Materials for Marine Systems and Structures: Treatise on Materials Science and Technology, Vol. 28, Volume 28Dennis F. Hasson, C. R. Crowe Treatise on Materials Science and Technology, Volume 28: Materials for Marine Systems and Structures provides an integrated approach, utilizing the environmental information of the ocean scientists, materials science, and structural integrity principles as they apply to offshore structures and ships. The book discusses the materials and their performance in marine systems and structures; the marine environment; and marine befouling. The text also describes marine corrosion; corrosion control; metallic materials for marine structures; and concrete marine structures. Materials for mooring systems and fracture control for marine structures are also considered. Professional scientists and engineers, as well as graduate students in the fields of ocean and marine engineering and naval architecture and associated fields will find the book useful. |
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Page 2
... fracture mechanics for subcritical crack growth in fatigue, corrosion fatigue, and stress corrosion cracking (SCC) provide a means to evaluate and design for defect tolerance. The materials selected for fabrication and the processes ...
... fracture mechanics for subcritical crack growth in fatigue, corrosion fatigue, and stress corrosion cracking (SCC) provide a means to evaluate and design for defect tolerance. The materials selected for fabrication and the processes ...
Page 10
... fracture behavior are drop weight (11) and dynamic tear tests (12). With the advent of fracture mechanics, however, more systematic approaches have been developed to account for fracture. In this regard, account is also taken of (c) and ...
... fracture behavior are drop weight (11) and dynamic tear tests (12). With the advent of fracture mechanics, however, more systematic approaches have been developed to account for fracture. In this regard, account is also taken of (c) and ...
Page 11
... fracture. In this case, the extent of the plastic zone at the crack tip is larger with respect to the crack length ... mechanics, which applies a correction for plastic deformation at the crack tip and uses the crack tip opening at the point ...
... fracture. In this case, the extent of the plastic zone at the crack tip is larger with respect to the crack length ... mechanics, which applies a correction for plastic deformation at the crack tip and uses the crack tip opening at the point ...
Page 12
... fracture mechanics, has been developed. The procedure is illustrated in Figure 8. The crack growth rate per loading cycle, da/dn, is measured as a function of applied stress intensity, AK, i.e., da/dn = f(AK), as schematically ...
... fracture mechanics, has been developed. The procedure is illustrated in Figure 8. The crack growth rate per loading cycle, da/dn, is measured as a function of applied stress intensity, AK, i.e., da/dn = f(AK), as schematically ...
Page 13
... CRACK SIZE S \ \ **** - * (As Va.) >< DESIGN * STRESS" =ls: * SAFE | ZONE A. SIGNIFICANT CRACK SIZE Fig. 8. Schematic showing the use of fracture mechanics in the design of structures for fatigue. IV. Materials Selection The selection ...
... CRACK SIZE S \ \ **** - * (As Va.) >< DESIGN * STRESS" =ls: * SAFE | ZONE A. SIGNIFICANT CRACK SIZE Fig. 8. Schematic showing the use of fracture mechanics in the design of structures for fatigue. IV. Materials Selection The selection ...
Contents
1 | |
35 | |
Chapter 3 Marine Biofouling | 89 |
Chapter 4 Marine Corrosion | 121 |
Chapter 5 Corrosion Control | 245 |
Chapter 6 Metallic Materials for Marine Structures | 277 |
Chapter 7 Concrete Marine Structures | 351 |
Chapter 8 Materials for Mooring Systems | 389 |
Chapter 9 Fracture Control for Marine Structures | 415 |
INDEX | 461 |
CONTENTS OF PREVIOUS VOLUMES | 471 |
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addition AISI aluminum alloys anode applications atmosphere attack Austenitic behavior bronze carbon cast iron cathodic protection cause chloride coatings composition concentration concrete construction containing copper corrosion rates corrosion resistance coupled crevice corrosion decrease deep depth developed effect elements Engineering environment example exposure factors failure fatigue Figure force fouling fracture galvanic heat important increased indicated initiation inspection joint less limited loading low alloy steels marine marine structures materials measured mechanical metal methods nickel North occur ocean offshore operation organisms oxygen performance pitting platforms practice prevent problem produce properties reduce Report resistance ropes salinity seawater selection ships showed shown solution specimens stainless steels strength Stress Corrosion Cracking structure studies surface TABLE temperature tests titanium treatment Type usually wave weight weld zone