【レポートの概要(一部)】
A. Executive Summary
Section 1: Understanding Nuclear Power
B. Basics of the Nuclear Industry
B.1 History of Nuclear Power
B.2 Types of Nuclear Reactors
B.2.1 Fission Reactor
B.2.2 Radioisotope Thermoelectric Generator
B.3 New & Upcoming Nuclear Technologies
B.4 Components & Parts of a Nuclear Power Plant
B.5 Analyzing the Fuel Cycle
B.6 Managing the Radioactive Waste
C. Profiling the Global Nuclear Power Industry
C.1 Industry Overview
C.2 Uranium Market
C.3 Market Features
C.4 Price Trends
C.5 Managing the Risk in Nuclear Power
C.6 Industry Trends
C.7 Economic Trends
C.8 Nuclear Hedging
C.9 Future Outlook
Section 2: Marine Applications of Nuclear Power
A. Introduction to Nuclear Marine Propulsion
A.1 Overview
A.2 History of Nuclear Power in Marine Applications
A.2.1 Military Use
A.2.2 Civilian Use
A.3 Marine-type Nuclear Reactors
A.4 Nuclear-powered Naval Vessels
B. Analysis of Naval Nuclear Applications
B.1 Overview
B.2 Nuclear-powered Aircraft Carriers
B.3 Nuclear-powered Submarines
B.4 Other Nuclear-powered Vessels
C. Benefits of Nuclear Marine Propulsion
C.1 Flexibility
C.2 High Power Density of Nuclear Power
C.3 Real-Time Response Time
C.4 End of Energy Dependency
C.5 Increasing the Capabilities of the Naval Forces
C.6 Environmentally Clean Source of Energy
D. Analysis of Naval Nuclear Reactor Development
D.1 Introduction
D.2 S1W Pressurized Water Reactor Design (STR)
D.3 Large Ship Reactors, A1W-A, A1W-B
D.4 SIR OR S1G Intermediate Flux Beryllium Sodium Cooled Reactor
D.5 Experimental Beryllium Oxide Reactor
D.6 SC-WR Super Critical Water Reactor
D.7 Organic Moderated Reactor Experiment
D.8 Lead-Bismuth Cooled Fast Reactors
D.9 Natural Circulation S5G Prototype
D.10 Fail Safe Control and Load Following S7G Design
D.11 S9G High Energy Density Core
D.12 Expended Core Facility
D.13 Ongoing R&D in Naval Reactors
E. Analysis of US Naval Reactors
E.1 Overview
E.2 Designation System for Reactors
E.3 History of Naval Reactor Industry in the US
E.4 Naval Reactors & Power Plants
E.5 Nuclear Reactors of the US Navy
E.5.1 A1B Reactor
E.5.1.1 Gerald R. Ford-Class Aircraft Carriers
E.5.2 A1W Reactor
E.5.3 A2W Reactor
E.5.3.1 USS Enterprise (CVN-65)
E.5.4 A3W Reactor
E.5.5 A4W Reactor
E.5.5.1 Nimitz-Class Aircraft Carriers
E.5.6 C1W Reactor
E.5.6.1 Long Beach Class Cruiser
E.5.6 D1G Reactor
E.5.7 D2G Reactor
E.5.7.1 Bainbridge Class Cruiser
E.5.7.2 Truxtun Class Cruiser
E.5.7.3 California Class Cruiser
E.5.7.4 Virginia Class Cruiser
E.5.8 NR-1 Reactor
E.5.9 S1C Reactor
E.5.10 S1G Reactor
E.5.11 S1W Reactor
E.5.12 S2C Reactor
E.5.12.1 USS Tullibee (SSN-597)
E.5.13 S2G Reactor
E.5.13.1 USS Seawolf (SSN-575)
E.5.14 S2W Reactor
E.5.14.1 USS Nautilus (SSN-571)
E.5.15 S2Wa Reactor
E.5.16 S3G Reactor
E.5.17 S3W Reactor
E.5.17.1 USS Skate (SSN-578)
E.5.17.2 USS Sargo (SSN-583)
E.5.17.3 USS Halibut (SSGN-587)
E.5.18 S4G Reactor
E.5.18.1 USS Triton (SSN-586)
E.5.19 S4W Reactor
E.5.19.1 USS Swordfish (SSN-579)
E.5.19.2 USS Seadragon (SSN-584)
E.5.20 S5G Reactor
E.5.21 S5W Reactor
E.5.21.1 Skipjack Class Submarine (SSN-585 class)
E.5.21.2 George Washington Class Submarine (SSBN-598 class)
E.5.21.3 Thresher/Permit Class Submarine (SSN-593/SSN-594 class)
E.5.21.4 Ethan Allen Class Submarine (SSBN-608 class)
E.5.21.5 Lafayette Class Submarine (SSBN-616 class)
E.5.21.6 James Madison Class Submarine (SSBN-627 class)
E.5.21.7 Benjamin Franklin Class Submarine (SSBN-640 class)
E.5.21.8 Sturgeon Class Submarine (SSN-637 class)
E.5.21.9 USS Parche (SSN-683)
E.5.21.10 USS Glenard P. Lipscomb (SSN-685)
E.5.22 S6G Reactor
E.5.23 S6W Reactor
E.5.24 S7G Reactor
E.5.25 S8G Reactor
E.5.26 S9G Reactor
F. Economic Viability of the Nuclear Navy for US
G. Analysis of Commercial Nuclear Ships
G.1 Overview
G.2 Reactor Designs
H. Analysis of Nuclear Navies
H.1 Overview
H.2 Navy Carrier Force
H.3 Nuclear Submarine Force
H.3.1 Russian Navy
H.3.2 Chinese Navy
H.4 Nuclear Surface Vessels
H.5 Nuclear Cruise Missile Submarines
H.6 Nuclear Ballistic Missile Submarines
H.7 Nuclear Attack Submarines
I. Emergence of the All-Electric Propulsion System & Stealth Ships
I.1 Industry Overview
I.2 Littoral Combat Ship
I.3 Anti-Submarine Warfare, ASW Continuous Trail Unmanned Vessel Program
I.4 Free Electron Lasers
I.5 Electromagnetic Rail Gun
I.6 High Powered Microwave Directed Beams
I.7 Multipurpose Floating Barges
I.8 Antisubmarine Warfare
J. Analysis of Nuclear-powered Ships
J.1 Industry Overview
J.2 Nuclear Naval Fleets
J.3 Nuclear Civil Vehicles
J.4 Nuclear Propulsion Systems
J.5 Floating Nuclear Power Plants
J.6 Future Perspective
K. Nuclear-powered Surface Ships in the US
K.1 Nuclear versus Conventional Power for Ships
K.2 US Navy Nuclear-powered Ships
K.2.1 Navy’s Nuclear Propulsion Program
K.2.2 Current Navy Nuclear-Powered Ships
K.2.3 Historical Data for Navy Nuclear-powered Cruisers
K.3 Analysis of the Initial Fuel Core
K.4 Role of the Defense Authorization Act (P.L. 110-181)
K.5 Looking at the CG(X) Cruiser Program
K.6 Analysis of the Construction Shipyards
K.6.1 Shipyards Building Nuclear-powered Ships
K.6.2 Surface Combatant Shipyards
K.7 Issues Facing the Navy
K.7.1 Cost Factor
K.7.1.1 Designing and Development Cost
K.7.1.2 Cost for Procurement
K.7.1.3 Life Cycle Cost
K.7.2 Operational Issues
K.7.2.1 Operational Value
K.7.2.2 Other Operational Advantages
K.7.3 Issues with Ship Construction
K.7.3.1 Shipyard Challenges
K.7.3.2 Lack of Component Manufacturers
K.7.4 Environmental Impact
L. Analysis of Nuclear-powered Icebreakers
L.1 Overview
L.2 Use of Nuclear-powered Icebreaker
L.3 Applications of Icebreakers
L.4 Russian Expertise in the Industry
L.5 Reactor Types
L.4 Analysis of Nuclear-powered Icebreakers
L.4.1 Lenin Nuclear Icebreaker
L.4.2 Arktika Icebreaker
L.4.3 Sevmorput
L.4.4 Taymyr Nuclear Icebreaker
L.4.5 Vaygach Nuclear Icebreaker
L.4.6 Yamal Icebreaker
L.4.7 NS 50 Let Pobedy
L.5 Planned Nuclear Icebreakers
L.6 Supporting Infrastructure
L.7 Use of Nuclear-powered Icebreakers in Tourism
L.8 Decommissioning and Defueling
L.9 Accidents with Icebreakers
L.9.1 USS Thresher, SSN-593 Accident
L.9.2 USS Scorpion, SSN-589 Accident
L.9.3 John S. Stennis, CVN-74 Loca Accident
L.9.4 San Francisco Underwater Collision
L.9.5 Nerpa, Akula Class Fire
L.9.6 USS Houston Coolant Leak
L.9.7 HMS Vanguard, Le Triomphant Collision
L.9.8 Hartford and New Orleans Accident
M. Analysis of Nuclear Submarines
M.1 Overview
M.2 History of Nuclear Submarines
M.3 Technical Features
M.4 Operational Nuclear Submarines in China
M.4.1 Type 091 (Han) Attack Submarines
M.4.2 Type 092 (Xia) Ballistic Missile Submarines
M.4.3 Type 093 (Shang) Attack Submarines
M.4.4 Type 094 (Jin) Ballistic Missile Submarines
M.5 Nuclear Submarines under Development in China
M.5.1 Type 095 Attack Submarines
M.5.2 Type 096 (Tang) Ballistic Missile Submarines
M.6 Operational Nuclear Submarines in France
M.6.1 Rubis Class Attack Submarines
M.6.2 Triomphant Class Ballistic Missile Submarines
M.7 Nuclear Submarines under Development in France
M.7.1 Barracuda Class Attack Submarines
M.8 Operational Nuclear Submarines in India
M.8.1 INS Chakra
M.9 Nuclear Submarines under Development in India
M.9.1 Arihant Class Ballistic Missile Submarines
M.10 Operational Nuclear Submarines in Russia
M.10.1 Project 941 (Typhoon) Ballistic Missile Submarines
M.10.2 Project 945 (Sierra) Attack Submarines
M.10.3 Project 949 (Oscar) Cruise Missile Submarines
M.10.4 Project 667BDR, Kalmar (Delta III) Ballistic Missile Submarines
M.10.5 Project 667BDRM, Delfin (Delta IV) Ballistic Missile Submarines
M.10.6 Project 1910 (Uniform) Special Purpose Submarines
M.10.7 Project 971 (Akula) Attack Submarines
M.10.8 Project 671RTM Shchuka (Victor III) Attack Submarines
M.11 Nuclear Submarines under development in Russia
M.11.1 Project 885 (Graney) Attack Submarines
M.11.2 Project 935 (Borei) Ballistic Missile Submarines
M.12 Operational Nuclear Submarines in the UK
M.12.1 Trafalgar Class Attack Submarines
M.12.2 Vanguard Class Ballistic Missile Submarines
M.12.3 Astute Class Attack Submarines
M.13 Operational Nuclear Submarines in the US
M.13.1 SCB-303: Los Angeles Class Attack Submarines
M.13.2 SCB-304: Ohio Class Ballistic Missile Submarines
M.13.3 Seawolf Class Attack Submarines
M.13.4 Virginia Class Attack Submarines
M.14 Argentina’s Plans for Nuclear Submarines
M.15 Brazil’s Plans for Nuclear Submarines
M.16 South Korea’s Nuclear Submarines
M.17 Nuclear Submarine Accidents
N. Analysis of Nuclear Submarines Worldwide
N.1 USS Alabama, SSBN-731
N.2 USS Alaska, SSBN-732
N.3 USS Albany, SSN-753
N.4 USS Albuquerque, SSN-706
N.5 USS Alexandria, SSN-757
N.6 HMS Ambush, S120
N.7 S605 Am?thyste, SNA (SSN)
N.8 USS Annapolis, SSN-760
N.9 INS Arihant, (ATV-1), SSBN-S02
N.10 HMS Artful, S121
N.11 USS Asheville, SSN-758
N.12 Astute-class (SSN)
N.13 HMS Astute, S119
N.14 HMS Audacious, S122
N.15 USS Augusta, SSN-710
N.16 USS Boise, SSN-764
N.17 USS Bremerton, SSN-698
N.18 USS Buffalo, SSN-715
N.19 Borei Class Submarine
N.20 Russian Submarine K-117 Bryansk
N.21 S603 Casabianca (ex-Bourgogne), SNA (SSN)
N.22 USS Charlotte, SSN-766
N.23 USS Cheyenne, SSN-773
N.24 USS Chicago, SSN-721
N.25 Churchill-class (SSN)
N.26 HMS Churchill, S46
N.27 USS City of Corpus Christi, SSN-705
N.28 USS Columbia, SSN-771
N.29 USS Columbus, SSN-762
N.30 USS Connecticut, SSN-22
N.31 HMS Conqueror, S48
N.32 HMS Courageous, S50
N.33 USS Dallas, SSN-700
N.34 RFS Dmitriy Donskoy, TK-208 (SSBN)
N.35 Delta Class Submarine
N.36 Russian submarine K-414 Daniil Moskovsky
N.37 HMS Dreadnought, S101
N.38 S604 ?meraude, SNA (SSN)
N.39 USS Florida, SSGN-728
N.40 USS Georgia, SSGN-729
N.41 USS Greeneville, SSN-772
N.42 USS Hampton, SSN-767
N.43 USS Hartford, SSN-768
N.44 USS Hawaii, SSN-776
N.45 USS Helena, SSN-725
N.46 USS Henry M. Jackson, SSBN-730
N.47 USS Honolulu, SSN-718
N.48 USS Houston, SSN-713
N.49 USS Hyman G. Rickover, SSN-709
N.50 S615 L’Inflexible, SNLE (SSBN)
N.51 USS Jacksonville, SSN-699
N.52 USS Jefferson City, SSN-759
N.53 USS Jimmy Carter, SSN-23
N.54 USS Kentucky, SSBN-737
N.55 USS Key West, SSN-722
N.56 Russian Submarine B-276 Kostroma
N.57 USS La Jolla, SSN-701
N.58 USS Los Angeles, SSN-688
N.59 USS Louisiana, SSBN-743
N.60 USS Louisville, SSN-724
N.61 USS Maine, SSBN-741
N.62 USS Maryland, SSBN-738
N.63 USS Memphis, SSN-691
N.64 USS Miami, SSN-755
N.65 USS Michigan, SSGN-727
N.66 USS Minneapolis-Saint Paul, SSN-708
N.67 USS Montpelier, SSN-765
N.68 USS Nautilus SSN-571
N.69 USS Nebraska, SSBN-739
N.70 USS Nevada, SSBN-733
N.71 USS New Hampshire, SSN-778
N.72 USS Newport News, SSN-750
N.73 USS Norfolk, SSN-714
N.74 USS North Carolina, SSN-777
N.75 Russian Submarine K-407 Novomoskovsk
N.76 Russian Submarine K-152 Nerpa
N.77 USS Ohio, SSGN-726
N.78 USS Oklahoma City, SSN-723
N.79 USS Olympia, SSN-717
N.80 Oscar Class Submarine
N.81 USS Pasadena, SSN-752
N.82 USS Pennsylvania, SSBN-735
N.83 S606 Perle, SNA (SSN)
N.84 USS Philadelphia, SSN-690
N.85 USS Pittsburgh, SSN-720
N.86 USS Portsmouth, SSN-707
N.87 USS Providence, SSN-719
N.88 Russian Submarine K-336 Pskov
N.89 Russian Submarine K-211 Petropavlovsk-Kamchatskiy
N.90 Russian Submarine BS-64 Podmoskovye
N.91 S611 Redoutable, SNLE (SSBN)
N.92 Resolution-class (SSBN)
N.93 HMS Resolution, S22
N.94 HMS Repulse, S23
N.95 HMS Renown, S26
N.96 HMS Revenge, S27
N.97 USS Rhode Island, SSBN-740
N.98 S601 Rubis (ex-Provence), SNA (SSN)
N.99 USS Salt Lake City, SSN-716
N.100 USS San Francisco, SSN-711
N.101 USS San Juan, SSN-751
N.102 USS Santa Fe, SSN-763
N.102 S601 Saphir (ex-Bretagne), SNA (SSN)
N.103 HMS Sceptre, S104
N.104 USS Scranton, SSN-756
N.105 USS Seahorse, SSN-669
N.106 USS Seawolf, SSN-21
N.107 Sierra Class Submarine
N.108 HMS Sovereign, S108
N.109 HMS Spartan, S105
N.110 HMS Splendid, S106
N.111 USS Springfield, SSN-761
N.112 HMS Superb, S109
N.113 Russian Submarine K-433 Svyatoy Georgiy Pobedonosets
N.114 Swiftsure-class (SSN)
N.115 HMS Swiftsure, S126
O. Analysis of Russia’s Nuclear-powered Naval Fleet
O.1 Military Vessel Classes and Generations
O.2 Civilian Vessel Classes and Generations
O.3 Civilian Marine Reactors in Russia
O.3.1 Overview
O.3.2 OK-150 Plant
O.3.2.1 Overview
O.3.2.2 Reactor Analysis
O.3.2.3 Fuel Analysis
O.3.2.4 Reaction Control
O.3.2.5 Pressure Vessel & Safety Radiation Shield
O.3.2.6 Cooling Circuit
O.3.2.7 Thermal Features
O.3.3 OK-900 Plant
O.3.3.1 Overview
O.3.3.2 Reactor Analysis
O.3.3.3 Fuel Analysis
O.3.3.4 Reaction Control
O.3.3.5 Safety System
O.3.4 KLT-40 Plant
O.3.4.1 Overview
O.3.4.2 Reactor Analysis
O.3.4.3 Fuel Analysis
O.3.4.4 Reaction Control
O.3.4.5 Safety System
O.3.4.6 Cooling Circuit
O.3.4.7 Radioactivity Containment System
O.3.5 Floating Nuclear Power Stations
O.3.5.1 Overview
O.3.5.2 History
O.3.5.3 Technical Features
O.3.5.4 Fueling Features
O.3.5.5 Developers of the Stations
O.3.5.6 Advantage of Location
O.3.5.7 Safety Issues
O.4 Military Marine Reactors in Russia
O.4.1 Overview
O.4.2 VM-A Reactor System
O.4.2.1 Reactor Analysis
O.4.2.2 Fuel Analysis
O.4.2.3 Reactivity Control
O.4.3 VM-4/ VM-2 Reactor Systems
O.4.3.1 Overview
O.4.3.1 Reactor Analysis
O.4.3.2 Fuel Analysis
O.4.3.3 Reactivity Control
O.4.4 OK 650/ KN-3 Reactor Systems
O.4.4.1 Overview
O.4.4.2 Reactor Analysis
O.4.4.3 Fuel Analysis
O.4.4.4 Reactivity Control
O.4.5 RM-1 and VM- 40 A Reactor Systems
O.4.5.1 Overview
O.4.4.2 Reactor Analysis
O.4.4.3 Fuel Analysis
O.4.4.4 Reactivity Control
O.5 Future of Russian Marine Nuclear Systems
O.5.1 Industry Forecast
O.5.2 Civilian Reactors
O.5.3 Military Reactors
P. Case Study: China’s Nuclear Submarine Force
Q. Case Study: India’s Nuclear Navy
Q.1 Introduction
Q.2 Maritime Nuclear Development in India
Q.3 Sino-Indian Nuclear Dynamic
R. Case Study: Safety of US Nuclear Powered Warships
R.1 Introduction
R.2 Design of Naval Reactor Plant
R.3 Operation of the Naval Reactor
R.4 Issue of Radiation Exposure
R.5 Disposal of Nuclear Waste
R.6 Environmental Impact
R.7 Preparations for Emergencies
R.8 Possible Radiation Leakage
S. Appendix
S.1 Analysis of the Shippingport Pressurized Water Reactor and Light Water Breeder Reactor
S.2 Figures & Tables
T. Glossary of Terms
【レポート販売概要】
■ タイトル:海洋産業における原子力発電:Marine Applications of Nuclear Power■ 発行日:2013年12月
■ 調査会社:Aruvian’s R’search
■ 商品コード:ARUV40131277
■ 調査対象地域:グローバル
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