SU1628031A1 - Borehole seismic instrument - Google Patents

Abstract

The invention relates to well seismic exploration. The aim of the invention is to improve the reliability of the device. The power pistons 8 and 9 and the rods 10 and 11 are made of different diameters and are installed one inside the other. In this case, the interaction of the short arms of the levers 12 occurs with the help of crackers on a large area, which increases the wear resistance and reliability of the assembly. 2 Il. Ј O N) 00 o so / 4

Description

The invention relates to borehole seismic exploration.

The purpose of the invention is to increase the reliability of the device.

FIG. 1 schematically shows a downhole seismic instrument; in fig. 2 shows section A-A in FIG. one.

The device includes a housing 1, an electric motor 2, a gearbox 3, a spindle 4, a main piston 5, hydraulic cylinders 6 and 7, power pistons 8 and 9, rods 10 and 11, clamping levers 12 and 13, a container with seismic receivers 14.

The power pistons 8 and 9 are connected to the main piston 5 by means of t g 15 and 16 with the possibility of their independent movement of one another. To do this, inside the power piston 8, a cavity 17 1 is provided, equal to the stroke of the rod 10 (with maximum opening of the pressure lever 12). In this case, a collar of 18 tons of gi 15 rests on the protrusion of the power piston 8. Inside the g of 15 there is another cavity 19 with the same depth. Burt 20 ti gi 16 rests on protrusions gi 15. The entire hydraulic system is filled with a working fluid, such as oil. Axes 21 and 22 of the clamping levers are located in the same plane at an angle of 90 ° to each other. The short arms 23 and 24 of the levers interact with their rods through crackers 25 and 26. The cylindrical parts of which are installed in the holes on the ends of the short arms of the levers, and the prismatic parts in the grooves of the rods 10 and 11. The grooves are located in the same plane. A window 27, made in stem Yu, allows the cracker 26 to interact with the rod 11 and allows the rods 10 and 11 to move independently with respect to each other. To realize independent displacement of the rods, the window is made of a length, graphed double value of the stroke of the rod.

The device works as follows.

The torque from the electric motor 2 is transmitted through the gearbox 3 to the spindle 4. The screw rotates, unscrews (screwed in) from the main piston 5. As the spindle 4 rotates, the main piston 5 moves downwards and through the working fluid presses on the power pistons 8 and 9, which move and act on the rods 10 and 11. The rods 10 and 11 through the crackers 25 and 26 open the levers 12 and 13, which press the device against the borehole wall. Primary parts of the crackers 25 and 26 interact with the rods of the side planes, 1 cylindrical parts with the short arms 23 and 24 of the levers. When the levers are opened, the prismatic parts of the crackers move along the grooves of the rods.

The short arms 23 and 24 of the levers while rotating around their axes 21 and 22 simultaneously rotate relative to the cylindrical part of the crackers 25 and 26. When investigating open hole wells, such a situation may arise when one of the levers, such as the pressure lever 12, touches the borehole wall, and the pressure lever 13 will appear in the cavern. In this case, the power piston 8 will stop, and the main piston 5 and the power piston 9 will continue to move. Burt 18 will move away from the protrusion of the piston 8 and the tons of 15 will enter the cavity 17. When the lever 13 touches the cavernous wall (i.e. selects this gap), then under pressure of the main piston 5 and the power pistons 8 and 9 the clamping levers 12 and 13 press the device against the borehole wall.

If the clamping lever 12 is in the cavity, the power piston 9 will stop. And the main piston 5 and the power piston 8 will continue to move. In this case, the collar 20 will move away from the protrusion of the cable 15. 15. The hectare 16 will enter the cavity of the cable 15.

When the electric motor is reversed, the main piston 5 begins to move in the opposite direction, and a tight 15 moves the power pistons 8 and 9 to the initial position. Hard seismic device clamping to the borehole wall is always provided at a minimum of three points: two points give the ends of the long arms of the pressure levers 12 and 13, and the third - forming the outer surface of the housing 1 located between the pressure levers 12 and 13 on the diametrically opposite side. In this case, an angle equal to or less than 90 ° between the clamping levers 12 and 13 provides the greatest stability of the system in the horizontal plane, which prevents the occurrence of parasitic rotational oscillations of this mechanical system.

The application of the invention allows to increase the reliability of the seismic instrument and to obtain high-quality results when performing work on high-resolution borehole seismic prospecting with three-component observations.

Claims (1)

Invention Formula A downhole seismic instrument comprising a sealed housing, a container with seismic receivers located therein, an actuator and a main piston associated with it, interacting with the power pistons located along the instrument axis, and two clamping levers mounted on the rods, characterized in that the purpose of improving the reliability of its work, white pistons and pinch rods the levers are made of different diameters and are installed one inside the other, while the rods are connected to the small arms of the clamping levers by means of crackers, the prismatic parts of which are installed in the grooves of the rods made in the same plane, and the cylindrical parts are installed in the holes at the ends of the small arms of the levers, and to enable the small arm of the lever to interact with the internal rod in the main shaft, a window is made on the side of this lever. Aa 26 FIG. 2