SU570702A1 - Borehole electrocontact - Google Patents

Description

one

The present invention relates to the field of field and geophysical research.

wells and their drilling technique, namely to the well wireline communication lines.

Known inductive electrocontact, containing the magnetic core, the coupling, the rod and the support, in which are placed the coupling with the rod 1.

The coupling of the specified electrical contact is made in the form of a cylindrical multi-layered roller, one end of which is connected to the cable outlet, and the other end is connected to the grounding ring and the support body. The core contains a welded magnetic core on which a multi-layer cylindrical roller is wound. One end of the coil is connected to the cable outlet, and the other is connected to the grounding ring.

The disadvantage of this electrical contact is large electrical loss and attenuation. In addition, in the case of sticking of the column, the electrocoactus prevents the tactile detection or torpedoes from descending into the coloin.

The closest technical solution to the present invention is a downhole electrical contact containing cable and instrument parts, the instrument part having a toroidal transformer with an output winding 2.

2

The magnetic cores of both parts of the contact of this electrical contact when docked form a common closed magnetic circuit. To provide a gapless connection of the detachable parts of the core, the magnetic core is made in the shape of a truncated cone, and the toroidal magnetic core has a conical groove, which, when joined, includes a core magnetic core.

The disadvantages of such an electrical contact are the complexity of its design, the presence of large electrical and hydraulic energy losses, adversely affecting its power, as well as the inability to freely descend into the column of various devices.

The purpose of the invention is to increase reliability by simplifying the electrical contact, ensuring the possibility of free descent into the column of various devices and reducing energy losses in contact resistances.

This is achieved by the fact that the cable part of the electrical contact is equipped with a permanent magnet earthing and is placed in the instrument part.

The drawing shows a downhole electrical contact containing cable 1 and instrument parts 2. The instrument part has a toroidal transformer 3 with an output winding 4. 1 abs1 to part 1 is equipped with a grounding conductor 5 with a magnetic magnet 6 and placed below the internal part 2. Electrical contact, in addition, includes a support made of outer cup 7 and inner cup 8. The upper end of the inner cup and the lower end of the outer cup are made in the form of inverse cones and form a toroidal chamber into which the transformer with the output winding 4 and filled with synthetic compound 9. The output winding is connected at one end to the hermetic connector 10, and the other to the case of the outer glass. The instrument container 11 or the next cable section is connected to the sealed connector. The upper end of the outer cup, made in the form of a cone, serves to fasten the support in the drill pipe lock 12.

Tale electric contact works as follows.

During the descent of the column into the well in the drill pipe lock 12, the electrical contact with the instrument container 11 is installed. The cable part 1 is lowered into the column until the lower end with grounding conductor 5 passes through the toroidal transformer 3 and goes below the instrument part. A coil of the input winding of the electrical contact is formed and the current passing through this coil induces a voltage in the output winding 4.

This electro contact has a relatively small hydraulic and electrical energy loss, a higher signal transfer rate n in a wider frequency range. Its efficiency reaches 40%, which is significantly higher than the well-known downhole electrical contacts.

The use of the proposed electrical contact in the downhole communication lines will significantly increase the efficiency and reliability of their work.

Claims (2)

1.Grachev Yu. V., Varlamov V. P. Automatic control in wells during drilling and operation. M., “Nedra, 1968, p. 64-67. 2. USSR author's certificate number 242084, cl. E 21B 47/10, 1969.