NO751060L - - Google Patents

Description

The present invention relates to a method and a carrying device for use with the inspection of pipe bodies, when these are led down into or pulled up from a wellbore. Preferably, the carrying device places the inspection head immediately in the vicinity of the turntable, when such is used, and enables movement of the inspection unit away from the turntable either in an emergency or for other reasons during lowering or pulling up of the pipes, so that e.g. stop wedges can be placed on the turntable in a known manner.

The support device is able to accommodate lateral displacement of the pipe bodies during their movement down into or up the borehole, without the inspection unit's work thereby being disturbed.

The invention is a continuation of applicant's prior U.S. patent application 431-093 of 7.1.197*1 regarding "Procedure and device for inspection of tubular bodies, when these are led down into or pulled up by a well bore". The present application can be used to support the applicant's patent no. (patent application 750.029) concerning "Measuring tools for tubular objects". One purpose of the present invention is to provide a relatively simple support device to support a device near a wellbore, so that tubular objects can be lowered into or pulled up from the wellbore for movement through the device for inspection. Another purpose of the invention is to provide a relatively simple carrying device for an inspection unit, comprising an electromagnetic induction device and a measuring device. for measuring variations in the outer diameter of tubular objects, when these are led down into or pulled up ;by a well bore.;Another purpose of. present invention is to provide a carrying device for an inspection unit near a well bore, so that the tubular objects, when they. is led down into or pulled up from the wellbore, and at the same time can be turned and inspected for any defects. A further purpose of the present invention is to provide a method for inspecting tubular objects, when they are led down into or pulled up by a well bore, whereby such an inspection can be carried out without interference from joints, couplings, rubber protectors, etc. Another purpose of the present invention is to provide a relatively simple support device for supporting a device near a wellbore, so that the tubular bodies can be lowered into or pulled up from the borehole to be moved through the device for inspection with a view to defects, and where the support device enables the device to be displaced in response to displacement of the tubular bodies when these are moved through the device. Other purposes and advantages of the present invention will be apparent from the following description of the drawings. Fig. 1 is a partially unfolded isometric drawing of an embodiment of the present invention. Fig. 2 is an elevation of the embodiment of the invention shown in fig. 1. Fig. 3 is a side view of the embodiment of the invention shown in fig. 1 and illustrates with a dashed line an alternative position of the support members, as well as a device for supporting an upwardly extending support member in place on a drill plate form. Fig. 4 is a section along the line 4-4 in fig. 3 and provides a schematic illustration of the arrangement of the measuring tool for the outer diameter and the device for electro-magnetic induction inspection which make up the inspection unit. Fig. 5 is a section along the line 5~5 in fig. 4 for better illustration of a device for continuous engagement between the tubular body and the electromagnetic induction inspection part of the inspection unit. Fig. 6 is an end view of the device which is indicated by a dashed line in an inclined position on the inspection unit. Maid. 7 is a section similar to fig. 4 and shows only; an electromagnetic induction inspection unit.; Fig. 8 is a perspective view of another embodiment of the invention. Fig. 9 is a plan view. of part of the structure which is shown in fig. 8.; Fig. 10 is a plan view along the line 10-10 in fig. 9S; partially reproduced in section.; In the drawing's fig. 1, the invention is generally designated 15. An upstanding support or column carrier, generally designated ;20, is arranged to receive side-directed arms, generally designated 25. The inspection unit, generally designated 30, is supported on the side-directed arm 25 and provided with an opening 30a for receiving tubular bodies. The vertical column carrier 20 comprises a foundation plate 21 which may have openings, as indicated at 21a, for suitable means such as bolts, for fixing the column in a vertical position on a drilling rig floor or the like. As shown, the column 20 is equipped with parts 22 and 23 which are arranged at a distance from each other and limit a longitudinal opening 24 between them. As shown, the parts 22 and 23 are designed as channel profiles with a base or step and two side parts. Each channel profile 22, 23 can be attached to the foundation plate 21 by appropriate means, such as the brackets 22a and 23a, which can be fixedly welded between the foundation plate 21 and the respective channel profiles 22, 23. In the elongated opening or slot 24, there is arranged a suitable power device, generally designated 31. As shown, such a power device comprises a cylinder 32 which rests on or is attached to the foundation plate 21 and accommodates a piston 33 - The piston is attached to a piston rod 34 which extends longitudinally between the channel profiles 22 and 23 in the slot 24. Bearing guides 35 and 36, arranged at suitable distances between the parts 22 and 23, provide support for the piston rod 34 and form guides for this during the movement of the piston rod 34, as discussed in more detail below. ;The side-directed arm 25 comprises, as shown, at least two parts 25a and 25b arranged in a telescopic connection. As shown, the parts 25a, 25b do not have a circular shape, although they may have any other shape. Suitable bearings 25C are arranged between the telescopically connected parts 25a and 25b to enable free telescopic movement therebetween. The lateral arm 25 is adapted to be attached to the vertical column 20 by any suitable means, and is shown pivotally connected to the column by an arrangement 40 so that the lateral arm 25 can pivot in a generally horizontal plane relative to the vertical column 20, as indicated by the dashed line in fig. 2. Suitable clamping means, generally designated 45, comprise blocks 46 and 47, arranged so that they fit into the slot 24 and engage with the piston rod 34. The two blocks 46 and 47 are each provided with overlapping edge portions 46a and 47a and each has its own partially circular opening, as shown at 46b and 47b, so that the blocks, when placed in the slot 24 as shown • in fig. 1, will fit into contact with the piston rod 34. Then a bolt and nut 48 can clamp the blocks 46 in place on the piston rod 34 in the slot 24. When the blocks 46 and 47 are clamped in the desired position on the piston rod 34, their overlapping edge portions 46a and 47a be in contact with the channel profiles 22 and 23} as shown in fig. 1 and 2 and 3 to act as guides during the movement of the piston rod, when the working cylinder 31 is operated. ;The block 46 is also provided with a circular sleeve 50 which fits between circular sleeves 51 and 52, mounted at a distance from each other on the end 27 of the lateral arm 25. When the sleeves 51 and 52 are flush with the sleeve 50, they are adapted for receiving of a bolt 53 > so that a pivoting connection is formed between the arm 25 and the vertical column 20. As shown in fig. 2 and 3, a further support can be provided for the vertical column 20 in the form of chains 555 attached to each side of the column and to a nearby leg of a drilling rig, or a stationary part, indicated by dotted line at 56 in fig. 3- ;The end 28 of the side-directed arm 25 is adapted for engagement with a bracket 29 which is shown attached to the inspection unit 30, so that the end 28 and the bracket 29 can again be fixed together by means of bolts and nuts 29a. The inspection unit 30, as shown in fig. 1-6, comprises a measuring device 60 for measuring variations in the outer diameter of tubular bodies that are moved through the inspection unit 30. The details of such a measuring device for outer diameter are discussed in a Norwegian patent (patent application 750.029).

The inspection unit 30 in fig. 1-6 also comprise an electromagnetic induction inspection unit 6l which contributes to the detection of any defects, faults, fatigue cracks, etc., both internally and externally in the pipes which are moved longitudinally through the inspection unit 30.

As shown in fig. 3, a suitable motor for turning the measuring unit 60 is arranged in the form of a fluid motor 62 or the like, provided with suitable means for receiving power from a source not shown, which can be arranged at an optional location near the unit.

Similarly, the electromagnetic inspection unit 6l is provided with means 63 for receiving power from a suitable power source for powering the inspection unit and for operating the electromagnetic induction inspection unit in a known manner. I. fig. 4, the outside diameter gauge 60, as well as the electromagnetic inspection unit 61, is shown schematically in detail. Suitable means such as a spring device 65 are used to press the rollers 66 into continuous contact with a tubular body, as shown at 67 in fig. 5" The rollers 66 are in turn mounted in a known manner with the inspection shoes 70.

As shown in fig. 6 is the circular shape of the end of the bracket 29 and the end 28 of the lateral arm so that, if necessary, the inspection unit can be positioned at any desired angle relative to the vertical, simply by turning the inspection unit 30 relative to the bracket 28

as indicated by the dashed line at 30a in fig. 6, whereupon nuts and bolts 29a are attached to the parts.

In fig. 3 is a rotary table of the type that is common on oil and gas drilling rigs shown in dotted line at 80. During normal operation of the present invention, it is desirable

having the inspection unit 30 in the vicinity of such a turntable as shown in fig. 3. The pipe shown in dashed line at 67

is either led down into or pulled up by the wellbore just below and is brought flush with the opening in the inspection unit 30.

If it should be desirable to fix the catch wedges in the turntable during the lowering or pulling up of the pipe, or if for some reason it should be desirable to move the inspection unit vertically in relation to the turntable 80, the cylinder 32 can receive suitable pressure fluid force through the connection 32a for influencing the piston 33 whereby the piston rod 34 is moved upwards in the gap 24 between the channel profiles 22 and 23. When this happens, the side-directed arm 25 will also be moved upwards, as it is clamped onto the piston rod by means of the blocks 46 and 47.

The inspection unit 30 can then be lowered back into place when this is desired, by releasing pressurized fluid from the cylinder 33.

As previously mentioned and as shown in fig. 2, the inspection unit 30 and the side-directed arm 25 can also be swung in a horizontal plane relative to the column 20 by means of the swing device 40, as indicated by the dashed line in fig. 2.

In fig. 7 shows an arrangement of the inspection unit which is here generally designated 30b, where only an electromagnetic induction inspection unit 6lb is used.

Fig. 8, 9 and 10 show an alternative embodiment of the invention 15, where parts corresponding to the parts shown in fig. 1-7 have corresponding reference numbers.

The foundation plate 21 has holes 21a for fixing the device 15 according to the invention. The channel profiles 22 and 23 are arranged at a distance from each other with a longitudinal gap 24 between them and a force device 31 is mounted on the foundation plate 21 at the lower end of the gap 24.

The power unit comprises a cylinder 32 with piston 33 and a piston rod 34 connected to the piston 33 and extending upwards in the gap 24 between the channel profiles 22 and 23. Suitable bearing guides 35 and 36, arranged at a distance from each other, guide and support the piston rod 34 when it is in motion.

Suitable lubrication connections 35' and 36' are arranged on the device 23 for supplying lubricant to the bearing guides 35 and 36, respectively.

The upper end of the parts 22 and 23 is provided with a plate

100, which has a groove or opening 101 which is placed between the parts 22 and 23 and through which the piston rod can be easily moved.

The arm 25' is rotatably connected to the vertical column 20 by means of the device which is generally designated 40 in the same way as discussed in connection with fig. 1 - 7" Such a pivotable support device comprises the sleeves 51 and 52 which are arranged at a distance from each other on the plate 50', which in turn are fixed with appropriate means such as bolts 27a, which project through the end 27 of the arm 25' and engage in the plate 50'. A sleeve 50, not shown, is carried by the clamping arrangement 45 and fits between the sleeves 51 and 52. A suitable pin or threaded member 53 may be engaged to hold the arm 25' pivotally attached to the clamping device which grips the piston rod 34.

In this form of the invention, the clamping device 45 comprises a block 45a, which can be formed of two parts with matching semicircular cavities that extend longitudinally through the block, so that they fit together around the piston rod 34. The two block parts can be attached together around the piston rod 34 by suitable means, such as the through bolts 45b. The sides 45c of the blocks have a sliding bearing against the steps 22a and 23a for the parts 22 and 23 when the piston rod'34 moves.

In this form of the invention, the side-directed arm 25 is shown with a cylindrical shape, comprising two parts 25a' and 25b' in a telescopic connection. The end 28' of the arm 25' here has the form of a rectangular plate with openings 28a' for receiving and rejecting the inspection unit 30, as discussed in connection with fig. 1 - 7«-

The cylindrical part 25b' is provided with an end cover 25c, which is adapted so that it can be screwed into the end of the part 25b', as shown. The end cover has a continuous opening 25d with an annular groove 25e for receiving the sealing member 25f which is in sealing and sliding contact with the part 25a'.

Appropriate bearings 105 and 106 are provided on the arm or portion 25a' to assist in guiding the arm 25a' upon relative longitudinal movement of the arm or portion 25b'. A further bearing 107 is arranged between the bearings 105 and 106 for further guiding the part 25a, when this is moved in the longitudinal direction in relation to the part 25b'. As shown in fig. 8, the bearing 106 comprises several rollers 1093 spaced around the circumference which are carried by the bearing 106 and are in contact with the inner surface 110 of the arm or part 25b' during movement between 25a' and 25b'. The bearing 105 may be a sleeve bearing, as shown.

The bearing 107 fits rotatably into a groove 113 in the part 25b'.

In fig. 8, the groove 113 is clearly shown partially cut away, so that the relationship between the bearing 107 and the groove in the arm 25b' can be seen. The groove 113 limits the relative longitudinal movement between the parts 25a<1> and. 25b' and also prevents relative rotation between these parts.

A suitable cover plate 115 can be attached to the arm 25b' with suitable means, such as screws 116 or the like, so that access is given to the bearing 107 for necessary inspection, repair or replacement.

A suitable connection has been created with the cylinder 32 for supplying fluid to the cylinder, so that the side-directed arm 25 can be placed in the desired vertical position, as discussed in connection with fig. 1 - 1. ■ The operation of the device in fig. 8 - 10 is the same as discussed in connection with fig. 1 - 7>, as the swing device 40 enables the lifting and lowering of the carrying device and the device that had to be carried by it with the help of the power device 31 - Relative movement in the longitudinal direction of the parts 25a' and 25b' can take place if necessary when using the invention.

When using the present invention, this will be arranged in such a way in relation to the rotary table 80 that it can receive tubular bodies when these are lowered or guided down into the wellbore or when they are pulled up step by step. from the well drilling, as shown in fig. 3- In all cases, the measuring instrument for external diameter will be rotated as discussed in the previously mentioned patent application. At the same time, an appropriate amount of power is supplied to the electromagnetic induction inspection unit 6l, so that a magnetic field is created in the tubular body as it passes through the inspection unit 30.

The outside diameter measuring instrument 60 in the inspection unit 30 measures variations in the diameter of the tubular bodies passing through the inspection unit and the inspection shoes 70 of the electromagnetic induction inspection unit sits on the tubular bodies and will detect any abnormality in the magnetic field as an indication of corrosion spots, fatigue cracks or other internal or external damage to the tubular bodies.

The spring device 65 makes it possible to compensate for unevenness caused by couplings, joints and protectors that pass through the inspection unit 6l and the spring device 65a on the measuring instrument, for the outside diameter has the same function.

The construction, arrangement of the method for using the present invention creates a minimum of disturbance to the normal work rhythm when lowering or pulling up pipes on an oil or gas drilling rig or the normal work rhythm on the rig otherwise.

The operation of the inspection unit is not disturbed by joints, couplings and/or protectors, and it should be noted that the inspection unit examines a full 360° of the pipes either when they are lowered or pulled up by the wellbore.

The invention not only provides a simple device for testing tubular bodies, but also enables a method for testing such bodies for recording damage or wear in the pipes, which could create problems during drilling or subsequent production from the well drilling.

The above description of the invention is intended as an illustration and explanation, and various changes can be made with regard to size and material, as well as with regard to details of the construction shown without leaving the scope of the invention.

Claims (12)

1.- Support device for a device near a wellbore for the movement of tubular bodies through the device, when they are led down into or pulled up by the wellbore, comprising (a) a vertically standing column carrier for placement near a wellbore, (b) a lateral arm attached to said vertical column support, (c) in that the side-directed arm comprises two parts in mutually telescopic connection, and (d) bearings between said two parts for guiding and abutting them. 2. Support device as stated in claim 1, characterized in that the vertically standing column support comprises organs for setting and lateral alignment of the arm at predetermined positions in the longitudinal direction of the column. 3. Support device as specified in claim 1, characterized in that the side-directed arm is pivotally attached to the vertical column support, so that the side-directed arm can swing in a horizontal plane in relation to the column support. 4. Carrying device as stated in claim 3, characterized in that the telescopically connected parts are constructed and arranged so that they can accommodate a limited relative axial movement between the parts. 5. Carrying device as specified in claim 1, characterized in that a bracket is mounted on the side-directed arm and intended for engagement with said device. 6. Carrying device as stated in claim 2, characterized in that the device for position placement includes: (a) a power device, (b) a piston rod which can be moved by the power device, (c) a clamping device for sliding attachment to the vertical column support and (d) means for attaching the lateral arm to the clamping device. 7. Carrying device as specified in claim 6, characterized in that the power device comprises a cylinder with a piston which is connected to the piston rod. 8. Support device as specified in claim 79, characterized in that it comprises bearing devices spaced apart in the vertical column support for contact with the piston rod. 9. Bearing device as stated in claim 1, characterized in that the bearing devices comprise a pair of bearings at a distance from each other, which are carried by one of the telescopically displaceable parts for cooperation with the inside of the other telescopically displaceable part's inside. 10. Carrying device as stated in claim 9, characterized in that at least one of the bearing devices comprises rollers for contact with the inside of the other telescopically displaceable part. 11. Carrying device as specified in claim 4, characterized in that it includes (a) a slot in one of said telescopically displaceable parts, and (b) a pivot bearing mounted on the other of the telescopically displaceable parts and in cooperation with the slot. 12. Procedure for inspection of tubular bodies during their immersion in or extraction from a borehole, characterized by the following steps: (a) the inspection unit is positioned so that tubular bodies can pass through it when lowered into or withdrawn from a wellbore, (b) a magnetic field is created in the tubular bodies as they are moved through the inspection unit; (c) the tubular bodies are rotated while moving through the inspection unit; (d) it is determined instrumentally whether there should be variations in the created magnetic field as an indication of defects in the tubular body, (e) contact is made with the exterior of the tubular bodies as they are rotated and moved through the inspection unit, and (f) any variations in the outer surface of the tubular bodies are recorded instrumentally, as an indication of variations in the outer diameter of the tubular bodies, when the tubes are rotated and moved in contact ■through the inspection unit.