RU2086753C1 - Device for cleaning wells by implosive method - Google Patents

Abstract

FIELD: oil and gas production industry. SUBSTANCE: device has implosion chamber 1 which is provided with geophysical head-piece 3 for connection to logging cable, load bar 6 suspended from upper part of chamber by destructible member 5. Also provided is stepped rod 7 located in lower part of chamber and centered by yoke. Located in sleeve 12 are cams 1. Stepped rod 7 is connected with centering bush 10 for possible closing of cams 11 in transport position, and at interaction with load bar 6 it releases sleeve 12 from engagement with adapter 13. Stepped bar 7 is connected with centering bush 10 by means of shear pins 9. Device is highly reliable in operation. EFFECT: high efficiency. 1 cl, 1 dwg

Description

 The invention relates to the oil and gas industry, namely, to devices for cleaning boreholes.

A device is known for processing the bottom-hole zone by implosion, including a metal casing with bleed holes, a replaceable fitting and a glass stopper. The device descends on a logging cable, an explosion using a detonator destroys a glass plug, after which the implosion chamber is filled [1]
It is also known a device for increasing the productivity of the formation by the implosion method, containing an implosion chamber with a geophysical headgear and an opening in the lower part closed by a destructible cover, an electric detonator, a damper with an opening installed in the housing above the electric detonator and dividing its cavity into separate chambers [2]
A common disadvantage of these devices is their low reliability, since water hammers or errors in the choice of explosives can lead to the destruction of the device. In addition, work with explosives is undesirable from the point of view of the safety of work.

The closest to the proposed technical essence and the achieved result is a device for cleaning wells from sand plugs, including a wellhead with channels and an internal protrusion, a housing with a check valve and radial channels and an axially movable shoe. The device descends on a logging cable. During descent, atmospheric pressure is maintained in the device casing. Upon reaching the bottom due to the interaction of the device with the bottom of the well, the shoe moves in the axial direction and the body is filled with sand. The check valve of the device is adjusted so that during the lifting of the device, excess pressure is maintained in it, which contributes to the quick emptying of the device on the surface [3]
The specified device also has low reliability due to the complexity of the design of the implosion chamber and the need to configure the non-return valve on the surface prior to the descent of the device.

 The problem to which the invention is directed, is to increase the reliability of the device.

 To solve this problem in a known device for cleaning wells by the implosion method, including an implosion chamber, the implosion chamber is equipped with a geophysical headgear for attachment to the logging cable, a weight rod suspended in the upper part of the chamber on a destructible element, a stepped rod located in the lower part of the chamber and centered by a bracket , glass, cams located in the glass, sub and centering sleeve, while the stepped rod is connected to the centering sleeve with the possibility of overlapping cams in the transport position and interaction with the weight bar to release the glass from engagement with the sub.

 In addition, the stepped rod is connected to the centering sleeve using shear pins.

 The drawing shows a diagram of the proposed device.

 The device consists of an implosion chamber 1, which is one or more, depending on the required volume, hermetically connected pipes. The implosion chamber through an electronic unit 2 and a geophysical headgear 3 is attached to a wireline cable (not shown). The electronic unit 2, in which the measuring sensors 4 are located, ensures the transmission of the received information via a wireline cable to the surface. This allows you to obtain operational information about the change in pressure inside the implosion chamber.

 In the upper part of the implosion chamber, for example, on a kapron filament 5 connected to a tungsten spiral, a weight bar 6 is suspended.

 In the lower part of the implosion chamber there is a stepped rod 7, centered by a bracket 8 and connected, for example, by means of a shear pin 9 with a centering sleeve 10. The lower step part of the rod 7 in the transport position overlaps the cams 11 located in the glass 12. The chamfered ends of the cams are located in the groove of the sub 13. Thus, the stepped rod 7 is connected to the centering sleeve 10 with the possibility of overlapping cams in the transport position and interacting with the weight rod to release the cup from engagement with sub 13. Bottom sub fastened nozzle providing the required direction of depression pin (not shown). The implosion chamber is equipped with valves for bleeding the air in the chamber at the time of its opening and the excess fluid pressure after lifting the chamber at the wellhead (not shown).

 The operation of the proposed device is as follows.

 The device in assembled form (as shown in the drawing) is lowered on the wireline into the well to the required depth (processing interval). Further, the required current (2-3 A) is supplied from the ground panel through a cable and a current-carrying core. As a result of heating the spiral and combustion of the kapron filament 5, the weight rod 6 is released, which falls down the implosion chamber and hits the stepped rod 7. In this case, the pin 9 is cut off and the rod 7 moves down the glass 12, releasing the cams 11. Under pressure from below, the cams 11 they move inside the glass 12, freeing it from engagement with the sub 13. The glass 12 together with the rod 7 moves upward, opening the implosion chamber 1. After opening the implosion chamber, the borehole and formation fluid rushes into the hollow th body of the implosion chamber, where the pressure is atmospheric. The formation is being cleaned. The sludge settles in the sump of the well. Monitoring this process with the help of measuring sensors is performed by changing the pressure in the implosion chamber.

 After equalizing the pressure in the implosion chamber, the glass 12 occupies the same or close position, reliably preventing the fluid from leaving the implosion chamber. The device rises to the surface.

 When lifting, they monitor the readings of pressure sensors inside the implosion chamber; if there is excessive pressure, it must be vented. On the surface, the device is dismantled.

Claims (2)

 1. Device for cleaning wells by the implosion method, comprising an implosion chamber, characterized in that the implosion chamber is equipped with a geophysical headgear for attachment to the logging cable, a weight rod suspended in the upper part of the chamber on a destructible element, a stepped rod located in the lower part of the chamber and a centered bracket , glass, cams located in the glass, sub and centering sleeve, while the stepped rod is connected to the centering sleeve with the possibility of overlapping cams in transport position and interaction with the weight bar to release the glass from engagement with the sub.  2. The device according to claim 1, characterized in that the stepped rod is connected to the centering sleeve using shear pins.