NO325584B1 - Method for closing a sub-channel against the flow of particulate matter - Google Patents

Abstract

Method and device for closing a subterranean channel (8) against the flow of particulate or settable material, wherein a plug (1), which is formed in an elastic material (2) with open pores (4) and openings (4) with a dimension which passes through fluid, but which retains the particulate or settable material, is placed in the channel (8).

Description

PROCEDURE AND DEVICE FOR CLOSING AN UNDERGROUND CHANNEL AGAINST THE FLOW OF PARTICULAR MATERIAL

This invention relates to a method for closing an underground channel against the flow of particulate material. More specifically, it concerns a method for closing an underground channel against the flow of particulate or settleable material where a plug, which is designed in an elastic material with open pores and openings of a design that lets fluid through, but which holds the particulate or putable material back, is placed in the channel. The invention also includes a device for carrying out the method.

In this context, channel means elongated openings such as, for example, a borehole, a pipe run or an annulus.

During some work operations in the ground, typically as is known from petroleum extraction, it is desirable or necessary to be able to shut off a channel permanently or temporarily.

Cementing a part of a channel is a typical example of such a work operation. If the channel is not closed, the cement, due to the different density compared to the fluid located at the cementing site, can sink down into the channel and also mix with the aforementioned fluid. This creates uncertainty as to whether a cementing operation has been successful.

It is thus common to place a plug in the channel at the cementing site to ensure that the cement remains in the part of the channel where it is intended to be.

Plugs according to known technology usually consist of relatively complicated mechanical devices which are designed to be able to provide a relatively large degree of expansion. Plugs of this type are typically made of metal and rubber. Most often, plugs are set according to known techniques using a setting tool in a separate setting operation.

Use of plugs according to known technology is thus relatively time-consuming and therefore expensive. Due to the plug's construction, where metals make up a significant part, it can be complicated to remove the plug after the cementing operation has been carried out.

A new plug construction is described in WO-document 2005/- 116394. The document deals with a plug which, in a compressed state, is designed to be placed in an area with excess pressure, and where the plug expands by filling cavities in the plug material with fluid. However, the plug according to WO 2005/116394 is not designed to allow fluid to pass through.

The purpose of the invention is to remedy or reduce at least one of the disadvantages of known technology.

The purpose is achieved according to the invention by the features indicated in the description below and in the subsequent patent claims.

A method in accordance with the invention for closing off an underground channel against the flow of particulate or settleable material is characterized by a plug, which is designed in an elastic material with open pores and openings of a design that lets fluid through, but which holds the particulate or putable material back,

placed in the channel.

Pressure differences across the plug are equalized by allowing fluid to flow through the plug material.

The plug can be compressed before it is placed in the channel, after which the plug, after it has been placed in the channel, is released for expansion, the open pores being filled with fluid. For transport down the channel, the plug can, for example, be pumped down via a pipe. The plug can then be compressed or it can rest against the pipe wall during the pumping down operation, for example from the surface. The plug may possibly be in a container from which it is displaced at the point of use; or it can be held in a compressed state by an enclosure that breaks at the mounting location. The enclosure can be broken mechanically, electrically or chemically.

The plug can advantageously be placed in a so-called "cement dump bailer" where it forms a sealing plug in the bailer that holds the cement in the bailer until the bailer is positioned at the cementing site. The plug is then moved out of the bailer and seals the channel by means of expansion.

The pores in the elastic material usually form both cavities that are filled with fluid when the plug expands, and openings through which fluid flows to achieve pressure equalization. The elastic material can advantageously consist of foam rubber or compressible composite material with open pores.

The pores are designed by, for example, appropriate dimensioning, so that particulate material above a certain predetermined size cannot pass into or through the pores.

The pores can be designed to allow one fluid to pass, but hold back another fluid, for example due to capillary forces or the fluid's viscosity. This solution can be appropriate for facilitating the setting of, for example, polymeric gelable materials, epoxies or other liquid-based setable materials.

The plug is particularly suitable for use during casting operations where cement is filled above the plug and where it prevents the cement from flowing down into the channel. The plug is also suitable for keeping gravel separate from other material, for example during fracturing work.

The plug's cross-sectional dimension before it is compressed is typically somewhat larger than the channel's cross-section. When the plug expands, it will thereby exert a certain bias against the channel wall.

In one embodiment, the plug in one part can be assigned a cross-section that fills the channel, while in another part it is assigned a dimension that does not fill the channel. If the annular space around the plug is filled with cement, an annular cement plug will form when the cement hardens.

It can also be advantageous to filter, for example, part of the fluid away from a casting compound through the plug in order to achieve a faster hardening of the casting compound.

Compared to the use of plugs according to known technology, the invention provides a significant simplification of, for example, the setting of a plug during casting work. The plug according to the invention can be easily removed either mechanically or with the help of chemical substances.

In what follows, an example of a preferred method and embodiment is described which is visualized in the accompanying drawings, where: Fig. 1 schematically shows a borehole where a plug according to the invention is being displaced out of a pipe; Fig. 2 shows schematically and on a significantly larger scale a section of the elastic material in fig. 1; Fig. 3 schematically shows a plug which is being pushed out of a container and into an annulus; and Fig. 4 schematically shows a borehole where a plug in an alternative embodiment is set in the borehole and where cement is placed surrounding the upper part of the plug.

In the drawings, the reference number 1 denotes a plug which is formed in an elastic material 2, the material 2 being provided with open pores 4, see fig. 2. In this preferred embodiment, the elastic material 2 is made of foam rubber.

As mentioned in the general part of the description, the pores 4 in the elastic material 2 usually constitute both cavities that are filled with fluid when the plug 1 expands, and openings 4 through which fluid flows to achieve pressure equalization. The functions can, if the conditions dictate, be taken care of by differently shaped pores 4 and openings 4. It should be noted that the same reference number 4 is used for both pores and openings since they normally consist of the same pores.

The plug 1 is in fig. 1 shown during extension from a pipe 6 into an underground borehole 8. The borehole 8 forms a typical channel. The plug 1 is compressed before it was placed in the pipe 6 or while it is placed in the pipe 6, and expands as it leaves the pipe 6, as the plug 1 seeks to assume its original shape. The plug 1 thereby expands towards the borehole 8. During the expansion, the pores 4 are filled with fluid from the surroundings.

The plug 1 may have been placed in the end part of the pipe 6 before the pipe 6 was moved into the borehole 8. Alternatively, the plug 1 may have been pumped down through the pipe 6, for example by means of a cementing compound 10.

During and after the expansion has taken place, any pressure difference across the plug 1 will be equalized by fluid flowing through the pores 4 of the plug 1.

After the plug 1 has expanded, casting compound is placed in the area above the plug 1, as casting compound can only flow into the plug 1 to a negligible extent.

In fig. 3 shows a plug 1 as it is displaced from a container 12 into an annular space 14 by means of an actuator 16 which displaces an annular piston 18. The plug 1 can thus seal an annular space between the borehole 8 or a not shown casing and the pipe 6.

In an alternative embodiment, see fig. 4, the plug 1 at a lower first part 20 is designed with a cross-section that fills the borehole 8, while the plug at its upper second part 22 is assigned a cross-section that does not fill the borehole 8.

An annular space 24 between the plug 1 and the borehole 8 is filled with cementing compound 10. When the cementing compound 10 hardens, it forms an annular plug.

Claims (7)

1. Method for closing off an underground channel (8) against the flow of particulate or settleable material, characterized in that a plug (1), which is designed in an elastic material (2) with open pores (4) and openings (4) of a design which lets fluid through, but which retains the particulate or settleable material, is placed in the channel (8). 2. Method according to claim 1, characterized in that the plug (1) is compressed before it is placed in the channel (8) and where the plug (1), after it has been placed in the channel (8), is released for expansion as the open pores (4) is filled with fluid. 3. Method according to claim 1, characterized in that particulate material is placed over the plug (1). 4. Method according to claim 1, characterized in that hardenable particulate material is placed over the plug (1). 5. Device with a plug (1) for shutting off an underground channel (8) against the flow of particulate or settleable material, characterized in that the plug (1) is designed in an elastic material (2) with open pores (4) and where the plug (1) also includes openings (4) with a design which allows fluid to pass through, but which retains the particulate or settleable material. 6. Device according to claim 5, characterized in that the openings (4) of the plug (1) are designed to allow one fluid to pass through, but to retain another fluid. 7. Device according to claim 5, characterized in that the plug (1) in a first part (20) is assigned a dimension that fills the channel (8), while in a second part (22) it is assigned a dimension that does not fill the channel (8) .