RU65571U1 - ANTI-EMISSION DEVICE - Google Patents

Abstract

A blowout preventer is designed to prevent the release of a research instrument lowered onto a cable by a dynamic fluid stream. The device comprises a centralizer, including a cut sleeve 1 for fastening with bolts 2 on the device body with centering rods 3 placed on it, and a braking unit, including a cut upper sleeve 4 for fastening with bolts 5 on the device case and a lower movable sleeve 6 with a movable conical mounted under it sail 9. The upper 4 and lower 6 bushings of the braking unit are connected by pivotally interacting elbows 8 and pointed rods 7, which are pierced by points into the inner surface of the pipe in case of sharp selection ca fluid from an oil or gas reservoir. The reliability of the blowout control device is increased regardless of cable stiffness.

Description

The utility model relates to the oil and gas industry and can be used when performing research in wells with devices lowered by cable to prevent the emission of devices by a dynamic fluid stream.

There are various blowout preventers used to prevent the release of devices from the well (see, for example, patent RU No. 2143556, IPC ⁶ ЕВВ 47/01; patent RU No. 2188318, IPC ⁷ Е21В 47/01; patents SU 823563, 1104251, 196686; US 4491181; patent RU No. 21617, IPC ⁷ ЕВВ 47/01).

The closest analogue of the known devices adopted for the prototype is a blowout preventer containing a mechanism that prevents the devices from being ejected by a dynamic liquid stream (see, for example, patent RU No. 2188318 of 03.10.2002, BIPM No. 24, 08/27/2002).

The disadvantage of the prototype is that the blowout mechanism is triggered by deformation of the cable when the device is thrown by a dynamic jet, but the cable is slightly deformed due to the high rigidity. Therefore, the blowout preventer does not always work.

The objective of the utility model is to eliminate this drawback of the prototype.

The technical result achieved by using the proposed utility model is to increase the reliability of the blowout device, regardless of cable stiffness.

The specified technical result is achieved in that in a blowout preventer for an oil or gas well containing a mechanism that prevents the device from being emitted by a dynamic fluid stream, according to the proposed mechanism comprises a centralizer including a cut sleeve for securing it with bolts on the device body with centering rods placed on it, and a braking unit, including a cut upper sleeve for fixing it with bolts on the device body and a lower sleeve that can be moved relative to the body of the device, while the upper and lower bushings of the braking unit are connected by articulated interacting pointed rods and elbows, and a conical sail is fixed to the lower sleeve with the possibility of movement relative to the body of the device.

The presence of a centralizer mounted on the device body allows you to center the device in the well, which increases the reliability of the blowout preventer.

The execution in the centralizer of a cut sleeve with bolts allows you to securely fasten the sleeve with bolts to the device body, completely independent of the cable stiffness.

The centering rods located on the cut sleeve provide direct centering of the device in the well.

The presence of a braking unit, fixed on the device’s body, provides braking of the device when it is ejected by a dynamic fluid stream also regardless of cable stiffness.

The fastening of the upper cut sleeve of the braking unit with bolts on the device body provides a reliable and centered arrangement of the braking unit, which increases the reliable operation of the blowout preventer regardless of cable stiffness.

The implementation of the lower sleeve of the braking unit with the ability to move relative to the centered body of the device allows the sleeve to move together with the sail under the action of a dynamic jet, which allows reliable operation of the braking unit also regardless of cable stiffness.

The connection of the upper and lower bushings by articulated interacting pointed rods and elbows ensures the deformation of the pipe walls by the pointed ends of the rods when moving the movable lower sleeve. The deformation of the pipe walls with pointed rods inhibits the movement of the rods together with the movable sleeve and even stops the movement. The ejection of the device stops. Therefore, the blowout preventer works reliably and regardless of cable stiffness. In general, the operation of the braking unit is in no way connected with the cable and its rigidity, since the braking unit together with both bushings is located on the device, and not on the cable.

The fastening of the conical sail braking unit to the lower bushing with the possibility of its movement relative to the device body together with the lower bushing ensures the transfer of the sail movement when a dynamic jet of liquid acts on it to the movable bushing, which causes the braking unit to trip with its stop after the contact of the pointed rods with the wall pipes. Since the sail is not connected to the cable, but moves together with the movable sleeve along the body of the device, the operation of the entire braking unit and centralizer does not depend on the state of the cable and its rigidity. The reliability of the blowout control device is increasing.

The proposed blowout device is shown in the drawing, which shows its side view.

The blowout preventer comprises: a centralizer fixed to the device body and consisting of a cut sleeve 1 with bolts 2, on which centering rods 3 are fixed; a braking unit fixed to the device body and consisting of a cut upper sleeve 4 with bolts 5 and a lower sleeve 6, which is movable relative to the device body, while the upper 4 and lower 6 bushings are connected by pivotally pointed rods 7 and elbows 8 interacting with each other, and a conical sail 9 is fixed to the lower sleeve 6 with the possibility of movement relative to the device body.

The specified blowout device operates as follows.

The cut bushings 1, 4, the movable bush 6 and the conical sail 9 are put on the device body and the cut bushings 1 and 4 are fixed with bolts 2 and 5. The centralizer and the anti-blowout braking unit are fixed on the device case.

After that, the device is fixed on the cable and lowered into the well together with a blowout preventer attached to the device.

During the descent, the total mass of the conical sail 9, the movable sleeve 6, the pointed rods 7 and the knees 8 moves these parts down along the body of the device. As a result, the pointed rods 7 are folded along the body of the device and do not interfere with its descent into the well.

In the case of a sharp ejection of fluid from an oil or gas reservoir, a dynamic fluid jet moving up the borehole acts on the lower bushing 6 through the conical surface of the sail 9. Since the sail 9 is connected to the movable bushing 6, they jointly move upward along the body of the device. Since the elbow 8 is pivotally connected with the upper part of the cut sleeve 4, which is rigidly fixed to the device body, when moving the lower sleeve 6, the pointed rod 7, turning around the hinges, is pierced by a point into the inner surface of the pipe installed in the well. The braking unit stops, the sleeve 4 holds the device with a cable on which the device is fixed. An accident does not occur with the device or with the cable, regardless of the cable stiffness.

When the fluid pressure in the borehole is equalized, the conical sail 9 with the movable sleeve 6, the pointed rod 7 and the elbow 8 return down along the body of the device, turning in hinges. The pointed rod 7 again disengages from

the inner surface of the pipe, and the device can be moved up and down until the next unexpected release of fluid.

In the process of fluid discharge, the centralizer, consisting of parts 1, 2, 3, does not allow the device and the braking unit to warp in the well, which ensures reliable operation of the braking unit. If the braking unit is skewed, there would be a possibility of unreliable fastening of the skewed rods to the inner surface of the pipe.

When lifting the device and blowout preventer up after the completion of the research in the well, the pointed rods 7 folded along the body of the device do not interfere with this movement.

This ensures reliable operation of a blowout preventer regardless of cable stiffness.

Therefore, the technical result is achieved.

Claims (1)

An anti-blowout device for an oil or gas well containing a mechanism that prevents the device from being emitted by a dynamic fluid jet, characterized in that the mechanism comprises a centralizer including a cut sleeve for bolting to the device body with centering rods placed on it, and a braking unit including a cut upper sleeve for bolting to the device body and the lower sleeve, mounted with the possibility of movement relative to the device body, while the upper and lower ki braking assembly connected pivotally cooperating spikes and bends, and a lower sleeve secured to move relative to the housing of the device the conical sail.