EP4182223A1

EP4182223A1 - A mounting device for an anti-fouling system

Info

Publication number: EP4182223A1
Application number: EP21745397.6A
Authority: EP
Inventors: Darren ROWLANDS
Original assignee: Nrg Marine Ltd
Current assignee: Nrg Marine Ltd
Priority date: 2020-07-16
Filing date: 2021-07-07
Publication date: 2023-05-24
Also published as: GB2597253A; GB2597253B; GB202010967D0; WO2022013524A1

Abstract

Disclosed is a mounting device for an anti-fouling system of a vessel, the mounting device comprising: a securing means for securing the mounting device to an inlet or outlet of a cooling system of the vessel; and a transducer plate operatively coupled to the securing means for vibrationally coupling an ultrasonic transducer to the cooling system of the vessel.

Description

A Mounting Device for an Anti-Fouling System

Technical Field of the Invention

The present invention relates to a mounting device for an anti-fouling system, and in particular an anti-fouling system for a vessel such as a boat. The invention extends to an anti-fouling system, a cooling system for a vessel, and vessel comprising the mounting device.

Background to the Invention

Fouling (e.g. biological growth including algae, weeds and barnacles) of vessels and in particular of the hulls of vessels is a known problem. If left uncontrolled, such growth will increase the weight of the vessel and its drag. This is likely to reduce the efficiency of the vessel, impact its handling and have an overall effect on performance. It is therefore important to reduce or prevent such growth.

Traditionally, such biological growth would be removed manually either through the use of a dry-dock or by diving. However, particularly where a dry-dock is used, this can result in a significant amount of time where the vessel is out of use and can be costly. Alternatively, the growth may be removed or inhibited chemically, for example, by applying a biocidal coating to the surface. However, such chemicals are generally harmful from an environmental point of view. Accordingly, it is advantageous to provide a solution which minimises the time a vessel is taken out of use, preferably to zero, and/or does not make use of such potentially harmful chemicals.

One such solution comprises the use of electrodes positioned on opposite sides of the vessel, and an electrical current provided between the two causes electrolysis of the surrounding seawater. This results in the formation of, for example, chlorine and sodium hypochlorite which act to remove such biological growth from the hull.

Alternatively, some anti-fouling systems may use one or more transducers to apply ultrasonic vibrations to the hull causing disruption to any biological growth present on the hull and/or preventing new growth thereon. Specifically, such systems use the application of ultrasonic vibrations to problematic surfaces to causes non- inertial cavitation of the liquid, e.g. seawater, adjacent to the surface causing a microscopic agitation of the biological growth on the surface, causing it to break up and deteriorate. However, in general, such solutions are only provided for preventing/reducing fouling of the hull of the vessel, whereas other components of the vessel may in fact be submerged during normal use of the vessel and are hence likely to be susceptible to fouling.

One such component may comprise a cooling system of the vessel, for instance a keel cooler which may include a pipework arrangement provided in thermal contact with the water acting as a heat exchanger for removing heat from coolant flowing through the cooler. Biological growth on the exterior of the cooler can inhibit this heat exchange process resulting in the coolant not being cooled adequately. In certain scenarios, for example where the coolant is provided for the controlling the temperature of an engine of the vessel, a reduction in the efficiency of this heat exchange process can result in a significant reduction in the operational efficiency of the engine through overheating. This can lead to increased fuel consumption, increased emission levels and ultimately engine failure if not kept under control. It is therefore important to ensure adequate operation of such cooling systems.

It would therefore be advantageous to provide means allowing for the use of an ultrasonic anti-fouling device to be used to prevent fouling of a cooling system, such as a keel cooler, of a vessel.

It is an aim of an embodiment or embodiments of the invention to overcome or at least partially mitigate one or more problems discussed herein.

Summary of the Invention

According to an aspect of the invention there is provided a mounting device for an anti-fouling system of a vessel, the mounting device comprising a securing means; and a transducer plate operatively coupled to the securing means for coupling a transducer to the vessel or a component thereof.

According to an aspect of the invention there is provided a mounting device for an anti-fouling system of a vessel, the mounting device comprising a securing means for securing the mounting device to an inlet or outlet of a cooling system of the vessel; and a transducer plate operatively coupled to the securing means for vibrationally coupling an ultrasonic transducer to the cooling system of the vessel. Advantageously, the mounting device of the present invention provides means to mount (and vibrationally couple) an ultrasonic transducer to a cooling system of a vessel. In this way, the transducer may be used to apply a vibration to the cooling system, e.g. one or more pipes of the system, to prevent or reduce biological growth thereon. Advantageously, the mounting device of the present invention may increase or maintain an operational efficiency of the cooling system, and as such an operational efficiency of one or more systems of the vessel, e.g. an engine.

The securing device may comprise a collar configured to be mounted about a standpipe of the inlet or outlet of the cooling system of the vessel. The collar may comprise a substantially circular aperture therethrough facilitating mounting of the collar about a substantially cylindrical standpipe, in use. The collar may be configured to be mounted about a standpipe having a diameter of 1.5 inches, 2 inches, 2.5 inches or 3 inches, for example, although the collar may be configured to be mounted about a standpipe of any diameter.

The collar may be threaded such that the mounting device may be threaded onto a threaded standpipe of the cooling system. The thread may comprise an NPT or NPS- M thread, for example, although any suitable thread pattern may be provided as required by the end application.

The collar may comprise a smooth, non-threaded collar sized to fit about a smooth standpipe, such as a flanged or collared standpipe of the cooling system.

The collar may comprise a split collar. The split collar may preferably be formed of two half collars which may be hinged or otherwise connected at one or more locations such that the two half collars may be positioned about the standpipe of the cooling system, in use.

The mounting device may be configured to be mounted directly onto a standpipe of the cooling system. In some embodiments, the mounting device may be configured to be mounted onto a standpipe of the cooling system, and be positioned in contact with one or more components thereof, for example in contact with a nut, bolt, washer or the like forming a connection means for connecting the cooling system to a further component of the vessel, for example for connecting a keel cooler to an exterior surface of a vessel.

The transducer plate may be substantially flat, for example, the transducer plate may comprise a substantially flat upper surface onto which the transducer may be mounted, in use. The transducer plate may comprise one or more notches, apertures or ridges therein to locate and/or orientate the transducer thereon.

The transducer plate may be configured such that the transducer may be secured thereto, through a mechanical connection such as one or more bolts/screws or the like, via welding, or through an adhesive coupling, for example. The transducer plate may be configured such that the transducer may be coupled, connected and/or secured directly or indirectly (e.g. via a transducer ring) thereto.

In use, the transducer plate may be provided with, or be configured to have applied thereto, an acoustic coupling agent such as a liquid, gel or paste for maximising the acoustic coupling between the transducer and the transducer plate.

The transducer plate may be orientated in the same plane as the securing device. For example, the mounting device may be configured such that it may be mounted on a vertical (or substantially vertical) standpipe of an inlet or outlet of the cooling system with the transducer plate being substantially horizontal.

The mounting device may be formed of a single piece, with the transducer plate and securing means being integrally formed. Advantageously, this may reduce cost and complexity in the manufacture of the mounting device.

The mounting device, and the securing means in particular may be made from a material which is equivalent to or complementary to the material of the cooling system. Advantageously, having the mounting device and cooling system made from equivalent or complementary materials may reduce any loss of vibration propagating through the components due to any boundary effects. Furthermore, using equivalent or complementary materials may prevent or reduce the likelihood of galvanic corrosion issues at the point(s) of contact between the mounting device and the cooling system.

The mounting device may comprise or be manufactured from brass or aluminium, for example. In embodiments, the mounting device may be formed of brass where the cooling system or components thereof (e.g. a coupling member such as a bolt or nut to or against which the mounting device may contact in use) comprises a copper- nickel construction. The mounting device may be formed of aluminium where the cooling system or components thereof are formed from aluminium. The mounting device may be formed of carbon fibre. In some embodiments the mounting device may be formed of a copper-nickel material.

According to an aspect of the invention there is provided an anti-fouling system for a vessel, the anti-fouling system comprising a mounting device of any preceding aspect of the invention and one or more ultrasonic transducers.

The anti-fouling system may comprise an anti-fouling system for use with, and to prevent fouling of, a cooling system of the vessel, for example a keel cooler of the vessel.

The anti-fouling system may comprise a plurality of ultrasonic transducers each operable to be coupled to one or more components of the vessel, in use.

The anti-fouling system may comprise a control unit. The control unit may be operable to control operation of the one or more ultrasonic transducers, for example, to control the amplitude, frequency or the like of the output from the one or more ultrasonic transducers.

According to another aspect of the invention there is provided a cooling system of a vessel comprising an anti-fouling system of the preceding aspect of the invention operatively coupled thereto.

The cooling system may comprise a keel cooler of the vessel. The keel cooler may comprise an inlet standpipe and/or an outlet standpipe. The cooling system may comprise an ultrasonic transducer operatively coupled to the inlet standpipe or outlet standpipe of the keel cooler.

According to an aspect of the invention there is provided a vessel comprising the mounting device, anti-fouling system or cooling system according to any preceding aspect.

Detailed Description of the Invention In order that the invention may be more clearly understood one or more embodiments thereof will now be described, by way of example only, with reference to the accompanying drawings, of which:

Figure 1 is a perspective view of an example transducer for use with the present invention;

Figure 2 is a side perspective view of an embodiment of a mounting device in accordance with the present invention, with a transducer mounted thereto;

Figure 3 is a perspective view of an example keel cooler for use with the present invention;

Figure 4 is a side perspective view of the mounting device shown in Figure 2 mounted to the inlet pipe of the keel cooler of Figure 3; and

Figure 5 is a side perspective view of a further embodiment of a mounting device in accordance with the present invention. In general, the present invention relates to a mounting device 10, 10' for an anti fouling system of a vessel. The mounting device 10, 10' comprises a securing means 14, 14' and a transducer plate 12, 12' operatively coupled to the securing means 14, 14' for coupling a transducer 52 to the vessel or a component thereof.

Figure 1 illustrates a transducer unit 50 which includes a transducer 52, transducer ring 54 and cable 56. The transducer ring 54 is able to be coupled/uncoupled from the transducer 52 through corresponding threaded portions provided on an exterior surface of the transducer 52 and an internal surface of the transducer ring 54 as shown.

In use, the transducer 52 is operable to be mounted to a component, e.g. the transducer plate 12, 12' of the mounting device 10, 10' via the transducer ring 54. The transducer 52 is connected to, and is controllable via, a control unit (not shown) via cable 56. The transducer unit 50 may comprise one of a plurality of transducer units 50 forming an anti-fouling system for the vessel. The transducer 52 is operable in use to provide a vibrational output to the component to which it is mounted to, here primarily for the purpose of removing or inhibiting biological growth on a keel cooler 20 of the vessel as is described herein.

Figure 3 illustrates a keel cooler 20 to which a mounting device of the present invention, specifically mounting device 10 may be mounted, in use, for reducing and/or inhibiting biological growth thereon. The cooler 20 comprises a series of pipes 21 through which coolant may flow, in use. When positioned on a vessel, and in normal use, the keel cooler 20 is submerged such that heat from the coolant flowing through said pipes 21 may be transferred from the coolant to the surrounding water before being recirculated through the vessel’s engine. The cooler 20 includes an inlet pipe 22a through which coolant enters the cooler 20, and an outlet pipe 22b for through which coolant leaves the cooler 20 to be recirculated through the engine. As shown, the inlet and outlet pipes 22a, 22b of cooler 20 are threaded.

Figure 2 illustrates a first embodiment of a mounting device 10 of the present invention. The mounting device 10 is specifically configured for coupling the transducer unit 50 to the cooler 20 described above.

Specifically, the mounting device 10 comprises a transducer plate 12 and securing means in the form of a securing collar 14. The securing collar 14 comprises a split collar formed of a first half collar 16a and second half collar 16b connected to one another to form the circular collar 14 with an aperture 18 therethrough. The interior surfaces of the two half collars 16a, 16b are threaded corresponding to the thread on a standpipe of an inlet/outlet 22a, 22b of the keel cooler 20.

The transducer plate 12 is substantially flat, with an upper surface defining the mounting surface for the transducer unit 50 as shown in Figure 2. The transducer plate 12 includes mounting apertures (not shown) for coupling the transducer ring 54 of the transducer unit 50 to the transducer plate 12 via one or more mechanical securing means such as bolts or screws.

The transducer plate 12 and the securing collar 14 may be integrally formed, or may comprise separate components which are welded or otherwise connected to one another. The invention is not limited in this sense. The mounting device 10 is formed from a material which is the same as or complements the material of the component to which it is to be mounted, in use. Specifically, the mounting device may be formed of brass where the cooling system or components thereof (e.g. a coupling member such as a bolt or nut 26 to or against which the mounting device 10 contacts in use) comprises a copper-nickel construction. The mounting device 10 may be formed of aluminium where the cooling system or components thereof are formed from aluminium. Advantageously, having the mounting device and cooling system made from equivalent or complementary materials may reduce any loss of vibration propagating through the components due to any boundary effects. Furthermore, using equivalent or complementary materials may prevent or reduce the likelihood of galvanic corrosion issues at the point(s) of contact between the mounting device 10 and the cooling system.

Figure 4 illustrates the mounting device 10 in position on the inlet 22a of the cooler 20. Specifically, the mounting device 10 is mounted on the inlet 22a at a threaded portion 24 thereof directly above, but separated from a nut 26 and washer 28 arrangement forming a connection means for connection and securing the cooler 20 to an exterior surface of the vessel. The transducer unit 50 is provided mounted on the transducer plate 12 of the mounting device 10 for providing a vibrational output to the mounting device 10 which propagates through said device 10 and the inlet 22a, either through the walls of the inlet 22a and/or potentially through the coolant flowing therethrough to provide a vibrational stimulus to the pipes 21 of the cooler 20.

Figure 5 illustrates a second embodiment of a mounting device 10' in accordance with the present invention. The mounting device 10' is substantially equivalent to mounting device 10, but is instead configured to be mounted to a standpipe 22a' which is smooth, specifically for where the standpipe comprises a flanged standpipe as shown in Figure 5.

Here, rather than having the connection means formed of the nut and washer 26, 28 arrangement, the standpipe 22a' is instead coupled to a cooler 20' through coupling of corresponding flanges 30, 32. Specifically, the inlet standpipe 22a' comprises a flange 30 at an open end thereof which is coupled, in use, to a flange 32 provided on the cooler 20'. Given that the standpipe 22a' is smooth (i.e. not threaded), the mounting device 10' comprises securing means in the form of a securing collar 14' which has a smooth internal surface. Again, and as with securing collar 14, the securing collar 14' comprises a split collar formed of a first half collar 16a' and second half collar 16b' connected to one another to form the circular collar 14' with an aperture therethrough. Otherwise, mounting device 10' is formed in substantially the same manner as mounting device 10 described herein.

The one or more embodiments are described above by way of example only. Many variations are possible without departing from the scope of protection afforded by the appended claims.

Claims

1. A mounting device for an anti-fouling system of a vessel, the mounting device comprising: a securing means for securing the mounting device to an inlet or outlet of a cooling system of the vessel; and a transducer plate operatively coupled to the securing means for vibrationally coupling an ultrasonic transducer to the cooling system of the vessel.

2. A mounting device as claimed in claim 1, wherein the securing device comprises a collar configured to be mounted about a standpipe of the inlet or outlet of the cooling system of the vessel.

3. A mounting device as claimed in claim 2, wherein the collar comprises a substantially circular aperture therethrough facilitating mounting of the collar about a substantially cylindrical standpipe, in use.

4. A mounting device as claimed in claim 2 or claim 3, wherein the collar is threaded such that the mounting device may be threaded onto a threaded standpipe of the cooling system.

5. A mounting device as claimed in claim 2 or claim 3, wherein the collar comprises a smooth, non-threaded collar sized to fit about a smooth standpipe.

6. A mounting device as claimed in any of claims 2 to 5, wherein the collar comprises a split collar.

7. A mounting device of any preceding claim, wherein the transducer plate is substantially flat, comprising a substantially flat upper surface onto which the transducer is mounted, in use.

8. A mounting device of any preceding claim, wherein the transducer plate comprises one or more notches, apertures or ridges therein to locate and/or orientate the transducer thereon.

9. A mounting device of any preceding claim, wherein the transducer plate is orientated in the same plane as the securing device.

10. A mounting device as claimed in any preceding claim, wherein the transducer plate and securing means are integrally formed.

11. A mounting device of any preceding claim, wherein the mounting device comprises or is manufactured from brass or aluminium.

12. An anti-fouling system for a vessel, the anti-fouling system comprising: a mounting device of any preceding claim; and one or more ultrasonic transducers.

13. A cooling system of a vessel, comprising an anti-fouling system of claim 12 operatively coupled thereto.

14. A cooling system of claim 13, wherein the cooling system comprises a keel cooler of the vessel.

15. A cooling system of claim 14, wherein the keel cooler comprises an inlet standpipe and/or an outlet standpipe, and wherein the cooling system comprises an ultrasonic transducer operatively coupled to the inlet standpipe or outlet standpipe of the keel cooler.

16. A vessel, comprising the mounting device of any of claims 1 to 11, an anti fouling system of claim 12 or a cooling system according to any of claims 13 to 15.