SU794182A1 - Device for eliminating emergencies associated with drill pipes - Google Patents

Description

the conical surface of the sub 5, fixed to the body of the downhole motor 4. On the shaft of the downhole motor is mounted a bm; at the lower end of which is mounted tip 7 having an internal conical surface, the conicity of which is less than the conicity of the interacting surfaces of the casing 1 and the sub 5. -The place of contact of the casing and The sub is sealed with a seal 9.

The casing through the adapter 2 is connected to the drill string.

The device works as follows.

Before the device is lowered into the squall, the Inu take over its downhole motor (turbo-drill) 4 in order to give its shaft left rotation. This is achieved by mounting the stator-rotor hub assembly with left rotation.

The housing is assembled with an energy storage system, and the downhole motor-flywheel is produced in a dynamic mode, so that upon impact contact of the surfaces of the housing and the sub 5, a connection is obtained, the uncoupling force of which is a multiple of the weight of the energy storage system.

In assembled form, the device is lowered into the well on conventional drill pipes with the right thread. The descent is stopped 2–3 m from the pipe string remaining in the well.

Then, normal circulation is restored in the well and the barrel is washed for 1-1.5 cycles. After washing, the circulation in the well stops the tool with the entire rotor rotating the rotor, but with the bobur stopped, it is lowered all the way down to accurately determine the mark on which the head of the stuck column is located and introduce it into the cavity of the guide 3 of the device. After determining the position of the head, the tool is raised so that the guide 3 enters the pipe to be caught, and there is some distance between its end and tip 7.

This is the starting position to start unscrewing the tubing to the left.

Then the pumps are turned on for the forced mode and the flywheel 6 is accelerated with the maximum possible speed, after which the untwisted mass is sharply fed down to the impact contact of the tip 7 with the head of the emergency pipe string. When connecting the cylindrical surface of the emergency pipe with the conical surface of the tip 7, a frictional force arises, which increases due to the initial impact connection of the conical surfaces of the casing 1 and the sub 5 when the device is assembled on

surface. When the tip 7 is in contact with the head of the stuck part of the pipes, which occurs with the axial movement of the device, the conical surfaces of the casing and the sub are in contact, due to the fact that their conicity is greater than the internal surface taper of the tip 7. When the casing of the downhole motor is disconnected from the column above

pipes, the upper pipes are completely isolated from torsional loads. The accumulated potential energy of the flywheel 6 is converted completely into kinetic energy in the form of a tangential impact with excitation of a shock wave in the emergency string of tubes, which reduces the sticking force and weakens the threaded connection to which the flywheel torque is simultaneously applied.

If the complete separation of the column does not occur, the casing is tensioned and introduced into the connection (contact) with the conical surface of the sub 5. This allows the left-hand torque to be transmitted.

moment of the turbodrill for a significantly relaxed connection, completely unscrew it and remove the turned part of the pipe string from the well.

Using an emergency response device eliminates the need for left-handed drillstring sets of pipes, significantly reduces the time required to turn the pipes on to the left and significantly improves work efficiency.

Claims (2)

1. Berkovich M. Ya. And others. “Prevention and liquidation of accidents in the drilling of wells. M., Gostoptekhizdat, 1960, p. 98-100. 2. John R. A. “Turboburs with an inclined pressure line, VNYIBT works, issue XXII, 1969, p. 84-85 (prototype).