NO134795B - - Google Patents

Description

The present invention relates to an improved dynamic mooring anchor of the type stated in the introduction to the following main claim.

Anchors can generally be classified into three groups: weight anchors that rest on the bottom and where weight and friction produce the holding force; semi-dynamic anchors that partially dig into the seabed when they are pulled along it, whereby both weight and the resistance of the bottom material are used to generate holding power; and dynamic anchors that dig all the way into the bottom material and where only the effect of the bottom material against the anchor tab produces the holding force. The present invention is directed to an improved anchor of the latter type which is particularly useful when mooring floating drilling vessels and other vessels which must be moored firmly to a place for longer periods of time. '

Dynamic anchors can further be divided into anchors with

fixed anchor claw. and with swiveling anchor anchor. The latter usually has a simple anchor claw and is usually deployed using two liners - the mooring line and an auxiliary line. A significant disadvantage of anchors with fixed claws comes from the fixed angle mentioned between the leg and the claw. The fact that this angle cannot be changed results in the holding force produced by the anchor varying significantly depending on the nature and quality of the bottom deposits. It is e.g. known that the claw angle should be limited to 30 -.35° for relatively firm sandy bottoms, while larger claw angles in the range of up to 50° are much better for softer mud or clay bottoms. Thus, the chosen claw angle will be the optimum for one bottom condition but not for the other, or it will represent a compromise between the two.

Anchors with pivoting anchor claws usually have two claws that swing freely to each side of the anchor leg, which are designed to dig in regardless of which side of the anchor comes into contact with the seabed. Such anchors can be lowered and set using a simple line. Furthermore, anchors with a pivoting claw can be easily adapted for use as anchors with a variable claw angle. With the help of a wedge or similar tool, the claw angle can be adjusted at the anchoring point to achieve the maximum holding force produced by the anchor under the prevailing bottom conditions.

Despite these advantages, anchors with a swiveling claw, like anchors with a fixed claw, have unfortunately not proved completely satisfactory for the mooring of floating drilling vessels. They are often dragged along the seabed without their claws being released and are, under such conditions, unable to dig down and produce any particular holding power. Adding release surfaces and similar devices to the claws for the purpose of forcing them to dig into the bottom has solved this problem to some extent, but has not significantly increased their reliability as mooring anchors. E.g. these anchors will often dig in and produce a significant holding force before suddenly, and so far inexplicably, giving way and being pulled completely loose. To counteract this irregular behavior of mooring anchors, either additional mooring lines have been used, or additional anchors have been placed in tandem on each line. This practice, which has been of some help, is both time-consuming and expensive and therefore leaves much to be desired. Drag tests of anchors carried out both with model and full-size anchors have led to the discovery that certain structural features of mooring anchors have caused their previously erratic behavior. In particular, it has been shown. that obstacles to the flow of bottom material over the anchor greatly weaken its formation of lasting holding power in the seabed. Such flow obstacles compress sediments that lie in front of the anchor along its drag path. The compressed material builds up as the anchor moves forward and eventually causes the anchor to swing up and the water to be pulled out of the bottom. In mud or clay bottoms, accumulations of the material become trapped on the front surfaces and tops of the claws and between the shank and the claw device, especially at their intersection or where stiffening ribs, out solution surfaces or other flow obstructions occur. In sandy bottoms, the sediments do not stick to the anchor, but collect in front of the anchor and are pressed together into stagnant masses which have the same destructive effect.

It has been shown that if an anchor is constructed in accordance with the initially mentioned type, these problems will be avoided to a significant extent. The present invention is aimed at an improved mooring anchor which has very little resistance to the flow of bottom sediments above it and which digs deep down and produces a persistently large holding force.

According to the invention, this is achieved by the anchor claw being arranged to be able to swing freely between a first minimum angle position and a second maximum angle position below and in relation to the lower leg.

Furthermore, the anchor claw can be designed to enable regulation of the maximum angle between the claw and the calf.

The clearly improved effect of the anchor according to the invention is due to a number of structural features. The anchor has no anchor cross or burial surfaces, both of which can capture stagnant masses of the base material when the anchor is pulled. By beveling the lower edge of the anchor leg and the front edge of the anchor claw, as well as by providing the anchor claw with a smooth upper surface free of ribs or other obstacles, as well as adapting the connection between the leg and the claw so that it offers very little resistance to the flow of bottom sediments, the anchor's overall flow resistance very greatly reduced. This prevents compaction and clumping of sediments that lie ahead of the anchor in its drag path and allows the anchor to dig deep and thereby produce and maintain a significant holding force. The swiveling anchor claw that only opens in the downward direction offers a number of advantages. Unlike other anchors with a swiveling anchor claw, the anchor will be deployed using two lines, which facilitates control and orientation of the anchor, thereby ensuring that the anchor lands on the bottom with the correct side up, i.e. with the anchor claw under the calf. Because the pivoting anchor claw is designed to form a minimum angle with the leg even when in the closed position, the claw will quickly dig into the bottom when...the anchor is pulled. The need for release surfaces or other flow obstacles which are otherwise necessary to effect a positive digging effect of the claws is thereby eliminated. This in turn allows a significant reduction in the armature's flow resistance. Furthermore, by ensuring that the pivotable claw remains on the lower side of the leg, the use of a simple claw is also permitted which is stronger than the fork-shaped or split claws which are usually normal for anchors with pivotable claws and which are more economical in construction. Furthermore, the pivotable claw device allows the provision of means for regulating the claw angle so that it can be adapted to the prevailing bottom conditions. It also allows the anchor to be folded which results in significant space saving during storage on board the vessel.

On the basis of these advantages and others which will appear from the detailed description and the drawing that follows and which are achieved by means of the features indicated in the subsequent claims, it is clear that the anchor according to the invention represents a significant improvement in relation to to previously known anchors.

In the drawing is

fig. 1 a plan view showing the upper side of an anchor constructed in accordance with the invention,

fig. 2 is a side view, partially in section, of the anchor in fig. 1,

fig. 3 shows a plan view, partially in section, of the underside of the anchor in fig. 1,

fig. 4 shows a cross-section of the lower leg along the line 4-4 in fig. 3, and

fig. 5 is a perspective view of the anchor according to fig. 1.

With reference to the drawing, the anchor according to the present invention consists of a leg 11 whose front edge,

i.e. the edge that cuts through the bottom material, sharply beveled. to reduce the leg's resistance to penetration of the bottom material. The degree of oblique cutting of the lower leg is best shown in the cross-sectional view of the lower leg in fig. 4. In a preferred embodiment of the invention, the lower leg is cut obliquely so that the oblique surfaces at the front edge form an angle between

which is not greater than 45°. It is clear, however, that the chosen acute angle can be varied significantly as long as it is consistent with preserving the leg's strength and reducing flow resistance against the bottom material. Means for attaching the anchor line near the front end of the leg are also included, e.g. shackle 13. The opposite end of the calf can conveniently form a Y where the lower branch has a hole 17 for receiving the anchor rod 19. The upper branch 21 - of the Y, can be adapted to cooperate with a device such as e.g. a wedge 23 to control the described maximum angle between

the claw 25 and the calf. Although the design shown is preferred, it is clear that the rear end of the leg can be pivotally connected to the claw in other ways as well.

A simple claw 25 is shown with a slot 27 designed to allow the lower branch 15 of the Y-shaped rear end of the calf to extend through. It is important that the upper surface of the claw, i.e. the flow surface over which bottom sediments pass when the anchor is pulled forward, is a smooth, streamlined surface free of ribs, protruding anchor crosses or other current obstructions. The front edge of the claw should preferably be sharply beveled to facilitate its introduction into the bottom sediments. This bevel cut can best be seen in fig. 2 and 3. Resistance to the claw's penetration is also reduced by tapering its front end to eh or two sharp points as shown. The connection - between the leg and the claw is designed to offer very little flow resistance to the bottom sediments.

The claw may include means for attaching a lifeline such as, for example. e-t eye 29 which is shown arranged at the rear end of the claw.. This means can alternatively be attached to the rear end of the calf. One or more reinforcing ribs can be arranged at the bottom surface of the claw. The placement of these on the underside of the claw is advantageous as this means that they do not lie in the bottom material's flow path in 'Although the drawing shows a box or chamber 31 comprising 4 ribs 33, other designs for support bodies can be used. The degree of reinforcement required will of course be determined by the surface size and thickness of the claw as well as by the desired holding power. Each of the ribs shown has an opening through it dimensioned and aligned with each other for receiving a log 19. Although a single claw is preferable, two claws can also be used. The claw's required surface size should be based on the well-known considerations for determining the desired anchor holding power.

The stick 19 is shown connected transversely to the anchor leg 11. The stick can be conveniently passed through the opening in the ribs

33 and then through the hole, 17 in the Y-shaped rear end of

the cane. The stick can preferably be made with hollow ends instead of as a solid bar if desired to reduce weight. In the position shown, the stock serves as a connecting bolt that allows the leg and claw to pivot relative to each other. The length of the stick should be sufficient to provide lateral stability to the anchor as it penetrates the sediments. The stick must also be long enough so that if the anchor lays on the bottom in an inclined position, the anchor will be supported by the front end of the shin, one end of the stick and a tip of the claw. If the stick is too short, the anchor will become unstable and fall over to the side instead of penetrating the bottom sediments. In this connection, it should be noted that the anchor according to the drawing comprises two claw tips at some distance from each other. This arrangement facilitates the engagement of the claw with the bottom when the anchor is inclined.

A device is provided to limit the minimum angle between the pivotable claw and the lower edge of the leg, to an angle slightly greater than zero. This forces the anchor to remain partially open at all times.' The device used can be a slot such as 27 in the claw 25 which causes the claw to come into contact with the calf at an angle of approx. 21°. It is clear that other devices can be used to limit the minimum angle between the claw and the leg <:> to an angle greater than zero.

A device is also provided to limit the maximum angle between the pivotable claw and the lower edge of the leg. A wedge 33 is shown placed on the claw and placed so that it interacts with the upper branch 21 on the rear side of the calf. This wedge controls the mentioned maximum angle1 between the leg and the claw, and by varying the size of the wedge on the anchor, the claw angle can be regulated to achieve the optimum size of the holding force the anchor produces in a particular bottom.

To use the anchor according to the invention for mooring a floating drilling vessel or other structure,

is it desirable to first make sure of the bottom conditions. This can be carried out either by collecting samples or using other known techniques such as carrying out samples with small anchors. As soon as the nature and quality of the bottom sediments are known, the claw angle can be adjusted to achieve the optimum size of

the generated holding power under the special prevailing conditions. Optimum holding power will be produced by the anchor according to the invention with a claw angle of approx. 34° for sandy bottom and 50° for mud or clay. The anchor is usually set out with the help of an auxiliary boat equipped with a winch. The mooring line which is connected to the vessel to be moored is attached to a shackle 3 at the front end of the leg. The auxiliary line from the rescue boat's winch is attached to the eye 29 at the rear end of the anchor, usually on the claw.

The anchor is then lowered to the bottom at the same time as each of the lines is stretched. When the anchor is suspended, it will orient itself so that the heavy claw hangs downwards. Lowering is continued until the anchor comes to rest on the seabed with the claw down. The auxiliary line is then preferably released and attached to a buoy to facilitate recapture. When the mooring line is pulled, the anchor, which has already been brought into position with the claw down and open corresponding to the minimum claw angle, will quickly penetrate into the bottom sediments. The base material's pressure against the claw causes the claw angle to open to the optimum angle that has been chosen for the greatest holding force. When it is desired to end the mooring, the auxiliary line is re-caught and a winch on board the auxiliary boat is used to hoist the anchor on board. Scale models of the anchor according to the invention were extensively tested in comparison with models of previously known anchor types with swiveling claw that were built in the same scale. These tests were carried out in model tanks, in beach sand and at various locations at sea and they resulted in holding force data that are representative of a wide range of bottom conditions. During the tests, the effect of the previously known' anchors was primarily weakened by two types of difficulties, 1 flounder failed to turn and dig into the bottom material, and 2 anchors clumped the bottom material with subsequent extraction of the bottom material. In contrast, the anchor according to the invention showed a high degree of reliability and its effect was superior in relation to the previously tested anchors, which e.g. shown in US Patent Nos. 2,677-343 and 3-015,299-

The following table compares the impact of a

400 kg anchor constructed in accordance with the invention, with a 400 kg anchor of the previously known type as shown in US Patent No. 2,677-343 having pivoting claws and an anchor cross projection to ensure positive claw effects. The data have been obtained from a series of anchor drag tests carried out at three different locations in the Gulf of Mexico.

ANCHOR HOLDING STRENGTH TESTS

The anchor pull tests are carried out with a boat equipped with a strain gauge. The tensile tests in the table were put into three different classes: l:completely successful - which indicates that the anchor developed at least 7,500 kg of holding force and showed no signs of producing soil clods or being pulled out, 2:partially successful - which 'indicates that the anchor developed at least 7,500 kg holding force, but produced lumps and was pulled out, and 3:unsuccessful - indicating that the anchor developed less than 7,500 kg holding force. According to the anchor, the invention was able to produce high holding power in the range from 12.5Q0 - 30,000 kg on all samples and it did not produce soil clods or lose holding power even when it was pulled approx. 200 - 300 m. On the other hand, the previously known anchor was only able to achieve moderate to high holding power under 50% of the kites and it clumped together the ground materials and lost holding power in half of the cases. It was completely successful in only 25% of the total tensile tests carried out.

Claims (3)

1. Dynamic mooring anchor of the swivel claw type, and having an anchor leg (11), an anchor stick (19) connected transversely to the rear end of the anchor leg (11), anchor line connection device (13) at the front end of the anchor leg (11), a claw (25) with a smooth upper surface arranged under the anchor leg (11) with its rear end pivotally connected to the rear end of the anchor leg, which anchor leg and anchor rod (19) and the connections between them, have surfaces that are substantially free of obstructions against the passage of bottom material, characterized by a first angle limitation device arranged to limit an acute minimum angle between the anchor claw (25) and the underside of the anchor leg (11) in combination with a second angle limitation device (23) arranged at the rear end of the anchor leg and which cooperates with the claw (25) and the anchor leg (11) for restriction of an acute maximum angle1 between the underside of the anchor claw and the anchor leg, which first and second angle limitation devices cooperate to limit the angular movement of the anchor claw (25) to an arc located below the anchor leg (11) and delimited between the acute minimum angle and the acute maximum angle1. 2. " Anchor according to claim 1, characterized in that the second angle limiting device (23) for controlling the maximum angle between the anchor claw (25) and the anchor leg (11), is adjustable. 3. Anchor according to claim 2, characterized in that the maximum angle lies in the range 30° to 50°.