FI57823C - ANORDNING FOER BORRHAOL - Google Patents

Description

RjSCT ΓΒ1 «« ADVERTISING PUBLICATION γπλλ 7 J »A LBJ (11) utlAggningsskiuft 5 7823 C Fatentti oy'inn2ti.y 10 10 1930

Patent i-eddelat (51) KwJk? YtafcCt3 E 21 B 33/14

FINLAND — FINLAND (21) -Nt «wm» afataf 2380 / 7U

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USA (US) 51888U

(71) (72) Solis Myron Zandmer, 111, Glen Avenue, Banff, Alberta, Canada (CA) (7U) Oy Jalo Ant-Vuorinen Ab (5U) Equipment used in a borehole - Anordning för borrhäl (62) Divided by application 830 / 66 (Patent U987I) -Avdelad fr & n trap 830/66 (Patent U9871) in addition, a safety cover with a valve with a body part made of acid-resistant metal and a center part made of acid-soluble metal is placed at the end of the tubular device closest to the housing.

Hitherto, borehole housings have been placed in boreholes by cementing, with the cement slurry being led down through the housing and then upwards along its outer surface so as to fill the annular space between the outer surface of the housing and the shaft wall. Once the cement has hardened, the connection between the housing and the producing zone is established by tearing the housing by blasting, e.g. with ammunition or suitably shaped cartridges, which also pierce the hardened cement and thus form channels through it. This procedure is unsatisfactory because the munitions or cartridges tend to break around the cement channels and thus provide vertical passageways, which in turn cause up and down movement from one hole to another. This in turn makes it impossible for the treatment to optionally be performed through each pipe separately, as the injected treatment agent passes cracked through the cement up or down without selectively observing the injected points, i.e. the gap layer at the end of each pipe.

Recently, it has been proposed to use an improved method and apparatus for providing a passageway between a housing and a producing layer. According to this proposal, a number of tubular devices are welded or otherwise attached to the outer surface of the housing at the openings made in the wall of the housing. These tubular devices have telescopic tubes or sleeves that are pulled inward when the housing is inserted into the borehole. When contact with the generating zone is to be made, these telescopic tubes are caused to protrude substantially horizontally towards the wall of the shaft so as to provide contact with the generating zone and a permanent connection between this and the housing. The cement slurry is introduced into the space between the housing and the shaft wall either before the telescopic tubes are pushed out or after pushing so that the cement settles around the tubes and the housing. The telescopic tubes of the tubular devices are made of steel or similar acid-resistant metal, and the upper ends of the tubes which come into contact with the producing zone are closed by acid-soluble metal plugs sealingly placed inside the tube so as to transiently prevent the substance from passing through the tube. When it is desired to establish a connection between the producing zone and the interior of the housing, acid is introduced into the housing and into the side-facing tubes to dissolve the plugs.

In previously proposed borehole devices, the tubular devices are welded or otherwise attached to the outer surface of the housing at the openings made in the wall of the housing. When contact with the generating zone is to be made, the telescopic tubes are pushed back from the retracted position away from the housing towards the shaft wall. This is accomplished by applying pressure inside the housing. In practice, it has been found that either due to a malfunction or other error, e.g. improper installation of the tubular device, some pipes may prematurely move towards a productive zone, resulting in a free connection between the interior of the housing and the space surrounding the housing. To prevent this, it has already been proposed to use a safety cover at the end of the tubular device closest to the housing. However, these 3 57823 safety covers are defective in so far as, when completely or partially dissolved, they provide a permanent connection between the tubular device and the housing, which can no longer be closed even if this becomes necessary for one reason or another. The construction of some known safety covers is also such that the opening formed after the cover has dissolved is so wide that detached parts in the tubular device, such as broken telescopic tubes, can penetrate through the tube into the housing when there is no pressure in the housing.

The device for use in a borehole according to the invention is then characterized in that the acid-resistant body part has a flange part with internal threads, to which the end part with external threads of the tubular device can be rotated to attach the safety cover to the end part.

When the housing with the pipe-forming devices is placed in the borehole, and when the pipes are pushed towards the producing zone, the safety cover is partially corroded by the acid so that flow can take place mainly unobstructed through the pipes in both directions. The safety cover is screwed to the rear end of the tubular device approximately at the level of the inner surface of the housing and at the corresponding opening in the housing. The lid, preferably in the middle thereof, has a narrow channel in which a non-return valve is placed on the lid so that flow can take place from inside the housing to the tubular device, while preventing flow from the device through the channel into the housing. The non-return valve is preferably a ball valve. The valve-controlled passage is located in the acid-soluble central portion, and when the telescopic tubes are pushed outward to their working position by the pressure inside the housing, the medium flows through the inner narrow passage and causes the tube to migrate to dissolve and disintegrate the central portion. The housing can be pressurized with a liquid containing a weak acid. The weak acid requires a relatively long time to dissolve the center section and its valve, so enough time is available to push the telescopic tubes out into the correct position. The dissolution of the middle part with acid is, of course, facilitated by the channel made in it, since this increases the surface area which can be affected by the acid. When the inner part, as well as the channel controlled by the “57823 valve”, is etched with acid, a substantially free connection is established between the inner part of the housing and the tubular device, since the remaining part of the cover restricts the relatively wide channel.

According to a preferred structure of the invention, the acid-soluble inner part has an inwardly conical surface against which a corresponding surface in the acid-resistant part of the safety cover rests. After the acid-soluble inner part has dissolved, an acid-resistant lid part remains, which delimits a channel having an inner diameter corresponding to the diameter of the soluble inner part and having a conical seat surface. If, for any reason, this expanded channel has to be closed during use, the ball seal can be floated down and supported by the liquid in the housing, made of a seal against this conical surface. However, the diameter of the channel formed after the acid-soluble inner part, and thus also the inner part, must be smaller than the diameter of the telescopic tubes, so that the tubes cannot move inside the housing if for some reason they become detached from their retaining members.

To illustrate the invention, reference is made to the accompanying drawing, which shows a preferred structure according to the invention.

In the drawing, Fig. 1 shows a side view of a double-hole housing with a tubular device attached to its outer surface, comprising an end tube or a sleeve closed by an acid-soluble metal screw plug. For the sake of clarity, those parts and members of the pipe forming device which are not the subject of the invention are not shown. Figure 2 shows on an enlarged scale a section along the line 5-5 in Figure 1. Figure 3 is a section along the line 2 of the back cover 6-6 of Figure 4 and Figure 2 an end view in the direction of arrow B.

As can be seen in particular from Figures 1 and 2, the tubular device, indicated as a whole by the number 100, is fixed to the outer surface of the borehole housing 10. For this purpose, the borehole housing 10, into which the opening 99 is machined, is provided with a nipple or mounting piece 98 welded to the outer surface of the housing at 97. The tubular device 100 has a hollow, cylindrical rear mounting portion 96 with external threads 95 corresponding to the nipple 9. 8 internal threads 9 * + - Part 98 of the tubular device 100 terminates in a flange or collar 93 which fits into a ring space 92 delimited by a shoulder 91 formed by a nipple 98. A sealing member such as an O-ring 66, 57823 can be placed between the collar 92 and the shoulder surface 91 that the tube-forming device becomes sealed with respect to the nipple 98. For this purpose, the collar 93 has an annular groove 89, as shown in Figure 2. The general structure of the pipe forming device is not shown,

The tubular device 100 is directed directly laterally out of the housing 10 and has an internally threaded end sleeve 13 to which a screw plug 50 is screwed. The screw plug 50 is shown in Figure 1 in a position where it is not completely screwed into the tube 13.

It can be seen from Figures 2 to 12 that a hollow mounting portion 96 threaded at the rear and threaded into the nipple 98 is associated with an externally threaded end portion 85. This portion 85 extends into an opening 99 in the housing wall 10. According to the invention, the security cover 80 has internal threads 79 in the collar portion 49. correspond to the external threads 78 in the end portion 85. The safety cover 80 can thus be screwed onto and removed from the end portion 85 if desired. In Figures 2 and 3, the lid is shown in the operating position in which it is screwed to the end portion 85. The lid 80 is made of steel or the like of an acid-resistant material, but has a central portion 75 made of an acid-soluble metal such as zinc, magnesium or aluminum. However, zinc is considered to be the most preferred metal because it has the best durability properties at the various pH values that can prevail in the borehole before this middle portion has to be dissolved in the acid.

A passage 74 is provided through the central portion 75 and is provided with a ball valve, as shown in Figures 2 and 3. The ball valve comprises a ball 73 located in the vefit housing 72, which in turn "forms an expanded portion in the channel 74. The ball seat forms a conical surface 71 and the ball remains in the housing 72 by a star-shaped plate 70, best seen in Figure 3. The plate 70 by means of the inwardly bent collar part 58. However, it is clear that the ball can also be kept in its correct position by other devices.

6 57823

The acid-resistant body portion 59 of the lid 80 has a conical or inclined surface 68 against which a correspondingly conical or inclined surface 67 of the acid-soluble central portion 75 rests. cover part 69 shoulder 62 past.

As previously mentioned, the star-shaped plate is held in place by a bent flange 58. In practice, the acid-resistant body portion 69 is first provided with a channel having a diameter slightly smaller than the diameter of the acid-soluble central portion 75, after which the acid-soluble portion is compressed into the channel. A hammer or the like is then formed to form a collar 63 for attaching the acid-soluble portion to the lid.

The lid 80 acts as a valve-controlled, flow-limiting member because the pressurized material introduced into the housing 10 due to the ball valve flows through the narrow passage 74 and the ball valve to the tubular device 100. On the other hand, the ball 73 and its conical seat 71 compress the pressure in the tubular device. against the seat 71 and thus prevents gas or liquid from flowing inside the housing.

The operation of the back cover is as follows:

When the housing 10 is positioned in the borehole and cement slurry or the like is pumped through its open lower end so as to rise around the housing and fill the space between the outer surface of the housing and the shaft walls, the pressure in the housing is increased to exceed the causes the telescopic tubes to pass through the cement slurry towards the walls of the shaft into contact with them.

The fluid used for this purpose enters the channel 74 and, since the non-return valve allows flow towards the screw plug 50, the compression then exceeds the clamping force of the retaining members, which has prevented the telescopic tubes from moving outwards. However, if the end of the tube-forming device 10 and the screw plug 50 extending past the collar 93 were prematurely displaced or broken during installation or otherwise damaged, no material could enter the tube because the ball, which was then subjected to the tubular device or outside 7 57823, is pressed against the seat 71 and thus prevents communication between the tubular device and the interior of the housing.

Even in the event that the outer ends of one or more tubular devices are broken, pressure can still be provided inside the housing to a sufficient extent so that the remaining devices can be pushed out. This is because leakage through narrow channels can be easily compensated by increasing the pumping rate. In previously known structures without a safety cover, the rupture of a single tubular device provided a relatively large channel leading out of the housing, which severely disrupted operation.

Once the housing is installed and the tubular members are urgently pushed outwardly into contact with the shaft wall, acid is introduced into the housing so that the acid-soluble central portion 75 dissolves to form a relatively wide channel in the body portion 69 corresponding to the size of the portion 75. However, if at some later stage of operation of the borehole it is desired to close the connection between the housing interior and the tubular device again, the ball seal can be floated down inside the housing, pressing it against the conical surface 67 of the acid-resistant part 69 and preventing connection.

If desired, the diameter of the ball seal may be smaller than the diameter of the channel formed after dissolving the central portion 75. If this is the case, the ball sealer will swim inside the channel. By forming a suitable seat (not shown) in the tube-forming device, the ball seal becomes compressed against this seat, thereby preventing communication as long as pressure is maintained in the housing without extending inside the housing itself.

It is also possible to use an oil-resistant, deformable ball seal which is slightly larger than the channel formed when the central part 75 dissolves, but smaller than the channel of the tube 13.

When the interior of the housing is under pressure, the ball seal is compressed into a cavity in the pipe through the channel, where it returns to its original shape, thus preventing passage.

In addition, power can be enhanced by using a conical seat inside the body portion 60 near the center portion 75. If the pressure in the housing decreases and the ball seal is instead subjected to compression by the fluid flowing from the shaft to the pipe, the ball seal presses against the inner seat and thus permanently closes the channel. This structure is particularly suitable if the gap is to be closed

Claims (2)

8 57823 at a certain height while others at the height remain open. The deformable ball seal can be any oil resistant rubber or the like. If the closed channel is to be opened later, a suitable solvent is introduced into the housing to dissolve the deformable ball seal. The use of the safety cover 80 provides additional benefits in connection with the use of the tube-forming devices. When the telescopic tubes are pushed outward against the shaft wall and the pressure is released from inside the housing, the acid-resistant portion 69 of the cover 80 effectively prevents the telescopic tubes of the tubular devices that are broken or broken from entering the housing. This is because, as can be seen from the drawing, the tubes have a larger diameter than the channel formed after dissolution of the acid-soluble central portion. The handling of tubular parts and devices becomes much simpler when using the safety cover 80 because it allows effective monitoring of the device. A device for use in a borehole, wherein the borehole housing (10) is intended to be placed in a borehole and a tubular device (100) made of acid-resistant metal is attached to an opening (99) formed in the housing wall and connectable to a generating zone. a safety cover (80) with a valve (70-73) and a body part (69) made of acid-resistant metal and a center part (75) made of acid-soluble metal is arranged at the end of the housing (10), characterized in that the acid-proof body the portion (69) has an internally threaded flange portion (49, 79) into which the externally threaded end portion (85) of the tubular device (100) is rotatable to secure the safety cover (80) to the threaded end portion. Device according to claim 1, characterized in that the acid-soluble central part (75) has a conical surface (67) tapering towards the inside of the tubular device, which cooperates with a correspondingly shaped surface part (68) in the acid-resistant body part, whereby the central part has dissolved, a substantially conical seat surface is formed in the body for the ball seal to be inserted in the housing.