SE506692C2 - Electrode station for use in water HVDC transmission - Google Patents

Abstract

The invention relates to an anchor (1), comprising a cavity structure (10) with a top surface (2) and essentially vertical wall means (4) extending downwards from said top surface (2) to form a cavity (10). The anchor has at least one sealable opening (5) in its top surface, and it is provided with means (8) for allowing supply of low density fluid, e.g. gas, to the interior of said cavity structure. It further comprises a bottom surface (3) with an opening (6) or openings for enabling sea water to enter said cavity (10) when the anchor is immersed. The top surface (2) extends in the horizontal plane beyond the periphery of said wall means (4) to form a circumferential flange (11). There is provided a similar flange (12) at the lower end of said wall means (4), said wall means (4) and said flanges (11, 12) thereby forming a receiving portion (13) on said anchor for receiving a windable member (14) therein. It also relates to an electrode station comprising an anchor and electrodes wound onto said anchor. <IMAGE>

Description

SUMMARY OF THE INVENTION This invention is intended to solve the problems of the prior art devices.

These problems are solved with the electrode station defined in claim 1.

The anchoring device used for anchoring the electrode in the electrode station has a groove-like receiving portion for receiving such electrodes by winding it. Such an anchoring device provided with an electrode wound thereon is very easy to transport and to place in the sea.

In a preferred embodiment, the anchoring device of the electrode station is provided with a valve means, e.g. a gas coupling for pressurized air, so that the interior of the anchoring device can be filled with a medium of low density, e.g. air, which facilitates the movement and lifting of the anchor from the Water.

Additional applications of this invention will become apparent from the detailed description given hereinafter. However, it is to be understood that the detailed description and specific examples, although indicating preferred embodiments of the invention, are given by way of illustration only, as various changes and modifications within the scope of the invention will become apparent to those skilled in the art from this detailed description.

The invention will now be more fully understood from the following detailed description and the accompanying drawings, which are given by way of illustration only and thus do not limit the invention, and in which Figure 1 illustrates an anchoring device according to the invention in perspective view; Figure 2 shows a cross section through the center of the anchoring device in Figure 1; Figure 3 shows an embodiment where the anchoring device is enclosed in a diaphragm; and Figure 4 shows an embodiment without a bottom surface.

Detailed Description of Preferred Embodiments An anchoring device according to a presently preferred embodiment of the invention is shown in Fig. 1 and is generally designated by the reference numeral 1.

In a preferred embodiment, the anchoring device is made of fiberglass-reinforced concrete, although other construction materials are conceivable. The illustrated embodiment of the anchoring device according to the invention comprises a top surface 2, a bottom surface 3, vertical walls 4, which walls in the preferred embodiment are cylindrical and form a cavity 10. However, other shapes are conceivable, e.g. square or rectangular.

The top surface 2 is provided with a set of holes 5 to enable seawater to flow through the entire structure as it is immersed in the sea.

In the embodiment shown, the bottom surface 3 is also provided with a set of heels 6, also to facilitate filling of the cavity with water during immersion of the structure 1.

It is possible to dispense with a bottom surface completely and to let only the cylindrical walls end in an opening 7 (see Fig. 4). This can be advantageous, e.g. from a manufacturing point of view.

The anchoring device is further provided with means 8 for supplying gas or some other low-density fluid to the interior of the anchoring device. Such means may be in the form of a standard type gas coupling, but should preferably be made of corrosion resistant material, e.g. titanium.

However, any material is conceivable that resists as much as several tens are in the underwater position without being significantly destroyed.

The anchoring device is also preferably provided with one or more lifting loops 9 in order to enable immersion in and uptake from the sea. These could also be manufactured by e.g. titanium.

When the anchoring device is to be used for anchoring an HVDC electrode on the seabed, the top surface preferably extends in the horizontal plane beyond the periphery of said walls to form a circumferential flange 11. A similar flange 12 is also provided at the lower end of the walls 4, the walls and said flanges forming a groove-like receiving portion 13 on the anchoring device for receiving the electrode in the form of a mat 14 or a cable having electrochemically active segments. A suitable electrode mat is the one previously mentioned in WO 89/12334. It is within the spirit of the invention to use any electrode structure that can be wound on the anchoring device. Metal mesh structures with different filament thicknesses and different mesh sizes can be used depending on the current densities required in a specific case. Of course, such electrode structures will have catalytic coatings suitable for the specific ones; conditions prevailing. For example. anodic or cathodic operation, varying salt concentration in the seawater, etc. will affect the choice. Conductive polymer mats or nets are also possible to use as electrodes.

The groove-like receiving portion 13 must be of sufficient size for there to be adequate convection of electrolyte due to flowing water, to prevent the development of elemental chlorine. Furthermore, the electrode surface must be of such a size that the buffer capacity of the seawater is not exceeded by the production of reactants, ie. there must be no lowering of the pH, and the formation of hypochlorite takes place in the alkaline area.

Furthermore, the receiving portion should preferably be coated with an inert material for protective purposes, as the reaction products at the electrode, such as hypochlorite, may be harmful to the concrete. Suitable materials for coating are e.g. polypropylene, high-density polyethylene, Halar or FEP, but bisphenol-type polyesters are preferably used, the latter preferably being sprayed on the surface. High quality plastic paint is also a possible choice. The important aspect is the ability to protect the concrete from attack by the hypochlorite that can be produced.

A practical size for an anchoring element is 2-3 m in diameter and 1-1.5, e.g. 1.2 m in height, although both smaller and larger sizes could be used.

However, the size must be sufficient to allow sufficient gas, preferably air, to be supplied to the interior to make the apparent density of the unit low enough to make the unit float or at least lift it.

In a further embodiment, the anchoring device with its inner cavity is enclosed inside an inert diaphragm 15, e.g. made of fluorocarbon polymers or any other inert polymer, which, however, becomes electrically conductive when impregnated with electrolyte. This embodiment may be highly desirable in cases where it is essential to control the electrochemistry at the electrode, especially when there are very strict requirements under chlorine-free conditions. There are also arranged means 16a, e.g. FEP or tubes of suitable type for insertion and means for removing synthetic electrolytes, which contain reducing species, to the "reaction chamber", i.e. to the receiving portion 13 where the electrode structure is located. The insertion member 16a is preferably connected to a perforated PEM tube 16b located along the periphery of the lower flange 12. The removal means, e.g. suitable hoses, may be connected to a pump to draw electrolyte through the interior of the diaphragm at a suitable speed. Synthetic electrolytes may be a reducing solution, for example comprising bisulfite, hydrogen peroxide or the like in proportion to the current.

In another embodiment, the electrodes in the form of mats or the like may be alternating of anodic and cathodic type, i.e. there may be concentric layers of anodic and cathodic elements. In this case, the assembly can be used as a bipolar type electrode.

The anchoring device is used as follows in HVDC applications.

A suitable electrode, e.g. the previously mentioned mat, is wound in several layers on the anchoring device in its receiving portion and secured e.g. by squeezing or any other suitable means.

The hook or a set of hooks on a crane or other lifting device is attached to one or more loops on the anchoring device and this is immersed in the sea. In this case, water will fill the cavity due to the openings in the top surface not being sealed. When the anchoring device is placed on the bottom at the desired location, divers place suitable plugs in the holes in the top surface. This step does not necessarily have to be performed when the unit is laid out, but you can instead wait until the time when you want to lift the anchoring device out of the sea again in the future. However, it may be advantageous to do so when laying, since the hollow surfaces are fresh and thus may be easier to seal than after e.g. 30 years of underwater operation.

From this description of the invention, it is obvious that it can be varied in many ways. However, such variations are not to be construed as departing from the spirit of the invention, and all modifications obvious to those skilled in the art are intended to be included within the scope of the following claims.

Claims (7)

A electrode station for use as a pole in HVDC transmission over water, comprising electrode means (14) for HVDC transmission in water and an anchoring device (1) with a cavity structure (10), which anchoring device is provided with means (8) for allowing the supply of a low density fluid, e.g. gas, to the cavity structure (10), the electrode means (14) being arranged on the anchoring device. The electrode station of claim 1, wherein the anchoring device comprises a top surface (2) and substantially vertical walls (4) extending downwardly from said top surface (2) to form said cavity structure (10), the top surface (2) extends in the horizontal plane beyond the periphery of the wall (4) to form a circumferential flange (11), and wherein a similar flange (12) is provided at the lower end of the wall, the wall (4) and the flanges (11, 12) ) forms a receiving portion (13) on the anchoring device for receiving said electrode means (14). The electrode station according to claim 1 or 2, wherein the top surface (2) of the anchoring device is provided with at least one sealable opening (5), and wherein the anchoring device further comprises a bottom surface (3) with an opening (6) or openings to enable seawater enters the cavity (10) when the electrode station is immersed. The electrode station according to claim 3, wherein the sealable opening (s) (5) in the top surface (2) is conical (a) and has a smooth surface for facilitating sealing with a soft material. The electrode station according to any one of the preceding claims, in which the cavity (10) has such a volume that the total density of the armature when said cavity is filled with a low density fluid becomes less than the density of the surrounding medium, e.g. sea water. The electrode station according to any one of the preceding claims, wherein the wall (4) is vertical and cylindrical. An electrode station according to any one of the preceding claims, wherein alternating electrodes of anodic and cathodic type are arranged in the receiving portion (13), i.e. as concentric layers of anodic and cathodic elements, the station being useful as a bipolar type electrode station. The electrode station according to any one of the preceding claims, enclosed in an inert diaphragm (15) having the property of becoming electrically conductive when impregnated with electrolyte. The electrode station according to any one of the preceding claims, comprising means (16a, 16b) for supplying and removing synthetic electrolyte to and from the interior of the diaphragm (15). ll. The electrode station according to any one of the preceding claims, wherein the electrode member is an elongate member, for example in the form of a mat or a cable, which is wound on the anchoring device.