NL1030653C2 - Equipment is for inhibition of growth of marine organisms, such as Japanese oysters, mussels and Cyprus larvae, which adhere to the hulls of vessels underwater - Google Patents

Abstract

The equipment is for the inhibition of growth of marine organisms, such as Japanese oysters, mussels and Cyprus larvae, which adhere to the hulls of vessels underwater. A vessel (5) is equipped with several electrodes (1-4) fixed on her water side. They are governed by a control unit, which causes a current with a specific resonance frequency to circulate which destroys the marine organisms. The control unit causes a current to flow from the one electrode to the others and alternately allows current to flow between different electrodes. This can occur in accordance with a given pattern or alternating patterns.

Description

DEVICE AND METHOD FOR INHIBITING THE GROWTH OF SOAP PICKS AND OTHER ORGANISMS

The present invention relates to a device for inhibiting the growth of organism, such as barnacles and mussels, on an underwater surface of a body. The invention relates in particular to inhibiting the growth of barnacles on the ship's hull of sea-going vessels.

Barnacle larvae swim freely in saltwater. When the barnacles are at a certain stage of growth, they attach themselves to a hard surface, such as the hull of ships.

The underwater line of sea-going vessels must be cleaned regularly because the growth of barnacles is too much of a hindrance. The use of antifouling paint is known. However, it contains extremely toxic tributyl tin or copper compounds.

The invention has for its object to provide a device and method with which in an environmentally conscious manner an inhibition of the growth of organisms on submerged surfaces can be effected.

To that end, according to the invention, the device is characterized by a circuit and resonant means included in the circuit for bringing the organisms into resonance. The organisms are brought into forced vibration, the excitation frequency being equal to or substantially equal to the natural frequency. This results in large deviations, and therefore in the loosening or breaking just before or after fouling of the organisms.

The resonant means preferably comprise 1030653

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2 electrical means for controlling the frequency of an electric or electromagnetic field.

The surface of the body to be treated can advantageously be used as a conductor for transmitting the desired vibration to the organisms.

To that end, the surface of the body forms part of the electrical circuit.

In an advantageous embodiment, the electric circuit comprises an anode and cathode for obtaining an electrolytic process. The same system can then also be used as an anti-fouling agent for preventing the growth of, in particular, algae, as further described in WO 2004/039664. The content of this application is incorporated herein by explicit reference.

If neither the anode nor the cathode is connected to the submerged surface of the body, the device finds a wide application, and is not limited only to ships and other bodies provided with surfaces that are electrically conductive. The water that surrounds the body serves in that case as a conductor.

The invention relates to a method for inhibiting the growth of organisms on an underwater surface of a body, such as a vessel, wherein the

organisms is brought into vibration of which the excitation frequency is substantially equal to the natural frequency.

The circuit preferably comprises an anode and a cathode. The surface of the submerged body can serve as an anode or cathode, so that the surface serves as a conductor. The water surrounding the submerged body can also be used as a conductor. In that case the anode and / or cathode are insulated connected to the surface to be treated.

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The resonance is preferably generated electrically, and not ultrasonically, so that lower power can be used.

By also (partially) including the surrounding water in the circuit, the larvae and other organisms are taken into the vicinity of the surface to be treated. This means that continuous surface treatment is not necessary.

The detection method described below for the resonance frequency of organisms that can cause fouling on a submerged part of a ship, such as the Pok, Japanese oyster, Mossel and Cyprus larva, are used. The Cyprus larva is the name of a barnacle in the phase before it will emerge and develop as a barnacle. This is the final phase before the barnacle starts to attach itself to a surface such as the underwater surface of a ship. The barnacle is now still a larva and will begin its search to attach itself. Killing by the resonance frequency of organisms may well be applied to the Cyprus larva because it is now still small enough to be killed by means of its resonance frequency. All other fouling organisms in water, such as mussels and oysters, can be treated and killed by the system in a similar manner. The various organisms are exposed to an alternating voltage in a laboratory. It is experimentally examined at which frequency of this alternating voltage the organisms become lifeless. A frequency between 1 and 10 mHz is applied. It is known that the resonance frequency is determined by the size and type of the organism. Thus, it can be concluded that the Cyprus larva must fall within a certain bandwidth of 1 03065 3 • f 4 resonance frequencies. This can reduce the search for the desired resonance frequency.

Example 1 Application on a ship with placement of electrodes 5

A ship 5 is equipped with a plurality of electrodes 1, 2, 3 and 4. These electrodes 1-4 are attached to the water side of the ship 5. The electrodes 1-4 are driven by a control unit (not shown). This unit will cause a current to flow at a certain resonance frequency, thereby killing the Cyprus larva or other fouling organism. The control unit sends a current source from one to the other electrode 1-4 as the current source. The control unit will alternately flow between 15 different electrodes 1-4. This can take place according to a predetermined pattern or changing pattern.

By using the different combinations of electrodes 1-4, an as large as possible electric field can be produced. In this way, the largest possible area around the electrodes 1-4 can be treated by the system. Figure 1 shows how the electrodes 1-4 are placed on the skin of the ship 5. The system is not active.

Figure 2 shows a display when the system is active. The control unit runs a current for a short time from electrode 1 to electrode 2. Electrode 1 now functions as an anode and electrode 2 as a cathode. Current causes an electric field 6 with the deadly resonance frequencies. After a short period, the control unit causes a current to flow from electrode 1 to electrode 3. Current causes an electric field 7 with the deadly resonance frequency. After this, the control unit runs a current from electrode 1 to electrode 4 (electric field 1030653 5), electrode 2 to electrode 3 (electric field 9), electrode 2 to electrode 4 (electric field 10) and electrode 3 to electrode 4 (electric field 11). So that all possible combinations are made. Combinations with more than 5 two electrodes are also possible. This increases the area in which the electric field is located even more. Increasing the number of electrodes 1-4 and combinations ensure that the system can keep a larger area of growth free. This cycle of driving the electrodes 1-4 does not have to be continuous, but can be repeated intermittently. Alternatively, the skin of a steel ship or propeller can serve as an (extra) electrode and be included in the system.

Example 2 Application to a ship with application of a conductive paint layer

An additional conductive layer is applied to the paint of the surface of a ship that is under water. This current-conducting paint layer is used to make the underwater part of the ship part of a circuit. A control unit will run a current with a certain resonance frequency, killing the Cyprus larva or other fouling organism. A voltage difference with resonance frequency will be pushed between the conductive paint layer and a further electrode. This electrode can be on the skin of the submerged part of the ship or in the water around the ship or the propeller can serve as an electrode. Optionally, the conductive paint may be applied to the skin of the ship electrically separated from the electrode. The submerged part of the ship can now serve as two or more electrodes over which the resonance frequency is applied. A way this _1 0306 5.?

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6 can be realized by applying to the skin of the ship a "patchwork quilt" of anodic and cathodic fields, which are mutually separated, with a layer of paint that is electrically conductive in contact with it.

The paint layer is alternately electrically contacted with the anodic and cathodic fields in order to obtain a circuit that runs over the skin of the ship.

Example 3 Application to protect drilling rig pillars against fouling.

The pillars of a drilling rig can be executed with the system. It is possible to place electrodes on the various pillars. The electrodes are driven by a control unit. This unit will run a current with a certain resonance frequency, killing the Cyprus larva or other fouling organism. As a power source, the control unit sends a current from one electrode to the other. The control unit will preferably run alternating currents between different electrodes. By making use of the different combinations of electrodes, an as large as possible electric field can be produced, all this as described above. In this way, the largest possible area around the electrodes can be treated by the system.

Example 4 Application of resonance frequency in combination with a cathodic protection system with printed current.

A combination can be made with a cathodic protection system that uses impressed current and an anti-fouling system that uses resonance frequencies. Reference is hereby made explicitly to WO 2004/039664, in which a cathodic protection system is described. A mixed anode which forms part of the cathodic protection system will be able to protect a metal, for example steel, object in the water against corrosion by means of impressed current. It will also be possible to periodically supply the system with a voltage with the desired resonance frequencies. Because the metal object acts as a cathode and the mixed anode as anode 10 within the system, a current will flow from the mixed anode to the metal object. The electric field caused by resonance frequencies will now also ensure that organisms are killed, so that no fouling or fouling of the ship's hull or pillars of a drilling platform takes place.

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Claims (7)

A device for inhibiting the growth of organisms on a surface of a body, such as a vessel, situated below the waterline, which device comprises a circuit and resonant means included in the circuit for bringing the organisms into resonance. 1 ’V · 2. Device as claimed in claim 1, wherein the resonant means comprise electrical means for controlling the frequency of an electric or electromagnetic field. 3. Device as claimed in claim 1 or 2, wherein the surface of the body forms part of the electrical circuit. Device as claimed in any of the foregoing claims, wherein the electrical circuit comprises an anode and cathode. 5. Device as claimed in claim 4, wherein the anode 20 and cathode are adapted to obtain an electrolytic process. The device of claim 4 or 5, wherein neither the anode nor the cathode is electrically connected to the submerged surface of the body. A method for inhibiting the growth of organisms on an underwater surface of a body, such as a vessel, wherein the organisms are made to vibrate whose excitation frequency is substantially equal to the natural frequency. 1 03065 3