DE102020106275A1 - Submarine cables for laying on the bottom of the water - Google Patents

Abstract

The application relates to a submarine cable (100, 200, 300, 400, 700), in particular a high-voltage or medium-voltage submarine cable (100, 200, 300, 400, 700), comprising at least one phase conductor (102, 202.1, 202.2, 202.3, 302, 402), set up to transmit electrical energy, and at least one outer jacket (106, 206, 306, 406) surrounding the at least one phase conductor (102, 202.1, 202.2, 202.3, 302, 402) with an outer jacket surface (108, 208, 308) , 408), the outer jacket surface (108, 208, 308, 408) being a structured jacket surface (108, 208, 308, 408).

Description

The application relates to a submarine cable, in particular a high-voltage or medium-voltage submarine cable, comprising at least one phase conductor, set up to transmit electrical energy, and at least one outer jacket surrounding the at least one phase conductor. In addition, the application relates to an offshore wind farm, a method for producing a submarine cable, a method for laying a submarine cable and a use of a submarine cable.

The inner cabling network of an offshore wind farm is formed by a large number of submarine cables. In particular, a submarine cable is used to transmit energy in an offshore wind farm. For example, a submarine cable can connect an offshore wind turbine and an offshore transformer station in order to transmit the electrical energy generated by the offshore wind turbine from the kinetic energy of the wind to the offshore transformer station. An offshore transformer station can in turn be connected to an onshore transformer station of the offshore wind farm via at least one further submarine cable in order to transmit electrical energy to it and, for example, to enable the electrical energy to be fed into a public (not part of the internal cabling network) power grid .

When installing an offshore wind farm, but also with other offshore systems, laying the at least one submarine cable is associated with a high level of effort. Thus, in the prior art, a submarine cable is buried in the bottom of the water (in particular a seabed) between two devices of the offshore wind farm, so that the submarine cable is safely and invariably arranged between the devices during operation. In particular, a large number of ship activities with corresponding costs are necessary for burying a submarine cable.

The application is therefore based on the object of providing a submarine cable for energy transmission which enables the submarine cable to be installed more simply and, in particular, with less effort.

According to a first aspect of the application, this object is achieved by a submarine cable according to claim 1. The submarine cable is in particular a high-voltage or medium-voltage submarine cable. The submarine cable comprises at least one phase conductor set up to transmit electrical energy. The submarine cable comprises at least one outer jacket surrounding the at least one phase conductor and having an outer jacket surface. The outer jacket surface is a structured jacket surface.

In contrast to the prior art, the application does not provide a submarine cable with a smooth or profiled outer jacket surface, but rather a submarine cable with an outer jacket with a structured or profiled outer jacket surface. In particular, it has been recognized that a submarine cable with a smooth surface (if it would be laid on the bottom of a body of water) is affected by a current of the bed of water in an installation state of the submarine cable (i.e. when it is installed between two devices in order to enable energy transfer between these devices) is moved considerably. In particular, in this case there would be constant movements (to and fro) of the submarine cable and / or a (slow) rinsing of the submarine cable. The movements described would result in tensile forces on the submarine cable which could damage the submarine cable and, in the worst case, lead to total failure of the submarine cable, in particular tearing of the submarine cable.

By providing a structured outer jacket surface according to the application, the freedom of movement of the submarine cable is at least reduced. In other words, the structured surface at least reduces the constant movements and at least makes flushing away more difficult, so that a tensile force exerted on such a submarine cable is significantly reduced. In the case of the submarine cable according to the application, digging into the bottom of the water is therefore no longer necessary. The installation effort and the corresponding costs are reduced, in particular without increasing the risk of failure of the submarine cable.

The submarine cable according to the registration is suitable for laying on the bottom of a body of water (e.g. seabed). For example, the submarine cable can electrically connect two offshore devices (e.g. an offshore wind farm) to one another. The submarine cable can preferably be a power cable, in particular in the form of a medium-voltage submarine cable (at least 10 kV) or in the form of a high-voltage submarine cable (at least 60 kV). The power capacity of the submarine cable according to the application is in particular between 3 MW and 2.5 GW.

For energy transmission, a submarine cable according to the application has at least one electrically conductive phase conductor (for example made of copper or aluminum). It goes without saying that two or more phase conductors can be provided. In a preferred embodiment, exactly three phase conductors are provided. In particular, this optimizes the transmission of energy via a submarine cable. A electrically conductive phase conductor can be formed from one or more electrically conductive elements.

In addition to the at least one phase conductor, a submarine cable according to the application has an outer sheath. It goes without saying that a submarine cable can preferably comprise further cable elements, as will be explained in the further course of the description.

The outer jacket surrounds the at least one phase conductor, in particular indirectly. This means in particular that further layers can be arranged between the outer jacket and the phase conductor.

The outer sheath according to the application serves in particular to protect the submarine cable elements. The outer jacket has an outer jacket surface and in particular an inner jacket surface. The outer surface of the jacket faces outwards and, when installed, makes contact in particular with the environment (e.g. water and / or the bottom of the body of water). The inner jacket surface faces in the direction of the at least one phase conductor and in particular makes contact with an inner layer of the submarine cable.

According to the application, it is provided that the outer jacket surface is not a smooth or profile-free jacket surface, but a structured jacket surface. According to the present application, a structured jacket surface means in particular that the (outer) jacket surface has a profile and, in particular, is uneven (in particular in comparison to a smooth or flat jacket surface).

According to a first embodiment of the submarine cable according to the application, the outer sheath can be formed from HDPE (high density polyethylene). HDPE is very robust and at the same time easy to process, so that the use of an outer jacket made of HDPE is preferred. It goes without saying that in other variants of the application, other materials can also be used as an alternative or in addition.

The structure on the outer jacket surface can preferably be a regular or periodic structure, that is to say in particular a specific pattern. Such a structure is particularly easy to manufacture and gives the submarine cable specific and consistent structural properties. In other variants of the application, the structure on the outer jacket surface can be an irregular or non-periodic (e.g. random) structure.

According to a further embodiment of the submarine cable according to the application, the structured jacket surface can be formed by a base area and a plurality of elevations which protrude from the base area. The base can in particular form the lowest point in the structure or the profile. The at least two elevations extend, in particular, starting from this base area in a radial direction. In particular, the result is a surface with a large number of unevenness.

In particular, the following directions can be defined for a submarine cable: A cable extends in the axial direction. A radial direction is perpendicular to the axial direction. A circumferential direction is defined perpendicular to the radial direction and perpendicular to the axial direction. Accordingly, a jacket surface of a submarine cable extends along the circumferential direction.

In principle, the outer surfaces of the elevations or unevenness can be formed as desired. In one embodiment of the submarine cable according to the application, at least one elevation can at least partially have a concave outer surface. Alternatively or additionally, at least one elevation can at least partially have a convex outer surface. Alternatively or additionally, at least one elevation can at least partially have a planar outer surface.

According to a preferred embodiment of the submarine cable according to the application, the distance (also called the depth of the structure or of the profile) between the base (i.e. in particular the deepest point of the structure) and a tip of an elevation can be at least 0.5 cm, preferably at least 1 cm ( and at most 10 cm, preferably at most 4, preferably at most 1.5 cm). Especially at a distance between 1 cm and 2 cm, the surface structure considerably restricts the freedom of movement of an installed submarine cable. At the same time, such structures can be easily manufactured.

The distance can preferably depend on the diameter of the submarine cable. The larger the diameter of the submarine cable, the greater the distance can be.

In other words, as the diameter increases, the distance can increase accordingly.

According to a further embodiment of the submarine cable according to the application, at least one elevation (of the plurality of elevations) can be an axially extending elevation. This means in particular that the elevation has an axial extension having along the axis of the submarine cable. In particular, the elevation can extend at a constant distance in the axial direction of the submarine cable over at least a portion of the submarine cable, for example over the entire submarine cable. This means in particular that the outer cross-sectional shape of the submarine cable remains essentially the same at least over the entire (axial) length of a section. For example, web-shaped elevations can be provided.

For example, the cross-sectional area of an elevation can be essentially triangular. Instead of flat surfaces in the case of a triangular shape, it is also possible to provide convex or concave surfaces or a combination in the case of a cross-sectional area of an elevation. It goes without saying that the leg opposite the tip of the elevation can be curved (depending on the radius of the submarine cable).

According to a further embodiment of the submarine cable according to the application, at least one elevation can be an elevation running in the circumferential direction. For example, an elevation (with a constant distance) can run around the entire circumference of the outer jacket. In particular, grooves (the lowest point of which can form the base area) or the like can be embossed in the outer jacket, e.g. by means of a stamp.

According to a particularly preferred embodiment, a submarine cable can have at least two differently formed jacket surfaces. In other words, the submarine cable can have at least a first section and at least one further section, at least one of these sections having a structured outer jacket surface.

The further section can preferably have a smooth outer jacket surface. The further section can in particular be adapted for the route between an electrical connection of an offshore device and the bottom of the water. In other words, the first section is adapted for contact with a body of water and the further section for exclusive contact with water.

Alternatively or additionally, the shape of the cross-sectional area in the further section can be oval (compared to the essentially circular basic cross-sectional area (that is, the area without the elevations) of the first section).

A corresponding design of a submarine cable with at least two sections with two differently formed outer jacket surfaces, which are each adapted to the surroundings of the submarine cable in the installed state, the tensile forces acting on the submarine cable (e.g. due to currents) can be reduced even further. This can also be supported by adapting the cross-sectional shape.

According to a further particularly preferred embodiment of the submarine cable according to the application, at least one elevation at the tip of the elevation can have an extension element. The extension element can have a rod-shaped cross section. For example, the extension element can be plate-shaped or rod-shaped (in cross section). In particular, an extension element can significantly reduce constant movement, such as wobbling back and forth. An even more stable position of the submarine cable in an installation state can be achieved.

According to the application, it has been recognized in particular that the structure of the outer jacket surface should be different depending on the type of body of water or the nature of the ground in a laying area of the submarine cable, i.e. the area of the bed of water on which the submarine cable is to be laid. Exemplary and non-exclusive types of water bodies are soft soils, such as sandy soils, and hard soils, such as rock or stone soils.

According to a preferred embodiment (also referred to as embodiment A) of the submarine cable according to the application, the submarine cable can have two elevations, each with an extension element arranged at the respective tip. Between the first extension element and the further extension element (adjacent to the first extension element in the circumferential direction) there can be an angle between 170 ° and 190 °, preferably of essentially 180 °.

In other words, the extension elements (described above) are arranged on opposite sides of the submarine cable. Further elevations (e.g. in the form of spikes or the like, but without extension elements) can preferably be arranged. Such a submarine cable is particularly suitable for a soft subsoil, such as a sandy bottom. The elevations can preferably have a distance (between tip and base) between 0.5 cm and 1.5 cm. An extension element can preferably have a length of 1 cm and 10 cm, particularly preferably between 1 cm and 4 cm.

In particular, in an installation state of the submarine cable, the submarine cable can have sunk half of its circumference into the ground and the extension elements on the Lay the bottom of the water (flat). In this case, the submarine cable offers particularly little contact surface for water flowing along it. A stable and low-movement installation can be ensured.

According to a further embodiment (embodiment B) of the submarine cable according to the application, the submarine cable can have four elevations (adjacent in the circumferential direction), each with an extension element arranged at the respective tip. Between two extension elements that are adjacent in the circumferential direction, in particular between each extension element that is adjacent in the circumferential direction, there can be an angle between 45 ° and 135 °, preferably of essentially 90 °. Such a submarine cable is particularly suitable for a hard body of water, such as stone. The elevations can preferably have a distance (between tip and base) between 0.5 cm and 1.5 cm. An extension element can preferably have a length of 1 cm and 10 cm, particularly preferably between 1 cm and 4 cm.

Two extension elements that are adjacent in the circumferential direction serve in particular to support the submarine cable on the bed of the water in an installation state. Since it is not possible to control how the submarine cable ends up on the seabed during laying, the submarine cable has in particular exactly four extension elements in the circumferential direction, which preferably each have an angle of essentially 90 ° to the extension element adjacent in the circumferential direction.

According to a further embodiment of the submarine cable according to the application, the outer sheath can be an outer sheath produced only by an extrusion process. This means in particular that at least a section of the submarine cable has an outer sheath that was applied by an extrusion process. In particular, an extruder with a shaping opening can be used, the shaping opening being shaped in such a way that a certain structured outer jacket surface is formed.

In the case of a submarine cable with at least two different sections, as described above, a corresponding number of different shaping openings can be used.

Alternatively or additionally, the outer jacket can be an outer jacket produced by a combined extrusion and stamping process. This means in particular that at least a section of the submarine cable has an outer sheath that was applied by an extrusion and stamping process. In particular, an outer jacket that is initially extruded on can be deformed by a punch in such a way that a certain structured outer jacket surface is formed. For example, a groove-shaped structure can be introduced using a correspondingly shaped punch.

As already described, a submarine cable can preferably have three phase conductors in order to transmit energy (or power or current). A phase conductor can be formed in one piece, but also in several pieces. A phase conductor can be either round or sector-shaped and single-wire or multi-wire. Exemplary and non-final phase conductors are segment conductors (also called "segmented conductor") with at least two segments, stranded phase conductors (also called "stranded conductor"), pressed (or compressed) phase conductors (also called "compressed round conductor"), profiled phase conductors (also called “profiled conductor”) and compressed phase conductors (also called “compacted conductor”).

An (inner conductive) layer (non-metallic, conductive sheath) (e.g. as a phase conductor screen), then an insulation layer (e.g. extruded in one layer) (also known as an insulation screen) and then an (outer) can advantageously be placed around a phase conductor Conductive) layer (made of a non-metallic sheath in combination with a metal part) can be arranged as, for example, a core protective layer (also called core sheath). Metallic shielding can additionally be provided between the core protective layer and the insulation layer.

Furthermore, in one embodiment, an optical phase conductor cable can optionally be provided. The optical phase conductor cable can be coupled to a temperature detection device in order to monitor the temperature in the submarine cable. It can also be used for data transmission.

In order to obtain a certain cable cross-section (e.g. essentially circular or oval-shaped, as described above) for the submarine cable or a certain section, the submarine cable usually has a filler material (also called fillers).

A so-called bedding layer can be arranged between at least one reinforcement layer and the elements (described above) arranged inside the submarine cable, in order to provide in particular a protective layer between the at least one reinforcement layer and the inner cable elements. A bedding layer can also be placed between two reinforcement layers (if any) and between one Reinforcement layer and the outer jacket be arranged.

A reinforcement layer can be formed from several cables. For example, at least one rope can be made of metal (e.g. steel) and / or a composite material (e.g. carbon fiber, glass fiber, etc.).

Another aspect of registration is an offshore wind farm. The offshore wind park comprises at least one first offshore device (e.g. offshore wind turbine, offshore transformer station, etc.) and at least one further device (such as an onshore transformer station or another offshore device, e.g. an offshore wind turbine, offshore transformer station Etc.). The first offshore device and the further device are connected via a previously described submarine cable.

An offshore wind turbine can have a generator that converts the kinetic energy of the wind into electrical energy.

• - Bereitstellen eines Kabelgrundkörpers, enthaltend zumindest einen Phasenleiter, eingerichtet zum Übertragen von elektrischer Energie, und
• - Aufbringen eines Außenmantels mit einer äußeren strukturierten Manteloberfläche auf den Kabelgrundkörper durch einen Extrusionsprozess oder einen kombinierten Extrusions- und Stempelprozess.

Another aspect of the application is a method for producing a submarine cable, in particular a submarine cable described above. The procedure includes:

• - Provision of a cable base body, containing at least one phase conductor, set up to transmit electrical energy, and
• - Application of an outer jacket with an outer structured jacket surface on the cable body by an extrusion process or a combined extrusion and stamping process.

In particular, a cable base body can be provided which comprises all cable elements of a submarine cable (except for the outer sheath). An outer jacket can then be applied to at least a section of the cable base body in the manner described above.

• - Bereitstellen eines ersten Seekabels, aufweisend einen Außenmantel mit einer ersten äußeren strukturierten Manteloberfläche, angepasst für eine erste Gewässerbodenart,
• - Bereitstellen mindestens eines weiteren Seekabels, aufweisend einen Außenmantel mit einer weiteren äußeren strukturierten Manteloberfläche, angepasst für eine weitere Gewässerbodenart,
• - Ermitteln der Gewässerbodenart im Verlegebereich des zu verlegenden Seekabels, und
• - Bestimmen des zu verlegenden Seekabels aus dem ersten bereitgestellten Seekabel und dem mindestens einen weiteren bereitgestellten Seekabel, basierend auf der ermittelten Gewässerbodenart.

Yet another aspect of the application is a method for laying a submarine cable, in particular a submarine cable described above. The procedure includes:

• - Provision of a first submarine cable, having an outer sheath with a first outer structured sheath surface, adapted for a first type of seabed,
• - Provision of at least one further submarine cable, having an outer sheath with a further outer structured sheath surface, adapted for a further type of seabed,
• - Determination of the type of seabed in the laying area of the submarine cable to be laid, and
• - Determination of the submarine cable to be laid from the first submarine cable provided and the at least one further submarine cable provided, based on the determined type of seabed.

In particular, before laying a submarine cable, the subsurface can be analyzed and the type of body of water determined. In particular, it can be determined whether an essentially hard subsoil or an essentially soft subsoil (for example, limit values can be specified) is present.

The submarine cable to be laid can be determined depending on the determined type of waterbed in the laying area (e.g. soft or hard; sandy or stone floor; or the like). For example, when a soft subsoil (e.g. predominantly sandy soil) is detected, the above-described embodiment A can be determined and when a hard subsoil (e.g. predominantly stone soil) is detected, the above-described embodiment B can be determined. Then the specific submarine cable can be laid.

Yet another aspect is the use of a previously described submarine cable for laying the submarine cable on a body of water.

The characteristics of submarine cables, offshore wind farms, processes and uses can be freely combined with one another. In particular, features of the description and / or the dependent claims, even with complete or partial circumvention of features of the independent claims, can be independently inventive on their own or freely combined with one another.

• 1 eine schematische Ansicht eines Ausführungsbeispiels eines Seekabels gemäß der vorliegenden Anmeldung,
• 2 eine schematische Ansicht eines weiteren Ausführungsbeispiels eines Seekabels gemäß der vorliegenden Anmeldung,
• 3a eine schematische Ansicht eines weiteren Ausführungsbeispiels eines Seekabels gemäß der vorliegenden Anmeldung,
• 3b eine schematische Ansicht eines weiteren Ausführungsbeispiels eines Seekabels gemäß der vorliegenden Anmeldung,
• 3c eine schematische Ansicht eines weiteren Ausführungsbeispiels eines Seekabels gemäß der vorliegenden Anmeldung,
• 3d eine schematische Ansicht eines weiteren Ausführungsbeispiels eines Seekabels gemäß der vorliegenden Anmeldung,
• 3e eine schematische Ansicht eines weiteren Ausführungsbeispiels eines Seekabels gemäß der vorliegenden Anmeldung,
• 4a eine schematische Ansicht eines weiteren Ausführungsbeispiels (insbesondere Ausführungsform A) eines Seekabels gemäß der vorliegenden Anmeldung,
• 4b eine schematische Ansicht eines weiteren Ausführungsbeispiels (insbesondere Ausführungsform B) eines Seekabels gemäß der vorliegenden Anmeldung,
• 5 ein Diagramm eines Ausführungsbeispiels eines Verfahrens gemäß der vorliegenden Anmeldung,
• 6 ein Diagramm eines Ausführungsbeispiels eines weiteren Verfahrens gemäß der vorliegenden Anmeldung, und
• 7 eine schematische Ansicht eines Ausführungsbeispiels eines Offshore-Windenergiesystems gemäß der vorliegenden Anmeldung.

There are now a large number of possibilities for designing and further developing the submarine cable according to the application, the offshore wind farm according to the application, the method according to the application and the use of a submarine cable according to the application. For this purpose, reference is made, on the one hand, to the claims subordinate to the independent claims, and, on the other hand, to the description of exemplary embodiments in conjunction with the drawing. In the drawing shows:

• 1 a schematic view of an embodiment of a submarine cable according to the present application,
• 2 a schematic view of a further embodiment of a submarine cable according to the present application,
• 3a a schematic view of a further embodiment of a submarine cable according to the present application,
• 3b a schematic view of a further embodiment of a submarine cable according to the present application,
• 3c a schematic view of a further embodiment of a submarine cable according to the present application,
• 3d a schematic view of a further embodiment of a submarine cable according to the present application,
• 3e a schematic view of a further embodiment of a submarine cable according to the present application,
• 4a a schematic view of a further embodiment (in particular embodiment A) of a submarine cable according to the present application,
• 4b a schematic view of a further embodiment (in particular embodiment B) of a submarine cable according to the present application,
• 5 a diagram of an embodiment of a method according to the present application,
• 6th a diagram of an embodiment of a further method according to the present application, and
• 7th a schematic view of an embodiment of an offshore wind energy system according to the present application.

In the figures, the same reference symbols are used for the same elements.

the 1 shows a schematic (cross-sectional) view of an embodiment of a submarine cable 100 according to the present application. The submarine cable 100 is in particular a high-voltage or medium-voltage submarine cable 100 for the transmission of energy.

The submarine cable 100 includes at least one phase conductor 102 , set up to transmit electrical energy. The phase conductor 102 is in a cable body 104 integrated, which will be explained by way of example in the following exemplary embodiments.

The submarine cable 100 has an outer jacket 106 on, which is made in particular of HDPE. As can be seen, the outer jacket surrounds 106 the at least one phase conductor 102 (indirect). The outer jacket 106 has an inner or inner jacket surface 110 on which the cable body 104 contacted.

As can also be seen, the outer jacket 106 an outer jacket surface 108 on. According to the application it is provided that the outer jacket surface 108 a structured jacket surface 108 is, that is, has a structure or a profile. The outer mantle surface 108 is therefore not a smooth surface, as is known from the prior art, but a structured jacket surface 108 , so a mantle surface 108 with bumps. In the present case, the outer jacket surface has 108 an irregular or non-periodic structure.

the 2 shows a schematic (cross-sectional) view of a further exemplary embodiment of a submarine cable 200 according to the present application. In order to avoid repetition, only the differences from the previous exemplary embodiment are shown below 1 and otherwise reference is made to the previous statements.

The submarine cable shown 200 has three phase conductors 202.1 to 202.3 to transfer energy (or power or electricity). A phase conductor 202.1 to 202.3 can be formed in one piece, but also in several pieces. A phase conductor 202.1 to 202.3 can be round or sector-shaped and / or be single-wire or multi-wire.

Around every phase conductor 202.1 to 202.3 An (inner conductive) layer can advantageously first be placed around it 212.1 to 212.3 (non-metallic, conductive sheath) (e.g. as a phase conductor screen (also called conductor screen)), then an insulation layer 220.1 to 220.3 (eg extruded in one layer) (also called isolation screen) and then an (outer conductive) layer 214.1 to 214.3 (made of a non-metallic cover in combination with a metallic part) as a core protective layer, for example 214.1 to 214.3 (also called core sheath). Between core protective layer 214.1 to 214.3 and insulation layer 220.1 to 220.3 A metallic shield (not shown) can also be provided.

Furthermore, an optical phase conductor cable can optionally be used 222 be provided. The optical phase conductor cable 222 can be coupled to a temperature detection device in order to monitor the temperature in the submarine cable. It can also be used for data transmission.

In the present case, a substantially circular cable cross-section for the submarine cable 200 the submarine cable indicates 200 usually a filler material 216 (also called fillers).

A so-called bedding layer 224 can between the at least one reinforcement layer 218 and inside the submarine cable 200 arranged (previously described) elements (phase conductor, optical phase conductor cable 222 etc.) be arranged to in particular a protective layer 224 between the at least one reinforcement layer 218 and to provide the internal cable elements.

A bedding layer (not shown) can also be arranged between two reinforcement layers and between a reinforcement layer and the outer jacket.

A reinforcement layer 218 can be made from several ropes 218.1 , 218.2 be educated. For example, you can use a rope 218.1 made of metal (e.g. steel) and / or a composite material (e.g. carbon fiber, glass fiber, etc.) and the at least one other rope 218.2 made of metal (e.g. steel) and / or a composite material (e.g. carbon fiber, glass fiber, etc.).

All layers described above (except for the outer jacket 206 ) in the present case form the basic cable body according to the application 204 . As already described, this can have more, fewer and / or different layers. The outer jacket 206 has a structured outer jacket surface 208 on. In the present case, the structure is on the outer surface of the jacket 208 a regular or periodic structure.

The structured jacket surface 208 is in particular formed by a base area 226 (which in particular forms the lowest point of the structure) and a plurality of elevations 232 that from the base area 226 protrude in a radial direction.

Any survey 232 in particular has a tip 228 on. The distance 230 (also called the depth of the structure or the profile) between a point 228 and the base area 226 is preferably between 0.5 cm and 1.5 cm. As can also be seen, the outer surfaces of the elevations 232 in the present case, concave shape. In addition, the surveys 232 each axially extending or extending elevations 232 be.

the 3a until 3e show (perspective) views of further exemplary embodiments of submarine cables 300 according to the present application. To avoid repetition, only the differences from the previous exemplary embodiments are essentially described below 1 and 2 and otherwise reference is made to the previous statements. In particular, it should be noted that, for the sake of a better overview, the respective cable base body 304 is shown simplified and only one phase conductor 302 and a cable body surrounding the phase conductor. For example, the cable base body 304 similar to the cable body 2 be educated.

Here, the reference symbol denotes 301 the axial direction, the reference number 303 the radial direction and the reference number 305 the circumferential direction.

the 3a shows a submarine cable 300 with a structured outer jacket surface 306 that have a plurality of surveys 332 and a base 326 having. As can be seen, the outer surfaces are the elevations 332 Shaped flat in the present case. In addition, the surveys extend 332 each axially along the axis 340 of the submarine cable 300 .

The individual surveys 323 have a substantially triangular cross-section. The side of the triangle, that of the top 328 opposite, is particularly curved (depending on the radius of the submarine cable 300 ). The submarine cable 300 in the present case has an essentially star-shaped cross section. It goes without saying that more or fewer elevations can be provided as seen in the circumferential direction.

the 3b shows a submarine cable 300 with a structured outer jacket surface 306 that have a plurality of surveys 332 and a base 326 having. Here, too, are the outer surfaces of the elevations 332 In the present case, flat and the individual elevations 323 in particular have a substantially triangular cross-section. The cross section of the submarine cable 300 In the present exemplary embodiment, it has an octagonal shape. It goes without saying that more or fewer corners can be provided as seen in the circumferential direction.

In the embodiment according to 3c protrude bumps 332 with a rectangular cross-section from the base 326 in the radial direction 303 emerged.

In the embodiment according to 3d protrude bumps 332 with a semicircular cross-section from the base 326 in the radial direction 303 emerged. In particular, the outer surfaces of the elevations 332 present convex.

Like that 3a until 3d can be seen, the surveys extend 332 each in the axial direction 301 along the axis 340 of the respective submarine cable 300 .

In the embodiment according to 3e extend the elevations 332 in the circumferential direction 305 . In particular, the outer jacket surface 308 in the circumferential direction 305 have running grooves. These can be embossed, for example, by a stamping process.

the 4a and 4b show schematic (cross-sectional) views of two preferred exemplary embodiments of submarine cables 400 according to the present application. To avoid repetition, only the differences from the previous exemplary embodiments are essentially described below 1 until 3e and otherwise reference is made to the previous statements. In particular, it should be noted that, for the sake of a better overview, the respective cable base body 404 is shown simplified and only one phase conductor 402 and one the phase conductor 402 surrounding cable body includes.

the 4a shows a submarine cable 400 , which is designed in particular for use on a soft body of water, in particular a sandy bottom, while the 4b a submarine cable 400 shows, which is designed in particular for use on a hard body of water, in particular a stone floor.

As from the 4a can be seen, has the structured outer jacket surface 408 a plurality of elevations spaced from one another in the circumferential direction 432 on. The surveys 432 in particular have a substantially triangular cross-sectional area or cross-section. The surveys 432 can in particular extend axially, but can also be formed like a hump, that is, for example, be conical or pyramidal.

On two opposite sides of the outer surface of the jacket 408 are elevations 432 arranged, each at the respective tip 428 an extension element 450 have with a preferably rod-shaped cross-sectional area or cross-section. The distance 430 between a point 428 and the base area 426 is preferably between 0.5 cm and 1.5 cm. The length 452 an extension element 450 is preferably between 1 cm and 4 cm. Between the extension elements arranged adjacent to one another in the circumferential direction 450 an angle α = 180 ° is provided in the present case. It goes without saying that in other variants of the application the angle can be between 170 ° and 190 °.

In the installed state of the submarine cable shown 400 this preferably sinks up to half of its circumference into the (soft) seabed 466 a. The extension elements in particular are in this state 450 on the bottom of the water 466 on. In this state, the submarine cable will move 400 , for example by a current, made much more difficult, so that a permanently stable position of the submarine cable 400 on the bottom of the water 466 is achieved. No digging is required.

In the embodiment according to 4b has the structured outer jacket surface 408 a plurality of elevations spaced from one another in the circumferential direction 432 on. The surveys 432 in particular have a substantially triangular cross-sectional area or cross-section. The surveys 432 can in particular extend axially, but can also be formed like a hump, that is, for example, be conical or pyramidal.

As can be seen, there are exactly four elevations arranged in the circumferential direction 432 at the top 428 one extension element each 450 arranged with a preferably rod-shaped cross-sectional area or cross-section. The distance 430 between a point 428 and the base area 426 is preferably between 0.5 cm and 1.5 cm. The length 452 an extension element 450 is preferably between 1 cm and 4 cm. Between the extension elements arranged adjacent to one another 450 an angle α = 90 ° is (always) provided in the present case. It goes without saying that with other variants the respective angle can be between 45 ° and 135 °.

In the installed state of the submarine cable shown 400 lies the submarine cable 400 on the bottom of the water 466 and is in this position by two extension elements arranged adjacent in the circumferential direction 450 supported. In this state, the submarine cable will move 400 , for example by a current, made much more difficult, so that a permanently stable position of the submarine cable 400 on the bottom of the water 466 is achieved. No digging is required.

the 5 shows a diagram of a method according to the present application for producing a submarine cable, in particular a submarine cable according to one of the previous exemplary embodiments.

In a first step 501 a basic cable body is provided (e.g. corresponding 2 ), containing at least one phase conductor (preferably three phase conductors), set up to transmit electrical energy.

In a further step 502 an outer sheath with an outer structured sheath surface is applied to the basic cable body by an extrusion process or a combined extrusion and stamping process.

the 6th shows a diagram of a method according to the present application for laying a submarine cable, in particular a submarine cable according to one of the previous exemplary embodiments.

In one step 601 there is a provision of a first submarine cable (for example embodiment A), having an outer jacket with a first outer structured jacket surface, adapted for a first type of body of water.

In one step 602 (which can be carried out at least partially in parallel) at least one further submarine cable (eg embodiment B) is provided, having an outer jacket with a further outer structured jacket surface, adapted for a further type of seabed. In particular, means providing a submarine cable in the steps 601 and 602 that the respective submarine cable is basically available for laying.

In one step 603 the type of seabed is determined in the laying area of the submarine cable to be laid. For example, soil samples can be taken and analyzed in the laying area.

In one step 604 the submarine cable to be laid is determined from the first and the at least one further submarine cable provided, based on the determined type of seabed.

In particular, a specific soil parameter range can be specified for each of the at least two submarine cables. If it is determined that the soil samples (at least predominantly) lie in the soil parameter range that is assigned to the first submarine cable (e.g. embodiment A), then the first submarine cable is determined or selected. If it is determined that the soil samples (at least predominantly) lie in the soil parameter range that is assigned to the further submarine cable (e.g. embodiment B), then the further submarine cable is determined or selected.

Then the specified submarine cable is laid on the bottom of the water.

It goes without saying that three or more different submarine cables with different structures on the outer jacket surface can be provided for a corresponding number of different bodies of water.

the 7th shows an embodiment of an offshore wind farm 760 according to the present application. Two offshore wind turbines are exemplary 762 shown. It goes without saying that an offshore wind farm can have a large number of offshore wind turbines and at least one offshore transformer station (not shown). For example, a plurality of offshore wind turbines can be electrically interconnected to form a plurality of strings, each string being able to be electrically connected to an offshore transformer station. The offshore transformer station can in turn be electrically connected to a further offshore transformer station or to an onshore transformer station of the offshore wind farm.

An offshore wind turbine 762 is present on a foundation structure on the bottom of the water 766 , especially a seabed 766 , Installed. In other variants of the application, an offshore device can also be a floating offshore device with a floating foundation structure.

An offshore wind turbine 762 is set up to convert the kinetic energy of the wind into electrical energy. To transfer the generated electrical energy to another offshore wind turbine 762 and then, for example, to an onshore transformer station in the offshore wind farm there is an internal cabling network in the form of submarine cables 700 intended. A submarine cable 700 can for example like a related to the 1 until 4b described submarine cable, so that reference is made to the above statements to avoid repetition.

A submarine cable can be particularly preferred 700 in at least two, in particular (exactly) three sections 700.1 to 700.3 , be divided. A first and a third section 700.1 , 700.3 can each from an electrical connection 764 an offshore device 762 to (approximately) the bottom of the water 766 get lost. The second part 700.2 runs from one end of the first section 700.1 to one end of the third section 700.3 .

In other words, is the first and the third section 700.1 , 700.3 in the installed state of the submarine cable shown 700 essentially surrounded exclusively by water, while the second section 700.2 on the bottom of the water 766 is resting (and may be partially sunk, for example).

The first and the third section 700.1 , 700.3 can preferably have an outer jacket surface without a structure, that is to say with a smooth, profile-free surface.

The outer jacket surface of the second section 700.2 is a structured jacket surface as described above. In addition, the first and the third section 700.1 , 700.3 a substantially oval-shaped cross-sectional area and the second section 700.2 have a substantially circular basic cross-sectional area (that is, the area without the elevations). In other words, is the first and the third section 700.1 , 700.3 optimized for a course through the water and the second section 700.2 for laying on a body of water.

Claims (14)

Submarine cables (100, 200, 300, 400, 700), in particular high-voltage or medium-voltage submarine cables (100, 200, 300, 400, 700), comprising: - at least one phase conductor (102, 202.1, 202.2, 202.3, 302, 402), set up to transmit electrical energy, and - at least one outer jacket (106, 206, 306, 406) surrounding the at least one phase conductor (102, 202.1, 202.2, 202.3, 302, 402) with an outer jacket surface (108, 208, 308, 408) ), characterized in that - the outer jacket surface (108, 208, 308, 408) is a structured jacket surface (108, 208, 308, 408). Submarine cables (100, 200, 300, 400, 700) according to Claim 1 , characterized in that - the structured jacket surface (108, 208, 308, 408) is formed by a base area (226, 326, 426) and a plurality of elevations (232, 332, 432), which extend from the base area (226, 326, 426) protrude. Submarine cables (100, 200, 300, 400, 700) according to Claim 2 , characterized in that - at least one elevation (232, 332, 432) at least partially has a concave outer surface, and / or - at least one elevation (232, 332, 432) at least partially has a convex outer surface, and / or - at least one Elevation (232, 332, 432) has at least partially a planar outer surface. Submarine cables (100, 200, 300, 400, 700) according to Claim 2 or 3 , characterized in that - the distance (230, 430) between the base (226, 326, 426) and a tip (228, 328, 428) of an elevation (232, 332, 432) is at least 0.5 cm, preferably at least 1 cm. Submarine cables (100, 200, 300, 400, 700) according to one of the Claims 2 until 4th , characterized in that - at least one elevation (232, 332, 432) is an axially extending elevation (232, 332, 432). Submarine cables (100, 200, 300, 400, 700) according to one of the Claims 2 until 5 , characterized in that - at least one elevation (232, 332, 432) is an elevation (232, 332, 432) running in the circumferential direction. Submarine cables (100, 200, 300, 400, 700) according to one of the Claims 2 until 6th , characterized in that - at least one elevation (232, 332, 432) at the tip (228, 328, 428) of the elevation (232, 332, 432) has an extension element (450). Submarine cables (100, 200, 300, 400, 700) according to Claim 7 , characterized in that - the submarine cable (100, 200, 300, 400, 700) has two elevations (232, 332, 432) each with an extension element (450) arranged at the respective tip (228, 328, 428), - wherein there is an angle between 170 ° and 190 °, preferably of substantially 180 °, between the first extension element (450) and the further extension element (450) adjacent to the first extension element (450) in the circumferential direction. Submarine cables (100, 200, 300, 400, 700) according to Claim 7 , characterized in that - the submarine cable (100, 200, 300, 400, 700) has four elevations (232, 332, 432) each with an extension element (450) arranged at the respective tip (228, 328, 428), - an angle between 45 ° and 135 °, preferably of essentially 90 °, being present between two extension elements (450) which are adjacent in the circumferential direction. Submarine cable (100, 200, 300, 400, 700) according to one of the preceding claims, characterized in that - the outer sheath (106, 206, 306, 406) is an outer sheath (106, 206, 306, 406) produced only by an extrusion process and / or - the outer jacket (106, 206, 306, 406) is an outer jacket (106, 206, 306, 406) produced by a combined extrusion and stamping process. Offshore wind farm (760) comprising: - at least one first offshore device (762) and at least one further device (762), - wherein the first offshore device (762) and the further device (762) are connected via a submarine cable (100, 200, 300, 400, 700) according to one of the preceding claims. Method for producing a submarine cable (100, 200, 300, 400, 700), in particular a submarine cable (100, 200, 300, 400, 700) according to one of the preceding Claims 1 until 10 , comprising: - providing a cable base body (104, 204, 304, 404) containing at least one phase conductor (102, 202.1, 202.2, 202.3, 302, 402), set up to transmit electrical energy, and - applying an outer sheath (106, 206, 306, 406) with an outer structured jacket surface (108, 208, 308, 408) on the cable base body (104, 204, 304, 404) by an extrusion process or a combined extrusion and stamping process. Method for laying a submarine cable (100, 200, 300, 400, 700), in particular a submarine cable (100, 200, 300, 400, 700) according to one of the preceding Claims 1 until 10 , on a body of water (466, 766), comprising: - providing a first submarine cable (100, 200, 300, 400, 700) having an outer jacket (106, 206, 306, 406) with a first outer structured jacket surface (108, 208, 308, 408), adapted for a first type of body of water, - Provision of at least one further submarine cable (100, 200, 300, 400, 700), having an outer jacket (106, 206, 306, 406) with a further outer structured jacket surface ( 108, 208, 308, 408), adapted for another type of water bed, - determining the type of water bed in a laying area of the submarine cable to be laid (100, 200, 300, 400, 700), and - determining the submarine cable to be laid (100, 200, 300, 400, 700) from the first provided submarine cable (100, 200, 300, 400, 700) and the at least one further provided submarine cable (100, 200, 300, 400, 700), based on the determined type of seabed. Use of a submarine cable (100, 200, 300, 400, 700) according to one of the previous ones Claims 1 until 10 for laying the submarine cable (100, 200, 300, 400, 700) on a body of water (466, 766).

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