NO334558B1 - Device for preventing leaching of pulp during subsea drilling - Google Patents

Description

FIELD OF THE INVENTION

The present invention relates generally to a washout preventer to prevent collapse of the ground on top of the critical zone in underwater drilling operations.

More specifically, the present invention relates to a device for preventing washout during underwater drilling, and which has at least one flap element attached to the area of the lateral walls of an anchor foundation, to be able to hold onto the ground around the anchor foundation.

More specifically, the present invention relates to a device for preventing washout during underwater drilling according to the preamble of claim 1.

TECHNICAL BACKGROUND OF THE INVENTION

Wellhead systems for underwater exploration will typically comprise a wellhead that has a wellhead housing attached to the well's casing. A blowout preventer is placed on top of the wellhead and a valve tree can be placed between the wellhead and the blowout preventer. The well frame supports the wellheads, while underwater foundations for the suction anchorage will support the well frame and other underwater structures.

From NO 139231 an anchoring foundation comprising a central well frame is known which is equipped with an opening for the passage of a drill string. Support members are hinged to each of the well frame's corners, which are fitted with flat foot plates at the outer end. These foot plates increase the well frame's contact area with the seabed and will stabilize the ground.

However, such a well frame, which is intended to lie on top of the seabed, must be very heavy. This makes the installation of the well frame demanding.

Typically, underwater anchor foundations will comprise four vertical cylinder structures. In recent times, such anchoring foundations have been developed as a single cylinder instead of four, often commonly known as a monobucket (English: «monobucket»). Underwater anchor foundations normally support a frame and well lock inserts for up to four wells.

During underwater drilling operations on the seabed, washing out of the ground on the top is often encountered during the initial drilling on the seabed, up to a depth of around 10 to 20 metres.

This leaching is usually due to pressure from drilling mud, which physically forces the soil structure out of the drilled hole on the seabed. This has the effect of a pressure washer and blasts out the soil. This is actually a challenge in drilling operations since, down to approximately 20 meters depth, the seabed will mostly comprise an unconsolidated loose formation.

Such washing out can also occur when there are large volumes of fluid, in the order of 2,000 and 5,000 liters per minute, which are flushed out of the borehole.

The end result, if washed out during the first 10 to 20 meters of drilling, will be a conical hole in the ground with a top diameter of around 7-8 meters.

It is also a common experience in drilling operations that such a conical hole will be a feared threat to the stability of underwater anchoring foundations, and consequently to the well frame, which often renders the entire installation that has been described here worthless. A collapse of the frame would be an extreme eventuality.

Thus, previous technology in this area has made several attempts to retain the top masses during drilling operations. However, such devices have often been found to have a complicated construction, which has a significant number of components, and which will lead to a cumbersome and expensive installation.

Furthermore, until now, prior art has not been focused on developing a simple device, which has been adapted to work in close proximity to underwater anchoring foundations and around well lock inserts, so that a retention of the ground around such foundations is achieved.

For example, WO 2004018830 shows a device to prevent such washing out, which comprises a modification of the drill stem so that it comprises a number of drill pipes. Each drill pipe has an inner centric tube and an outer tube, so as to have an annular space between them. The annular space is arranged to carry return fluid out of the borehole. This document shows a device which has the disadvantages mentioned in the two preceding paragraphs.

Accordingly, there has been a long-felt need for a device to prevent soil washout during underwater drilling which, in addition to being simple, is adapted to operate in close proximity to underwater anchor foundations and around well sluice liners, so that soil containment is achieved around such foundations.

It is also known that surfaces with large areas, i.e. a large horizontal area (which is a likely solution to prevent washout) have a very difficult time getting through the splash zone (i.e. the zone that has the first intermittent contact with the sea surface ). The critical parameter that will apply in calculations for the splash zone will increase with area (as a factor for weight) and will increase with wave height. This leads to structures with large surfaces having a very limited operating window for launching through the splash zone. A reduced exposed area provides a larger operating window.

Thus, there is a need to find a method to reduce the exposed area when it is to be launched through the splash zone, while it must still be possible to prevent washing out as mentioned earlier.

Thus, there is also a need for a device that prevents washing out of the ground during underwater drilling, which must be adapted so that it can easily be submerged through the splash zone.

The present invention meets the previously mentioned long-felt needs as well as other associated needs.

OBJECTS OF THE INVENTION

The principal purpose of the invention is to provide a device to prevent washing out of the ground during underwater drilling which, in addition to being simple, is adapted to work in close proximity to anchoring foundations underwater and around well lock inserts, so that a retention is achieved of the ground around such foundations.

It is another object of the present invention to provide a device to prevent washing out of the ground during underwater drilling, which is adapted to be easily lowered through the splash zone.

It is another object of the present invention to provide a device to prevent washing out of the ground during underwater drilling, which is adapted to have a minimal projected area towards the sea surface through the splash zone, and also during the following immersion towards the seabed.

It is a further object of the present invention to provide a device for preventing washing out of the ground during underwater drilling, which is adapted to operate under extreme weather conditions, thereby reducing time and costs.

It is another object of the present invention to provide a device to prevent washing out of the ground during underwater drilling, which is adapted to act as a mainly horizontal construction which encloses the well lock insert to stop washing out of the seabed.

It is another object of the present invention to provide a device to prevent washing out of the ground during underwater drilling, which is adapted to be lowered to the seabed with an ROV and/or with cable and winch.

It is another object of the present invention to provide an underwater anchoring foundation which is adapted to support an underwater structure, such as a frame, which is operatively connected in close proximity to a device which prevents washing out of the ground during underwater drilling, where the device fulfills some or all of the purposes described above.

How the foregoing objects are achieved, and some other advantageous features not shown in the prior art, will become clear from the following non-limiting description.

Throughout the description, including the requirements, the words "underwater", "flap element / flap", "drill bit", "drill rod", "anchoring foundation",

"frame", "well sluice insert", "well sluice" are interpreted in the broadest sense of the respective expressions, and include all corresponding objects in the field known by other terms, as will be obvious to professionals in the field. Restrictions/limitations, should there be any such, which are referred to in the description, will only be an example of and for understanding the present invention.

SUMMARY OF THE INVENTION

According to a first aspect of the present invention, a device is shown for preventing washing out of the ground during underwater drilling, which has means to be able to hold onto the ground around the anchoring foundation, in accordance with the preamble of the subsequent claim 1.1 according to the present invention is a flap element known per se hinged to a structure which supports the well lock insert adjacent to the lateral wall of the underwater monobucket foundation, and that the flap element is equipped with an opening to receive the well lock insert.

Preferably, the flap element is hinged along the lateral walls of the anchoring foundation.

In an advantageous embodiment, said flap element is arranged to remain in its position with the main plane substantially parallel to and close to the lateral walls of the foundation during installation through the water.

In an alternative embodiment, said flap element has a fold line across its main plane and portions on each side of the fold line are folded vertically together like butterfly wings during installation through the water.

In an advantageous embodiment, said flap element, when in parallel orientation with the seabed, is arranged to be vertically adjustable in relation to the seabed in order to adapt to the seabed profile and ensure optimal contact with the seabed.

Preferably, said flap element is adapted to be fixed opposite well lock inserts by means of an adjustment device, such as a plurality of adjustment screws.

In an advantageous embodiment, said flap element has a circular or rectangular or cubic or folded shape and is mainly flat with a possibly downward-facing flange

BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS

After having described the most important features of the invention above, a more detailed and non-limiting description of some preferred embodiments will now be given in what follows with reference to the drawings, where: Figure 1 is a schematic longitudinal section of a typical basic formation, where drilling is carried out on the seabed.

Figure 2 illustrates an eventuality where the borehole is washed out during drilling.

Figure 3 illustrates a preferred embodiment of the device, according to the present invention, with the flap vertically on the seabed. Figure 4 illustrates the device in Figure 3 with the flap placed mainly parallel to the seabed. Figure 5 illustrates an enlarged view of a detail of the device shown in Figure 4. Figure 6 illustrates an enlarged view of a detail of the device shown in Figures 3, 4 and 5, with the flap placed in a vertical position. Figure 7a schematically illustrates another preferred embodiment of the device according to the present invention with the flap attached to the side walls of a mono-bucket and in a parked position. Figure 7b illustrates the device in Figure 7a with the flap that opens for operation. Figure 7c illustrates the device of Figure 7a with the flap in the open state, ready for operation. Figure 8a schematically illustrates the preferred embodiment of the device shown in Figures 3 to 5 with the flap attached to the side walls of a mono bucket and in a parked position. Figure 8b illustrates the arrangement of Figure 8a with the flap that opens for operation. Figure 8c illustrates the device in Figure 8a with the flap in the open state, ready for operation. Figure 9a schematically illustrates another preferred embodiment of the device, according to the preferred embodiment, with the flap attached to the side walls of a mono-bucket and opening for operation. Figure 9b illustrates the device in Figure 9a with the flap in the open state, ready for operation.

DETAILED DESCRIPTION OF THE INVENTION

In what now follows, a detailed, non-limiting description of some preferred embodiments of the present invention will be provided which are only intended as examples.

Drilling a borehole on the seabed 2 is shown in figures 1 and 2. These two figures have no consequence for the present invention and have been included from prior art to explain the problem which the present invention proposes to solve.

The shaded area in Figure 1 indicates the critical zone 3 close to the borehole which is prone to washout. This indicates the first 10 to 20 meters of the unconsolidated base formation 4. Figure 4 shows the drill string 5 and also the drill bit 6 and the frame 1.

Figure 2 shows the end result of a washout due to large volumes of fluid being flushed out from the borehole. This fluid could be drilling mud. The washout zone is a substantially conical hole, as shown, with a top diameter of, for example, 7 to 8 meters. The figure also shows the displacement of the frame 1 due to excavation of a part of the seabed 2 in the loose formation zone 4.

As mentioned earlier, this occurs primarily because the underwater suction anchoring foundation, which supports the frame, is also destabilized due to washing out and erosion of the ground.

This is exactly what the present invention is focused on preventing, i.e. the aim will be to hold back the ground around the well lock inserts next to the anchorage. The solution in the present invention has not been proposed or thought out in prior art.

For the sake of gaining an understanding in a simplified way, an application of the present invention to a single foundation / mono bucket is shown. For professionals in the field, it should be understood that the present invention is effectively applicable with regard to all types of underwater anchoring foundations, which support well frames and other underwater structures. Furthermore, for reasons of simplification in the description, only one flap 7' is shown. However, there could be one or more such flaps 7' around the foundations and the well lock inserts.

In all figures, like reference numbers will represent the same constructional features.

As shown in Figure 3, the washout preventer comprises a flap 7' attached to the side wall of a mono bucket 7 by means of a hinge joint 11. Of course, the flap 7' could be hinged either on the side wall of the mono bucket as shown in Figure 3 or under a construction 9, which supports the well lock efforts 8.

Figure 3 indicates a position where the flap 7' is vertical on the seabed 2. The flaps are hinged so that when the monobucket 7 is lifted from the vessel (not shown) and it is lowered through the splash zone (not shown), the flaps will be in a stored position, folded vertically along the side wall of the monobucket 7 as shown in figure 3 (also shown in figures 7a, 8a, 9a, as discussed later) or folded vertically as wings under the well lock inserts 8.

The advantage of the arrangement shown in the preceding paragraph is to ensure a minimum projecting area towards the sea surface through the splash zone, and also during the immersion towards the seabed 2. The flap 7' has a centric hole 7" through which the well lock insert 8 and the end pipe 8' can pass . It also helps the flap 7' to remain in place during drilling. The exact shape of the centric hole 7" is adjusted to match the hinge geometry. In general, it will preferably be an elongated hole.

When it has reached its position on the seabed 2, the flap 7' is opened either using an underwater ROV or using a cable and winch from the surface.

Figure 4 shows the position when the flap 7' is ready for operation and is mainly parallel to the seabed 2 to be drilled.

The hinge joint 11, as shown in figures 3 and 4 and also in the subsequent figures 5 and 6, could be equipped with a slot 11' for the hinge pin 11. This ensures that the flap 7' will first be led through a swinging movement to make it parallel to the seabed to be drilled, followed by a vertical adjustment and alignment with the actual seabed 2. The flap 7' could be slightly inclined in relation to the horizontal to fit the seabed profile and ensure maximum contact with the seabed 2.

As shown in further detail in figures 4 and 5, the flap 7' will be prevented from moving in a vertical direction as soon as it has come into engagement with adjusting screws in a three-point system 10 which is fixed on the well sluice insert 8.

Figure 5 is an enlarged detail of Figure 5, while Figure 6 shows, for the sake of understanding the various components, the device from the underside.

The flaps 7' could be completely flat or be curved to match the outer profile of the mono bucket diameter, or be flat with a downward facing flange, forming a shallow bucket. Figure 7a schematically illustrates another preferred embodiment of the flap 7' attached to the side walls of a mono bucket 7 in the parked state. The flap 7' is here rectangular. Figure 7(b) illustrates the flap 7' as it is lifted up for operation. Figure 7c illustrates the flap 7' shown in Figure 7a in a fully raised state, ready for operation. Figure 8a schematically illustrates the preferred embodiment of the flap T shown in Figures 3 to 5 attached to the side walls of a mono bucket 7 in the parked state. The flap 7' is here rectangular. Figure 8b illustrates the flap T as it is lifted up for surgery. Figure 8c illustrates the flap 7' shown in Figure 8a in a fully raised state, ready for operation. Figures 9a and 9b show an alternative embodiment, where the flap 7' will be able to be folded over itself by a folding line, which extends diametrically over the flap 7', corresponding to the wings of a butterfly, when the device is lowered through the water. Figure 9a schematically illustrates the flap 7' attached to the side walls of a mono bucket 7 while it is being opened for operation. Figure 9b schematically illustrates the flap 7', shown in Figure 9a in an unfolded open state, ready for operation.

The simple construction, which was previously described here, retains the ground around the anchorage 7, for the first 10 to 20 meters of drilling. The flap-like design 7' which is substantially parallel to the seabed 2 during the drilling operation, and which acts as a lid or lock, thus holding the bottom in place under the pressure exerted by the fluid. Furthermore, the valve provides a solid barrier against any incipient leakage or prevents a path for the fluid. This prevents a path from forming to the sea, and consequently the chances of washing out will be greatly reduced.

Thus, the present invention will provide a mainly horizontal construction on the seabed which encloses a well lock insert to prevent washing out. It also ensures that there is a minimum of area towards the sea surface through the splash zone during its installation. Reduction of projected area will also allow a larger operating window, and thus operation in more extreme weather, which ultimately reduces the required time and cost for installation.

Based on the preceding description and also from the appended claims, it will be clear to those skilled in the art that all purposes of the present invention are achieved.

The present invention has been described with reference to some preferred embodiments and some drawings only for the sake of understanding and it should be clear to those skilled in the art that the present invention includes all legitimate modifications within the scope of what has been described here previously and required in the attached requirements.

Claims (7)

1. Device for underwater anchoring foundation, in the form of a mono-bucket foundation (7), which is equipped with means to prevent washing out of the ground during underwater drilling, with at least one substantially planar flap element (7') adapted to be located substantially parallel with the seabed and act as a lid or lock to physically hold the bottom in place, the flap element (7') being attached to the anchoring foundation (7) in such a way that the flap element (7') can be oriented with the main plane of the flap (7' ) parallel to the direction of movement when the anchorage (7) is lowered to the seabed, and is oriented with the main plane mainly parallel to the seabed when the anchorage (7) has reached the seabed, characterized in that the flap element (7') is hinged to a structure (9) which supports up the manhole insert (8) adjacent the lateral wall of the underwater monobucket foundation (7), and that the flap member (7') is provided with an opening (7") to receive the manhole insert ( 8). 2. Device according to claim 1, characterized in that said flap element (7') is hinged (11) along the lateral walls of the underwater mono-bucket foundation (7). 3. Device according to any one of claim 2, characterized in that said flap element (7') is arranged to remain in its position with the main plane substantially parallel to and close to the lateral walls of the foundation (7) during installation through the water . 4. Device according to any one of claims 2 or 3, characterized in that said flap has a fold line across its main plane and that portions on each side of the fold line are folded vertically together like butterfly wings during installation through the water. 5. Device according to any one of the preceding claims, characterized in that said flap element (7'), when in parallel orientation with the seabed (2), is arranged to be vertically adjustable in relation to the seabed (2) in order to adapted to the seabed profile and ensure optimal contact with the seabed (2). 6. Device according to any one of claims 3 to 5, characterized in that said flap element (7') is adapted to be fixed against the well lock insert (8) by means of an adjustment device (10), such as a plurality of adjustment screws. 7. Device according to any one of the preceding claims, characterized in that said flap element (7') has a circular or rectangular or cubic or folded shape and is mainly flat with a possible downward facing flange.