NO843096L - DEVICE FOR MEASURING THE LINE DEPTH OF UNDERGROUND BURNS - Google Patents

Description

When completing and overhauling oil or gas wells

it is common to use tools suspended from a wire. It is very important to know the depth at which the tool is located,

and this is usually achieved by measuring the length of the wire or sandline that has been run down the well.

Well completion operations are usually performed using

of drilling rigs, which are well equipped for continuous measurement of the length of the wire that has been led down into the well in order to

set the depth of the tool. Most drilling rigs are in fact provided with permanent equipment next to the cable drum" on which the wire is stored. Hand-held depth gauges are also available. Thus, there is no problem in passing the wire over a dial and holding the path of the wire as it passes over the disk in essentially constant position in order to eliminate any accidental slippage of the wire in relation to the disc.

In overhaul operations, however, such luxury is not available or advisable. A sluice pipe assembly is usually connected to the top of the valve tree mounted on the valve head, and the tool-carrying wire or sandline is passed through the sluice pipe by means of a portable crane or drilling rig. Since there are hundreds of versions of portable cranes and drilling rigs, it is not surprising that no measuring device for the wireline depth that can be used for any type of overhaul rig has been developed to date. Furthermore, it must be remembered that a wire measuring device must be mounted in cooperation with the wire in the field and is thus exposed to very rough handling. There is therefore an undoubted need for a wireline depth measuring device that can be attached in the field to any type of overhaul rig that uses a sluice pipe device and that is capable of providing very accurate depth measurements for tools that are lowered into the well using a wire or sandline of an overhaul rig.

The invention provides a measuring device for wireline or sandline depth which can be attached to a rigid well structure adjacent to or surrounding the path of the wire when it is led down into the well. Preferably, the depth measuring device is mounted on the upper part

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of a sluice pipe device. The preferred location of the depth gauge is on the oil saver which is usually mounted on top of the sluice pipe to skim off oil that adheres to the wire or line as it is pulled up the well and conveys the skimmed oil through a pipe to a storage tank.

The wire depth measuring apparatus comprises a main element which is attachable to the top part of the sluice pipe device, and a disk mounting part which is axially separated from the main part in the direction of the path of the wire. The sheave mounting portion comprises two brackets which are rotatably connected to each other, and at least one of the brackets encloses the path of the wire. Adjustable springs are arranged between the brackets to force both against the wire. Each bracket carries at least one disk. One of the disks acts as a guide disk and has a notched periphery for engagement with the wire. Another disc acts as a measuring disc or roller and has a cylindrical surface in contact with the wire or sand line. The dial or roller carries means for counting its rotations, such as one or more permanent magnets mounted on the dial to move in a rotating path, proximity switches or Hall effect elements. Conventional sensing coils can be mounted on the bracket that carries the measuring disc,

and the signals formed by such sensing coils are transmitted to a conventional logic circuit to convert the signals received by the passage of the permanent magnets past the sensing coils into indications corresponding to the depth of the tool driven down the well by means of the wire. Proximity switches or Hall effect elements may operate in a similarly conventional manner.

Since it is known that the wire or sandliner has a tendency to arbitrarily move laterally from its normally vertical axial path into the sluice tube assembly, an elongate, laterally unbonded flexible member is provided for mounting the disc brackets to the main body, which member is rigidly connected with the top part of the sluice pipe device. Thus, the deviation of the wire in the lateral direction can be adapted by this flexible mounting of the disk brackets, and the possibilities of errors due to unintentional slippage of the measuring disk in relation to the wire are reduced to a great extent. The additional flexibility also protects the device from damage during assembly and handling.

Further advantages of the invention will appear more clearly to the person skilled in the art from the following detailed description of the embodiment of the invention shown in the attached drawings. Fig. 1 is a schematic elevation of a sandline which is supported by a drilling rig and is led down into a sluice pipe device for overhaul operations in a well on which the sluice pipe device is mounted. Fig. 2 shows, on an enlarged scale, an elevation of the wire depth measuring device according to the invention mounted on the top part of the sluice pipe device in fig. 1.

Fig. 3 is a section along plane 3-3 in fig. 2.

In fig. 1 schematically shows a well 1 which has a conventional valve tree 2 mounted on the wellhead at the surface. A conventional sluice pipe device 3 extends upwards from the valve tree 2, and a conventional oil saving device 4 is mounted on the top part of the sluice pipe device.

Although the invention can be used for any type of wire or sandline and can be used to measure the driven-in depth of wireline tools during the completion of a well, it must be described and illustrated in connection with overhauling a well by driving suitable tools into a sandline L. The sandline L is supported and guided over a disc (not shown) which is supported in a conventional manner at the top of a portable derrick 5. It will be clear that any type of portable crane can be used instead of the portable derrick 5. A wire depth gauge device 10 according to the invention is supported on top of the sluice pipe device 3, preferably by a bracket or main part 11 being bolted to a cylindrical part 4a on the oil saving device 4.

Reference should also be made to fig. 2 and 3, where it will be seen that the depth measuring device 10 comprises an upright tubular post 12 which is bolted to the outer end of the main part or bracket 11. The tubular post 12 supports an upright, resilient deformable column 13, which is shown here as a tight coiled compression spring, but which may comprise a massive column of suitable resilient material. The important factor is that the resilient deformable column 13 is laterally unbound and can bend in any direction about the vertical axis of the support post 12. In another embodiment of the invention, the sleeves 12 and 16 rest against each other while the spring 13 does not carry the weight of the upper device. However, lateral deflection will not be significantly prevented by the sleeves resting against each other.

A primary disk bracket 15 is provided with a downward-extending hollow post or sleeve 16 which is bolted to the upper end of the resilient deformable post 13. The main disk bracket 15 comprises two separate, parallel plate portions 15a and 15b, which are bolted to opposite sides of the downward-extending post 16 using bolts 15c. A secondary disc bracket 20 which has . arm parts 21 and 22 which enclose the path for the wire or sand line L, are rotatably mounted to the primary bracket 15 by means of a pivot pin 17. The secondary bracket 20 comprises two parallel plate parts 20a and 20b which are attached to each other by means of bolts 20c and distance tubes 20d. A pair of spring devices 23 and 24 are mounted on either side of the brackets 15 and 20. In the embodiment shown, the devices 23 and 24 provide an adjustable, resilient influence of the secondary bracket 20 against the primary bracket 15. The tensioning devices 23 and 24 can, however, be replaced by conventional tension springs.

The adjustable tensioning devices 23 and 24 are identical and comprise a yoke-shaped cutout 23a and 24a, the single end of which is rotatably attached to a mounting pin or bolt 21a and 22a to the middle portion of the bracket arms 21, respectively. 22. The other end of the adjustable spring elements 23 and 24 are mounted on adjustment screws 25, respectively. 26 and is stored in bearing ears 18 attached to the bracket plates 20a and 20b. Screws 25 and 26 are passed through nut elements 29 arranged in the yoke-shaped parts 23a and 24a of the spring assembly yokes 23 and 24. The adjustment screws 25 and 26 are provided with handles 27 and 28 to facilitate the adjustment of the screws in relation to the nut 29 to thus compress the springs 29a mounted between the nuts and the outer closed end of the yoke parts 23a and 24a.

The cable pulleys 30 and 31 are stored respectively. in the secondary bracket 20 and the primary bracket 15 by means of shafts 20f and 15f. One of the discs, e.g. disc 30, constitutes the wired depth measuring disc and is provided with a cylindrical outer surface 30a. The second disc 31 has a notched outer surface 31a and engages with the wire or sandline L at two points so as to center the line L in relation to the cylindrical surface 30a of the measuring disc or roller 30. A further guide disc identical to the disc 31 (not shown) can also be arranged on the opposite side of the measuring roller.

From the preceding description, it will be clear that the adjustable force exerted by the adjustable spring devices 23 and 24 causes the wire or sandline L to be gripped between the notched outer surface 31a of the guide disc 31 and the cylindrical surface 30a of the measuring disc 30.

The measuring disk 30 is provided with electronic means to count the number of revolutions of the measuring disk, as schematically indicated by the two circles 33 which indicate permanent magnets which are mounted in a suitable manner near the periphery of the measuring wheel 30 so as to be moved in a rotating path. A sensing coil or sensing device 35 is arranged close to the path of rotation of the magnets 33 and is of conventional construction arranged to give signals every time one of the permanent magnets 33 passes the sensing coil 35. Such signals are transmitted by means of suitable electrical conductors 35a to a conventional electrical circuitry (not shown) at ground level and comprising a logic circuit which converts the pulsating signals induced by the permanent magnets 33 into indications of the length of the wire or sand line L which has passed over the periphery of the measuring disc 30. Other conventional sensing devices, such as Hall- .

elements, can be used to register the rotation.

An important feature of the device described above is the fact that the measuring device 10 is not adversely affected by significant lateral deviation of the wire or sand line L from the vertical position. Any such lateral deviation, in any direction, will be absorbed by the flexible, laterally unbound support element 13, and thus the frictional engagement between the wire or sand line L and the cylindrical surface 30a of the measuring disc 30 will remain undisturbed. In overhaul operations, it is in fact common to mount the desired tool on the sandline L in the lock pipe assembly 3 while the lock pipe assembly is in a horizontal position on the ground, and then raise the lock pipe assembly to the vertical position shown by raising the upper end of the lock pipe assembly by means of the sand line L. This would obviously expose the measuring device 10 to significant forces and cause damage to it if it was not spring mounted by means of the laterally unobstructed flexible support element 13.

It will be apparent to those skilled in the art that the apparatus described above provides a simple, economical, yet highly reliable wireline or sandline depth measuring instrument which can be attached to any well for completion or overhaul by attaching it to the top of a sluice pipe assembly or to any another body which is placed laterally next to the wire line's L path.

The depth measurement indications are not affected by lateral deflections of the wire or the sandline in relation to the entry point in the well. Furthermore, the device can advantageously be mounted on top of any sluice pipe device and is thus ready for use without the need for the fabrication of special mounting brackets to mount the equipment on a crane boom or in a drilling rig.

Although the invention has been described in connection with a particular exemplary embodiment which is shown in detail, it will be understood that this has only been done for illustration purposes and that up-. the invention is not necessarily limited to this, since alternative embodiments and methods of use will be obvious to the person skilled in the art in light of the preceding description. For example, the described device can be used to measure the length of other tubular elements, such as coiled pipes, which can be guided down the well, in addition to measuring a sandline or wire. Furthermore, it will be understood that the device can be easily adapted to

to measure speed as well as distance when the tubular element is introduced into or withdrawn from the well. Thus, modifications can be carried out without deviating from the idea or scope of the invention.

Claims (10)

1. Device for continuous measurement of the movement of a tubular element that can be introduced into a well, comprising a main part that can be attached to a rigid structure adjacent to the path of the tubular element; a measuring roll support which at least partially encloses the tubular element and is spaced along the tubular element relative to the main body; a measuring roll which is stored in said support; resilient means which keep the periphery of the measuring roll in contact with the tubular element to rotating the measuring roll; means responsive to the rotation of the roll to indicate the movement of the tubular member passing past the measuring roll; and an elongate flexible member connecting said support to the main body to absorb lateral deviations of the tubular member relative to the rigid construction. 2. Device for continuously measuring the depth of a tool carried by a wire in a well, comprising a main part which is attachable to a rigid structure adjacent to the path of the wire; a gauge roll support which at least partially encloses the wire and is spaced along the wire relative to the main body; a measuring roller stored in the support; resilient means which keep the periphery of the measuring roll in contact with the wire to rotate the measuring roll; means responsive to the rotation of the roll to indicate the length of the wire passing the measuring roll; and an elongate flexible member connecting the support to the body to absorb lateral deviations of the wire relative to the rigid structure. 3. Device according to claim 2, characterized in that the means which react to the rotation of the measuring roller comprise at least one magnet which is mounted on the measuring roller to move in a rotating path and at least one sensing coil which is mounted on the support until the magnet's path of rotation. 4. Device according to claim 2, characterized .v .e d that the spring means which keep the periphery of the measuring roll in contact with the wire comprise at least one guide disk which is stored on the opposite side of the wire in relation to the measuring roll and adjustable spring means which force the roll and the disk into contact with the wire. 5. Device according to claim 2, characterized in that said elongated flexible element comprises a laterally unbound compression spring. 6. Device for continuously measuring the depth of a tool carried by a line in a well, comprising a main part attachable to a rigid well structure surrounding the path of the line; a first disk support bracket axially spaced from the main body; a first disc which is stored in said first disc supporting bracket and which can be brought into contact with the line; a second roller support bracket having arm portions that at least partially enclose the line and is rotatably mounted on the first sheave support bracket; a second roller which is stored in the second roller support bracket and which can be brought into contact with the line on the diametrically opposite side of the first sheave; resilient means that force the disc or the roller brackets against the line in order to maintain frictional contact between the line and the sheave or the scroll; means for counting revolutions of the sheave or roller to indicate the length of line passing the sheave and roller; and an elongated flexible member connecting the brackets to the main body to absorb lateral deviations of the line relative to the rigid well structure. 7. Device according to claim 6, characterized in that the means for counting the revolutions of the roller comprise at least one magnet which is mounted on the measuring roller and which is movable in a rotational path, and at least one sensing coil which is mounted on it respective bracket near the magnet's path of rotation. 8. Device for measuring the depth of a sandline introduced by an overhaul rig into a well through a sluice pipe device, characterized in that it comprises in combination a main element which is attachable to the top part of the sluice pipe device, a measuring disk support which is at least partially enclosing the sandline and arranged at an axial distance from the main part, a measuring disc stored in said support; resilient means which keep the periphery of the dial in contact with the sand line to rotate the dial; means responsive to the dial's rotation to indicate the length of the sandline passing the dial, and an elongate flexible member connecting the support to the main body, whereby lateral deviation of the sandline relative to the sluice tube device does not cause slippage of the sandline relative to the dial. 9. Device according to claim 8, characterized in that the means which react to the rotation of the measuring disk comprise at least one magnet which is mounted on the measuring disk for movement in a rotational path, and at least one sensing coil which is mounted on the support near the magnet's rotational path. 10. Device according to claim 8, characterized in that said spring means which keep the periphery of the measuring disk in contact with the sand line, comprise a guide disk which is stored on the opposite side of the sand line in relation to the measuring disk, and adjustable means which force the disk into contact with the sand line.