NO323161B1 - Installation that is less exposed to ice damage at sea. - Google Patents

Abstract

Installation that is little exposed to ice damage at sea. which installation comprises a shaft extending in a vertical direction from a deck level down to a level. under water, which shaft comprises an ice-breaking section which in the vertical direction downwards has an increasing cross-sectional dimension and extent from above the waterline level to below the waterline level, the ice-breaking section having an angle of inclination upwards from the horizontal so that ice is deflected mainly in the direction upwards of the section, characterized by that immediately above the ice-breaking section, the shaft comprises a shoulder section which has a smaller angle of inclination upwards from the horizontal than the ice-breaking section.

Description

Field of the invention

The present invention relates to installations for use at sea in areas with deposits of ice. More specifically, the invention relates to an installation that is little exposed to ice damage at sea.

Background of the invention and prior art

When using installations in ice-prone areas at sea, such as in Arctic waters, it can be a major problem that the installations are exposed to large forces applied from ice and floes that drift on the sea surface. Even in areas where large icebergs do not occur, mobile ice will be a potential threat to the integrity of the installation and could potentially cause damage to it, perhaps make it unstable or move it horizontally.

There are two main methods for reducing stresses from ice in such waters.

The first method involves forming a protective barrier around the installation, for example in the form of a protective filling around the installation, as described in patent publication US 4,828,431.

The second method consists of including features in the installation itself that work to reduce the stresses caused by ice. In this second method, for example, an ice-breaking section is built into the installation, at the level of the waterline, which section can have an upward slope from the horizontal so that ice is deflected mainly in the direction upwards of the section. For most constructions known to date, the aforementioned section is designed so that the inclination towards the horizontal is even or increases upwards along the installation, calculated from the seabed. Reference is made to patent publications US 4,486,125, US 4,639,167, US 4,808,036 and US 5,269,632, all of which describe ice-breaking sections with increasing inclination towards the horizontal with increasing distance from the sea surface. A typical ice-breaking section according to the aforementioned publications has an hourglass-like shape, as ice drifting towards the installation is broken upwards towards the narrowest part of the section, while the section higher up has a slope outwards from the centreline of the installation, so that broken ice is deflected back towards the direction of the ice drift direction, and falls down towards the sea surface. There are also constructions which have a slope in the waterline downwards from the horizontal and which thus mainly deflect ice in a downward direction.

There is still a need for alternative designs of installations for use in ice-prone waters. There is a particular need for an ice-breaking construction which is more effective with regard to quickly breaking up the ice into smaller pieces, so that the pieces of ice are not carried towards the platform and accumulate close to the platform's deck.

Summary of the invention

The above-mentioned needs are met with the present invention, by providing an installation that is little exposed to ice damage at sea, which installation comprises: a shaft that extends in a vertical direction from a deck level down to a level under water, which shaft comprises

an ice-breaking section (a ramp) which in a vertical downward direction has an increasing cross-sectional dimension and extent from above the waterline level to below the waterline level, the ice-breaking section having an angle of inclination upwards from the horizontal so that ice is deflected mainly in the direction upwards on the section, characterized by the fact that immediately above the ice-breaking section, the shaft comprises a shoulder section which has a smaller angle of inclination upwards from the horizontal than the ice-breaking section.

With the installation according to the invention, the ice is first deflected upwards from the water line. Then, as the ice arrives at the shoulder section, the ice is deflected downward towards the waterline. Thus the ice is deflected and broken in two bending directions, first upwards and then downwards, which results in a faster breaking up of the ice into smaller pieces. With a faster break-up into smaller pieces, in most cases the forces acting on the installation due to the ice are reduced, especially when the ice has stuck to the seabed. With the previously known constructions, the ice is only deflected upwards (possibly only downwards) from the waterline, which causes the ice to stick together to a greater extent.

The ice-breaking section can advantageously have a uniform inclination towards the horizontal, which is advantageous with regard to simple construction and construction. Alternatively, the ice-breaking section can have an increasing slope towards the horizontal in the upper part of the section, which can be advantageous in order to have an increased bending angle, and a reduced contact surface for the ice against the ice-breaking section. Reduced contact surface can reduce friction and. ease the deflection. Furthermore, a low deflection angle on the lower part of the ice-breaking section can ensure that all ice is deflected upwards on the section. The ice-breaking section conveniently has a slope of approx. 45° to the horizontal.

The shoulder section advantageously has a slope of approx. 10° to the horizontal, but it can have a varying slope or be horizontal. A certain slope is most preferred so that the ice can more easily slide off the shoulder section in the direction of the ice-breaking section.

The difference in angle of inclination between the ice-breaking section and the shoulder section is advantageously at least 20°, which is appropriate for getting a good breaking up of the ice in the transition.

Installation is advantageously a gravity-based installation that rests on the seabed, more preferably a gravity-based structure (gravity-based structure) constructed of concrete or steel or a combination of these, with one or more shafts, each shaft being designed according to the invention. Heavy, vertically acting ice load on the shoulder section can be tolerated better for an installation that rests on the bottom than for a floating installation, but the invention can also be used for floating installations in areas with a moderate occurrence of ice provided that the installation's buoyancy is satisfactory. For an installation that rests on the bottom, a heavy ice load will be able to stabilize the installation.

Figures

The invention is illustrated using three figures, where:

Figure 1 illustrates an installation with a polygonal cross-section, according to the invention, Figure 2 illustrates an installation with a circular cross-section, according to the invention, and

Figure 3 gives a closer illustration of an installation according to the invention.

Detailed description

Reference is first made to Fig. 1, which in simplified form illustrates a gravity-based installation 1 according to the invention, comprising a shaft 2 which extends from a deck level 3 downwards to a level under water. The shaft 2 contains an ice-breaking section (a ramp) 4 which extends from above waterline level to below waterline level and has an angle of inclination upwards from the horizontal so that ice is deflected mainly in an upward direction on the section. Immediately above the ice-breaking section, a shoulder section 5 is arranged which has a lower angle of inclination towards the horizontal. The illustrated installation has a polygonal (possibly square or rectangular) cross-section normal to the vertical in the shaft, an ice-breaking section with an angle of inclination approx. 45° upwards from the horizontal, and a shoulder section with an inclination angle of approx. 10° upwards from the horizontal. The shoulder section has a typical width in the horizontal direction of approx. 10 m from outer edge to inner edge towards the shaft. The ice-breaking section will normally be larger than the shoulder section, and it will typically extend vertically from slightly below the lowest waterline to slightly above the highest waterline, with a sufficient margin that the lower edge of drift ice is always expected to hit the ice-breaking section. An angle of inclination upwards from the horizontal of approx. about. 45° on the ice-breaking section is believed to be optimal with regard to the forces applied by the ice in most cases.

The cross section of the installation normally on the vertical in the shaft can have different shapes. Fig. 2 and Fig. 3 illustrate an embodiment of a gravity-based installation according to the invention with a round cross-section, with a corresponding design of the ice-breaking section and the shoulder section. Fig. 3 illustrates how ice 6 will be broken up against the ice-breaking section and the shoulder section. Initial break-up of ice is assumed to take place when the ice hits the ice-breaking section 4, further break-up takes place at the transition 7 between the ice-breaking section and the shoulder section, where it is assumed that the ice will accumulate first. Accumulated ice, pack ice, contributes due to increased weight to stabilize the installation, both with regard to tipping moment caused by ice and resistance to sliding on the seabed. Accumulated ice will protect the installation in the event of a collision with larger drifting amounts of ice later in the ice season. Spraying with water to generate accumulated pack ice later in the ice season is therefore assumed to be unnecessary. Thus, the installation according to the invention leads to increased passive ice protection, which means that active measures for ice protection can be reduced.

Claims (10)

1. Installation that is not exposed to ice damage at sea, which installation comprises: a shaft (2) extending in a vertical direction from a deck level (3) downwards to a level under water, which shaft comprises an ice-breaking (4) section which in a downward vertical direction has increasing cross-sectional dimension and extent from above waterline level to below waterline level, the ice-breaking section having an angle of inclination upwards from the horizontal so that ice is deflected mainly in the direction upwards of the section, characterized in that immediately above the ice-breaking section the shaft comprises a shoulder section (5) which has a smaller angle of inclination upwards from the horizontal than the ice-breaking section. 2. Installation according to claim 1, characterized in that the ice-breaking section (4) has an even slope towards the horizontal. 3. Installation according to claim 1, characterized in that the ice-breaking section (4) has an increasing slope towards the horizontal in the upper part of the section. 4. Installation according to claim 1 or 2, characterized in that the ice-breaking section (4) has a slope of approx. 45° to the horizontal. 5. Installation according to claim 1 or 2, characterized in that the ice-breaking section (4) is designed with a polygonal cross-section and with an average slope of approx. 45° to the horizontal. 6. Installation according to claim 1, characterized in that the shoulder section (5) has a slope of approx. 10° to the horizontal. 7. Installation according to claim 1, characterized in that the shoulder section (5) has a varying slope. 8. Installation according to claim 1, characterized in that the difference in angle of inclination between the ice-breaking section (4) and the shoulder section (5) is at least 20°. 9. Installation according to claim 1, characterized by the fact that it is a gravity-based installation that rests on the seabed. 10. Installation according to claim 1, characterized in that it is a gravity-based structure constructed of concrete or steel or a combination thereof, with one or more shafts.