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→Acoustical Isolation
For a production boat it’s feasible to do a spectrum analysis and design suitable sound attenuation and test it. For a bespoke boat this is unlikely to be feasible. Thus a good cost-effective approach is to focus on reducing sound transmission in a target range such as 1,000-2,500 Hz (wavelengths of 13.5 to 5.4-in or 34.3 to 13.72 cm).
== Methods of Isolation
Acoustical isolation works by converting sound waves into heat that is then dissipated. Some methods of isolation are:
* Reflecting sound waves
* Dampening sound waves
* Converting sound waves to heat energy
* Decoupling surfaces
Reflecting sound within a room causes sound to lose energy, reducing the amount of sound radiation outside the room. A common method of achieving this is to have reflective material on the outside surface of insulation. However the room shape and size can also have a major impact. The best shape for noise cancellation is a cube. The next best is a room where all dimensions are a multiple of the height, e.g., an engine room that is 7 x 14 x 14 ft.
Dampening sound is achieved by absorbing it in insulation. The depth of insulation should be calculated to absorb the desired wavelengths (e.g., 6-14 in).
Sound waves can be converted to heat energy by adding mass to surfaces. Vibrating a mass absorbs more of the sound energy.
Decoupling is achieved by using viscoelastic dampers between surfaces, and air gaps to prevent direct conduction. Air gaps need especial attention because they can resonate, especially at the lower frequency (1000-400 Hz) wavelengths of 13.5 to 33.76 in (34.3-85.75 cm). Resonance will transfer energy across the gap.
These techniques are applied in the following hypothetical example where a saloon is located above an engine room, and cabins are adjacent to engine-room bulkheads.
In a saloon above the engine room, sound can be attenuated in the design of the sole and the engine-room ceiling below that. For acoustic isolation in the sole build up a layered floor consisting of (starting at the bottom) a sub-sole, viscoelastic glue as a damper, an underlayment of acoustic mat made of dense rubber (similar to the mat used in horse stalls), then cement board and flooring.
In the engine room design the ceiling to provide attachment points for a drop ceiling. Apply composite insulation such as lead-fibreglass with the fibreglass rated at, say, R13. Since we are dealing with wavelengths of, say, 5- to 14-in, the thickness of the insulation should be in the same range. Install a decoupled drop ceiling consisting of two layers of non-combustible panels bound with viscoelastic glue. Several marine-approved panel materials are available.
Use spring ceiling hangers or other means to attach the panels to the attachment points in a decoupled way. In a capsize the spring hangers should be able to withstand high accelerations of mass to avoid detaching the ceiling. There should be an air gap between the insulation and the panels. Where the drop ceiling meets the walls, prevent flanking noise leaking through using a flexible acoustic sealer.
A ceiling of this type, combining mass, decoupling, resilient mounts and insulation is capable of attenuating noise 60-75 dB over 1000-5000 Hz.<ref>The Green Glue Company, http://www.greengluecompany.com</ref>
Similar techniques could be used on the bulkheads where feasible. Consider alternate arrangements to simplify construction. For example, in the engine room use a viscoelastic glue to stick a non-combustible panel on the bulkhead, then attach the composite insulation. In the living space on the other side attach furring strips using neoprene rubber. If more isolation is needed incorporate rubber mat or more insulation. Always leave an air gap to prevent conduction.
If there is ductwork originating in the engine room, use round lined ductwork (insulated on the inside). Round ducts transfer less sound than square ones. In the engine room coat the exterior of the duct with a viscoelastic material, and cover it with a soffit to prevent exposure to direct sound. Consider a 90 or 180 degree bend to force sound to interact with the duct liner. Where possible, use serpentine lengths of lined flex duct to create a more complex path for sound.
Design an engine room entrance that has a double door. The inside door should be the watertight one (with a view port), and the outside one should be air tight. The space in-between would make a good place to hang ear protectors, etc. Both doors should have significant solid mass.
Finally, some cautions. Some complex isolation schemes were described above, but you should keep the design as simple and robust as possible. For example:
* The performance of two mass panels isolated by a viscoelastic glue can exceed that of a limp mass, such as lead-loaded composite insulation. It may be feasible to use just ~R13 fibreglass with the mass panels.
* A triple mass-panel sandwich alone that consists of a mass panel glued (viscoelastic) to either side of a bulkhead can achieve attenuations of 60 dB.<ref>The Green Glue Company, http://www.greengluecompany.com</ref>
* Test (sound meters with a range of 35-130 dB can be rented.):
* Start with a basic installation of isolation in the engine room. Run the engine and use a sound meter to measure the noise in adjacent cabin areas. Upgrade the isolation to reach your sound goal.
* Or, build a small test box with a logging sound meter inside. Add test isolation externally. Evaluate the performance of your choices by suspending the test box in the engine room and running the engine.
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