APERTURE

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority from UK Patent Application No. 21 03881 .5, filed on 19 March 2021.

BACKGROUND OF THE INVENTION

The present invention relates to a latch for insertion into an aperture.

When building offshore wind turbines, it is necessary to connect them to the shore or to an offshore substation by cabling buried in the seabed. For turbines having fixed foundations, such as monopiles, the cable must pass through the wall of the foundation and rise to the generator. Typically, a latch is used to attach the cable to the wall. This may be known as a latch mechanism, a mechanical latch, a cable protection system latch, and so on.

However, due to the fact that the cable rises from the seabed to connect to a monopile or other foundation, the aperture in the wall is generally at an angle to the wall of less than 90°, and thus the latch is also at an angle to the wall. Typical latches include a number of spring-loaded latch fingers, and work on the assumption that at least two of these will engage with the inside of the wall and prevent removal of the latch from the aperture. However, this causes uneven load on the engaged latch fingers, and allows the latch to rattle within the aperture causing further stress to the fingers. Stress fatigue on the fingers may eventually result in failure of the latch.

It is therefore an object of the invention to provide an improved latch suitable for insertion into an aperture.

BRIEF SUMMARY OF THE INVENTION

According to a first aspect of the present invention, there is provided a latch according to claim 1. According to a second aspect of the present invention, there is provided a kit of parts according to claim 20. According to a third aspect of the present invention, there is provided a method of locating a latch within an aperture in a wall according to claim 21. According to a fourth aspect of the present invention, there is provided a method of removing a latch from a wall according to either claim 23 or claim 24. Embodiments of the invention will be described, by way of example only, with reference to the accompanying drawings. The detailed embodiments show the best mode known to the inventor and provide support for the invention as claimed. However, they are only exemplary and should not be used to interpret or limit the scope of the claims. Their purpose is to provide a teaching to those skilled in the art. Components and processes distinguished by ordinal phrases such as “first” and “second” do not necessarily define an order or ranking of any sort.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

Figure 1 illustrates an environment in which the invention may be used; Figure 2 illustrates a cable and cable protection entering a monopile shown in Figure 1 ;

Figure 3 is an illustration of a latch shown in Figure 2;

Figure 4 is another illustration of the latch shown in Figure 2;

Figure 5 illustrates an inner housing shown in Figure 3; Figure 6 is an illustration of the component parts of the inner housing shown in Figure 5;

Figure 7 is an illustration of the component parts of an outer housing shown in Figure 3;

Figure 8 is a side view with a partial cross-section of the latch and wall shown in Figure 2;

Figure 9 is another side view with a partial cross-section of the latch and wall shown in Figure 2;

Figure 10 is a cross-section of a buffer shown in Figure 3;

Figure 11 is an illustration of the latch and wall shown in Figure 2; Figure 12 is a cutaway illustration of components of the outer housing shown in Figure 3;

Figure 13 is another cutaway illustration of components of the outer housing shown in Figure 3;

Figure 14 is another cutaway illustration of components of the outer housing shown in Figure 3;

Figure 15 is an illustration of latch fingers shown in Figure 3;

Figure 16 is a cross-section of the latch shown in Figure 3; Figure 17 is another cross-section of the latch shown in Figure 3;

Figure 18 is a cross-section of the latch shown in Figure 3 after a release mechanism has been operated;

Figure 19 is another cross-section of the latch shown in Figure 3 after a release mechanism has been operated; and

Figure 20 illustrates installation of a wind turbine shown in Figure 1.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

Figure 1

A wind turbine 101 is of a type known as a monopile turbine. It comprises a monopile 102 embedded in the seabed 103. A transition piece 104 is attached to the top of monopile 102, and a tower 105 is on top of transition piece 104. Tower 105 comprises the generator 106 and blades 107. The foundation of the monopile descends below the seabed and is not shown here.

Cable 108 connects turbine 101 to the rest of the wind farm, allowing generated energy to be provided to a transformer station. The cable runs under the seabed, exits the seabed under a protective structure 109, passes through the scour area 112, and enters the monopile 102, terminating at a control box 110. Further cabling (not shown) runs through the tower to connect the control box to the generator. Monopile 102 is a hollow steel tube 5 m in diameter, and the thickness of the wall 111 is 15 cm. Cable 108 passes through an aperture in wall 111 and is latched in place as will be described with reference to Figure 2.

Figure 2

Figure 2 illustrates a portion of the wall 111 of monopile 102, and the free span of cable 108 in scour area 112. As is typical, the cable is protected from scouring by rocks 201 at the point where it exits seabed 103. There is then a free span of a few metres before the cable enters angled aperture 202 in wall 111.

The bend of cable 108 needs to be restricted in scour area 112, as otherwise the movement of the cable caused by the waves would cause kinking and breakage. Restriction in this example is provided by bend restrictor 203 around cable 108, although other suitable cable protection could be used. The bend restriction means that it is not possible, given the short free span, for cable 108 to bend in such a way to allow it to enter monopile wall 111 at an angle orthogonal to the wall. Additionally, the free span should be as short as possible to minimise potential damage to the cable. For this reason, the axis of aperture 202 is at an acute angle with respect to wall 111 , typically around 45°. Bend restrictor 203 is latched to monopile wall 111 using latch 204, through which cable 108 runs, which prevents movement of bend restrictor 203 in a direction towards or away from aperture 202, and protects cable 108 as it passes through aperture 202. A bend stiffener 205 is attached to the front end of latch 204 to prevent cable 108 kinking as it exits the latch. Cable 108 can pass freely through bend restrictor 203, latch 204 and bend stiffener 205, to allow it to be pulled upwards during installation of wind turbine 101 to control box 110

Figures 3 and 4

Figures 3 and 4 illustrate latch 204 in its unattached state, viewed from different angles. Body 301 is configured to be inserted into aperture 202, and comprises an inner housing 302, and an annular outer housing 303, which is free to rotate around a central part of inner housing 302 with respect to a longitudinal axis 300 of body 301. In this example latch is around 130 cm in length. Body 301 is around 29 cm in diameter, to fit an aperture of around 30 cm diameter. The whole apparatus is around 50 cm in diameter. However, the invention can be used for any size of latch.

Body 301 has a forward end 304 and a rearward end 305, defined with respect to the way in which body 301 is to be inserted into aperture 202 - in the direction of longitudinal axis 300, forward end 304 first. At forward end 304, inner housing 302 defines a knuckle 306 for connection to bend stiffener 205, while at rearward end 305 inner housing 302 defines a knuckle 307 for connection to bend restrictor 203.

Inner housing 302 defines a cylindrical internal bore 308 through which cable 108 is passed. Thus, when latch is attached to a bend restrictor and a bend stiffener, or other cable protection, around a cable, outer housing 303 is free to rotate while inner housing 302, the cable and the cable protection remain in place.

Mounted on outer housing 302 are six latch fingers 308, 309, 310, 311, 312, and 313. The latch fingers are arranged in three rows of two, the latch fingers in each row being opposite each other. In the top row, ie the row closest to front end 304, are latch fingers 308 and 309; in the middle row are latch fingers 310 and 311; in the bottom row, ie the row furthest from front end 304, are latch fingers 312 and 313. Latch fingers 308 and 312 are aligned with each other along a line parallel to longitudinal axis 300, as are latch fingers 309 and 313. Latch fingers 310 and 311 are in a position rotated 90° from those in the top and bottom rows.

The latch fingers are rotatably mounted at their top end on pins attached to outer housing 303, as will be further described with reference to Figure 15, and may be in a closed or open position. They are biased using a torsion spring to an open position, which is that shown in Figures 3 and 4. When body 301 is passed through aperture 202, forward end 304 first, they are forced into a closed position as they pass through the aperture, in which position they do not protrude beyond the circumference of body 301. Once through the aperture they return to the open position, and in that position any latch fingers that are in contact with the inner surface of the monopile wall engage with the wall to prevent removal of the body from the aperture in the opposite direction.

In prior art latches, such latch fingers are fixed in their rotational position, and therefore it is a matter of luck, when inserting a latch into an angled aperture, which and how many fingers engage with the wall. However, in the invention described herein, the latch fingers are mounted on outer housing 303 which is free to rotate, and therefore the latch fingers can be moved into a rotational position relative to the wall 111 that allows an optimal number of fingers to be engaged. In the embodiment shown in Figures 3 and 4, one latch finger from the top row and one latch finger from the bottom row will be engaged, plus both latch fingers from the middle row, as will be described with respect to Figure 9. In addition, because their rotational position can be specified, the latch fingers can be profiled so as to present the largest possible engagement surface to the wall.

In this embodiment, latch 204 further includes a guide 320 attached to body 301. The guide herein described comprises four buffers 321 , 322, 323 and 324 located equidistantly around the circumference of body 301. Each buffer comprises a wheel mounted on an axle attached to outer housing 303 near the rearward end 305 of body 301. Thus buffer 321 comprises wheel 331 mounted on axle 341, buffer 322 comprises wheel 332 mounted on axle 342, buffer 323 comprises wheel 333 mounted on axle 343, and buffer 324 comprises wheel 334 mounted on axle 344. Wheels 331 to 334 have a hemispherical end, to maximise contact with the outer surface of wall 111. The buffers are in opposite pairs, with buffers 321 and 323 forming one pair and buffers 322 and 324 forming another pair. In each pair, the wheels are opposite each other with respect to longitudinal axis 300, ie they are the same distance from the end of the body; thus wheels 331 and wheels 333 are opposite each other, and wheels 332 and 334 are opposite each other. Each pair of wheels is offset from the other pair with respect to longitudinal axis 300, such that wheels 331 and 333 are closer to forward end 304 of body 301 than the other two. In this embodiment this is achieved by axles 341 and 343 being longer than axles 342 and 344, although it could equally be achieved by mounting one pair of buffers forward of the other pair. Thus, buffers 321 and 323 are referred to herein as the forward buffers, while buffers 322 and 324 are referred to as the rearward buffers.

The buffers are aligned with the latch fingers along a line parallel to longitudinal axis 300, as follows: buffer 321 is aligned with latch finger 310, buffer 322 is aligned with latch fingers 308 and 312, buffer 323 is aligned with latch finger 311, and buffer 324 is aligned with latch fingers 309 and 313. As will be further described with reference to Figures 8 and 9, when body

301 is inserted into angled aperture 202, guide 320 guides the rotational position of outer housing 303 into one of two predetermined positions, thus locating the latch fingers in one of two predetermined positions, in either of which they are optimally placed to engage the inside of the wall. Thus there is herein described a latch, which in this embodiment is latch

204, comprising a body 301 having a forward end 304, a rearward end 305 and a longitudinal axis 300, configured to be inserted into an aperture by its forward end in a first direction parallel to the longitudinal axis. The body comprises an inner part, which in this embodiment is inner housing 302, and an annular outer housing, which in this embodiment is outer housing 303, surrounding at least part of the inner part and rotatable around the inner part. It also comprises a plurality of latch fingers 308 to 313 moveably attached to the outer housing, each latch finger moveable between a closed and an open position, such that in the open position a latch finger prevents removal of the body from the aperture in the direction opposite to said first direction.

The latch may also comprise a guide, which in this example is guide 320, attached to the body and configured to bias the rotation of the outer housing, when the body is inserted into an aperture, to a predetermined rotational position, thereby also locating said latch fingers in said predetermined rotational position. There may be a plurality of predetermined rotational positions, and the guide biases the rotation of the outer housing to any one of them. Alternatively, the latch may include a different guide, or may include another system for rotating the outer housing. For example, the outer housing may be manually moveable, either by a person or by a robot. As a further example, the latch may include a manually or automatically operated motor to drive rotation of the outer housing, and some form of feedback to indicate when a predetermined rotational position has been reached. There could be a camera, or sensors on the latches to provide an indication of when they are open or closed.

Figures 5 and 6

Figures 5 and 6 show inner housing 302 before outer housing 303 is placed around it. As shown in the side view of Figure 5, it comprises a central portion 501 between knuckles 306 and 307, around which outer housing 303 is placed. At every point along central portion 501 , its outer profile has a circular cross-section in order that outer housing 303 can rotate around it. Rotation is facilitated by two ball bearings, created by complementary grooves in the inner and outer housings. Grooves 502 and 503 on the outside of inner housing 302 are for this purpose. Inner housing 302 is formed in two pieces, as shown in Figure 6, which is a perspective view from the forward end. Half shells 601 and 602 are configured to be bolted together using bolt holes, such as complementary holes 603 and 604. In this embodiment the latch 204 is supplied in a single piece for cable 108 to be threaded through, but it could also be supplied in half-shells to allow it to be formed around the cable in situ.

In this embodiment, inner housing 302 defines an internal bore 308 to house cable 108, but in other embodiments, particularly if a latch is used to terminate a cable, it may be solid, in which case it would be more suitable for being formed in a single piece. Further, any suitable attachment means may replace the knuckles, depending on what is to be attached, which could be any form of cable protection, an unprotected cable, or anything else that requires latching in position.

Figure 7

Outer housing 303 is also formed in two pieces, as shown in a perspective view from the rearward end in Figure 7. Half shells 701 and 702 are bolted together around central portion 501 of inner housing 302 using bolt holes, such as bolt holes 703 and 704 in half-shell 701 and corresponding bolt holes in shell 702 that are not visible.

Each half shell is itself formed of three components, for ease of manufacture. For example half-shell 701 is formed from components 705, 706 and 707. Components 705 and 706 are bolted together using bolt holes, such as bolt hole 708, and components 706 and 707 are bolted together using bolt holes, such as bolt hole 709.

The inner surface of outer housing 303 is shaped to be substantially complementary to the outer surface of central part 501 of inner housing 302. At every point along outer housing portion 303, its inner surface has a circular cross- section that is slightly larger than the corresponding part of inner housing 302, to allow it to rotate. Circumferential gap 714 is defined on the inner surface of outer housing 302. As will be described with reference to Figure 12, this is to house part of an optional release mechanism.

As discussed with reference to Figure 5, rotation is facilitated by two ball bearings, created by complementary grooves. Grooves 710 and 711 can be seen on the inside surface of half-shell 702, and they continue (not both visible in this Figure) on the inside surface of half-shell 701. Groove 710 is complementary with groove 502 on the outside of inner housing 302; similarly groove 711 is complementary with groove 503. Once outer housing 303 has been bolted around inner housing 302, balls and lubricant are introduced into the bearings at holes 712 and 713, after which the holes are capped as can be seen in Figure 3. Figure 8

After cable 108 has been passed through bore 308 in latch 204 and cable protectors have been attached to knuckles 306 and 307, the cable can be pulled through aperture 202 in wall 111 (the installation of cable 108 in wind turbine 101 will be discussed in more detail with respect to Figure 20).

Figure 8 illustrates a side view of body 301 of latch being inserted into aperture 202 of curved wall 111, which is shown in cross-section. For clarity the cable and cable protectors are not shown in this and subsequent Figures.

Aperture 202 is at an angle 801 (meaning the sides of the aperture are at an angle) of approximately 45° from the outer surface 802 or inner surface 803 of wall 111 , so that latch 204 is inserted at the same angle. Latch 204 is optimised for this angle; in other embodiments a latch may be optimised for a different angle.

Body 301 is inserted into aperture 202, forward end 304 first, in a direction parallel to its longitudinal axis 300. Latch fingers 308 to 313 are forced into their closed position as they pass through aperture 202, as shown in this Figure by latch fingers 309 and 310, and then return to their biased open position once through the aperture. Outer housing 303 is free to rotate around inner housing 302, such that when first inserted outer housing 303 may be in any rotational position. Guide 320 then guides the rotation of outer housing 303 into one of a set of predetermined positions, as will now be described.

The wheel of one of the forward buffers 321 or 323 will be the first part of guide 320 to come into contact with outer surface 802 of wall 111. In Figure 8, wheel 331 of buffer 321 has contacted outer surface 802. The pulling of cable 108 continues to move body 301 through aperture 202, but wheel 331 prevents that movement unless outer housing 303 rotates. Therefore outer housing 303 rotates around inner housing 302, to allow further movement of body 301 into aperture 202. This rotation is further facilitated by wheel 331 rotating on axle 341.

In this example the rotation is in a clockwise direction as shown by arrow 804, but outer housing 802 is free to rotate in either a clockwise or an anti- clockwise direction, as are wheels 331 to 334.

Figure 9

Figure 9 illustrates the final rotational position of outer housing 303, again as a side view of latch 204 with wall 111 in cross-section. While inner housing 302 has remained in the same rotational position, outer housing 303 has rotated until the wheels of buffers 321, 322 and 323 (not visible in this Figure) are in contact with outer surface 802 of wall 111, creating three points of contact between guide 320 and outer surface 802, around half of the circumference of body 301. The wheel of buffer 324 is not in contact with outer surface 802. It is no longer possible for outer housing 303 to rotate further in either direction.

If outer housing 303 had started in a different position, it might have instead rotated (in either direction) to the position where the wheels of buffers 321, 323 and 324 were in contact with outer surface 802.

There are therefore two rotational positions towards which outer housing 303 is biased by guide 320, and in each one rearward buffers 322 and 324 are at the top and bottom of body 301 , and forward buffers 321 and 323 are at each side. Because latch fingers 308 to 313 are aligned with the buffers, these are now similarly located at the top, bottom and sides of the body. The latch fingers are positioned and profiled for maximum engagement with inner surface 803, no matter which of the two rotational positions is assumed by outer housing 303.

In this example, top row latch finger 309 has engaged with inner surface 803 at the top of aperture 202, bottom row latch finger 312 has engaged at the bottom of aperture 202, and both middle row latch fingers 310 and 311 (not shown in this Figure) have engaged, one at each side of aperture 202. If the other rotational position had been assumed, then top row latch finger 308 and bottom row latch finger 313 would have engaged instead. Both middle row latch fingers always engage. Each latch finger 308 to 313 is rotatably mounted at its top end on a pin within a recess in outer housing 303, and has a base that can engage with inner surface 803. Because the latch fingers always engage with inner surface 803 in the same rotational position and therefore at the same angle, their bases can be profiled for maximum engagement. Thus, top row latch finger 309 has a flat base 901, and top row latch finger 310 has a flat base 902, both of which are profiled for engagement with inner surface 802 at the top of aperture 202.

In this embodiment, where the longitudinal axis 300 of latch 204 is at approximately 45° to the walls of the aperture, this means that the flat bases 901 and 902 are also at approximately 45° to axis 300, when the latch fingers are open. Thus, the flat bases are at an acute angle, shown at angle 903, to longitudinal axis 300, when measured from forward end 304. Similarly, bottom row latch fingers 312 and 313 have flat bases 904 and

905 respectively. These are profiled for engagement with inner surface 803 at the bottom of aperture 202, and therefore the bases are at an oblique angle, shown at angle 906, to longitudinal axis 300, when measured from forward end 304.

Because middle row latch fingers 310 and 311 engage with inner surface 803 on either side of aperture 202, their bases have a curved profile, such as base

907 of latch finger 310.

In other embodiments, where the aperture is at a different angle to the wall, or where there are more or fewer possible rotational positions that outer housing 303 can assume, the bases of the latch fingers would be profiled differently for maximum engagement with the inner surface of the wall.

Thus in this embodiment the guide is provided by four buffers, one pair of which is offset with respect to the other pair. These bias the rotation of outer housing into one of two predetermined rotational positions. In other embodiments, other guides could be used. For example, the ends of the buffers might not be wheels, if the outer surface of the wall were smooth enough to permit the buffer ends sliding across it. One of the rearward buffers in this embodiment could be further forward of the forward buffers, creating a complementary shape to the wall and thus creating a single possible rotational position. A single annular slanting buffer could be used. Alternatively, a single buffer that locates in one or more recesses in the wall would also bias the outer housing towards one or more predetermined positions. In other embodiments, the guide could comprise something other than buffers, in which case the latch could have a separate element to prevent the body being pulled all the way through the aperture.

Figure 10 Once the engaging latch fingers have passed through aperture 202, they need to open and engage with inner surface 803 of wall 111 to facilitate latching. Rotation outwards from their closed position requires clearance between the bases of the fingers and inner surface 803. Thus, when guide 320 reaches the rotational position shown in Figure 9, it may be necessary for body 301 to be further inserted into aperture 202 to allow the engaging latch fingers to open. To facilitate this, buffers 321 to 324 are compressible and spring-loaded, such that wheels 331 to 334 are biased towards forward end 304 of body 301 , but may also be moved towards rearward end 305 of body 301.

Buffer 322 is shown in cross-section in Figure 10. Wheel 332 is rotatably mounted on axle 342, which is housed within bearing 1001. Bearing 1001 is contained within buffer housing 1002, which is mounted on outer housing 303. Within bearing 1001 and encircling axle 342 is spring 1003. Collar 1004 on axle 342 engages with the top of spring 1003. The other buffers are similar except that buffers 321 and 323 have a longer axle and a correspondingly longer bearing.

Thus wheel 332 can be moved downwards, which compresses spring 1003, but on removal of the downward force spring 1003 will expand and return wheel 332 to its original position. In other embodiments, other methods of providing a compressible buffer biased towards the forward end of the body could be used.

Thus, returning to Figure 9, once the final rotational position has been reached, continued pulling on cable 108 moves body 301 still further into aperture 202 by compressing the buffers that are in contact with outer surface 802, which in this example is buffers 321 , 322 and 323, thus allowing the engaging latch fingers to open. When the maximum compression of the buffers has been reached, the latch has been fully inserted and pulling on cable 108 can cease. The spring-loading of the buffers then causes the latch 204 to move slightly backwards in aperture 202 until the engaging latch fingers fully engage with inner surface 803. The buffers may at this point still be slightly compressed, or may have returned to their original positions. This compressible spring loading of the buffers produces a secure latch, reducing rattle within the aperture. However, in other embodiments this could be omitted. Buffer 322 further includes a housing base 1005, attached to the base of buffer housing 1002 using two threaded bolts 1006 and 1007. Bearing 1001 has a shoulder that engages with base 1005. Nut 1008 is threaded onto bolt 1006 and nut 1009 is threaded onto bolt 1007. Turning these nuts in one direction causes base 1005 to move away from buffer housing 1002, allowing bearing 1001 to move downwards under gravity and thus moving buffer 322 away from the wall and disengaging it. Turning them in the other direction re-engages the buffer. Disengaging the buffer is necessary to allow removal of latch 204 from aperture 202, which will be described further with reference to Figure 14.

Figure 11

Figure 11 is a view of latch 204 in position in aperture 202, with a portion of wall 111 shown. Wall 111 is curved, but latch 204 could equally be used in an aperture in a flat wall. Latch fingers 309, 310 and 312 are engaged with the inner surface 803 of wall 111 (latch finger 311 is engaged on the side that is not visible). Thus the load of the latch is equally spread between four equidistant latch fingers, ensuring that none of the fingers is subject to unnecessary fatigue.

Figures 12 and 13 It is sometimes necessary to remove a latch from a wall in which it has been installed, and therefore latch 204 includes an optional release mechanism, which moves the latch fingers into their closed position thus allowing body 301 to be removed from aperture 202. Figures 12 and 13 are cutaway illustrations of latch 204, each showing a view of half-shell 701 with the release mechanism inside; Figure 12 is from slightly above and Figure 13 is from slightly below.

Release mechanism 1201 includes a circular washer 1202 constructed from two semi-circular plates 1203 and 1204 joined together. Screwed to washer 1202 are four upstanding rods 1205, 1206, 1207 and 1208. Rods 1205 and 1207 are longer than rods 1206 and 1208. Release mechanism 1201 is encased in outer housing 303. Washer 1202 is housed within gap 714, defined by the inner surface of outer housing 303. Each of rods 1205 to 1208 is within a cylindrical hole in outer housing 303 leading from gap 714, each hole being parallel with longitudinal axis 300 and aligned with the latch fingers. As shown in Figures 12 and 13, rods 1206 and 1207 are housed in half-shell 701. Rods 1205 and 1208 are housed in half-shell 702, which is not shown here.

Short rod 1206 has a collar 1209 near its tip, and similarly short rod 1208 has a collar 1210 near its tip. Long rod 1205 has a collar 1211 near its tip, and another collar 1212 nearly halfway along its length. Similarly, long rod 1207 has a collar 1213 near its tip, and another collar 1214 nearly halfway along its length.

Where each latch finger is attached to outer housing 303, there is defined a slot in the outer housing, each one communicating with one of the cylindrical holes so that a rod passes through or into it. Each collar is aligned with one slot. Thus, in half-shell 701, collars 1213, 1209 and 1214 are aligned with slots 1215, 1216 and 1217 respectively, for the top row, middle row and bottom row latch fingers respectively. Similarly (shown in Figures 16 and 17) in half-shell 702, collars 1211, 1210 and 1212 are aligned with slots 1218, 1219 and 1220 respectively, for the top row, middle row and bottom row latch fingers respectively. The diameter of each collar is greater than the diameter of the cylindrical holes, and thus the collars are confined to the slots.

Thus, washer 1201 can be moved up and down within outer housing 303, by an amount limited by the collars’ movement within the slots.

To construct latch 204 including release mechanism 1201, it is necessary to construct outer housing 303 in pieces around inner housing 302, rather than constructing two half-shells and bolting them together. However, if it is preferred to construct the latch in situ, release mechanism 1201 can be separated into two halves, each included in a half-shell 701 or 702. To facilitate this, washer 1202 should be rotated by 90° so that each plate 1203 and 1204 is aligned with a halfshell.

A latch according to the invention need not include a release mechanism. If there will never be a need to remove the latch then the release mechanism can be omitted.

Figure 14

Figure 14 shows the cutaway illustration of Figures 12 and 13 viewed from the other side. Half-shell 701, shown here without the buffers or the latch fingers, defines recesses 1401, 1402 and 1403 in which will be rotatably mounted latch fingers 308, 310 and 312 respectively. Similarly (shown in Figures 16 and 17) half shell 702 defines recesses 1404, 1405 and 1406 in which will be rotatably mounted latch fingers 309, 311 and 313 respectively. Each recess defines one of slots 1215 to 1220 in its wall; shown in this Figure are slot 1215 defined in the wall of recess 1401, and slot 1217 defined in the wall of recess 1403. Rod 1207 is visible in the slots, along with collars 1213 and 1214. As will be described with reference to Figure 15, each latch finger has a tip at its top end, and each slot is configured to accept a tip when the latch finger is in its open position. Movement upwards of washer 1201 causes each collar to move upwards in its slot and push the corresponding tip out of the slot, thus moving the latch fingers back to a closed position.

Outer housing 303 defines four apertures, one either side of each forward buffer (and therefore on the side of the latch when it is inserted), through which a tool can be inserted and operated to move washer 1201 towards forward end 304. When removing a latch underwater, as from a monopile, a hydraulic tool would be suitable. One such aperture, aperture 1404, is visible in Figure 4. Other means of moving the washer could be used in other embodiments. In order to disengage the engaged latch fingers to allow them clearance to rotate back to their closed position, it is necessary to push body 301 further into aperture 202 before moving washer 1201. Typically, removal of a latch from the monopile of a wind turbine will be carried out by a diver, who would not be able to exert enough force to compress the buffers and move body 301. Therefore, as described with reference to Figure 10, each buffer includes a means for disengaging it from outer surface 802 of wall 111 by moving it towards rearward end 305. This allows clearance for body 301 to be pushed into aperture 202 before release mechanism 1201 is operated. Thus,

Figure 15 Figure 15 shows views of latch fingers 308 (309 is identical), 310 (311 is identical) and 312 (313 is identical), separated from latch 204 and shown from different angles, in order to illustrate their configuration.

Each latch finger 308 to 313 has a tip terminating its top end. Latch fingers 308 to 313 have tips 1501, 1502, 1503, 1504, 1505 and 1506 (not all shown in this Figure) respectively. Each tip defines an indentation; for example tip 1501 defines indentation 1511. These indentations are shaped to receive one of rods 1205 to 1208. Each latch finger additionally defines a cylindrical aperture to receive a pin (not shown) around which it rotates; for example latch finger 308 defines aperture 1521. Each pin is mounted in the recess for the latch finger; for example the pin for latch finger 308 is mounted in recess 1401. Thus each latch finger is rotatably mounted to outer housing 303. In other embodiments, the latch fingers could be moveably attached to the outer housing in another way which allows each finger to move between an open and a closed position. For example, the latch fingers could be bolts that move inwards and outwards, potentially individually controlled by electronic means in a setting that is not in water. Thus in use, tip 1501 of latch finger 308 receives rod 1207 in its indentation

1511. Tip 1501 rests on collar 1213. When release mechanism 1201 is operated by moving washer 1202 towards forward end 304, rod 1207 and thus collar 1213 also move towards forward end 304. Collar 1213 pushes tip 1501 out of slot 1217, and thus moves latch finger 308 into a closed position. The other latch fingers are similarly configured, and therefore are also moved into the closed position at the same time.

Thus there is disclosed a release mechanism in which each said latch finger comprises a tip terminating its top end, and the outer housing defines a plurality of recesses aligned with said tips, such that for each latch finger, its tip is received within an aperture when the latch finger is in the open position. Each tip can be pushed out of its respective aperture, thus moving each latch finger to the closed position. In this embodiment the latch includes a plurality of rods, each defining at least one bead, each bead aligned with one of the tips with respect to the longitudinal axis. When the rods are moved towards the forward end, each bead engages with a tip and pushes it out of its respective recess. In this way, the latch fingers are moved to the closed position. Other methods of pushing the tips out of their apertures may be used. In this embodiment each bead is a collar on the rod, but the bead may for example be a protrusion on the rod, possibly integrally formed or attached later. It may go around the whole circumference of the rod or protrude in only one direction.

When force on washer 1202 is released, it moves towards rearward end 304, back to its original position. This allows all the latch fingers to return to their open position, towards which they are biased. This biasing is facilitated by a torsion spring (not shown) for each latch finger.

In this embodiment the rods all have the same diameter and therefore the indentations in the tips are substantially identical. This may not be the case in other embodiments. In still further embodiments, where the release mechanism is different, the tips may not have indentations. For example, the release mechanism may be designed so that the rods pass by the tips, rather than being received in them.

Figures 16 and 17 Figures 16 and 17 are cross-sections of latch 204, taken along two mutually orthogonal planes each containing longitudinal axis 300. In these cross-sections the latch is not in position, and therefore buffers 321 to 324 are not compressed.

Outer housing 303 rotates around inner housing 302, which defines an internal bore 308. Buffers 321 to 324 are mounted on outer housing 303. Recesses 1401 to 1406 are defined in the outer surface of outer housing 303, in which latch fingers are rotatably mounted. Thus latch finger 308 is mounted in recess 1401, latch finger 309 is mounted in recess 1402, latch finger 310 is mounted in recess 1403, latch finger 311 is mounted in recess 1405, latch finger 312 is mounted in recess 1403, and latch finger 313 is mounted in recess 1406. Each latch finger is rotatably mounted on a pin at its top end. For example, latch finger 308 is rotatably mounted on pin 1521.

In the open position, each tip is received in a slot defined in the wall of its respective recess. Thus, tip 1501 of latch finger 308 is received in slot 1215 in the wall of recess 1504. Similarly, the tips 1502 to 1506 of latch fingers 309 to 313 respectively are received in slots 1218, 1216, 1219, 1217 and 1220 respectively.

Rod 1207 passes through indentation 511 in the tip of latch finger 308 and a similar indentation in latch finger 312, with collars 1213 and 1214 just underneath the tips. Rod 1205 passes through indentations in the tips of latch fingers 309 and 313, with collars 1211 and 12142 just underneath the tips. Rod 1206 passes through an indentation in the tip of latch finger 310, with collar 1209 just underneath the tip. Rod 1208 passes through an indentation in the tip of latch finger 311 , with collar 1210 just underneath the tip. All four rods are attached to washer 1202.

Figures 18 and 19

Figures 18 and 19 show the same cross-sections when washer 1202 has been moved towards forward end 304. The collars have pushed their respective tips out of their slots, and all the latch fingers have rotated around their respective pins, such as pin 1521 for latch finger 308, to move to a closed position within their respective recesses. The outer circumference of body 301 is now such that, if it is in place in an aperture, it can be pulled out of the aperture in the direction of rearward end 306.

Figure 20

Installation of cable 108 in monopile 102 is illustrated in Figure 20. Typically, such installation is carried out by a self-elevating installation vessel 2001. This is a boat that, after navigating to the required position offshore, elevates itself on a number of legs, such as leg 2002. This ensures that the vessel is kept in position during installation of wind turbines and provides a foundation for the lifting of the heavy components. However, for the installation of cable an anchored boat may be sufficient.

Vessel 2001 has a crane 2003 including a hoist rope 2004. Underwater, the installation is assisted by a remotely operated underwater vehicle (ROV) 2005. This is wirelessly connected to control equipment on board vessel 1001 , for control by an operator. It includes a camera to provide an underwater view to the operator.

Before the cable is installed, a messenger wire 2006 is fed through the monopile and out through aperture 202 with the assistance of ROV 2005, and the underwater end is then passed back up to installation vessel 2001. The other end is attached to hoist rope 2004.

Cable 108 is held on spool 2007 on vessel 1001. On the vessel, a cable protection assembly 2008 is added to the end of cable 108, comprising bend restrictor 203, latch 204 and bend stiffener 205. The end of cable 108 is fed through latch 204, or alternatively a latch 204 may be formed around the cable by bolting together two sets of half-shells. Bend stiffener 205 is added by bolting two half-shells together around cable 108 and knuckle 306, and bend restrictor 206 is added by bolting two half-shells together around cable 108 and knuckle 308. Cable 108 is attached with a breakable attachment to the front end of bend stiffener 205, and is then attached to messenger line 2006. By pulling on hoist rope 2006, messenger line 2006 and cable 108 are pulled through aperture 202 until latch is fully engaged, as described with reference to Figure 9. Outer housing 303 automatically rotates into position as body 301 is pulled through the aperture, such that its latch fingers are rotated into a predetermined position in which they optimally engage with the inside of monopile wall 111.

Once the engaging buffers of latch 204 have been fully compressed, it is not possible to pull body 301 any further through aperture 202. The continued pulling on hoist rope 2004 causes the breakable attachment between cable 108 and bend stiffener 203 to break. Latch 204 then settles into its final engaged position. Cable 108, now running free through protection assembly 2008, is then pulled upwards to platform 104. The cable is then secured and the messenger wire 1006 disengaged. The remainder of the cable is then unspooled to the seabed before being buried. Typically, installation vessel 1001 includes a trenching unit or other cable burial equipment.

Thus, there is described herein a method of installing an electrical cable in an offshore wind turbine having a support structure, which in this example is monopile 202. It comprises the steps of attaching a clamp, which in this example is clamp 204, to the cable, and attaching a bend stiffener, which in this example is bend stiffener 205, to the back end of the clamp such that it surrounds the cable. The cable is passed into the support structure, such that the clamp enters structure front end first, and pulled upwards until it reaches a desired height. Thus, there is described herein a method of locating a latch within an aperture in a wall, which in this example is wall 111 of monopile 102. It comprises the steps of obtaining a latch, which in this example is latch 204, and inserting the body of the latch into the aperture, allowing the guide to rotate during insertion until the outer housing has reached a predetermined position. Insertion of the body is continued until a plurality of latch fingers are in an open position, preventing removal of the body from the aperture.