NO333130B1 - A method for vertical alignment of a twine - Google Patents

Abstract

Method for vertically aligning a support element (5) which is suitable for supporting an equipment unit such as a wind turbine or the like. and which is designed for connection to a foundation (1) installed on a seabed. (B). The method includes the steps of:. a) measuring the slope angle of the foundation (a) ,. b) transmitting the angle of inclination (a) to a first end of the support element (5), c) forming an end part (8) with an angular orientation relative to the longitudinal axis (y) of the support element corresponding to the angle of inclination, and d) installing the support element via its first end on the foundation, so that thereby the support element assumes a vertical orientation.

Description

A method for vertical alignment of a tower The invention relates to foundations for supporting equipment units such as wind turbines and the like, and where these foundations are designed for placement on a seabed. More specifically, the invention relates to a method for vertical alignment of a support element which is suitable for supporting an equipment unit such as a wind turbine or the like, and which is designed for connection with a foundation which is installed on a seabed.

A requirement for wind turbine towers is that they must have minimal or no deviation from an exact vertical position. In the offshore wind sector, it is a particularly practical challenge to be able to achieve satisfactory verticality. The towers have been manufactured as standardized components, which fit onto foundations with flanged connections placed above sea level. Leveling procedures have thus far been focused on providing a horizontal flange where the tower can be installed.

The known technique for achieving verticality includes a number of methods:

• Leveling of the seabed before the foundations are installed,

• Use of transition parts with shrink compound,

• Use of spacer elements ("shims") or other distance-keeping objects,

• Jacking and shuddering of tower legs, and

• Use of eccentric skirt spaces (for example as described in the international patent publication WO 2010NO00211).

All the known methods, however, require a certain degree of extra offshore work, and associated logistics, which is costly and time-consuming.

Furthermore, DE 102008000382 A1 and WO 2011/007065 A1 describe other methods for providing vertical adjustment of a support element. The former publication shows a system of loose "wedges" which can be rotated to adjust the angle of the tower, while the latter shows a device for being able to adjust the verticality of the tower after it has been installed.

The applicant has developed and realized the invention in order to overcome the disadvantages associated with the previously known technique, and to be able to achieve further advantages.

The invention is characterized in the independent patent claim, while the non-independent patent claims describe other inventive characteristics.

A method has been developed for the vertical alignment of a support element suitable for supporting an equipment unit, such as a wind turbine or the like, and designed for connection with a foundation installed on a seabed, where the method comprises the step:

a) measurement of the angle of inclination of the foundation,

where the procedure is further characterized by the steps:

b) transferring the inclination angle to a first end of the support element,

c) forming an end part on the first end of the support element, where the end part has a

angular orientation in relation to the longitudinal axis of the support element which corresponds to

the inclination angle, and

d) installing the support element on the foundation via the first end of the support element,

whereby the support element assumes a vertical orientation.

In one embodiment, step c) includes removing a region from the first end of the support member, which region has an angular dimension corresponding to the angle of inclination.

In one embodiment, a first flange is attached to the end portion prior to step d).

In one embodiment, step d) includes a connection of the first flange with a second flange associated with the upper end of a support structure projecting from the foundation.

In one embodiment, step d) is carried out above sea level.

In one embodiment, step d) is carried out at an offshore installation site.

In one embodiment, the foundation is installed with a naturally provided slope on a seabed below a body of water prior to step a), and a free end of the support structure element projects above sea level.

The inventive method of achieving verticality eliminates the need for costly and time-consuming offshore works and associated logistics, allowing the top of the foundation to remain non-vertical.

These and other characteristics of the invention will emerge from the subsequent description of a preferred embodiment, here given as a non-limiting example, with reference to the drawing, where: Fig. 1 shows a side view of a wind turbine foundation which is installed on a sloping seabed ,

Fig. 2 shows an enlarged view of the end of a tower,

Fig. 3 is a side view corresponding to the side view in fig. 1, but also shows a tower designed in accordance with the inventive method, and

Fig. 4 is an enlarged section of the area marked "A" in fig. 3.

Fig. 1 shows a typical situation where a foundation 1 is installed - in a manner known per se - on a sloping or uneven seabed B. In the embodiment shown, the foundation includes a ballastable buoyancy body 1a with a bottom plate 2, and a ground-penetrating skirt 3 A support structure, here a tubular column 4, extends up from the body la, and to a distance above sea level S.

As a result of the slope of the seabed and/or as a result of an uneven skirt penetration, the tower 4 has an angle of inclination (or angle of inclination) a. This angle of inclination may lie outside acceptable tolerances.

In order to take this angle of inclination into account, and to achieve a vertical alignment of a tower that is suitable for supporting an equipment unit such as a wind turbine or the like (not shown), the angle of inclination is measured and transferred to the manufacturing site where the wind turbine tower is manufactured. Fig. 2 shows the end of the tower 5 which is to be connected to the tubular column 4. The figure shows how the angle of inclination has been transferred to the end of the tower 5, and how an angular section 9 has been removed, for example by means of grinding or sawing, so that a angled end part 8, which has an angle corresponding to the angle of inclination of the foundation a. Figures 3 and 4 show the tower 5, with the angled end part 8, connected to the inclined column 4, and shows that the tower has a vertical orientation that is within acceptable tolerances for the installation of a wind turbine. In this embodiment, the connection is provided by means of respective flanges 6, 7 (see fig. 4).

In the drawing, the angle of inclination is exaggerated to illustrate the invention. Acceptable deviations in the vertical position of the tower are typically within the range of 0.1° to 0.3°, while inclination angles for installed foundations can have levels of from 1° to 2°, or more.

Although the invention is described here in connection with a tubular column and a tower carried by a ballastable buoyancy foundation, the invention can equally well be used for square structures, trusses, steel tube foundations, pile foundations and the like.

Claims (7)

1. Method for vertical alignment of a support element (5) suitable for supporting an equipment unit such as a wind turbine or the like, and designed for connection with a foundation (1) installed on a seabed (B), where the method comprises the step: a) measurement of the angle of inclination of the foundation (a), where the method is further characterized by the steps: b) transfer of the angle of inclination (a) to a first end of the support element (5), c) forming an end part (8) on the first end of the support element (5), where the end part (8) has an angular orientation in relation to the longitudinal axis of the support element (y) which corresponds to the angle of inclination (a), and d) installing the support element via its first end on the foundation, whereby the support element assumes a vertical orientation. 2. Method according to claim 1, where step c) includes the removal of an area (9) from the first end of the support element, which area (9) has an angular dimension corresponding to the angle of inclination (a). 3. Method according to claim 1 or 2, where before step d) a first flange (6) is attached to the end part (8). 4. Method according to claim 3, where step d) includes the connection of the first flange (6) with a second flange (7) which is connected to the upper end of a support structure (4) which projects from the foundation. 5. Method according to one of the preceding claims, where step d) is carried out above sea level (S). 6. Method according to one of the preceding claims, where step d) is carried out at an offshore installation site. 7. Method according to one of the preceding claims, where the foundation (1) before step a) is installed with a naturally provided slope on a seabed (B) under a body of water, and a free end of the support structure element (4) extends above sea level ( S).