NO132345B - - Google Patents

Description

This invention relates to an anchor for mooring or anchoring an object, such as a vessel or a floating structure to an anchoring bottom, such as the bottom of a sea, comprising a shaft, to one end of which is attached a barb having at least one burial surface and if another., the front end, which is farthest from the barb, has an attachment point for a cable or the like, where the shaft lies in the anchor's vertical plane of symmetry, and comprising at least one rail that runs across the barb and the anchor's plane of symmetry and serves to orient the anchor.

There are different types of anchors in use, and the design and weight vary according to the purpose for which the anchor will be used. There are anchors both with and without crossbars. In the case of conventional anchors, the crossbar must help to keep the anchor's barb or barbs in the correct burial position. Danish patent 59 966 describes a ship's anchor without a crossbar and with a fixed barb which is extended in one with the anchor's shaft and has a largely arched cross-section with the concave part facing inwards towards the shaft. The transition or the connection between the shaft and the barb consists of a short arm that forms approximately a right angle with the shaft. This known anchor is not equipped with any special devices which help to keep the anchor in the correct burial position on the seabed. In German patent 19 68l, an anchor is described which is equipped with a single barb, and which, rather than a crossbar, is equipped with a more or less heart-shaped or triangular-shaped crossbowle which should contribute to the anchor-laying, position on the sea floor. The design is such that the barb and the crossbow are arranged on opposite sides of the anchor shaft, and the length of the shaft in relation to the barb is relatively large. The anchor is particularly designed for use on solid ground.

In addition to the mentioned anchors, there are a large number of anchors with movable or pivotable barb sticks, but such anchors are outside the scope of the invention. It is known that the anchoring force for an anchor increases with the anchor's penetration depth in the bottom. In order to achieve the greatest possible penetration depth, it is necessary that an anchor can first be oriented to the correct working position or burial position on the bottom or at least orient itself to the correct position, as soon as there is a pull in the anchor cable. Furthermore, it is necessary that the anchor stays in the burial position, and that this position remains stable until the anchor has reached the required depth. In addition to the aforementioned requirements, it is also desirable that the force for pulling up the anchor from the bottom should be as small as possible in relation to the anchoring force. It is also an advantage to design the anchor so that the length of the mooring cable is not too long.

The purpose of the invention is to provide an anchor of the initially mentioned type which satisfies the aforementioned requirements. The anchor according to the invention is essentially distinguished by the fact that the anchor's rail is curved and attached - at least either to the shaft or to the barb, that the rail comprises two arms which are arranged symmetrically in relation to the anchor's plane of symmetry, and so that a point that moves along the center line of an arm in the direction of the barb during its movement moves away from the cable attachment point on the shank while approaching the center of the area of the barb's burial surface, to achieve that the anchor will roll -to a burial position with the barb's burial surface in engagement with the anchoring bottom when there during the sewing, the anchor cable is pulled and an arm rests against the bottom. In one embodiment of the invention, the rail is continuous and has a closed shape. The shape may be substantially elliptical. In another embodiment, the rail is attached to the barb and forms a curved part with free ends that face upwards when the anchor is in the burial position. The anchor can also be extended so that the rail's arms are extended in width with stabilizing surfaces arranged symmetrically on each side of the anchor's plane of symmetry, and. which forms an angle with. the plane of symmetry, which stabilization surfaces are arranged so that a line running through the center of each stabilization surface's area and substantially perpendicular to the stabilization surface intersects the anchor's plane of symmetry above the straight line connecting the center of the barbed surface and the anchor's "th" point when the anchor is. in the burial position. Other features of the anchor according to the invention appear from the sub-claims-.

With the help of the invention, an anchor is provided which ensures a several times greater anchoring force. than previously known anchors, with approximately the same weight. At the same time, it has been achieved that the pull-out force (the force required to break the anchor out of the bottom) is many times less than for other anchors of approximately the same weight and less anchoring force.

The invention shall be explained in more detail by means of examples with reference to the drawings, where fig. 1 to 5 show perspective views of various embodiments of the anchor according to the invention, fig. 6 shows a schematic side view of the anchor according to fig. 1 and serves to explain the geometry of the anchor., and fig. 7 shows a schematic plan of the anchor according to fig. 6.

Fig. 1 shows an anchor 1 for anchoring a vessel to or in an enrichment bed over a cable. According to the anchor

.the invention has a shaft 2 formed by an elongated rail with a largely elongated rectangular cross-section and boyd such that there

the actual shaft 2a and a shaft arm 2b located in a plane of symmetry are formed which must be vertically oriented when the anchor is in

work position. The anchor has a single digging barb 3 which is ..largely triangular in shape, is attached to the shaft arm .2b and has a concave upwardly directed digging surface 3A. The front end of the shaft has an eyelet 5 for fixing the cable, while the end of the shaft arm carries the barb 3 located across the plane of symmetry of the anchor. The inner edge of the bowed shaft 2 is chamfered to facilitate the shaft's penetration into the anchoring bottom. The line of intersection between the working surface of the barb and the plane of symmetry of the anchor forms an angle (3 (fig. 6) with a line that runs through the middle of the cable buoy 5 and the forward point of the barb, which angle lies in the area between !+5 and 75, preferably between, 60 and 70° This angle shall for convenience be called the "acute angle".

The distance S between the center of the cable attachment eye and the front point of the digging barb in the plane of symmetry is called the "tip distance" and the expression will be used in the explanation below.'

The shaft 2a has a length L of 0.9 »S to 1.5*S, preferably 1.32*S, and the shaft arm 2b has a length L 2 of

0.^'S to 0.8'S, preferably 0.6»S, both of these ranges being limited by. the requirement that the distance Dg between the center of the digging barb's 3 area C (fig. 7) and the shaft's 2a axis should lie in the range 0.^"S to 0.8"S, preferably 0.6-S. The projected length P-^ of the barb. 3 on the anchor's 1 symmetry plane lies in the range 0.^-^S to 0.8°S, preferably 0.62°S, and the maximum width of the barb 3 is 75% of the projected length. The angle a (fig. 7) between the 3 front edges of the barb is between h0 and 80°.

A rail h with a circular cross-section" and in the form of a closed ellipse is attached to a point on the bottom surface of the barb 3 near the center of the area C and surrounds the barb 3 so that the largest diameter of the ellipse lies in the plane of symmetry of the anchor. The rail k has cross arms 6 and 7 The plane containing the rail h forms a right angle with the plane of symmetry of the anchor and intersects the shaft 2a axis aft of the cable attachment hole 5 and forms an angle 9 between 15 and <1>+0° with a straight line passing through the cable attachment hole and the attachment point for the rod or the rail h on the bottom surface of the barb. The largest diameter of the rail k is from 0.7-S to 1.3"S, preferably 0.8"S, while the smallest diameter is between 0.7 and 1.0$ of the largest diameter .The elliptical rail cross-sectional diameter is 0.015'S to 0.015'S..

In normal use, the anchor is connected to a speed buoy by means of a single cable of suitable length. The anchor is thrown onto the anchoring bottom, where it can lie (a) with the point of the barb 3 and the front end of the shaft 2 in contact with the anchoring bottom, or (b). with part of the rail or bar h and the front end of the shaft 2 in contact with the anchoring base, or (c) with part of the rail h and the rear part of the shaft 2 in contact with the anchoring base.

Burying of the anchor 1 takes place appropriately in position (a). When the anchor is pulled over the anchoring bottom in position (b), the center of pressure for the part of the rail k that is in contact with the ground will move along the rail, especially mostly along the rail's center line, to get as far away as possible from the hole 5 and will force the anchor to roll on the rail h until position (a) is reached. When the anchor 1 is pulled over the bottom in position (c), the center of pressure of the part of the rail k that is in contact, against the bottom, will first act as a tipping point, over which the anchor 1 tilts to take the position (b), after which further tension causes the anchor to come into position (a), which is the starting position for burying the anchor in the bottom.

Fig. 2 shows another embodiment of the anchor according to the invention. The anchor 1 comprises a shaft 2 and a barb 3 as explained above. In this case, the rail h is discontinuous and forms a semicircle. The rail h is attached to the bottom of the barb 3 near the surface center C of the barb and runs curved around the side edges of the barb 3 in the direction towards the actual shaft part 2a. The curved rail's radius R (fig. 2) is 0.3"S to 0.65°S, preferably 0.50"S. In this case, does the plane containing the rail intersect the axis of the shaft part 2a in front or behind the city 5? and at an angle

y between the k plane of the rail and the straight line through the center of the town 5 and the attachment point for the rail on the barb, where y is between 15° in front of the straight line and 60° behind the straight line, and with the further limitation that the distance between a point on the curved rail h and the city's 5 center always increase when the point on the rail h moves along the rail towards the attachment point between the rail h and the barb 3. A preferred angle for the plane containing the rail h is h5° behind the straight line through the city's 5 center and the attachment point for the rail h on the barb 3.

The projection of the curved rail V ends hk down on the plane of symmetry for the anchor lies between the barb 3 and the outer edge of the shaft part 2a and is located at a distance from the outer edge of the shaft part 2a. This distance is between 0.105"S and 0.^-05"S to ensure that only one of the rail's ends engages with the bottom in the opposite position of the anchor with the upper edge of the shaft part 2a situated on the bottom. This contributes to the rail h immediately causing the anchor 1 to roll to come with its barb 3 into engagement with the bottom when the anchor is pulled along it. The hands of the rail are pointed to facilitate penetration into the bottom.

When the anchor according to fig. 2 is thrown down on the bottom, it can take a position (a) which is identical to the position (a) explained in, in connection with fig. 1 or the position (b), which is exactly the opposite position with the outer edge of the shaft part 2a and one end of the rail h in contact or engagement with the surface of the bottom, or the anchor can take the position (c) with the rear part of the shaft 2 and one end a <y> the rail h in contact with the bottom surface.

When the anchor is pulled over the bottom in position (a), it will dig down. In position (b), one end of the rail k- will penetrate into the bottom and the center of pressure of the buried part of the rail h will move along the rail to get as far as possible away from the center of the town 5, whereby the anchor 1 will roll to position (a) has been reached. When the anchor is in position (c), the k end of the rail will tilt the anchor to position (b), after which position (a) is reached, provided that the cable force acts roughly horizontally. If the cable force acts at a greater angle with the horizontal in position (c), but not greater than ^-O<0>, one end of the rail will descend into the seabed, after which the center of pressure will move towards position (b), so that the anchor will roll until the barb 3 comes into contact with the bottom, after which the barb will dig down if it is at a suitable angle to the horizontal.

Fig. 3 shows a third embodiment of the invention, in which the rail is attached to the outer edge of the shaft part 2a. The ground plan of the rail is still elliptical, but it will be seen that

the part of the ellipse that lies between the barb and the smallest diameter of the ellipse has been removed.

The anchor according to fig. 3 acts-largely as the anchor according to fig. 1, except that the position (b) changes to the position (a) only after the barb 3 has come into engagement with the bottom of the boat and begins to dig in the anchor.

Since the effect of the rail h in all the three designs mentioned is due to the center of pressure for the part of the rail h that engages with the anchoring base, to the greatest possible extent. moves away from the city.5 as a result of the anchor being pulled along the bottom, it will be understood that the rail h will continue to act in this way until the entire rail h is buried below the surface of the bottom. Therefore, this rail h has two functions, namely one to orient the anchor on the bottom, if the barb is not immediately in the correct engagement position., and the other to stabilize the anchor roll in the final engagement position until the rail h is completely buried below the surface of the bottom .

The rail h will continue its stabilizing effect to a reduced extent during continued burial, if the material in the anchoring base has sufficient shear strength in the area between the ends of the rail. -

To ensure sufficient stabilization in anchorage bases that do not have such firmness, e.g. in a clay bottom in a saturated state or very bare mud, according to the invention, a fourth embodiment according to fig. <*>+, showing an anchor with a shaft 2, a barb 3? an elliptical rail h, but where the elliptical rail h is attached to the barb 3 at a place behind and at a distance between 0.!+0"PL and 0.65"PL (fig. 6) from the forward point of the barb, and where the rail in this case, two portions have in the form of curved, pointed plates 6, 7 which "extend from a place on the rail near the edge of the barb to a point generally near the k-smallest ellipse diameter of the rail. The inner surfaces 9"-10 of the curved plates 6, 7 which make up the anchor's stabilization

surfaces lie in an upwardly concave surface of a cone whose axis lies in the plane of symmetry for the anchor, and which converges backwards with a convergence angle in the range from 0 to 15°, preferably 5°. In fig. h are the centers of the area of the two stabilization surfaces 9 > 10 denoted by P. Imagine a line from this point P. largely perpendicular to the surface 9' or 10 (the surfaces are not planar), this line will intersect the anchor's plane of symmetry in a point Z located somewhere between the anchor shaft's rear transition part 2b (or behind it) and the line X - X (see also

fig. 1) which runs through the center C of the barb 39 3-A and the center of the cable eye 5. However, the surface can also be cylindrical. The barb also lies in this upwardly concave surface. Maximum width of each curved plate, i.e. the dimension in the length of the anchor, at the edge of the barb is between 0.20-PL and 0-.50"PL (fig. 6), preferably 0.If6-PL- The leading edge of each plate 6, 7 is parallel to the median line of the inner side of the rail . To achieve the least possible rolling resistance from the barb 3 e? its surface arranged in one part

of the same conical surface, in which the inner surfaces of the plates 6, 7 lie.

When the anchor is in use and is in the one in fig. h showed burial position, even in the event that for some reason the anchor rolls on its axis, i.e. the straight line through the center of the city 5 and the center of the area of the barb 3, one of the curved plates 6, 7 will come down further than the other with the result that the force vector from the plates 6, 7 will cause a torque to arise which will counteract the rolling and bring the anchor to the burying position. Otherwise, the anchor according to Fig. <i>+ acts in the same way as the anchor according to Fig. 1. The faces 9?10 and the center line 11 of the barb are also shown in Fig. h.

In the embodiment according to fig. 5, the upper part of the rail h is curved, so that you only have the curved plates 6, 7, whose dimensions and arrangement correspond to what is explained in connection with fig. 5. The skin's, i.e. the smallest diameter of the ellipse lies in the area between 0.80"S and 1.10"S.

The outer ends 6A, 7A of the plates 6, 7, however, proceed from the conical surface explained above, so that the outer half of the ■median line of the inner surface of each plate 6, 7 forms a straight line which is tangential to the outermost end of a partial ellipse•which lies in the conical surface and is formed at the innermost half of said median line. The backward convergence angle between these outer ends of the plates 6, 7 measured in a plane parallel to the axis of the straight conical surface and perpendicular to the plane of symmetry of the armature, increases progressively from the preferred 5°

(or another angle between 0 and 15°) to an angle above 110° near the tips for de-oblong, curved plates. This helps the anchor come into contact with the bottom at greater angles of inclination between the cable and the horizontal.

The ellipse for the median line of the inner halves of the plates 6, 7 intersects the plane of symmetry of the anchor at a point on the upper surface of the barb 3 behind the tip of the barb and at a distance from the same, of between 0.6OPL and 0.85°PL (fig. 6). The straight line through the city's 5 center and the intersection between said median line ellipse and the plane of symmetry for the anchor forms an angle with the plane containing the ellipse of between 10° and 30°. All longitudinal sections of the plates 6, 7 and the barb 3 are generally wedge-shaped with the tip of the wedge pointing forward at an angle of 3" to 12°.

The angular space between the "back k- Ofo of the shaft part 2a and the upper 65$ of the shaft arm 2b can comprise a flange or rib 8 which is attached to the shaft.

The anchor according to fig. 5 works in a similar way to the anchor according to fig. 2, but with the additional stabilizing effect obtained by means of the anchor according to fig. h. If the anchor 1 rolls about its rolling axis, i.e. the straight line through the center of the town 5 and the surface area of the barb 3, the shaft rib 8 will also be displaced from the normal vertical position and subjected to a relative torque from the anchoring base which is at an angle with a surface of the rib 8, so that a resultant -force vector which lies across the armature's plane of symmetry and extends behind and above the armature's rolling axis.

The net torque is due to the displaced plates

6, 7 which act together with the force vector from the shaft rib 8 to roll the axis of the anchor 1 in such a direction that the rolling of the anchor is counteracted, and to guide the anchor back to the original burial position.

Modifications may occur. The rail h on the anchor according to fig. 1 can, for example, be attached to the shaft 2.

Claims (3)

Anchor for mooring or anchoring an object, such as a vessel or a floating structure, to an anchoring bottom, such as the sea bottom, comprising a shaft, to one end of which is attached a barb having at least one burial surface and the other, forward end, which is furthest away from the barb, has an attachment point for a cable or similar, where the shaft lies in the anchor's vertical plane of symmetry, and comprising "at least one rail which runs across the barb and the plane of symmetry of the anchor and serves to orient the anchor, characterized in that the rail ( h) is curved and attached at least either to the shaft (2) or to the barb (3), that the rail includes two arms (6, 7) which are arranged symmetrically in relation to the anchor's plane of symmetry and so that a point that moves along the center line (11) of an arm (6, 7) in the direction of the barb (3), during its movement moves away from the cable attachment point (5) on the shaft (2), while at the same time approaching seg the center (C, fig. 7) for the area of the barb's burying surface (3A) to achieve that the anchor will roll to a burying position with the barb down- . digging surface in engagement with the anchoring bottom when, during the mooring, the anchor cable is pulled and an arm (6, 7) rests against the bottom. 2. Anchor according to claim 1, characterized in that the rail (h) is continuous and has a closed shape (fig. 1). 3. Anchor according to claim 2, characterized in that the rail (<*>+) has an essentially elliptical shape (fig. 1). h. Anchor according to claim 3?characterized in that the center line of the barb (3) burial surface (3A) and the arms (6, 7) lies essentially in a part of a cylindrical surface or of a conical surface, the axis of which is in the anchor's plane of symmetry, and where the barb's burial surface is, in a manner known per se, concave in an upward direction when the anchor (1) is in the burial position. J. Anchor according to claim K, characterized in that the surface comprising the barb, the burial surface (3A) and the arms (6, 7? fig. 2, 3) respectively the longitudinal center line of the arms, extending across the barb (11, Fig. V, 5)? is a conical surface or cone surface that converges in a direction away from the cable attachment point (5) and whose convergence angle lies in the range between 0° and 15°. , 6. Anchor according to claim 1, characterized in that the rail (k) is attached to the barb (3, fig. 2) and forms a curved part with free ends (^A) which faces upwards when the anchor is in the burial position. 7. Appeal according to claim 6, characterized by. that the projection of the ends (^A, 6A, 7A) of the arms (6, 7) on the anchor's plane of symmetry lies between the barb (3) and the upper edge (2') of the shaft (2) when the anchor is in the normal burial position (Fig. 2, 5 ). 8. Appeal according to claim 6 or 7, characterized by. that the arms (6, 7) lie in the cable pulling direction at a considerable distance from the anchor's rear transition part (2b) which connects the barb (3) with the essentially straight shaft part (2a). 9. Anchor according to one or more of the preceding claims, characterized in that the arms (6, 7) of the rail (h) are extended in width with stabilizing surfaces (9, 10. fig. ^5 5) arranged symmetrically on each side of the anchor's plane of symmetry and forming an angle with the plane of symmetry, and that these stabilization surfaces (9? 10) are arranged in such a way that a line through the center (P) of each stabilization surface's area and essentially perpendicular to the stabilization surface intersects the plane of symmetry of the anchor the straight line (X - X) which runs through the center of the barbed surface (3A) and the anchor's cable attachment eye (5) when the anchor is in the buried position. 10. Anchor according to requirements ^characterized by the fact that the arms (6, 7) have the stabilizing rafts (9, 10) is in one with the barb (3) and forms extension parts of the same that extend from the side edges of the barb (3) to each side of the anchor's plane of symmetry, so that the burial surface of the barb (3A) and the stabilization rafts (9, 10) form a continuous surface 11. An ker according to claim 9 or 10, characterized in that the stabilization rafts (9, 10) and the barb's burial surface (3A) in the anchor's burial position are located in a part of a cylindrical or conical surface which is concave upwards and whose axis lies in the plane of anchor symmetry. 12. Anchor according to claim 11, characterized in that the surface is conical and the cone angle is between no , ,-0 o and 15 . 13. Anchor according to claim 11 or 12, characterized in that an outer part (6A, 7A) of each stabilization surface (9, 10) deviates from and is essentially tangential to the cylindrical or conical surface part that contains the burial surface of the barb (3A). li+. Anchor according to claim 11 or 12, characterized in that the outer parts (6A, 7A) of the stabilization rafts (9, 10) deviate from the cylindrical or conical part containing the barb's burial surface (3A), as the cone angle increases towards the outer ends of the parts.