CATHODIC PROTECTION AND ANTI-FOULING ARRANGEMENT AND METHOD

Abstract

An anti-fouling arrangement in a marine vessel with a marine propulsion system, the propulsion system comprising at least one driveline housing, a torque transmitting drive shaft extending out of the driveline housing, and at least one propeller mounted on the drive shaft. The at least one propeller is electrically isolated from its drive shaft, wherein each electrically isolated propeller is connected to a positive terminal of a direct current power source, and each metallic component to be protected against fouling is connected to a negative terminal of the direct current power source. A control unit is arranged to regulate the voltage and current output from the direct current power source.

Claims

1. Cathodic protection and anti-fouling arrangement in a marine vessel with a marine propulsion system, the propulsion system comprising; at least one driveline housing at least partially submerged in water; a torque transmitting drive shaft extending out of the driveline housing; at least one propeller mounted on the drive shaft; the arrangement being wherein the at least one propeller is electrically isolated from its drive shaft; each electrically isolated propeller to be protected against fouling is connected to a positive terminal of a direct current power source; each metallic component to be protected against corrosion is connected to a negative terminal of the direct current power source; and that a control unit is arranged to regulate the voltage and current output from the direct current power source.

2. Cathodic protection and anti-fouling arrangement according to claim 1, wherein the arrangement is an impressed current cathodic protection arrangement and that the at least one propeller is an anode.

3. Cathodic protection and anti-fouling arrangement according to claim 1, wherein the at least one propeller is made from an inert metallic anode material.

4. Cathodic protection and anti-fouling arrangement according to claim 1, wherein the metallic component to be protected is the at least one driveline housing.

5. Cathodic protection and anti-fouling arrangement according claim 1, wherein the metallic component to be protected is at least one trim tab.

6. Cathodic protection and anti-fouling arrangement according claim 1, wherein the metallic component to be protected is a metal portion of the vessel hull.

7. Cathodic protection and anti-fouling arrangement according claim 1, wherein a torque transmitting electrically isolating component is mounted between the at least one propeller and the drive shaft.

8. Cathodic protection and anti-fouling arrangement according to claim 7, wherein the torque transmitting electrically isolating component is made from an elastic material.

9. Cathodic protection and anti-fouling arrangement according to claim 8, wherein the elastic material is a natural or synthetic rubber.

10. Cathodic protection and anti-fouling arrangement according claim 1, wherein a reference electrode is at least partially submerged in water and is connected to the control unit in order to provide a ground reference value.

11. Cathodic protection and anti-fouling arrangement according claim 1, wherein a dielectric shield is provided between the at least one propeller and the drive shaft.

12. Cathodic protection and anti-fouling arrangement according to claim 11, wherein the dielectric shield comprises a layer of dielectric material extending along the drive shaft over at least the entire axial extension of the propeller hub.

13. Cathodic protection and anti-fouling arrangement according claim 1, wherein the propeller is connected to the positive terminal of the direct current power source by wiring extending through a hollow portion of the drive shaft.

14. Marine vessel wherein the marine vessel is protected by a cathodic protection and anti-fouling arrangement according to claim 1.

15. A method for protecting a marine vessel with a marine propulsion system against corrosion and fouling, the propulsion system comprising; at least one driveline housing at least partially submerged in water; a torque transmitting drive shaft extending out of the driveline housing; at least one propeller mounted on the drive shaft; of the method comprising: providing electrical power from a direct current power source; causing at least one metallic component of the vessel to act as a cathode, and causing the at least one propeller of said marine propulsion system to act as an anode in a galvanic circuit which comprises at least one metallic component, at least one propeller and water, in which water the metallic component and the propeller are at least partially submerged, and electrically connecting said anode to the direct current power source and directing a direct current flow through said galvanic circuit.

16. A method according to claim 15, further comprising—controlling the direct current flow through said galvanic circuit using a reference electrode at least partially submerged in water to provide a ground reference value for the control unit.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0025] With reference to the appended drawings, below follows a more detailed description of embodiments of the invention cited as examples. In the drawings:

[0026] FIG. 1 shows a schematically illustrated vessel comprising a marine anti-fouling arrangement/corrosion protection system according to the invention;

[0027] FIG. 2 shows a schematic a cross-section of the rear portion of the marine vessel;

[0028] FIG. 3A-B show schematic cross-sections through a pair of propellers; and

[0029] FIG. 4 shows a schematic diagram illustrating the operation of an anti-fouling arrangement according to the invention.

DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS OF THE INVENTION

[0030] FIG. 1 shows a schematically illustrated marine vessel 100 comprising an anti-fouling arrangement according to the invention. The vessel comprises a hull with a transom 104 to which a marine propulsion system is attached. The propulsion system in this example comprises a single driveline housing 101 at least partially submerged in water, a torque transmitting drive shaft 106 (not shown) extending out of the driveline housing 101, and a pair of counter-rotating propellers 102, 103 mounted on the drive shaft 106. In the current example, both propellers 102, 103 are electrically isolated from its drive shaft 106. The drive shaft arrangement is shown in FIG. 2 and will be described in further detail below. Each electrically isolated propeller 102, 103 to be protected against fouling is connected to a positive terminal 111 of a direct current (DC) power source 110, such as a battery, in order to form an anode. Further, each metallic component 101, 104, 10 to be protected against corrosion is connected to a negative terminal 112 of the direct current power source 110, in order to form cathodes. A control unit 113 is connected to the direct current power source 1 and distributes current to all component parts forming an electrical circuit. The control unit 113 is arranged to regulate the voltage and current output from the direct current power source 110. In order to assist regulation of the voltage and current output a reference electrode 124 is mounted on the hull remote from the anode and connected to the control unit 113 via an electrical wire 123. The reference electrode 124 measures a voltage difference between itself and the metallic components, which is directly related to the amount of protection received by the anode. The control unit 113 compares the voltage difference produced by the reference electrode 124 with a pre-set internal voltage. The output is then automatically adjusted to maintain the electrode voltage equal to the pre-set voltage.

[0031] Regulation of the voltage and current output from the direct current power source is controlled to automate the current output while the voltage output is varied. This allows the protection level to be maintained under changing conditions, e.g. variations in water resistivity or water velocity. In a sacrificial anode system, increases in the seawater resistivity can cause a decrease in the anode output and a decrease in the amount of protection provided, while a change from stagnant conditions results in an increase in current demand to maintain the required protection level. With ICCP systems protection does not decrease in the range of standard seawater nor does it change due to moderate variations in current demand. An advantage of ICCP systems is that they can provide constant monitoring of the electrical potential at the water/hull interface and can adjust the output to the anodes in relation to this. An ICCP system comprising a reference electrode is more effective and reliable than sacrificial anode systems where the level of protection is unknown and uncontrollable.

[0032] The anti-fouling arrangement is an impressed current cathodic protection (ICCP) arrangement using the propellers 102, 103 as an anode 115. In FIG. 1, the metallic component to be protected against corrosion is the driveline housing 101, the trim tabs 105 (one shown), and a metal portion of the hull, in this case the transom 104. Note that this is a non-exclusive list of metallic components suitable for marine growth and corrosion protection. In order to achieve this, the positive terminal 111 and the negative terminal 112 of the battery 1 are connected to the control unit 113. The control unit 113 is arranged to connect the positive terminal 111 to the propellers 102, 103 via a first electrical wire 114. The control unit 113 is further arranged to connect the negative terminal 112 to an electrical connector 117 on the driveline housing 101 via a second electrical wire 116. The negative terminal 112 is also connected to an electrical connector 119 on the trim tab 10 via a third electrical wire 118, and connected to an electrical 3 connector 121 on the transom 104 via a fourth electrical wire 120.

[0033] FIG. 2 shows a cross-section of the rear portion of the marine vessel 100 of FIG. 1, through a transom 204 and a driveline housing 201. The single driveline housing 201 is partially submerged in water and comprises torque transmitting drive shafts 232, 233 extending out of the driveline housing 201. A pair of counter-rotating propellers 202, 203 is mounted on their respective drive shafts 233, 232. In this example, the drive shafts 232, 233 are driven by an internal combustion engine ICE via a transmission 231. Transmissions for driving counter-rotating propellers are well known in the art and will not be described in detail here. Alternative drive units for driving the propellers are possible within the scope of the invention. Both propellers 202, 203 are electrically isolated from its respective drive shaft 232, 233 (see FIGS. 3A-B). As schematically indicated in FIG. 2, each electrically isolated propeller 202, 203 is connected to a positive terminal 211 of a direct current power source 2 at schematically indicated points 2 via electrical wiring 214. The electrical connection of the propellers will be described in further detail below. Further, each metallic component 201, 204, 20 to be protected against fouling is connected to a negative terminal 212 of the direct current power source 210. A control unit 213 is arranged to regulate the voltage and current output from the direct current power source 210. As described above, the positive terminal 211 and the negative terminal 212 of the battery 2 are connected to the control unit 213. The control unit 213 is arranged to connect the positive terminal 211 to the propellers 202, 203 via a first electrical wire 214. The control unit 213 is further arranged to connect the negative terminal 212 to an electrical connector 217 on the driveline housing 201 via a second electrical wire 216. The negative terminal 212 is also connected to an electrical connector 219 on the trim tab 205 (one shown) via a third electrical wire 218, and connected to an electrical connector 221 on the transom 204 via a fourth electrical wire 220. A reference electrode 224 is mounted on the hull remote from the propellers 202, 203 forming an anode and connected to the control unit 213 via an electrical wire 223. Regulation of the voltage and current output from the direct current power source using the control unit 213 has been described above.

[0034] FIGS. 3A and 3B show schematic cross-sections of propeller arrangements suitable for use with the invention. FIG. 3A shows a schematic propeller 302 that is electrically isolated from its drive shaft 301 by a torque transmitting electrically isolating component 305 mounted between the propeller 302 and the drive shaft 301. The electrically isolating component is mounted in a gap formed by the outer surface of the drive shaft 301 and the inner surface of the propeller hub 303. The torque transmitting electrically isolating component 30 can be made from an elastic material, such as a natural or synthetic rubber. The propeller 302 is connected to the positive terminal of the direct current power source (see FIG. 2) by electrical wiring 314 extending through a hollow portion 304 of the drive shaft 301. For instance, an axially extending internal groove can be provided in the inner surface of the drive shaft can be used for the electrical wiring. Alternatively an external groove in the outer surface of the drive shaft can be used for the electrical wiring to the propeller. The location of the wiring is dependent on factors such as whether a single propeller or a counter-rotating duo-prop arrangement is used. The electrical wiring 314 is electrically connected to the hub 303 of the propeller by means of a wiping contact 3 mounted between the drive shaft 301 and the hub 303. A wiping contact mounted inside the transmission housing and an electrical wire in or along the drive shaft can be used for connecting the positive terminal of a power source to the propeller hub.

[0035] FIG. 3B shows a schematic propeller 302 that is electrically isolated from its drive shaft 301 by a torque transmitting electrically isolating component 30 mounted between the propeller 302 and the drive shaft 301. As in FIG. 3A, the electrically isolating component is mounted in a gap formed by the outer surface of the drive shaft 301 and the inner surface of the propeller hub 303. The torque transmitting electrically isolating component 30 can be made from an elastic material, such as a natural or synthetic rubber. The propeller 302 is connected to the positive terminal of the direct current power source (see FIG. 2) by electrical wiring 314 extending through a hollow portion 304 of the drive shaft 301. For instance, an axially extending internal groove can be provided in the inner surface of the drive shaft can be used for the electrical wiring. Alternatively an external groove in the outer surface of the drive shaft can be used for the electrical wiring to the propeller. The location of the wiring is dependent on factors such as whether a single propeller or a counter-rotating duo-prop arrangement is used. The electrical wiring 314 is electrically connected to the hub 303 of the propeller by means of a wiping contact 315 mounted between the drive shaft 301 and the hub 303. Alternative solutions can include a wiping contact mounted inside the transmission housing and an electrical wire in or along the drive shaft for direct connection to the propeller hub.

[0036] The example in FIG. 3B differs from that of FIG. 3A in that a dielectric shield 307 is provided between the propeller 302 and the drive shaft 301 on which the propeller is mounted. The dielectric shield 307 is used as an electrical insulator that can be polarized by an applied electric field. When a dielectric material is placed in an electric field, electric charges do not flow through the material as they do in an electrical conductor but only slightly shift from their average equilibrium positions causing dielectric polarization. Because of dielectric polarization, positive charges are displaced in the direction of the field and negative charges shift in the opposite direction. This creates an internal electric field that reduces the overall field within the dielectric itself. In this arrangement the dielectric shield 307 is used to protect the surface of the drive shaft 301 near the propeller hub 303 from hydrogen embrittlement caused by unacceptably high potentials in areas adjacent the propeller 302 that is used as an anode in the anti-fouling arrangement.

[0037] The dielectric shield 307 can comprise a layer of dielectric material extending along the drive shaft over at least the entire axial extension of the propeller hub 303. The dielectric shield 307 is preferably arranged to extend a predetermined length L.sub.1 and L.sub.2 in front of and behind the propeller hub 303, respectively, in order to ensure that the protection potential at the point of contact with the shaft does not become to electronegative. The lengths L.sub.1 and L.sub.2 will vary depending on anode area, propeller hub design and the protection current used for the actual application. A dielectric material is a substance that is a poor conductor of electricity, but an efficient supporter of electrostatic fields. A non-exclusive list of suitable materials for use in such a dielectric shield includes polymer or polymer-ceramic materials with suitable dielectric properties.

[0038] FIG. 4 shows a schematic diagram illustrating a method of operating a cathodic protection and anti-fouling arrangement according to the invention. In operation, the method comprises an initial step 400 when the arrangement is being operated for protecting a marine vessel with a marine propulsion system against corrosion of submerged metallic components and fouling of the propellers. The cathodic protection and anti-fouling arrangement can be operated using an on-board source of DC power, as described in connection with FIGS. 1 and 2, or using DC power supplied from a shore facility, in order to conserve the on-board power source.

[0039] As described above, the propulsion system comprises at least one driveline housing at least partially submerged in water; a torque transmitting drive shaft extending out of the driveline housing; and at least one propeller mounted on the drive shaft. In a first step 401, the method involves providing electrical power from a direct current (DC) power source. In a second step 402, the method involves causing at least one metallic component of the vessel to act as a cathode, by connecting the at least one metallic component to a negative terminal of the DC power source. In a third step 403, the method involves causing the at least one propeller of said marine propulsion system to act as an anode, by connecting the at least one propeller to a positive terminal of the DC power source. The arrangement forms a galvanic circuit which comprises the DC power source, the at least one metallic component, the at least one propeller and water, in which water the metallic component and the propeller are at least partially submerged. In a fourth step 404, the method involves electrically connecting said anode to the DC power source and directing a direct current flow through said galvanic circuit. In a fifth step 405, the method involves controlling the direct current flow through said galvanic circuit by means of a control unit. In a sixth step 406, which can be optional, the method involves connecting the control unit to a reference electrode which at least partially submerged in water. The reference electrode provides a ground reference value for the control unit. After a predetermined period of operation, the anti-fouling arrangement can be disconnected from the power source in a final step 407. The cathodic protection and anti-fouling arrangement can be operated continuously or at least over extended periods of time, as long as shore power is provided. When an on-board source of power is used, the anti-fouling arrangement can be operated intermittently or over limited periods of time, while the power levels of the on-board power source allows.

[0040] It is to be understood that the present invention is not limited to the embodiments described above and illustrated in the drawings; rather, the skilled person will recognize that many changes and modifications may be made within the scope of the appended claims.