NO129894B - - Google Patents

Description

Burying device for anchor with anchor cable.

This invention relates to a burying device for anchors with anchor cable for anchoring an object in the seabed.

In previously proposed anchor cable systems, the anchor has an anchor shaft with an anchor blade that can be tilted in relation to the shaft so that the blades with the anchor on a soft seabed of e.g. mud, sand or gravel and with the shaft running horizontally and connected by an extended cable to the object to be anchored, will dig into the seabed when the anchor is subjected to a horizontal pulling force from the cable. (By "cable" is also meant wire, rope chain etc.)

It has been found advantageous in previously proposed anchor label systems that the anchor is buried considerably to increase the system's anchoring force. In the previously proposed anchor cable systems, however, the buried part of the cable with increased burial will expose the anchor to lifting forces that increase with depth.

The operation of previously proposed anchor cable systems which are already in use will now be explained with reference to fig. 1,2 and 9 on the accompanying drawings.

For an anchor of the previously proposed type, the maximum angle of attack of the blades in relation to the horizontal in the working position is the largest angle between the plane through the blades and a straight line through the junction between the pivot shaft for the cable shackle bolt and the front end of the anchor shaft and which passes through the pivot point for the leaves.

With the anchor in working position, the angle of attack for the blades can be called a and the above-mentioned straight line can be called the tangent to the cable at the shackle bolt or, briefly, the tangent.

With such an anchor on the seabed and with the blades buried in the surface of the bottom and with the part of the cable closest to the anchor approximately horizontal and for horizontal movement of the anchor, the forces developed by the anchor can be resolved into a vertical downward burying component, P = a function of a = f(a), and a horizontal resistance component, D = f(a) + K, where K is the horizontal component of the anchor resistance when the anchor's orientation is such that the cross-sectional area in the direction of movement is minimum.- In the the above position is the tangent of the cable at the shackle bolt horizontal.

As the anchor buries itself with the nearest part of the cable under the action of the horizontal force from the cable, the buried portion of the cable will tend to assume a curve approximating a catenary in shape due to distributed resistance forces acting along the length of the cable length due to the resistance force in the seabed. The part of the cable which directly abuts the shackle bolt on the anchor shaft, and consequently the tangent, will therefore have an inclination angle 3 in relation to the horizontal. The angle of attack of the anchor, a, will therefore be reduced by 3 as the anchor and cable are buried in the seabed so that P = f (a-$) and D = f(a—3) + K. The forces developed by the anchor will therefore decrease by increasing burial due to the gradual reduction of the angle of attack of the blades which is caused by the increasing curvature of the cable.

The resistance forces that are distributed along the buried part of the cable can also be resolved vertically and horizontally and summed to give an upward lifting component that opposes the burying force, P, of the anchor and a horizontal resistance component that opposes the pull of the cable over the seabed.

When all force components developed by the buried part of the cable and the anchor are added together, the horizontal resistance components will act together to form the horizontal holding force of the anchor cable system, while the vertical lifting and sinking components will counteract each other and be equal in magnitude. the bodyweight fitness.

As the burial of the anchor increases, the overlying reaction volume of seabed material will increase and therefore the burial force resulting from this reaction volume will also increase. But as the angle 3 increases, the angle of attack of the blades will decrease with the result that the rate of increase of the burial force with increasing burial is reduced to a rate less than the rate of increase of upward lifting force developed by the cable. The increasing upward lifting force will eventually overcome and balance the downward force component developed by the anchor and vertical equilibrium of the anchor cable system will then be reached. In this equilibrium position, the anchor will have achieved the maximum burial that the cable will allow and since then it can only move horizontally. The horizontal holding force developed with the anchor barely in motion, consisting of anchor resistance and cable resistance, is therefore constant and is usually used as a measure of the anchor's holding force, even though a significant part of the holding force in such an anchor cable system is developed by the buried part of the cable.

The purpose of the invention is to provide a burial device of the type mentioned at the outset which ensures a significant increase in the holding power and thus the burial depth. The device according to the invention is essentially distinguished by the fact that the device includes devices for fixing the device on the anchor cable so that the longitudinal axis of the device can become coaxial with the cable when it is under tension, and at least one with a fin or finned part which includes a burial surface which in the device's normal burying position is at a fixed angle of inclination to the device's said longitudinal axis for generating burying forces which are sufficient to bury the device. Other features of the device according to the invention appear from the subclaims.

By means of the device according to the invention, it is achieved that the cable is forced to deviate from the normal chain line and occupy an approximately rectilinear position with a constant degree of inclination over its buried length in the seabed. The tangent at the anchor shaft's shackle bolt will have the same degree of inclination as the cable and lie on the same line as this. The distributed burial forces produced by several successively arranged devices on the cable can be utilized to produce a known constant degree of inclination on the rectilinear buried part of the cable, so that the above-mentioned angle B never becomes large enough to reduce the angle of attack of the anchor very much from maximum. The anchor will therefore continue to work effectively and develop an almost constant digging force regardless of the penetration depth of the anchor and the cable under the seabed.

Each burying device is capable of developing a burying force equal to the lifting force developed by the cable section between the devices with the addition of the burying force necessary to bury the relevant fin device. Therefore, there is no increase in the upward lifting force acting on the anchor when the burial depth for the anchor increases. The holding power of such an anchor with burial devices will therefore only depend on the depth of anchor-permeable material in the seabed, provided that burial devices are mounted on a sufficient length of the cable closest to the anchor. With a given depth of anchor-penetrable seabed, the holding force can be chosen as close to the breaking strength of the anchor cable as desired by placing a sufficient number of burial devices on the cable to allow the anchor to penetrate deep enough below the seabed.

The invention shall be explained in more detail by means of examples with reference to the drawings, where: Fig. 1 shows a section through a burial device according to the invention, fig. 2 a side view of another embodiment of the device according to the invention, fig. 3 shows on a smaller scale a device according to fig. 1 seen obliquely from below, fig. 4 is a front view of the device according to fig. 1 or 3 seen in the direction of arrow A in fig. 1, fig. 5 shows the device according to fig. 1, 3 or 4 seen obliquely from above, and fig. 6 schematically shows an anchoring system, e.g. for mooring ships where burial devices according to fig. 1-5 are used. The figure illustrates the increase in the angle of attack (et * g) for the wings or arms of the anchor as a result of the use of the inventive device. Fig. 6 shows an anchoring system known per se with an anchor 18 for anchoring or mooring a vessel 2 in a soft seabed 3 (e.g. bottom of mud, sand or shingle) which is connected to the vessel by means of a cable 19 whose length is many times greater than the water depth at the mooring location. When the anchor 18 lies on the bottom 3, the cable section closest to the anchor therefore runs essentially horizontally. When the cable 19 is pulled, e.g. as a result of the movement of the vessel 2, the anchor's wings 18 will assume a maximum angle of attack ot in relation to the seabed 3. Horizontal movement of the anchor in this position forces the anchor wings to bury the anchor with the consequence that also a part 19A of the cable 19 will be buried below the bottom surface. Forces in the bottom which counteract the burial and which are distributed along the buried length of the cable 19A force the cable to assume a chain curve-like course as shown. As the burial continues, the angle 3 between the tangent to the cable and the horizontal at the anchor collar will increase until the angle of attack (a t 3) at the anchor wing is reduced so that further burial of the anchor 18 is excluded. The anchor 18 and the cable 19A are now in equilibrium and the anchor 18 moves horizontally in a limited depth A which is dependent on the resistance forces acting on the cable 19A and counteracting the burial.

The burial depth for the anchor 18 and thus also the mooring force or anchoring force in a conventional anchoring system is limited by the resistance to penetration of the cable that builds up when the cable is pulled under the seabed.

A device made in accordance with the invention and its mode of operation will now be explained with reference to fig. 1-6. In fig.

1 shows a burial device placed on a cable 20 which is to be attached to an anchor 21 for mooring a ship to the seabed. It is assumed that several burial devices 22 are placed at regular intervals on the cable section closest to the anchor. The distance H between the devices 22 should be of suitable length so that the burying force developed by each device 22 can bury the device and in addition counteract the vertical resistance from the part of the cable 20 that lies between adjacent devices 22. For use on wire cables (fig. 1 and 3-5) each device 22 comprises a rotatable sleeve 23 (Fig. 1) on the cable and two clamping rings 24,25, one at each end 23A, 23B of the sleeve 23 and locked to the cable 20, for fixing the sleeve 23 on the cable 20 .Two opposite fins 26 (Figs. 4 and 5) protrude from the sleeve and form

angle with each other (see fig. 5) and with the axis of the sleeve 23, so that with the cable 20 placed horizontally on the seabed 3, the two fins 26 form an angle of attack with the seabed 3 when the midpoint of the area for the fins 26 lies above the cable 20 in the vertical plane through the cable axis. The angle of incidence of the fins with respect to the cable axis is preferably in the range of 15° to 60°, but can be any angle, whereby useful burial force sufficient to bury the device 22 together with the nearest part of the cable is developed as the cable is pulled through the seabed. The front clamping ring 24 has an end wall 27 with an annular recess 28 in it, and the front end of the sleeve 23A is placed inside this recess 28. The other (rear) end 23B of the sleeve 23 has a recess 29 into which the rear clamping ring 25 is inserted to position the sleeve 23 on the cable 20. A rearwardly projecting extension 30 of the front collar 24 serves as a bearing for the sleeve 23. A third fin 31 is located between the opposing fin ends 26 and projects perpendicular to the sleeve 23. The third fin is located in a plane containing the axis of the sleeve 23.

The device according to fig. 2 is adapted for use on a chain and comprises a rotating sleeve 40 whose front end 40A is placed and supported in a front front shoe 41 equipped with a chain ring 42 and the rear end 4OB of the sleeve 40 encloses the front end of a rear cuff 43. The front shoe and the cuff connects the sleeve to the chain thing much like a chain link. Two inclined fins 44 protrude in opposite directions from the sleeve 40 corresponding to the fins 26 in the arrangement in fig. 1 and works in a similar way. The front connector 41 has an end wall 45 with an annular recess (not shown), and the front end 4OA of the sleeve 40 is placed inside this recess, and the other (rear) end 40B of the sleeve 40 has a similar recess (not shown), into which a clip ring can be mounted which will enclose a rearward cylindrical extension of the front shoe connector 41, so that it serves as a bearing for the sleeve. The rear chainring 42 of the front shoe 41 is mounted at the rear of the rearward-directed cylindrical extension of the front shoe 41. As in the device 22 of fig. 1, a third fin 46 is located between the opposite fins 44 and projects perpendicularly from the sleeve 40 and is located in a plane containing the axis of the sleeve 40.

The cable system is intended for use especially in soft seabeds of the type already described.

When using the anchor cable system, e.g. for mooring a ship 1 to a soft seabed 3, the length a<y> of the cable 20 used is several times longer than the sea depth at the anchorage, so that the part 2OA of the cable closest to the anchor 21 lies approximately horizontally along the seabed. The anchor can be of any type suitable for burial. When a traction force is applied to the cable 20 due to movement of the ship 1, the anchor 21 and the part of the cable 2OA closest to the anchor will penetrate the seabed 3. Penetration of the seabed surface by the cable 20 under the influence of the anchor 21 will cause the devices 22 grips the seabed with the result that burial forces are developed at the inclined fins 26.44. These burying forces will bury each device 22 and overcome the forces which oppose penetration of the bottom and which act vertically on the cable between each device 22, so that the buried part of the cable will tend to occupy an approximately straight-line course with the inclined fins 26, 44 on the devices 22 are more or less mutually parallel and trailing behind the cable due to the effect of the middle fin 31, 46 and the staggered position of the burial fins 26, 44.

It will be understood that the burial devices 22 will automatically take up the correct trailing position when engaging the seabed 3 due to the distance between the center point of the fins 26.44 area and the axis of the cable and as a result of the location of the fins on the cable.

In that way, the angle of incidence 3 for the cable's anchoring end

in relation to the horizontal held less than would be the case if the cable was not equipped with devices 22 and was consequently allowed to occupy an approximately chain line as previously described. This reduced value of 3 does not vary with the burial depth of the anchor and causes a clear reduction of the angle of attack of the anchor so that it can continue to develop a useful burial force at the end of the cable. The burying force of the anchor 21 will therefore remain large because it is not reduced by the penetration resistance of the bottom which acts on the buried part of the cable. Consequently, the burial depth for the anchor 21 is no longer limited by the aforementioned resistance, but only by the length of the cable section which is equipped with burial devices 22. By appropriately determining the length of the cable section to be equipped with burial devices, the burial depth for the anchor and thus the anchoring force or mooring force is determined and, if desired, increased right up to the limit determined by the strength of the material used in the various parts of the system.

To prevent clogging with e.g. sand of the clearances between the sleeve ends 20,40 and the clamp rings or shoes 24,25 (or 41), the clearances are so rigid that the sand etc. can pass freely The invention is not limited to what appears in the drawings. The fins can e.g. is mounted on a sleeve between two clamping rings which are attached to the cable with a space in between. It is of course also possible to remove the middle fin 31.46.

In cases of permanent mooring, where an anchor and a cable are placed on the seabed by divers, there will be no need for pivoting wings on the anchor and rotatable devices 22. An anchor with fixed wings and non-rotating devices 22 can therefore be used for permanent mooring provided that all the devices are identically oriented on the cable and that the anchor 21 is similarly oriented, so that the anchor cable system can start to work in the usual way after divers have placed the anchor and the cable in the correct position on the seabed and the cable is exposed to horizontal traction. It is clear that the invention is equally applicable to the mooring of vessels in rivers, lakes and similar waters.

Claims (11)

1. Burying device for anchor with anchor cable for anchoring an object in the seabed, characterized in that the device comprises devices (24,25) for fixing the device (22) on the anchor cable (20) so that the longitudinal axis of the device can become coaxial with the cable when this is under tension, and at least one fin or fin-made part (26) which comprises a burial surface which, in the device's (22) normal burial position, is at a fixed angle of inclination to the device's mentioned longitudinal axis for generating burial forces that are sufficient to bury the device (22). 2. Device according to claim 1, characterized in that the relative inclination angle of the burial surface (26) is in the range 15° - 60°, preferably 30° - 60°. 3. Device according to claim 1 or 2, characterized in that it has two or more fins (26) arranged at an angle to each other and to the device's longitudinal axis so that the device (22) is symmetrical about a vertical plane that intersects the device in normal burial position. 4. Device according to claim 3, characterized in that the location of the burial fin floats (26) on the device (22) is such that when interacting with the surface of the seabed in an upside-down position, the resultant force vector will be produced by the parts of the burial fin that lie on either side of the vertical plane which intersects the device (22) and is in engagement with the surface material in the seabed, lie on a straight line which intersects the vertical plane of symmetry at a point below the device's longitudinal axis, whereby a torque is produced about said axis and which forces the device to become unstable in the upside-down position and become stable in the normal burrowing position. 5. Device according to one or more of the preceding claims, characterized in that the center of the area for the inclined fins (26) lies above the longitudinal axis of the device when it is in its nor paint burial position. 6. Device according to claim 5, characterized in that at least three-fifths of the total burial fin area (26) of the device (22) lies on one side of the device's longitudinal axis. 7. Device according to claim 5 or 6, characterized in that the part (40) of the device (22) which carries the fin or fins is rotatable about the longitudinal axis of the device to allow the displaced fins (23,46) to hang along said longitudinal axis and adjust automatically an efficient working position for the fins (26). 8. Device according to claim 7, characterized in that it comprises a front clamping sleeve (24,30) which can be placed on an anchor cable and which has an annular recess (28) in one end wall, a sleeve (23) on which two oppositely offset fins (26) are arranged at an angle in relation to the axis of the collar (30) and at an angle to each other, and a third fin (31) arranged between the opposite fins (26) and protruding from the sleeve (23), where the front end of the sleeve (23A ) is inserted into the recess (28) in the front sleeve (24), while the sleeve's rear end (23B) has a recess, and where a rear clamping sleeve (25) is inserted into the recess (23B) so that the sleeve (23) is rotatable on the cable (30). 9. Device according to claim 7 for attachment to an anchor chain thing, characterized in that there is arranged a front shoe (41) with a chain ring (42} and with an annular recess (45) in its end wall, a sleeve (40) on which the are placed two opposite fins (44) placed at an angle in relation to the axis of the front shoe (41) and to each other, and a third fin (46) placed between the opposite fins (44) and protruding from the sleeve (40), where the sleeve's (40 ) front end is placed in the recess (45) of the front shoe (41) and rotatable on a backward extending cylindrical projection (43) which extends from the front shoe and which serves as a bearing for the sleeve (40). 10. Device according to claim 9, characterized in that the sleeve's rear end (4OB) has an annular recess, in which a holding cuff (43) is inserted and which surrounds the rear end of the cylindrical projection extending from the front shoe. 11. Device according to claim 10, characterized in that a chain ring (42) is placed on the rear end of the projection (43), and where the cuffs and the chain ring are attached to the projection.