SU1469106A1 - Device for measuring the resistance to cable progress in a well - Google Patents

Abstract

This invention relates to modeling the movement of a cable in a well-t nah. The goal is to improve the accuracy due to the interval determination of resistance forces. The device contains a simulator 5 wells, made in the form of an elastically deformed pipe 6. In the latter there is a cable simulator with a load 13. The simulator cable connects

Description

one

The invention relates to a technique for modeling the movement of extended flexible elements in mines and wells, and can be used to study the resulting resistance forces, in particular, to determine the resistance forces when a geophysical cable is moved in oil and gas wells to determine possible cable deformations. .

The purpose of the invention is to improve the accuracy due to the interval determination of the resistance force.

FIG. 1 shows the device a general view; in fig. 2 — well simulator design; on; FIG. 3 - construction of the recording unit.

The device comprises a panel 1, on which a trip unit is mounted, an onset drum 2 and an actuator. To panel 1, a simulator 5 of a borehole, made in the form of an elastically deformed pipe 6 with pressed-in current-carrying rings 7, is attached with brackets 4. 6 is non-metallic (although this is not necessary), additional means for isolating the rings 7 are not required. Elastic deformable pipe 6 is made of a set of individual tubes 8, installed one into another, for which a protruding element a is made in each of the tubes 8 at one end and the other end at the other end b. Inside the pipe 8 rings 7 are pressed.

The protruding element in the rings 7 is used to solder the wires. Profile formation is carried out using stops 9-11, reproducing different radii of curvature of the wells (K, and R) at a certain scale. Inside the pipe 6 there is a cable simulator, made in the form of high-resistance wire 12 (nichrome, constantan). One end of the wire is wound on the drum 2, and a load 13 is imitated on the other end, simulating the weight of the downhole tool. The recording unit contains a switch 14 with terminals 15 and a contact

16. Each of the current-carrying rings 7-rings K ... K (connected to the input terminals 1 5 of the switch 14. Rotating, contact 16 alternately connects terminals 14 - K-tC K, Kj, etc. Terminals K - K are connected to the recorder inputs with carrier 17 (for example, a light beam logging oscilloscope HO-28), in which the resistance of wire sections 12 in contact with the rings 7 is recorded. The resistances of various cable sections are recorded on the carrier 17 channels K. , K.,

TO

The device works in the following way.

Reproduce a certain scale (usually 1: 1000 or 1: 750) 35 well profile, for which purpose the pipe 6 is bent at the required angles and radii by means of stops 9-11.

five

thirty

Then the pipe 6 is fixed with brackets 4. As wire 12, PENH grade nichrome wire with a diameter of 0.10-0.015 mm is used. Having suspended the load 13 to the free end of the wire, the drive 3 carries it down into the tube 6.

As it comes into contact with the rings 7 of the tube 6, certain channels of the oscilloscope can register changes in the resistance of different portions of the wire 12 (a pattern of changes in the resistance of the wire 12 during descent is recorded). For example, for the case depicted in FIG. 1, to fix the change in resistance will be terminals Ks-K, K5 - K, K.-K.z K ,,,. I, f, -i К.,, К j ,, -К.

Producing the device, the diagram of the resistance of different sections of the cable is also recorded. Since the change in wire resistance 1 2 is directly proportional to the applied load, i.e.

LC K-DR, (1) and considering that

RGR + FC

(2) (3)

Fr

P6A CnVCR

(four)

F B - 2K.

(I

0

five

five

0

0

where LK is the difference in resistance of olio names} {of the aropopoki sites, 12 when lifting and with a bar.

Since the speed of descent and ascent of the wire is the same in the limits of one descent-lifting operation, the overlap of the diagram of resistance change during ascent and descent determines the value of dR, which is related to FC by formula (5).

Changing the profile model configuration, reproducing the different values of each of its components (curvature radii, lengths of the horizontal and vertical sections), determine the patterns of change in resistance to movement of the wire 1 2 in the pipe 6.

Claims (1)

Invention Formula A device for determining the resistance to movement of a cable in a borehole, which contains a well simulator, made in the form of an elastically deformed tube: inside which is a cable simulator with a load connected to the trip unit, force sensors connected to the recording unit, characterized by which, in order to increase 35 where f Accuracy due to the interval determination of the resistance forces, the force sensors are made in the form of electrically insulated conductive load cells 13 and sigilts installed in the well simulator, arranged with resistance, interacting with the cable simulator, determine the resistance force wires to high wire 12 in pipe 6: electric resistance. -R and FC, respectively, tension force of wire 12 during descent and ascent. FIG. 2 / V 15 K1-2 K2-3 5 WW-; KL, I Kn, P ; fig.Z I 17