NO163768B - STABILIZATION DEVICE. - Google Patents

Description

Method and device for preventing fouling of submerged structures.

The present invention relates to the prevention of delimitation

structures submerged in seawater, more specifically a new electrolytic method to prevent such fouling and a new electrode equipment or device applicable to such a method.

To prevent the difficulties that arise from choking

of flow channels, e.g. in liavvann.sk j ole er rudder steam-power plants, ships and the like because marine organisms attach to these and to exclude the various unwanted folds of these firmly grown marine organisms on submerged parts of the hull, it is in practice common to coat those surfaces which is in contact with the seawater, with copper-containing paint and introduce chlorine into the seawater's passage through drainage channels.

It is also known that non-consumable electrodes of pla-! tin, platinum alloys, magnetic iron oxides, when these an-

in turned as anodes for electrolysis of seawater, will develop chlorine

in and hypochlorite which prevents fouling by marine organisms.

It is also known that during the electrolysis of seawater, hydrogen will usually be released on the cathode and lead to an increase in the amount of hydroxyl ions (on) around the cathode, with consequent deposition on the cathode of calcium carbonate and magnesium hydrolf-syd which are hard components of the sea water. Since the specific conductivity of seawater is usually as little as kOOO |iVer the power loss due to the seawater's resistance is undesirably large. For this reason, it is advisable when carrying out the electrolysis of seawater for the purpose of preventing fouling by marine organisms which attach to submerged surfaces to use the smallest possible gap or space between the electrodes in order to thereby reduce the power loss to the minimum possible. However, such a reduced gap between the electrodes can enable clogging of the gap by deposits on the cathode and thus until the passage of seawater is impeded.

For the above reasons, it is important in the application

of electrolysis of seawater to prevent the deposition of marine organisms on submerged structures, to provide a method which excludes the possibility of choking between the electrodes in the case of cathode deposits and likewise to provide electrodes that are particularly suitable for preventing such choking. Moreover, the electrode arrangement must be such that the relatively expensive anode can be protected against mechanical damage due to drifting objects or objects thrown overboard and other wreckage in the ship.

As a result of experiments, it has been shown that the deposition of the hard components in the seawater on the cathode increases proportionally with the cathode current density until the current density reaches 0.1 A/dm 2. The deposits assumed e.g. a thickness of 0.5 now using a strbm density of 0.05 A/dm for 100 hours, but with a strbm density of 1 A/dm^ the deposits are significantly reduced and at a strbm density above _'} A/dm 2 there is almost no deposit on the cathode. Above a current density of 1 A/dm, the thickness of the cathode deposits thus decreases with increasing current density on the cathode.

The thickness of the deposit on the cathode is 0.2 mm in k$ hours

with a strbm density of 0.05 A/dm 2 and at normal temperature.

The thickness of the cathode deposit at strbmdensities of 0.05> 0.1,; 2, k and 18.6 A/dm 2 are shown in the following table:

The above-mentioned relationship between cathode strbm density and measured thickness of the cathode deposit is shown graphically in fig. 8, from which it will be seen that the thickness of the deposit is greatly reduced at a strain density of not less than 3 A/dm.

The probable reason for the observed phenomenon is that at a cathode current density of no less than 3 A/dm 2 the pH value of the seawater around the cathode will increase until the deposit dissolves again and that the thus strongly developed hydrogen bubbles can tear the Ibs deposits from the cathode.

In order to prevent marine organisms from binding to structures submerged in seawater, it is usually necessary for the electrodes to either choose an extremely low cathode current density or a density of at least 3 A/dm 2 , to avoid the unfortunate result that the space or gap between the electrodes is blocked again. On the other hand, the strength of the anode must be chosen on the basis of the strength required for the effective production of the chemical components that will prevent fouling by marine organisms in accordance with the amount of seawater that is in contact with the structures and likewise on the basis of the critical strength density which can be applied to the anode.

Parallel plate electrodes which are usually used are not able to comply with such requirements due to the fact that the narrow and possibly mainly long space between the electrodes is easily clogged or blocked.

It is already known to use electrolysis to prevent! fouling of marine organisms on structures submerged in seawater by submerging an insoluble anode in the water close to the structure and placing a cathode near the anode and conducting electrical current between these electrodes. However, the hitherto known methods and devices have not proven to be sufficiently effective when it comes to preventing the deposition of marine organisms when electrolysis is used, as the space between the cathode and the anode is sealed and the electrolyte is prevented from functioning effectively. -in reverse thrust. in

It is thus an object of the present invention to provide a method for preventing fouling by marine organisms1 on structures submerged in seawater, which method is not affected by the above-mentioned disadvantages, as the method involves a non-dissolvable anode and at least one cathode are immersed in the sea water close to the structure and close to each other and there; a strbm is placed between the anode and the electrode. It is also an object of the invention to provide an electrode device which can be used to prevent fouling by marine organisms on structures submerged in seawater using the method according to the invention.

The invention is distinguished by the fact that a method of the above kind is carried out with a strbm which has a density on the cathode of over 3 A/dm 2. It is also a feature of the invention that a plurality of cathodes are immersed in the seawater around a central anode j and with uniform distance from each other and from the central anode.

An electrode device according to the invention for carrying out the method is distinguished by the combination of at least one electrode device comprising a non-dissolvable anode and a plurality of cathodes which surround the anode at a uniform distance from each other and at a uniform distance from the anode, as well as a device for lining between the anodes and cathodes of a strbm with a density on the cathodes of more than 3 A/din 2.

According to the invention, an anode is placed which can be a sbylean anode comprising sblv coated with platinum or platinum

miter, titanium coated with platinum or magnetic iron oxide in the center of an electrode device. This anode is surrounded by a cathode construction and the cathode construction may comprise a plurality of rods or net-like spiral or cylindrical metal elements provided with a plurality of perforations and a net dielectric material is placed between the anode and the cathode construction. The device is such that a coherent unit is produced where the current density on the cathodes is kept at a value of no less than 3 A/dm, the current passing between the anode and the cathode for electrolysis of the seawater. The cathodes that surround the anode also serve to protect the latter from stbt from driftwood or other objects in the seawater.

For a better understanding of the basic idea of the invention, this will be explained in more detail in the following with reference to the drawings, which show typical examples of the invention, and where fig. 1 is a perspective elevation, partly in section, of a form of an electrode unit according to the invention, fig. 2 is a perspective elevation of the anode which forms part of the unit shown in fig. 1, fig. 3 is a perspective elevation, partially broken through, of a device comprising a plurality of electrode units shown in fig. 1 and mounted on a water intake, fig. k is an elevation, partially broken away by another device comprising the electrode unit shown in fig. 1 and mounted in an electrolytic container in connection with the seawater cables, fig. 5, 6 and 7 show schematic horizontal sections of other anode and cathode devices according to the invention, fig. 8 is a diagram showing the relationship between the cathode strbm density and the thickness of the deposit on the cathodes, in accordance with Table A mentioned above, and fig. 9a - 9d are a series of photographs showing test results.

The one in fig. 1 shown electrode unit according to the invention comprises a plurality of round rod cathodes 2 which surround an anode 1. The anode 1 is e.g. made from a round rod of commercially available magnetic iron oxide, with a diameter of 56 mm and a length of 7^0 mm. The anode 1 is placed in the center of the unit and surrounded by the cathodes 2 which, in the embodiment shown, are six in number made of bare steel as round rods attached at equal distances to end support frames 3 and 3' of bare steel. To facilitate assembly of the unit, the end frame 3 is provided with a flange.

A suitable dielectric material k is used for insulation between the anode 1 and the cathodes 2. In the embodiment shown, this dielectric or insulating material is a rigid tube of polyvinyl chloride used in the form of sleeves on the upper and lower parts of the anode. These sleeves are sealed with synthetic resin at the top and bottom of the anode ends, as they have round rod cathodes 2. one i

IN

uniform distance from the anode 1. A cathode supply conductor 5 is conveniently attached to a clamp on the support frame 3 and an anode conductor 6 is attached to the equipment in such a way that the anode equipment \

IN

1-4 can easily be pulled out of the electrode unit by simply • pulling the conductor 6 upwards.

Own. 2 shows the anode which forms part of the unit shown in : fig. 1. The anode is calculated for an anode current of 50 A (5 A/dm 2 ■) -> As the surface area for a round rod cathode is around 230 cm<2>, the average current density on the cathode is k, J A/dm<2>or hby enough to prevent the possibility of the formation of deposits on the cathodej Generally, an electrolytic strbm concentration of • 0.3 A/ (m^/h) of seawater can prevent fouling by marine organisms. If it is assumed that the intake for a seawater intake line to be protected against fouling is 2000 m^/h (which corresponds to the amount of water for cooling a condenser for a power plant with a capacity of about ljOOO kiv), the necessary electrolytic strbm are calculated to

0.3 A/(m-Vh) x 2000 m<J>/h = 600 A To comply with this requirement, it is necessary to use only approx.:

10 electrode units of the one in fig. 1 shown type.

Fig. 3 shows these electrode units mounted at a seawater intake opening. In fig. 3, the individual electrode units are shown in fig. 1 denoted by 7. A seawater pipeline is denoted by 8, a strainer for removing driftwood and particles in the seawater is denoted by 9 and a carrying device for the electrode units is denoted by 10. This carrying device 10 is in turn attached to a mounting l' 1 even on the yfjål. The support device 10 has a cylindrical shape with an appropriately perforated wall around the perimeter and an upper end wall, so that it can prevent evaporation of the j electrolysis products and prevent dispersion of the active ! constituents due to the bblge force and the like.. j

Since each individual anode is surrounded by cathodes as described, ! the current distribution is practically even and the generation of vagal j bonding currents is reduced to the minimum possible, whereby j other devices are prevented from corrosive attack. A further advantage of the device is that the staff's safety is ensured by the fact that the cathodes are grounded for protection against electric shock.

For reasons of structural strength, the cylindrical support device 10 is made of ordinary forged steel and is preferably connected to the negative side of the electrode unit, so that this support device can be protected against corrosion.

Fig. 4 shows the electrode unit according to the invention mounted in an electrolytic container connected to the seawater pipeline. In this case, a seawater conduit is designated 11 and extends into an electrolytic container 12 which accommodates the electrode assembly. The container can have any desired design, although its capacity is dependent on the dimensions of the seawater line. The electrode unit of the invention is shown at 13, as it comprises a central anode surrounded by a plurality of cathodes as described in connection with fig. 1. Supply conductors 1k and 15 are connected to the anode and cathodes respectively.

A support plate for the electrode unit is generally denoted by lb and forms part of the cover for the electrolytic container and has a threaded extension 17 which serves as a holder for an electrode device. The extension 17 is designed with openings for inserting the electrode unit into the electrolytic container and is threadedly connected to a lid 19 with an intermediate gasket 18. The cathode's conductor can extend from the lid 19, the support plate 16 or the electrolytic container 12.

It is also possible to mount the cathodes for electrode equipment 13 on the carrier plate 16 in any desired manner, surrounding the respective individual anode. Thus, the arrangement of the anodes and cathodes in the electrode equipment according to the invention can assume the various modified forms shown in fig. 5-7" where it will be noted that in each case anode 1 is surrounded by cathodes 2. Fig. 8 graphically shows the relationship between the current density and the thickness of the cathode deposits. It will be clear from fig. 8 that the deposition decreases to a great extent when the cathode current density is at least 3 A/dm.

Fig. 9a - 9d show, in the form of photographs, the results of a trial run in accordance with the invention. The electrode materials, the current density and the duration of the current are indicated in table B.

As a summary of the invention described above, it can be noted that the method for preventing fouling by marine organisms and the electrode equipment for carrying out the invention and thereby clogging of seawater intake lines and other difficulties, such as increased resistance on hull bottoms due to the deposition of marine organisms, in the case of electrolysis of seawater, includes the placement of cathodes around respective individual anodes, as the mutual electrode distance is very small compared to that for electrode plates arranged in parallel, whereby the power loss due to liquid resistance is reduced to the minimum.

Nevertheless, the short mutual electrode distance can be prevented from clogging by hard components of the sea water and thereby effectively prevent fouling of marine organisms by electrolysis of the sea water. The apparatus according to the invention is very valuable industrially, particularly because the relatively expensive anodes are surrounded by cathodes and therefore protected against mechanical damage which may be caused by drifting goods and other objects in the seawater.

Claims (5)

1. Method to prevent fouling by marine organisms on structures immersed in seawater, where a non-dissolvable anode and at least one cathode are immersed in the seawater close to the structure and close to each other, while a current is fed between the anode and the electrode, characterized in that this current has a density on the cathode of over 3 A/dm 2. Method according to claim 1, characterized in that a plurality of cathodes are immersed in the seawater around a central anode and at a uniform distance from each other and from the central anode. 3. Electrode device for use in carrying out the method according to claims i and 2, characterized by the combination of at least one electrode device comprising a non-dissolvable anode and a plurality of cathodes which surround the anode at a uniform distance from each other and at a uniform distance from the anode, as well as a device for lining between the anodes and the cathodes of a strbm with a density on the cathodes of more than 3 A/dm^. 4. Electrode device according to claim 3, characterized in that the anode is a central coil for the electrode device, the cathodes being arranged around the circumference of a circle with the center in the anode and at an even distance from each other around the circumference. 5. Electrode device according to claim 4, characterized in that the anode is a cylindrical rod (i) with a circular cross-section, a pair of dielectric sleeves (4) each surrounding said anode (l) at its ends and a. pairs of cylindrical support frames (3) which live engage with each of the respective dielectric sleeves (4) and the cathodes comprise rods (2) with a cylindrical cross-section which extend between and are carried by the support arms (3)