deep ocean materials
TRANSCRIPT
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Deep Ocean Materials
Lavinio GualdesiSaclant Undersea Research Centre
La Spezia Italy
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Objectives
• Develop a measuring range at 3500 meters depth
• Maximize corrosion free endurance time (time between overhauls)
• Minimize maintenance time• Minimize failure risk• Respect budget constraints
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Two Main Options
• Use market available products and design to improve system reliability
• Invest in material performance research aimed to design and develop a system as a complete prototype
• A cost effective compromise of above is to integrate market products into a customized system
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Targets• Withstand depth pressure with an acceptable
flexural deformation• Preserve the relative motion between moving parts
without an excess of friction• Preserve for long time the surface integrity
avoiding corrosion • Privilege non magnetic or even non conductive
materials to avoid galvanic effects and influence compass related instrumentation
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Titanium Alloys• Excellent response to corrosion and fouling• Non magnetic• High mechanical strength• Medium availability• Its higher cost is largely compensated by the
use of less material weight to obtain the same strength and by savings in maintenance cost
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Titanium Alloys• Its low density and high strength candidates
it for the best material to make effective pressure vessels, but coupling connectors and joints of different material may cause galvanic problems to them.
• Welding Titanium alloys needs an expensive skilled procedure
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Design Policy
• It is important to establish a design policy: - if the reference is Titanium alloy, any compulsory deviation from it must be considered as a case study- only Composite Technology may be associated to it with careful design of the joints due to the different elastic properties.
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Composites Advantages• Corrosion free• Non magnetic• Damage propagation very low• Creative design due to the fact that the
designer make its own production:- it is virtually possible to change material
density and composition at any section
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Composites Limits
• A good quality assurance system is needed to avoid to transform a creative design in arbitrary solutions during production phase
• Normally an expensive set of models and moulds are needed for each component. Therefore this solution becomes cost effective after a large number of components per mould (with some exceptions)
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Composites Optimization
• Standard lamination process with woven roving creates a part with maximum flexural strength in 0-90 degree directions, with minimum strength along -45 +45 directions.
• A special material woven along -45 +45 degree has been produced by reinforcement specialists to better hysotropy
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Laminate Porosity
• Quality Assurance Problem• Rigorous test of construction materials• High quality polyester isoftalic resin • Avoid any contamination of the resin with
undue fillings
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Lamination Data Sheets• Design the appropriate sequence• Avoid to make joints with surfaces subject
to cure on the mould because the joint will be weak.
• Use insert on the mould to accommodate particular shape
• do not insert metallic part in the sheets to avoid interlaminar shear effect
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Deep Water Resins
• Syntactic foam to encompass electronic boards with the associated wiring and underwater connector
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BucklingLarge plates may suffer from creep or even a buckling effect which is particularly negative to moving joints:
• a hybrid glass carbon reinforcement and unidirectional tapes along the strength lines
• a straight fiber sewed 0-90 degrees glass reinforcement
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Sandwich Composites
Solution for moving joints and rigid light parts:
• Hybrid sandwich composed by syntactic foam core and two titanium alloy skins
• Use a sandwich composed by a syntactic foam core and pre-impregnated FRP skins cured in oven
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CAD CAM Models
Novel procedure to make inexpensive moulds:• CAD drawing of the model• CAM file of the working sequence• a 7 axis robot machines the CAD model• lamination of the mould on the model• production of FRP parts out of the mould
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Innovative composites technology Innovative composites technology for marine environmentfor marine environment
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3D CAD Design3D CAD Design
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Model disassemblyModel disassembly
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CAM PathCAM Path
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Tool Path SimulationTool Path Simulation
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Robot machiningRobot machining
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Robot machiningRobot machining
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Robot machiningRobot machining
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Model preModel pre--assemblyassembly
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Model preModel pre--assemblyassembly
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Model FinishingModel Finishing
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OtherOther modelsmodels
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Machining a sonar dome Machining a sonar dome modelmodel