EP3892529A1 - Floating power supply station - Google Patents

Abstract

The invention relates to a floating power supply station (2) for providing electricity, in particular for berthing ships, comprising a floating body (4) to ensure that the power supply station (2) can float independently, a foundation (6) for attaching the floating body (4) to one Ground (8), in particular at the bottom (8) of a body of water, a mechanical connecting means (10) for connecting the foundation (6) to the floating body (4), an electrical conductor (12) for electrically connecting the power supply station (2) to a electrical supply line (14), at least one connection (16) for establishing an electrical connection with the power supply station (2), in particular with a berthing ship.

Description

The present invention relates to a floating power supply station for providing electrical power, in particular for supplying power to ships.

In order to minimize particulate matter pollution in areas close to ports, a power supply for ships docking in ports is usually provided via shore power supply devices that supply the docking ships with electricity. In this way, the ships' diesel engines, which are polluting particulate matter, do not have to be active to supply the ships with electricity. The surrounding air is therefore not polluted. In times of high port utilization, however, it is not possible to simultaneously supply all ships berthing in a port with electricity via the shore power supply devices. In addition, depending on the water level, it is not always possible, especially for larger ships, to to be moored directly in the port in order to gain access to the shore power supply facilities tied locally to the port location.

In addition to a power supply for ships docking in coastal regions, it is necessary to provide a sufficient charging infrastructure in these regions also to provide power supply points for electric or hybrid vehicles. However, setting up charging stations within coastal regions is a major challenge, in particular because of the adverse weather conditions and the risk of storm surges and the like, since the known power supply devices in these regions are regularly irreparably damaged.

It is therefore the object of the present invention to at least partially remedy the aforementioned disadvantages of known power supply devices. In particular, the object of the invention is to provide a robust, reliable and always available power supply both for ships and for land vehicles in coastal regions.

According to the invention, a floating power supply station is provided for providing power, in particular for berthing ships. Here, the floating power supply station according to the invention comprises a floating body to ensure that the power supply station can swim independently, a foundation for attaching the floating body to a bottom, in particular the bottom of a body of water, a mechanical connecting means for connecting the foundation to the floating body, an electrical conductor for electrically connecting the Power supply station with an electrical supply line and at least one connection for establishing an electrical connection with the power supply station, in particular with a berthing ship.

The floating power supply station can in particular be used to supply power to ships, but it is also conceivable to supply other means of transport, such as supplying flying objects or motor vehicles, in particular electric or hybrid vehicles. In addition, a supply of stationary objects by means of the floating power supply station in question is also conceivable. The power supply station according to the invention can function as a charging station and battery-operated Supply means of transport or battery-operated stationary objects with charging current to charge the batteries. On the other hand, the current made available by the power supply station can also be provided for direct consumption, for example for lighting and operating other electrical loads on ships or the like. In this context, a floating body is understood to mean a body which ensures that the power supply station is buoyant by generating buoyancy when the power supply station is arranged in the water. With a view to reliable buoyancy, the floating body can preferably be in the form of an at least partially spherical, at least partially conical or at least partially barrel-shaped body. In the context of the invention, a foundation is understood in particular as a heavy, rigid and vibration-resistant body that is intended to attach the float, preferably to the bottom of a sea, a river, a canal or a lake, but possibly also on land, especially in coastal regions at risk of flooding . Here, the foundation can also be at least partially hollow-shaped and, for example, accommodate components, in particular electrical components, of the power supply station. An electrical supply line for supplying power to the power supply station in question can also be designed in particular in the form of a high-voltage line, preferably in the form of a submarine cable. It is also understood that more than one connection for establishing an electrical connection with the power supply station can also be provided, which, for example, allows a number of current collectors to be connected at the same time.

In order to ensure reliable buoyancy and simultaneous material robustness, it can advantageously be provided according to the invention that the floating body is at least partially hollow-shaped, the floating body preferably being a material of high density arranged on the outside and at least one material or medium arranged in the interior less Having density. Here, the floating body can for example have a watertight, stable cover made of a high-density material, for example a metal material, arranged on an outside of the floating body, and the interior can be filled with air or a solid low-density material such as cork or styrofoam or the like. In this context, a high density can in particular be understood to mean a density that is greater than that of water, i.e.> 1g / cm ³ , whereas a low density can be understood to mean a density that is smaller than that of water, i.e. <1g / cm ³ is. It goes without saying that a floating body with a hollow structure can also be constructed in such a way that a high-density material arranged in the interior is enveloped by a water-tight, low-density material which has corresponding cavities.

With a view to generating sufficient buoyancy to ensure a structurally simple arrangement of functional and externally accessible components of the power supply station, it can advantageously be provided that the float is designed in such a way that at least 1/3 of the power supply station is located in the water , preferably at least 2/5 of the total height of the float is permanently arranged above the water surface. The total height can be viewed in connection with the center of gravity of the float in the water, so that the maximum length or extension of the float perpendicular to the water surface when the float is arranged in the water can be viewed as the total height of the float in the context of the invention. To ensure a corresponding buoyancy, it is advantageous if the float is designed to be water-tight so that no water can penetrate the float when it is used in water. This also enables the possibility of accommodating water-sensitive components of the power supply station, such as, in particular, all electrical components.

In the context of a particularly durable and stable design of the power supply station in question, it can advantageously be provided in particular that the float is at least partially made of a corrosion-resistant material, preferably at least partially made of stainless steel, in particular at least partially made of V2A or V4A steel. Alternatively or additionally, the floating body can be provided with a protective layer, in particular a protective lacquer or the like. With regard to the possible inclusion of electrical components, it goes without saying that the floating body advantageously has a corresponding seal against the ingress of water.

With regard to a secure and reliable fastening of the power supply station according to the invention even in adverse weather conditions, in particular strong currents or strong waves, it is particularly conceivable that the foundation in the form of an at least partially metal-containing material, preferably in the form of a Metal framework is formed with a concrete cladding, in particular in the form of reinforced concrete. Here, within the framework of a particularly stable arrangement, it can also be provided that the foundation is additionally attached to the ground, in particular to the bottom of a sea or another body of water.

In order to ensure a simple, flexible and at the same time stable attachment of the floating body to the foundation, it can objectively also advantageously be provided that the mechanical connecting means for connecting the foundation to the floating body is in the form of a chain, preferably a link chain. Alternatively, other forms of connecting means would also be possible, for example wire ropes, in particular steel ropes. In the context of a particularly stable and reliable attachment of the float to the foundation, more than one mechanical connecting means for connecting the foundation to the float, for example at least two connecting means, can be provided, the connecting means then preferably being attached on opposite sides of the float. The connecting means can then also be fastened on opposite sides of the foundation. Alternatively, only one, then preferably centrally arranged, fastening point can also be provided on the foundation.

In the context of a long-lasting and stable design of the power supply station in question, it is particularly conceivable that the mechanical connecting means for connecting the foundation to the floating body is designed and attached to the foundation in such a way that the electrical conductor at a maximum expansion of the mechanical connecting means as a result of buoyancy of the float has not yet reached its maximum expansion in order to minimize the mechanical tensile stress on the electrical conductor. In this way, the electrical conductor is protected from wear and tear caused by undesirable tensile stresses. In order to prevent or minimize mechanical tensile stress on the electrical conductor, the connecting means can either be significantly shorter than the electrical conductor or be attached to the foundation in a correspondingly decentralized manner.

With regard to a stable and at the same time flexible design of an electrical conductor in question, it can advantageously be provided according to the invention in particular that the electrical conductor is formed in the form of a flexible conductor, preferably in the form of a stranded conductor. Alternatively, the training of full leaders or Busbars or the like can be provided which, for example, can have flexible elements to ensure the necessary flexibility. The electrical conductor can be connected to the foundation, preferably at least partially arranged within the foundation. As part of a simple and reliable connection of the electrical conductor to the electrical supply line, the electrical conductor can be connected to the electrical supply line within the foundation, for example. In this case, for example, one connection or several connections for connecting the electrical conductor to the electrical supply line can be provided within the foundation. As an alternative to a connection of the electrical conductor to the electrical supply line within the foundation, the electrical conductor can, for example, also be passed through the foundation and be connected to the electrical supply line at a different position outside the foundation. With regard to sufficient electrical conductivity for the rapid transmission of even higher currents, it can be provided in an objectively advantageous manner that the electrical conductor is made of a material with a specific electrical conductivity σ of more than 20. 10 ⁶ S / m, preferably at least partially from an aluminum material, in particular at least partially from a copper material. The conductors in question should preferably be insulated with high-performance and wear-resistant insulators, for example based on polyethylene, polyvinyl chloride, polyester or the like. With regard to sufficient current conductivity, it can advantageously be provided according to the invention that the electrical conductor enables a current transmission capacity of more than 10 kW, preferably of more than 100 kW, in particular of more than 250 kW.

In order to guarantee a secure electrical connection between the power supply station and an object receiving power, for example a ship or an electric vehicle, it can be provided in particular that the connection is in the form of a charging socket for inserting a charging plug, the connection preferably being a flap for closing the connection, the flap in particular having a pretensioning element which holds the flap in a closed state. In contrast to a permanently installed cable or the like, when a charging socket is arranged there is not so easy the risk that the connection will come into contact with water. As long as the power supply station only has a single connection, there is no need for a charging control device to control a current output. In addition to permanent protection against water splashes, the objective is used preferably provided flap, in particular a protection of the charging socket from being covered, for example by excrement from seagulls and other sea birds.

In order to ensure stable and secure storage of the float, especially when the water level drops, it can advantageously be provided according to the invention that a holding device is provided for supporting the float, the holding device preferably having an opening for receiving the holding device, the opening in particular corresponding to the shape of the float Shape of the floating body is formed. The holding device can in particular be fixed to the foundation, preferably firmly connected to the foundation. The floating body can then preferably be stored in the holding device when the water level is low. If the water level then rises, the power supply station can swim in the water via the buoyancy of the floating body, so that the power supply station is conveyed out of the holding device. To support a simple transport of the floating body out of the holding device, the holding device can, for example, have recesses for the penetration of water. In particular when the floating body is stored in the holding device, the holding device could also be formed as a ramming protection in front of berthing ships. For this purpose, the holding device could, for example, be made of a robust or partially elastic material. It would be conceivable, for example, to have an elastic collar arranged along the opening of the holding device, which could function as a ram protection or the like.

With a view to inserting a charging plug into the connection in a manner that is gentle on the material, provision can in particular be made that a holding device is provided for fixing the power supply station, the holding device preferably having a holding element for fixing, the holding element being in the form of a fastening eyelet. In this way, for example, berthing ships can be fixed to the power supply station during a charging process or while a power is being tapped from the power supply station. In addition to the design of a holding device in the form of a fastening eyelet, for example in the form of an eyebolt or the like, other forms of holding devices can of course also be provided, for example handles or holding loops or the like.

With regard to reliable protection of the electrical components of a power supply station, it can furthermore be provided in particular that the power supply station has a housing for accommodating the electrical components, the housing preferably being designed to be watertight. The housing can preferably be arranged within the floating body. Alternatively, the housing can also be arranged at least partially in the foundation or on the floating body. For example, the floating body can be arranged in a ring around the housing and firmly connected to it and have the effect that the housing does not sink when placed in the water, but rather floats. It is also conceivable that the floating body itself represents the housing and can accommodate individual components, in particular the electrical components of the power supply station.

In order to ensure the fastest possible disconnection of the power supply station from a supply network, for example when a fault current or the like is detected, with regard to a safe design of the power supply station in question, it can be provided according to the invention in particular that a disconnection device for separating the electrical connection between the power supply station and a electrical supply line is provided, wherein the separating device is preferably arranged within the foundation. As an alternative to an arrangement within the foundation, the separating device can also be provided remote from the power supply station at a connection point between the electrical conductor and the supply line.

In order to ensure further protection of the power supply station in question against impact processes with pantographs, for example berthing ships or the like, it can furthermore advantageously be provided according to the invention that a ram protection is provided for protection against an impact with pantographs, the ram protection preferably in the form of at least partially elastic bodies is formed, which are arranged in particular around the floating body. In the context of a simple and inexpensive design, the ram protection can be in the form of air-filled buoys or the like, which are arranged around the floating body.

In order to enable an automatic delivery of a current, including preferably an automatic payment or the like, can be provided in particular be that a control device is provided for controlling the delivery of a current and sensors are provided for recording current transmission-specific parameters, the control device being set up to control a current transmission on the basis of the parameters recorded by the sensors. Power transmission-specific parameters can in particular be a current amount of electricity, a current electricity tariff, a current electricity availability, an electricity provider, a current temperature, a current demand or the like. The arrangement of a control device is particularly relevant for a version with more than one charging connection in order to control the simultaneous charging of several customers.

Further advantages, features and details of the invention emerge from the following description, in which exemplary embodiments of the invention are described in detail with reference to the drawings. The features mentioned in the claims and in the description can be essential to the invention individually or in any combination.

Fig. 1

eine schematische Darstellung einer Schnittansicht eine erfindungsgemäßen schwimmenden Stromversorgungsstation zur Bereitstellung von Strom bei einer Trockenlagerung gemäß einem ersten Ausführungsbeispiel,

Fig. 2

eine schematische Darstellung einer Schnittansicht einer erfindungsgemäßen schwimmenden Stromversorgungsstation zur Bereitstellung von Strom im schwimmenden Zustand bei einer Lagerung im Wasser gemäß einem zweiten Ausführungsbeispiel,

Fig. 3

eine schematische Darstellung einer Vorderansicht eine erfindungsgemäßen schwimmenden Stromversorgungsstation zur Bereitstellung von Strom bei einer Trockenlagerung gemäß einem dritten Ausführungsbeispiel.

Show it.

Fig. 1

a schematic representation of a sectional view of a floating power supply station according to the invention for providing power in dry storage according to a first embodiment,

Fig. 2

a schematic representation of a sectional view of a floating power supply station according to the invention for providing power in the floating state when stored in the water according to a second embodiment,

Fig. 3

a schematic representation of a front view of a floating power supply station according to the invention for providing power in dry storage according to a third embodiment.

Fig. 1 shows a schematic representation of a sectional view of a floating power supply station 2 according to the invention for providing power in dry storage according to a first embodiment.

Here, the floating power supply station 2 comprises a floating body 4 to ensure that the power supply station 2 can float independently, a foundation 6 for fastening the floating body 4 to a bottom 8, in particular to the bottom 8 of a body of water, a mechanical connecting means 10 for connecting the foundation 6 to the floating body 4, an electrical conductor 12 for electrically connecting the power supply station 2 to an electrical supply line 14 and at least one connection 16 for establishing an electrical connection with the power supply station 2, in particular with a berthing ship.

In the present case, the floating body 4 is at least partially hollow-shaped and has a watertight, stable shell made of a metal material arranged on the outside and an inner, air-filled core. The float 4 is also designed in such a way that the power supply station 2 is permanently arranged above the water surface for at least 1/3 of the total height H of the float 4 when it is arranged in the water, in order to protect the connection 16 from the ingress of water.

The mechanical connecting means 10 is in the present case in the form of two elastic ropes fastened on opposite sides of the floating body 4, so that the floating body 4 can swim when it is arranged in the water by generating the buoyancy on the water surface. The mechanical connecting means are here also attached to opposite positions of the foundation 6 and in particular designed in such a way that even with maximum tensile stress on the connecting means 10, no mechanical tensile stress acts on the electrical conductor.

The electrical conductor 12, which is largely arranged within the housing 22, is here (as cannot be seen here) wound in the housing 22 on a corresponding receiving device, so that the entire length of the electrical conductor 12 is significantly longer than that of the elastic mechanical connecting means 10 and in particular is designed to be variable. The electrical conductor 12 is here in the form of a stranded conductor made of an aluminum or a copper material and insulated with wear-resistant waterproof insulators, for example based on polyethylene, polyvinyl chloride or polyester.

The connection 16 for inserting a charging plug also has a flap 16 'for closing the connection 16, which comprises a pretensioning element that keeps the flap 16' in a closed state outside of operation in order to protect the connection 16 from splashing water and dirt.

As shown in Fig. 1 the floating body 4 is arranged within a holding device 18 for mounting the floating body 4, which is fastened to the foundation 6 in a central position. The holding device 18 also has on the underside (not visible in the present case) recesses for the ingress of water, which, if the power supply station 2 floods, ensure that the floating body 4 is conveyed upwards by the penetrating water and the power supply station 2 is at least partially on the Water surface floats.

It is also off Fig. 1 to recognize the holding device 20 arranged next to the connection 16 for fixing the power supply station 2, which preferably has a holding element for fixing so that, for example, docking ships can be fixed to the power supply station 2 during a charging process or while a current is being tapped from the power supply station 2.

Within the foundation 6, a separating device 24 is also provided for separating the electrical connection between the power supply station 2 and the electrical supply line 14, which is intended to ensure rapid separation of the power supply station 2 from the supply network in the event of a detected fault current or the like.

Fig. 2 shows a schematic representation of a sectional view of a floating power supply station 2 according to the invention for providing power in the floating state when stored in the water 26 according to a second embodiment.

According to the second exemplary embodiment, the mechanical connecting means 10 are in the present case in the form of chains which are attached to opposite sides of the floating body 4 and to the outer ends or the edge of the holding device 18 and which hold the floating body 4 on the foundation 6. How out Fig. 2 As can be seen, no mechanical tension acts on the electrical conductor 12 in the present case waterproof cladding of the housing 22, the electrical components of the power supply station 2 are safely protected against the ingress of water, while the power supply station 2, in particular the floating body 4 of the power supply station 2, floats in the water 26 in such a way that the connection 16 is always above the water surface 26 'and is accessible to ships at all times. In this way, a power supply for ships can be made available at any time, even when there is a great need or when the water level is shallow.

Fig. 3 shows a schematic representation of a front view of a floating power supply station 2 according to the invention for providing power in dry storage according to a third embodiment.

According to this third embodiment, the power supply station 2 according to the invention is designed in the form of a charging station, which can be set up, for example, in coastal areas with flood or storm surge risk, so that a sufficient distribution of charging stations can also be ensured in these high-risk areas.

According to this third exemplary embodiment, the housing 22 is only partially arranged within the floating body 4, which in the present case is formed from a total of three floating rings 4 ′, which are arranged around the housing 22 from the outside and are fastened to it. As in the first and second exemplary embodiment, the floating body 4 ensures that the power supply station 2 according to the invention drifts on the surface in the event of flooding or arrangement in the water and it is therefore to be expected that no major damage will occur to the power supply station 2 in the event of flooding .

List of reference symbols

2

Floating power station

4th

Float

4 '

Swim rings

6th

foundation

8th

reason

10

mechanical fasteners

12th

electrical conductor

14th

supply line

16

connection

16 '

flap

18th

Holding device

20th

Holding device

22nd

casing

24

Separator

26th

water

26 '

Water surface

H

Total height

Claims (15)

Floating power supply station (2) for providing power, in particular for berthing ships, comprising: - a float (4) to ensure that the power supply station (2) can float independently, - a foundation (6) for fastening the floating body (4) to a bottom (8), in particular to the bottom (8) of a body of water, - a mechanical connecting means (10) for connecting the foundation (6) to the floating body (4), - An electrical conductor (12) for the electrical connection of the power supply station (2) to an electrical supply line (14), - At least one connection (16) for establishing an electrical connection with the power supply station (2), in particular with a berthing ship. Floating power station (2) according to claim 1,
characterized,
that the floating body (4) is at least partially hollow, the floating body (4) preferably having a high-density material arranged on the outside and at least one low-density material or medium arranged in the interior. Floating power supply station (2) according to claim 1 or 2,
characterized,
that the floating body (4) is designed in such a way that the power supply station (2) is permanently arranged above the water surface 26 'for at least 1/3, preferably at least 2/5 of the total height (H) of the floating body (4) when it is in the water is. Floating power supply station (2) according to one of the preceding claims,
characterized,
that the floating body (4) is formed at least partially from a corrosion-resistant material, preferably at least partially from stainless steel, in particular at least partially from V2A or V4A steel. Floating power supply station (2) according to one of the preceding claims,
characterized,
that the foundation (6) is in the form of an at least partially metal-containing material, preferably in the form of a metal frame with a concrete cladding, in particular in the form of reinforced concrete. Floating power supply station (2) according to one of the preceding claims,
characterized,
that the mechanical connecting means (10) for connecting the foundation (6) to the floating body (4) is in the form of a chain, preferably a link chain. Floating power supply station (2) according to one of the preceding claims,
characterized,
that the mechanical connecting means (10) for connecting the foundation (6) to the floating body (4) is designed and fastened to the foundation (6) in such a way that the electrical conductor (12) at a maximum expansion of the mechanical connecting means (10) in As a result of buoyancy, the floating body (4) has not yet reached its maximum extent in order to minimize the mechanical tensile stress on the electrical conductor (12). Floating power supply station (2) according to one of the preceding claims,
characterized,
that the electrical conductor (12) is in the form of a flexible conductor, preferably in the form of a stranded conductor. Floating power supply station (2) according to one of the preceding claims,
characterized,
that the connection (16) is in the form of a charging socket for inserting a charging plug, the connection (16) preferably having a flap (16 ') for closing the connection (16), the flap (16') in particular having a pretensioning element that holds the flap (16 ') in a closed state. Floating power supply station (2) according to one of the preceding claims,
characterized,
that a holding device (18) is provided for mounting the floating body (4), the holding device (18) preferably having an opening for receiving the holding device (18), the opening being designed in particular to correspond to the shape of the floating body (12). Floating power supply station (2) according to one of the preceding claims,
characterized,
that a holding device (20) is provided for fixing the power supply station (2), the holding device (20) preferably having a holding element for fixing, the holding element being in the form of a fastening eyelet. Floating power supply station (2) according to one of the preceding claims,
characterized,
that a housing (22) is provided for receiving electrical components of the power supply station (2), the housing (22) preferably being watertight. Floating power supply station (2) according to one of the preceding claims,
characterized,
that a separating device (24) is provided for separating the electrical connection between the power supply station (2) and an electrical supply line (14), the separating device (24) preferably being arranged within the foundation (6). Floating power supply station (2) according to one of the preceding claims,
characterized,
that a ram protection is provided to protect against impacting pantographs, wherein the ram protection is preferably formed in the form of at least partially elastic bodies, which are arranged in particular around the floating body (4). Floating power supply station (2) according to one of the preceding claims,
characterized,
that a control device is provided for controlling the output of a current and sensors are provided for recording current transmission-specific parameters, the control device being set up to control a current transmission on the basis of the parameters recorded by the sensors.

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