ssc-452 aluminum structure design and fabrication guide ship

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Introduction 10-1 Result of fire aboard cruise ship Star Princess March 2006 10-1 10-2 Air spaces with insulating value of 0.0 S 10-13 10-3 Air spaces with insulating value of 0.05 S 10-14 10-4 Air spaces with insulating value of 0.10 S 10-14 10-5 Air spaces with insulating value of 0.15 S 10-15 10-6 Example of fire protection insulation 10-16 11-1 Single degree of freedom system 11-2 11-2 Simply supported plate vibrating 11-5 11-3 Simply supported beam vibrating in its second mode 11-9 12-1 Corrosion of aluminum where lead or iron oxide primer spilled over from 12-5 priming a steel door frame 12-2 Corrosion of aluminum primed with iron oxide 12-5 12-3 Corrosion where standing water at an internal stiffener permitted buildup of 12-6 salt concentrations 12-4 Doubler plate welded over a crack 12-8 12-5 Improving weld profiles in fillet welds 12-8 12-6 Inserting a backing strip in a tubular member 12-9 12-7 Improving the profile of a butt weld 12-10 12-8 Comparison of Eurocode 9 and NSWCCD fatigue S-N curves for butt welds 12-11 12-9 Recracking of one-sided repair weld where the original crack was not 12-11 removed 12-10 Reinforcement of a hatch opening 12-13 12-11 Exfoliation of 5454-H321 plate at a deck drain 12-14 12-12 Exfoliation at a joint between a 5456-H321 deckhouse and a steel coaming 12-15 12-13 Intergranular corrosion with plate beginning to pop out 12-16 12-14 Pitting corrosion on a plate susceptible to intergranular corrosion 12-16 12-15 Stress corrosion cracking and pitting on shell plating 12-17 13-1 Polar plot of pitch angle for a patrol vessel in Sea State 3 13-2 13-2 Example of the bridge display from a hull monitoring system for a tanker 13-5 13-3 Display of monitoring system of super liner Ogasawara 13-7 14-1 Schematic illustration of friction stir welding 14-2 14-2 Tip of the friction stir welding tool 14-2 14-3 Section through friction stir weld 14-3 14-4 Completed friction stir welds 14-3 14-5 Friction stir welding panels together 14-4 14-6 Friction stir welding facilities at the Tamano works of Mitsui Engineering and 14-4 Shipbuilding Company 14-7 Panels fabricated using friction stir welding at the Tamano works of Mitsui 14-4 Engineering and Shipbuilding Company 14-8 Friction stir welding aluminum to steel 14-6 14-9 Scanning electron microscope image and EDS line analysis of friction stir 14-7 welding joint between aluminum and steel 14-10 Cross-sectional view aluminum to steel friction stir welded joint after tension 14-7 test 14-11 Friction stir weld joint geometries 14-8 xiii
Aluminum Marine Structure Guide 14-12 Transverse friction stir welds on aluminum alloys 6013 and 6082 compared 14-9 with EC-9 curves 14-13 Laser beam welding process 14-10 14-14 Laser beam welding of a lap-penetration joint with the conduction mode 14-11 14-15 Concept for simultaneously welding with the laser beam process in the 14-12 keyhole and conduction modes 14-16 Experimental apparatus for laser stir welding 14-12 14-17 Laser stir lap weld 14-13 14-18 Laser beam lap weld 14-14 14-19 Laser stir lap fillet weld 14-14 14-20 Laser beam lap fillet weld 14-15 14-21 Laser stir fillet weld 14-15 14-22 Laser beam fillet weld 14-15 14-23 Fatigue testing of laser stir welded and laser welded lap penetration joints 14-16 14-24 Possible applications of laser stir welding 14-17 14-25 Electrospark welding apparatus 14-19 14-26 Laser welding schematic 14-21 14-27 Section through laser welds in of 5182 and 5754 alloys 14-22 14-28 Electron beam welding of panels 14-23 List of Tables Table Title Page 2-1 Chemical Composition of Aluminum Alloys 2-2 2-2 Mechanical Properties Marine Aluminum Alloys 2-5 2-3 True Stress-Strain Properties of Aluminum Alloys 2-5 2-4 Yield Strength of Some Aluminum Alloys at Elevated Temperatures 2-6 2-5 Dynamic Tear Energy of Aluminum Alloys 2-7 2-6 J-Integral Fracture Toughness of Aluminum Alloys 2-7 2-7 Corrosion Testing of Aluminum 2-14 2-8 Yield Strength of Welded Aluminum Alloys 2-20 2-9 Corrosion-Erosion Resistance of Different Alloys 2-29 2-10 Seawater Galvanic Series 2-31 2-11 SNAME Tee Sections 2-33 2-12 SNAME Angle Sections 2-33 2-13 Properties of Rounded Tees 2-34 2-14 Properties of Bulb Flats 2-36 2-15 Exit and Quench Temperature Data For Selected 6xxx-Series Alloys 2-42 2-16 Standard Tolerances for Extruded Wire, Rod, Bar and Profiles 2-48 3-1 Comparison of Requirements of ABS HSC and DNV High Speed Light Craft 3-10 3-2 Allowable Stress Levels for Bottom Plating 3-12 3-3 Effective Width of Plate based on Buckling Strength 3-17 3-4 Values of Coefficient C to be used in U.S. Navy Equation for Plating 3-22 3-5 Comparison of Requirements for the Bottom Plating of a 61-meter, 50-Knot 3-25 xiv
Page 1 and 2: NTIS # PB2007- SSC-452 ALUMINUM STR
Page 4 and 5: Technical Report Documentation Page
Page 6 and 7: Introduction Table of Contents Sect
Page 8 and 9: Introduction 5 Welding and Fabricat
Page 10 and 11: Introduction 12.3.2 Welding a Doubl
Page 12 and 13: Introduction 5-1 Hull with stick co
Page 16 and 17: Introduction Craft 3-6 Coefficients
Page 18 and 19: Chapter 1 Introduction 1.1 Backgrou
Page 20 and 21: Introduction aluminum welding had a
Page 22 and 23: Introduction similar to those in st
Page 24 and 25: Introduction The need for fire prot
Page 26 and 27: Chapter 2 Material Characteristics
Page 28 and 29: Material Characteristics For heat-t
Page 30 and 31: Material Characteristics Alloy and
Page 32 and 33: Material Characteristics Table 2-5
Page 34 and 35: Material Characteristics alloy A.W.
Page 36 and 37: Material Characteristics nearly con
Page 38 and 39: Material Characteristics “H321 -
Page 40 and 41: Material Characteristics 120° F (4
Page 42 and 43: Material Characteristics In the beg
Page 44 and 45: Material Characteristics Figure 2-6
Page 48 and 49: Material Characteristics 2.4.1 Gene
Page 50 and 51: Material Characteristics make a jud
Page 52 and 53: Material Characteristics Both the 5
Page 60 and 61: Material Characteristics 700 Sectio
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Material Characteristics high inter
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Material Characteristics Heated alu
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Material Characteristics applicatio
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Material Characteristics Design wi
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Material Characteristics Figure 2-
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Material Characteristics 2.7 Summar
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Chapter 3 Structural Design 3.1 Int
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Structural Design The design triang
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Structural Design instrument actual
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Structural Design sponsored by the
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Structural Design more conservative
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Structural Design seakeeping progra
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Structural Design provided only for
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Structural Design The units of dist
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Structural Design b e E = 1.9 t σ
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Structural Design Jennings et al. d
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Structural Design emergency floodin
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Structural Design Jones and Walters
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Structural Design panel 800 mm long
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Structural Design Bruchman and Dins
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Structural Design levels are implic
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Structural Design where: σ c π =
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Structural Design For fixed end col
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Structural Design Pp σ' Yp = , s l
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Structural Design Figure 3-6 Geomet
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Structural Design 2 - 4π D σ pbe
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Structural Design Figure 3-7 Buckli
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Structural Design Aluminum does not
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Chapter 4 Structural Details 4.1 In
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Structural Details Table 4-1 Steel
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Structural Details 23, 3.4 14, 3.4
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Structural Details 4.2.1.9 End Brac
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Structural Details 4.2.2 Tripping B
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Structural Details 4.2.2.3 Tripping
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Structural Details 4.2.3.2 Nontight
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Structural Details 4.2.4.3 Tight Co
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Structural Details 4.2.5.2 Welded G
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Structural Details 4.2.6.7 Weld Cle
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Structural Details 4.2.8 Deck Cutou
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Structural Details 4.2.9.2 Tubular
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Structural Details 4.2.9.3 Open Sec
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Structural Details 4.2.10.2 End cli
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Structural Details 4.2.11.2 Angle a
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Structural Details 4.3.1 Deck Panel
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Structural Details Flat Bar Extrude
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Structural Details Figure 4-7 Egg c
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Chapter 5 Welding and Fabrication 5
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Welding and Fabrication difficult o
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Welding and Fabrication 5.3 Structu
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Welding and Fabrication Shielding g
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Welding and Fabrication Residual
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Welding and Fabrication The extrusi
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Welding and Fabrication The lap bon
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Chapter 6 Riveting Although once us
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Riveting equivalent to the military
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Riveting is between 1.5 d and 2.0 d
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Riveting 6.3 Fatigue of Riveted Joi
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Chapter 7 Joining Aluminum to Steel
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Joining Aluminum to Steel Structure
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Chapter 8 Residual Stresses and Dis
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Residual Stresses and Distortion cu
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Residual Stresses and Distortion fi
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Residual Stresses and Distortion A
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Residual Stresses and Distortion Us
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Residual Stresses and Distortion Wi
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Residual Stresses and Distortion Fi
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Residual Stresses and Distortion 8.
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Residual Stresses and Distortion e)
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Chapter 9 Fatigue and Fracture Desi
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Fatigue Design and Analysis Procedu
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Chapter 10 Fire Protection 10.1 Int
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Fire Protection Class B divisions a
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Fire Protection 10.2.3 U.S. Coast G
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Fire Protection spread of fire whil
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Fire Protection Insulation is not g
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Fire Protection Table 10-2 U.S. Coa
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Fire Protection sheathing should be
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Fire Protection FIRE Notes: Air spa
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Fire Protection Table 10-5. The bul
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Fire Protection Table 10-6 Typical
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Fire Protection A sprayed fire prot
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Chapter 11 Vibration 11.1 Introduct
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Vibration Table 11-1 Coefficients f
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Vibration where: p 2 a n b
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Vibration Other forms of propulsion
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Vibration For a simply supported be
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Vibration t a s p k 1000 σ a 260
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Vibration Table 11-2 Comparison of
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Chapter 12 Maintenance and Repair P
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Maintenance and Repair is obtained
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Maintenance and Repair Figure 12-1
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Maintenance and Repair crack, grind
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Maintenance and Repair 12.3.3 Grind
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Maintenance and Repair 1000 Stress
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Maintenance and Repair Detail Stres
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Chapter 13 Mitigating Slam Loads Th
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Mitigating Slam Loads 13.3 Weather
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Mitigating Slam Loads the sensors.
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Mitigating Slam Loads Figure 13-3 D
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Chapter 14 Emerging Technologies Al
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Emerging Technologies that have sli
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Emerging Technologies Figure 14-7 P
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Emerging Technologies Figure 14-9 S
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Emerging Technologies Table 14-1 Ty
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Emerging Technologies Beam oscillat
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Emerging Technologies The initial i
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Emerging Technologies Figure 14-20
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Emerging Technologies the geometry
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Emerging Technologies 250 m thick a
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Emerging Technologies Figure 14-26
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Emerging Technologies The three pri
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Chapter 15 Research Needs In review
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Research Needs 6. Use the data to e
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Research Needs 15.6 Fatigue Strengt
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Research Needs 15.9 Fire Protection
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Research Needs damage to indicators
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Chapter 16 Summary Aluminum is the
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Summary fatigue strength. A sealing
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Chapter 17 References ABS, Rules fo
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References Bleich, Friedrich, and L
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References Gross, M.R., Low-Cycle F
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References Martukanitz, Richard and
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References Shumaker, M.B. Method of
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SHIP STRUCTURE COMMITTEE LIAISON ME
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