core 135 are fixed together with a pin 141 which extends from opposite sides of the sleeve 100 through the longitudinal slots 91 in the upper insertion sleeve 90 and the opposite sides of the core 135. The pin 141 secures the retaining sleeve 100 for the wedges of the core, so that the two parts are rigidly connected to each other and therefore move as a unified unit. Similarly, the fish neck and the upper insertion sleeve 90 are assembled to move as a unit relative to the retaining sleeve 100 for the wedges and the core 135. When the fish neck is raised or lowered, the upper insertion sleeve 90 is correspondingly raised or lowered relative to the retaining sleeve 100 for the wedges and relative to the core 135. Movement of the fish neck 80 moves the upper insertion sleeve 90 relative to the wedge retaining sleeve 100 which holds the upper locking wedges 102, and thus the locking wedge release recess 95 will be moved relative to the wedges 102. In the same way, movement of the fish neck move the clamping sleeve fingers 132 which hang down from the sleeve 130, so that the clamping sleeve heads 133 are moved along the core 135 in relation to the release recess 136. The upper locking wedge heads 111 and the lower locking wedge heads 133 on the clamping sleeve fingers 132 act so that the insertion tool R is connected to the locking mandrel M, affects the locking mandrel M and releases the insertion tool from the locking mandrel at the different inter-locks s positions between the upper and lower insertion sleeve, upper and lower locking wedges and the clamping sleeve fingers on the lower insertion sleeve.

The locking door M and the insertion tool R are suitable for inserting and fixing with line standard remote-controlled safety valves for production pipelines in nipples of the stop shoulder type (no-go type). A typical safety valve with which the locking mandrel tool can be used is the Otis DK safety valve shown on page 3998 of the 1974-75 edition of The Composite Catalog of Oilfield Equipment and Services, published by World Oil, Houston, Texas and an Otis RQL stop shoulder nipple for the safety valve shown on page 4004 in the same catalogue. When used together with the DK Otis safety valve, the locking mandrel M according to the invention will replace the locking mandrel shown on page 3998 in the catalogue.

In preparation for operating the locking mandrel M and the insertion tool R according to the invention, the locking mandrel is attached to a safety valve S as shown in fig. 17B by screwing the lower end of the locking mandrel packing mandrel 31 into the internally threaded upper end portion of the housing 150 of the safety valve. The operating fluid system for the safety valve, which is not shown, is connected to an appropriate source of control fluid pressure which is used to pump the safety valve to the open position, in which the operating tube 151 in the safety valve will be in a lower end position as shown in fig. 17B. The operating tube 151 is connected to a fluid actuated piston and a spring (not shown) which allows remote control of the valve from the surface after it is installed. When using the valve down the borehole, the valve is held open by fluid pressure exerted from the surface and when the pressure is relieved, the spring will close the valve. When the valve is pumped open, the spring is compressed and exerts an upward force on the operating tube.

With the safety valve pumped open, the insertion tool R is extended to maximum length by the fish neck 80 sliding against the sleeve 100. The insertion tool is then inserted into the connected locking mandrel M and safety valve S. As the insertion tool is inserted, the collet fingers 132 will move along the locking mandrel until the fingers insert into output sleeve 33, past the internal cam surface 52 with the tension sleeve heads 33 springing outwards into the larger bore in the sleeve 33 below the cam surface 52. The heads 111 of the locking wedges 102 rest against the upper end of the retaining sleeve 30 and move into the bore in the sleeve below the inner shoulder 41 and into the bore part 40 of the sleeve. The core 135 extends down through the locking mandrel into the upper end of the safety valve. The fluid pressure which keeps the safety valve open is then relieved, so that the spring which rests against the operating tube 151 in the safety valve drives the operating tube upwards towards the conical end edge surface 138 of the probe 137 which is fixed at the lower end of the core. The upward force from the safety valve spring lifting the core exerts an upward force on the pin 141 which drives the wedge retaining sleeve 100 upwardly. The upward force on the sleeve 100 drives the upper locking wedges 102 upwards along the outside of the sleeve 90 over the release recess 95 in the sleeve, so that the heads 111 of the wedges are caught in the annulus between the bore 40 of the sleeve 30 around the sleeve 90 between the inner annular conical surface 41 in the sleeve 30 and the lower conical end edge surfaces 101a of the windows 101 in the holding sleeve 100 for the wedges. The upward force on the sleeve 100 is exerted from the window surfaces 101a against the inner end surfaces 121 of the locking wedge heads 111, so that the locking wedges are driven upwards and outwards and so that the upper outer surfaces 113 of the locking wedge heads are driven against the inner annular conical surface 41 in the locking mandrel sleeve 30 for locking of the insertion tool to the sleeve 30. At the lower end of the insertion tool, the clamping sleeve heads 133 are held in normal positions by the outside of the core under the core recesses 136, so that the surfaces 134 of the clamping sleeve heads 133 can engage with the cam surface 52 in the locking mandrel output sleeve 33. The insertion tool is manipulated by pulling the fish neck 80 away from the locking mandrel a distance until the shear pin holes 41' in the locking mandrel sleeve 30 align with the shear pin holes 93 in the insertion tool sleeve 90. Cutting pins are then inserted through the holes 41' in the locking mandrel into the holes 93 in the insertion tool, so that the pins lock the mandrel to the insertion tool . Fig. 17A and 17B show the safety valve and locking mandrel connected together on the insertion tool for insertion and placement of the safety valve. It will be seen that the upper wedges 102 of the insertion tool engage in the sleeve 30 of the locking mandrel M, while the heads 133 of the clamping sleeve fingers grip firmly in the output sleeve 33 of the locking mandrel, and the output sleeve 33 is in its lower end position where the locking lugs 32 on the locking mandrel are in inner release positions. The locking door and safety valve are now ready for insertion into a wellbore and for placement in a landing nipple.

The insertion tool R is connected at the fish neck 80 to a line tool string which is not shown and which is used to lower the insertion tool, the locking mandrel and the safety valve through a flow guide in a wellbore (not shown) and into a landing nipple 160 as shown in fig. 18B. The landing nipple is provided with an internal annular locking recess 161 and a stop shoulder 162. The safety valve and the locking mandrel are driven downwards by means of impact in the line tool string until the stop flange 45 on the lower end of the locking mandrel sleeve 30 comes into contact with the shoulder 162 in the landing nipple. The sealing device 34 moves downwards along the sealing surface 163 of the landing nipple under the shoulder 162. Further thrust downwards to exert downward forces on the fish neck 80, drives the fish neck downwards until the lower end edge of the skirt 83 of the fish neck comes into contact with the upper end edge of the mandrel sleeve 30, and cuts off the pins 155 connecting the insertion tool to the mandrel skirt. Figs. 18A and 18B show the safety valve and locking mandrel positioned in place in the landing nipple on the shoulder and the insertion tool operated to cut off the pins 155 which form the connection between the insertion tool and the locking mandrel sleeve 30. The insertion tool remains connected to the locking mandrel by means of the upper wedges 102 and collet fingers 132 The spring in the safety valve continues to exert an upward force on the probe 137 and the core 135, and this force is transmitted through the pin 141 to the upper insertion sleeve 100 which exerts the upward and outward force from the sleeve window edges 101a, to keep the retaining wedges 102 tightly expanded in locking relation to the locking mandrel sleeve 30 against the shoulder 41 of the sleeve. Upward force is exerted on the line, not shown, for the 1ine tool string. A tension in the line greater than the weight of tools in the string indicates that the safety valve S is in place in the landing nipple. The fish neck 80 is moved upwards, so that the upper insertion sleeve 90 and the lower insertion sleeve 130 are pulled upwards and the clamping sleeve fingers 132 are lifted between the core 135 and the retaining sleeve 100 for the wedges, and this sleeve remains fixed against upward movement due to the locking effect of the upper retaining wedges 102. As the collet fingers 132 are lifted, the upper edge surfaces 134 of the collet head 133 come into contact with the inclined shoulder 52 in the locking mandrel output sleeve 33, which lifts the sleeve 33 inside the locking lugs 32. As the sleeve 33 moves upwards, the cams 55 and 60 on the sleeve come into contact with the inner cam surfaces 70 and 71 at the locking lugs, so that these cams are guided radially outwards to a fully completed position as shown in fig. 19A and 19B and fig. 1. The locking cams 32 are moved outwards until the outer bosses on the cams come into contact with the landing nipple's locking recess 161 and lock the locking mandrel M together with the safety valve S against movement in the longitudinal direction inside the landing nipple. The locking cam's output sleeve 33 is moved to an upper end position, in which the cam surface 55 of the sleeve 33 rests against the stop shoulder 42 inside the sleeve 30 for the mandrel M. In the upper position of the sleeve 33 within the cams 32, the cams are held in a radially executed position as shown in fig . 19A and 19B and in fig. 1. An upward force or tension is then exerted on the line carrying the line tool string and fluid pressure is exerted on the control line leading to the safety valve S. The control line pressure in the safety valve chamber against the piston on the safety valve operating tube 151 moves the safety valve tube down somewhat and relieves the upward force from the spring in the safety valve which acts on the operating tube and which has driven the tube towards the core of the insertion tool and kept the insertion tool locked to the locking mandrel by means of the upper retaining wedges 102. The upward tension on the line will then lift the fish neck 80 and pull the upper insertion sleeve 90 and the lower insertion sleeve 130 upwards in relation to the holding sleeve 100 for the wedges and the core 135 for the insertion tool. The upward movement of the sleeves 90 and 130 lifts the release recess 95 in the sleeve 90 into engagement behind the retaining wedge heads 111 and lifts the collet finger heads 133 which are cam guided into the recess 136 on the core. When the release recess 95 is aligned with the retaining wedges' heads 111, the ring spring 123 will squeeze the retaining wedges 102 inwards and pull the wedge heads 111 back from engagement with the shoulder 41 at the upper end of the bore part 40 in the locking mandrel sleeve 30, thus releasing the insertion tool from the locking mandrel. As the insertion tool is pulled upwards, cam shoulders 52 in the locking mandrel sleeve 33 will act on the cam edges 134 of the clamping sleeve fingers 133, which now move upwards. The heads 133 of the collet fingers are clamped into the recess 136 on the core, and release the collet finger heads from the locking mandrel output sleeve. The frictional engagement between the packing device 34 on the locking mandrel M in the sealing surface of the landing nipple below the shoulder 162 holds the locking mandrel back and from being pulled out of the landing nipple while the locking mandrel is operated by the insertion tool for locking the mandrel to the landing nipple. If the locking mandrel does not release the insertion tool properly, the mandrel and safety valve will be pulled back upward when the insertion tool is lifted. If e.g. the control pressure is not properly exerted on the safety valve, the upward force on the probe surface 138 will not be relieved, so that the upper locking wedges 102 will not be released from the locking mandrel's sleeve surface 41. If, in a similar way, the locking lugs 32 are not brought out into the locking position in relation to the landing nipple's locking recess 161, the output sleeve 33 cannot be pulled up and thus holds back the heads 133 of the collet fingers, so that these cannot be pulled up along the core to be aligned with the release recess 136 and therefore the insertion tool will be held back in the locking mandrel by the collet fingers 132. If such a malfunction occurs and allows the insertion tool together with the locking mandrel and the safety valve to be withdrawn from the landing nipple, the insertion tool, locking mandrel and safety valve can be driven back down into the landing nipple, repeating the necessary steps for placing the locking mandrel in the landing nipple and for releasing the insertion tool. After proper release of the insertion tool from the locking mandrel, the locking mandrel remains releasably locked in the landing nipple and the safety valve is under control from the control pressure operated from the surface to open and close the safety valve as needed as dictated by the working conditions in the well. The outlet sleeve 33 for the locking mandrel M is held against accidental release by contact with the locking flanges 72 on the inside of the lugs 32 in the locking recess 61 in the sleeve and by the locking boss 71 along the lower end part of the sleeve being placed over the internal annular locking flange 74 in the packing mandrel 31 for the locking mandrel.

It will be seen that the equipment according to the invention comprising the locking mandrel M and the insertion tool R forms a well tool structure adapted for insertion and placement in a shoulder type landing nipple by the application of a downward force and suitable for locking the locking mandrel M to hold the safety valve in place in a well bore by the application of a reversed upward force. Unintentional release and possible accidental locking or other malfunction during guiding the locking mandrel downwards into position in a landing nipple is avoided. The locking door M with safety valve S can be removed from the landing nipple using a standard Otis type GR or GS pulling tool as shown on pages 3988-3989 of the 1974-75 edition of the "Composite Catalog of Oilfield Equipment and Services". Pulling tools of this nature are provided with a nose or tooth connected to the core of the pulling tool to cooperate with the release of the locking mandrel outlet sleeve 33 by downward movement of the sleeve and to engage with the operating tube 151 of the safety valve S to hold the valve open while the mandrel and the valve is pulled loose.

A safety feature of the insertion tool will enable the mandrel latches 32 to be released for pulling the insertion tool, the mandrel M and the safety valve back out of a well. The set screw or screws 131 are selected to be cut off when the lower insertion sleeve 130 is released from the upper insertion sleeve 90. If there is a malfunction, e.g. in the control fluid pressure of the safety valve after the mandrel is locked, an upward jerk of the head 80 will shear the screws

131. The head is then driven downwards, which forces the upper insertion sleeve downwards towards the lower insertion sleeve and towards the output sleeve 33 which is driven down to a lower end position from the position behind the cams 32, so that these are released and can be moved inwards. The head 80 is then pulled up, but when the lower insertion sleeve 130 is released from the upper sleeve 90, the clamping sleeve fingers 132 are not pulled up into the output sleeve 33 and thus the output sleeve is not guided behind the cams 32

which thus remain free, as the pulling tool, mandrel and safety valve are pulled up. The mandrel can then be pulled up without resetting the locking lugs.

Claims (4)

1. Insertion tool (R) for placing and locking a coupled locking mandrel (M) and well tool (S) in a landing nipple in a well flow pipe, which locking mandrel (M) is of the type that includes a body (30) with side windows (35), a internal annular recess (40), a carrying shoulder (45) for supporting the locking mandrel (M) in a landing nipple stopper, a radially movable locking cam (32) in each of the side windows (35), an annular sealing device (34) around the body (30) ) for sealing between this and a sealing surface in the landing nipple, an outlet sleeve (33) in the body, slidable within the locking lugs (32) in a direction opposite to the direction of movement of the locking mandrel into the landing nipple for deployment and withdrawal of the locking lugs (32), an internal ring-shaped recess or cam surface (52) in the delivery sleeve (33) for maneuvering this, as well as means for connecting to well- the tool (S), which insertion tool (R) includes a head device (80) for connection to a working tool string, an upper insertion sleeve (90), a tubular core (135) which is arranged in the upper insertion sleeve (90) and is limited axially movable in relation to this, a probe (137) which is attached to the core (135) and extends downwards to abut against the well tool's operating pipe (151), devices for releasable coupling to the locking mandrel's annular recess (40), and devices for engagement with the output sleeve's internal cam surface (52) for maneuvering the output sleeve, characterized in that the devices for releasable connection to the locking mandrel (M) annular recess (40) include an upper locking wedge device (100, 101, 102), comprising a wedge holder sleeve (100) with windows (101) and locking wedges (102) which are arranged concentrically around the upper insertion sleeve (90) and are secured to the core (135) for movement together with this in in relation to the insertion sleeve, that the devices for engagement with the internal cam surface (52) include a lower insertion sleeve (130) which is attached to the upper insertion sleeve (90) and has clamping fingers (132) with finger heads (133) which can spring inward and outward, and that one annular depression (95) is arranged on the outside of the upper insertion sleeve (90) and another annular depression (136) is arranged on the outside of the core (135), which sleeve depression (95) and core depression (136) are aligned to to cooperate with the locking wedges (102) and fingers (133) respectively to release the insertion tool (R) from the locking mandrel (M) when the insertion sleeve (90) and sleeve (130) are raised to align the recess (95) behind the wedge heads (111) and fingers ( 133) combing s into the core recess (136). 2. Insertion tool according to claim 1, characterized in that the tool comprises means including shear pin devices (41', 93, 155) for releasably retaining the insertion tool (R) in the locking mandrel (M) while the core (135) and the source holder sleeve are in an upper position, viewed in relation to the insertion sleeve (90, 130), where the locking wedges (102) engage with the locking mandrel's annular recess (40) and the finger tips (133) rest against the insertion sleeve's internal cam surface (52). 3. Insertion tool according to claim 1 or 2, characterized in that the wedge holder sleeve (100) is secured to the core (135) by means of a pin (141) which runs in slots (91) in the upper insertion sleeve (90). 4. Insertion tool according to claim 1, 2 or 3, characterized in that the lower insertion sleeve (130) is attached to the upper insertion sleeve (90) by means of shear pin devices (94, 131).