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Emerging Carbon Fiber Applications

Trends and opportunities in this market to 2016 by various segment and region (North America, Europe, Asia Pacific, Rest of the World)

Publisher:        Lucintel

# of Pages:        150+

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1 User License $4,850

Publication Date:  October, 2011

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  1. Executive Summary  

 2. Carbon Fiber Snapshot  
 2.1. Overview  
 2.2. Carbon Fiber Value Chain  
 2.3. Carbon Fiber Market Characteristics  
 2.4. Carbon Fiber: Types  
 2.4.1. Continuous Fiber  
 2.4.2. Chopped Fiber  
 2.4.3. Milled Fiber  
 2.4.4. Metal Coated Fiber  
 2.5. Evolution of Carbon Fiber Applications  
 2.6. Key Success Factors for Rapid Carbon Fiber Adoption  
 2.7. Carbon Fiber Recycling  
 2.7.1. Recycled Carbon Fiber from Manufacturing and Cured Component  
 2.7.2. Recycled Carbon Fiber from End of Life Structures  
 2.7.3. Associations Related to Recycled Carbon Fiber from End of Life Structures  
 2.7.4. Recycled Carbon Fiber Markets  

 3. Emerging Carbon Fiber Applications  
 3.1. Overview  
 3.2. Methodology  
 3.3. Nuclear Centrifuge Rotor Tubes  
 3.3.1. Overview  
 3.3.2. Working of Nuclear Centrifuge Rotors  
 3.3.3. Evolution of Carbon Fiber Applications in Nuclear Centrifuges  
 3.3.4. Problems with Maraging Steel/Alloy Rotors  
 3.3.5. CFRP Centrifuge Rotor  
 3.3.6. Technology Roadmap  
 3.3.7. Growth Drivers for the use of CFRP in Nuclear Centrifuge Rotors  
 3.3.8. Challenges: Carbon Fiber in Nuclear Centrifuge Market  
 3.3.9. Opportunity Analysis in Nuclear Centrifuge Rotor Tubes  
 3.3.10. Hexcel, ATK and USEC Tripartite Supply Agreement  
 3.3.11. Key Success Factors  
 3.4. Consumer Electronics  
 3.4.1. Overview  
 3.4.2. Laptops  
 3.4.3. Apple Inc's Plan to Use Carbon Fiber in Laptops  
 3.4.4. Growth Drivers in Laptop Industry  
 3.4.5. Challenges in Laptop Industry  
 3.4.6. Market Potential Analysis in Laptop  
 3.4.7. Mobile Phones  
 3.4.8. Carbon Fiber Mobile Phone Case  
 3.4.9. Growth Drivers in Mobile Phone Industry  
 3.4.10. Challenges in Mobile Phone Industry  
 3.4.11. Potential Analysis in Mobile Phone Industry  
 3.5. Offshore Oil and Gas Applications  
 3.5.1. Industry Overview and Characteristics  
 3.5.2. Oil Drilling Technologies  
 3.5.3. Desired Material Properties for Offshore Oil and Gas Applications  
 3.5.4. CFRP Application Details  
 3.5.5. Drilling Riser with CFRP Choke and Kill Lines Benefits  
 3.5.6. TLP Tethers  
 3.5.7. Subsea Umbilicals  
 3.5.8. Major Contracts for Carbon Fiber Umbilicals  
 3.5.9. CFRP Advantages in Offshore Oil Industry  
 3.5.10. Technology Roadmap  
 3.5.11. Growth Drivers in Oil and Gas Industry  
 3.5.12. Challenges in Oil and Gas Industry  
 3.5.13. Opportunities in Oil and Gas Industry  
 3.5.14. Key Success Factors  
 3.6. Wind Energy  
 3.6.1. Overview  
 3.6.2. CFRP Application Details  
 3.6.3. Technology Roadmap  
 3.6.4. Growth Drivers in Wind Energy Markets  
 3.6.5. Challenges in Wind Energy Markets  
 3.6.6. Opportunity Analysis in Wind Energy Markets  
 3.6.7. Carbon Fiber Benefits in Wind Turbine Industry  
 3.6.8. Wind Turbine Blade Manufacturing Processes Comparison  
 3.6.9. Key Success Factors  
 3.7. High Pressure Tanks  
 3.7.1. Overview  
 3.7.2. Classification of Gas Storage Tanks  
 3.7.3. Characteristics of CFRP Gas Storage Tanks Market  
 3.7.4. Key Material Requirements  
 3.7.5. Technology Roadmap  
 3.7.6. Growth Drivers in Gas Storage Tanks  
 3.7.7. Challenges in Gas Storage Tanks  
 3.7.8. CFRP Overwrap in Type III CNG Cylinders  
 3.7.9. Opportunity Analysis in Gas Storage Tanks  
 3.7.10. Hydrogen Gas Storage  
 3.7.11. Key Success Factors  
 3.8. Automotive and Transportation  
 3.8.1. Overview  
 3.8.2. CFRP Application Details  
 3.8.3. Technology Roadmap  
 3.8.4. Growth Drivers in Automobile Industry  
 3.8.5. Challenges in Automobile Industry  
 3.8.6. Carbon Fiber Potential and Opportunity Analysis in Automobile Industry  
 3.8.7. Emerging Applications in Automobile Industry  
 3.8.8. CFRP Advantages in Automotive Industry  
 3.8.9. CFRP Recycling  
 3.8.10. Key Success Factors  
 3.9. Bridge Rehabilitation and Construction  
 3.9.1. Overview  
 3.9.2. Carbon Fiber Product Types Used in Construction Industry  
 3.9.3. Technology Roadmap  
 3.9.4. Growth Drivers in Bridge Rehabilitation  
 3.9.5. Challenges in Construction Industry  
 3.9.6. Opportunity Analysis in Construction Industry  
 3.9.7. Bridges  
 3.9.8. CFRP Bridge Advantages  
 3.9.9. Carbon Fiber Reinforced Concrete (CFRC)  
 3.9.10. Key Success Factors  
 3.1. Fuel Cell Applications  
 3.10.1. Overview  
 3.10.2. Fuel Cell Operation  
 3.10.3. Evolution and Research: Carbon Fiber in Fuel Cells  
 3.10.4. Commercialized Technologies: Carbon Fiber in Fuel Cells  
 3.10.5. Carbon Fiber Bipolar Plates  
 3.10.6. Gas Diffusion Layer (GDL)  
 3.10.7. Fuel Cell Cost Breakdown  
 3.10.8. Carbon Fiber Benefits in Fuel Cell  
 3.10.9. Technology Roadmap in Fuel Cell Markets  
 3.10.10. Growth Drivers in Fuel Cell Markets  
 3.10.11. Challenges in Fuel Cell Markets  
 3.10.12. Key Success factors  

 4. Medical and Biomedical Applications  
 4.1. Overview  
 4.1.1. Tabletops  
 4.1.2. Oncology Therapy  
 4.2. Surgical Tables  
 4.3. Human Organ Transportation Devices  
 4.4. Cranioplasty  
 4.5. Socket for an Artificial Limb  
 4.5.1. Overview  
 4.5.2. Socket Manufacturing Process  
 4.5.3. Advantages and Disadvantages  
 4.6. Endolign  

 5. Emerging Applications in Commercial Aerospace  
 5.1. Industry Overview and Characteristics  
 5.1.1. Cyclical in Nature  
 5.1.2. Backlog Driven Market  
 5.1.3. Secular Trend towards Composites  
 5.2. CFRP Application Details  
 5.3. Technology Roadmap in Commercial Aerospace Industry  
 5.4. Carbon Fiber Supply Chain for Commercial Aerospace  
 5.5. CFRP Advantages  
 5.5.1. Aircraft Cost of Ownership  
 5.5.2. Fuel Savings  
 5.5.3. Aircraft Maintenance Reduction  
 5.5.4. Impact of Corrosion in Aircraft  
 5.6. Growth Drivers in Commercial Aerospace Industry  
 5.7. Challenges in Commercial Aerospace Industry  
 5.8. Opportunities in Commercial Aerospace Industry  
 5.8.1. Existing Aircraft  
 5.9. Emerging Applications  
 5.9.1. Carbon Fiber in Volvo Engines  
 5.9.2. Airbus A350 XWB Fuselage  
 5.1. Key Success Factors  

 6. Recent and Future Applications  
 6.1. Overview  
 6.2. Carbon Fiber Debit/Credit Cards  
 6.3. Carbon Fiber Biometric Scanner Door  
 6.4. Carbon Fiber LCD TV  
 6.5. Carbon Fiber in Video Displays (MEMS)  
 6.6. GPS Telescopes  
 6.7. Baggage Scanning Tunnels  
 6.8. Carbon Fiber Guitars  
 6.8.1. Overview  
 6.8.2. Manufacturing Process  
 6.8.3. Advantages  
 6.9. Carbon Audio Video Racks  
 6.9.1. Overview  
 6.9.2. CFRP Benefits  
 6.1. Bikes  
 6.11. Carbon Fiber Tripods  
 6.12. Carbon Fiber Gun Grip  
 6.13. Carbon Fiber Shin Guard  
 6.14. Carbon Fiber Monowheel Exercise Bike  
 6.15. Carbon Fiber Tables  
 6.16. Carbon Fiber Trophies  
 6.17. Mercedes F-CELL  
 6.18. Ferrari Hybrid Car  
 6.19. Carbon Fiber Tires  
 6.2. Carbon Fiber Pedal for Rockband  
 6.21. Carbon Fiber Watches  
 6.22. Carbon Fiber Fins  
 6.23. Carbon Fiber Computer Case  
 6.24. Carbon Fiber Tramontana R, 720hp V12 Monster  
 6.25. New Carbon Fiber Snowboard Concept  
 6.26. Carbon Fiber Key Chain  
 6.27. Carbon Fiber Ring  
 6.28. Carbon Fiber Mouse and Mouse pad  
 6.29. Carbon Fiber Electric Razor  
 6.3. Carbon Fiber Xbox Controllers  
 6.31. Carbon Fiber Staircase  
 6.32. Carbon Fiber in Shoes  
 6.33. Carbon Fiber Helmets  
 6.34. Carbon Fiber Toilet Bowl  
 6.35. Carbon Fiber Tissue Box  
 6.36. Carbon Fiber Car Wheel  
 6.37. 2011 Kawasaki Ninja 1000 R-77 Slip-on systems  
 6.38. SMX-2 Air Carbon Gloves  
 6.39. Carbon fiber mirror holder  
 6.4. Ashby West Road Bridge  
 6.41. Carbon fiber athletic footwear  
 6.42. Carbon Fiber Prius X Parlee Bicycle  
 6.43. Carbon Fiber Canoe  

List of Figures  
 List of Tables  
 Abbreviations and technical units  
 Disclaimer  
 Copyright  
 About Us  

List of Figures
 
Chapter 1
Figure 1.1: Carbon fiber demand forecast for emerging applications in $ million shipments
Figure 1.2: Application production volume to per unit consumption
Figure 1.3: Life cycle placement of various applications in carbon fiber
 
Chapter 2
Figure 2.1: Carbon fiber value chain
Figure 2.2: Carbon fiber supply agreements
Figure 2.3: Different types of carbon fiber forms
Figure 2.4: Typical continuous carbon fiber
Figure 2.5: Typical chopped carbon fiber
Figure 2.6: Typical metal (nickel)-coated carbon fiber
Figure 2.7: Growth volume matrix for carbon fiber
Figure 2.8: Key success factors for carbon fiber adoption
Figure 2.9: Recycling process from manufacturing and cured component waste
Figure 2.10: Recycling process flow for end-of-life waste
 
Chapter 3
Figure 3.1: Nuclear fuel cycle
Figure 3.2: Working of nuclear centrifuge
Figure 3.3: Iraqi centrifuge components, destroyed by inspectors in the early 1990s
Figure 3.4: Comparison of rotor speed of various materials such as AL, MS, CFRP
Figure 3.5: Comparison of maximum length of rotor made using various materials such as AL, MS, CFRP
Figure 3.6: Comparison of uranium productivity by rotor made using various materials such as AL, MS, CFRP
Figure 3.7: Difference between various rotor materials
Figure 3.9: Technology roadmap for rotor tube materials
Figure 3.10: Technology roadmap for rotor tube speed
Figure 3.11: Technology roadmap for rotor tube uranium separation efficiency
Figure 3.12: Technology roadmap for rotor tube length
Figure 3.13: Penetration of centrifuge method in uranium separation
Figure 3.14: Leaders’ share in nuclear energy separative works unit market
Figure 3.15: Business units of Atomenergoprom with separate carbon fiber engineering division
Figure 3.16: Carbon fiber material flow diagram in Hexcel USEC agreement
Figure 3.17: Key success factors for carbon fiber in nuclear centrifuge market
Figure 3.18: Acer Ferrari 1000 carbon fiber laptop
Figure 3.19: Acer Ferrari 1100 carbon fiber laptop
Figure 3.20: Acer Ferrari 5000 carbon fiber laptop
Figure 3.21: Sony Viao TX carbon fiber body laptop
Figure 3.22: Apple’s patented carbon fiber scrim layer for MacBook
Figure 3.23: Apple MacBook weight distribution by component
Figure 3.24: Forecast (2011–2016) in mobile PCs shipment in million units
Figure 3.25: Carbon fiber potential in global laptop market
Figure 3.26: LG Black Label series carbon fiber mobile phone
Figure 3.27: LG Black Label series carbon fiber finished mobile phone
Figure 3.28: Nokia 8800 carbon arte phone
Figure 3.29: Carbon fiber case for iPhone
Figure 3.30: Global mobile phone shipments in million units
Figure 3.31: Regional distribution of mobile phones
Figure 3.32: Carbon fiber potential at different scenarios
Figure 3.33: ATP/NIST funded projects for CFRP risers and choke and kill lines
Figure 3.34: Most common floating production units
Figure 3.35: A typical tension leg platform
Figure 3.36: Different SPAR platform types
Figure 3.37: Different types of risers used in platforms
Figure 3.38: Application of production risers used in TLPs
Figure 3.39: Detailed view of riser
Figure 3.40: Production riser manufacturing process
Figure 3.41: Application of carbon fiber in choke and kill lines
Figure 3.42: Carbon fiber applications in tethers
Figure 3.43: Carbon fiber pultruded rods in tethers
Figure 3.44: Vello Nordic carbon fiber pultruded rods
Figure 3.45: Key technological developments of CFRP products in oil and gas industry
Figure 3.46: Shift in production riser material
Figure 3.47: Increase in average well depth in feet
Figure 3.48: Upcoming oilfields of more than 7,000 feet in depth
Figure 3.49: Growth in ultra-deepwater rigs
Figure 3.50: Oil production forecasts from deepwater rigs
Figure 3.51: Key success factors for carbon fiber in oil and gas industry
Figure 3.52: Integrated approach for offshore oil and gas product developments
Figure 3.53: Trend (2005-2010) in wind energy market in capacity (MW) installation
Figure 3.54: Different designs used to manufacture wind turbine blades
Figure 3.55: Cross-section view of wind turbine blades
Figure 3.56: Materials use in wind turbine
Figure 3.57: Carbon glass hybrid structure
Figure 3.58: Technology roadmap for types of wind turbine installations
Figure 3.59: Technology roadmap for materials used in wind turbine blades
Figure 3.60: Technology roadmap for increase in average turbine capacity with time
Figure 3.61: Global annual wind energy capacity (MW) installation forecast (2011–2016)
Figure 3.62: Penetration of 2.5 MW turbines in wind energy industry
Figure 3.63: Offshore floating wind turbine
Figure 3.64: Past, present, and future of wind turbine capacities
Figure 3.65: Carbon fiber applications in large size wind turbines
Figure 3.66: Multibrid M5000 production targets
Figure 3.67: Key success factors for carbon fiber in wind industry
Figure 3.68: Different kinds of tanks
Figure 3.69: Breakdown by cylinder type
Figure 3.70: Technology roadmap for cylinder wrapping
Figure 3.71: Technology for CFRP tanks
Figure 3.72: Trend (2005–2010) in CNG vehicles shipment in terms of units
Figure 3.73: Regional distribution of CNG vehicles in 2010 in terms of units
Figure 3.74: Regional trend (2005-2010) of CNG vehicles
Figure 3.75: Details of a hydrogen tank
Figure 3.76: Material weight breakdown of 70 MPa CFRP hydrogen tank
Figure 3.77: Material cost breakdown of 70 MPa CFRP hydrogen tank
Figure 3.78: Material weight breakdown of CFRP hydrogen tank
Figure 3.79: Material weight breakdown of 5,000 psi CFRP hydrogen tank
Figure 3.80: Material weight breakdown of 10,000 psi CFRP hydrogen tank
Figure 3.81: Key success factors for carbon fiber in gas storage tanks
Figure 3.82: Typical hood body weight comparison
Figure 3.83: CFRP shaft weight comparison
Figure 3.84: CFRP penetration in automotive industry
Figure 3.85: Material development in automotive industry
Figure 3.86: CFRP component production time in automotive industry
Figure 3.87: CFRP component weight comparison
Figure 3.88: Carbon fiber potential at different penetration levels
Figure 3.89: Structural weight of buses using CFRP and steel body
Figure 3.90: Carbon fiber interiors in BMW M6
Figure 3.91: Carbon fiber interiors in Mercedes SL65 AMG
Figure 3.92: Carbon fiber interiors in Chrysler 200C concept
Figure 3.93: Graph showing end-of-life vehicle targets
Figure 3.94: Toray’s CFRP recycling flow diagram
Figure 3.95: Key success factors for carbon fiber applications in automotive sector
Figure 3.96: Car component production time comparison – Toray’s method vs. conventional RTM
Figure 3.97: Flow diagram for CFCC preparation
Figure 3.98: Different kinds of CFCC
Figure 3.99: Smooth leadline rods
Figure 3.100: Spiral leadline rods
Figure 3.101: Intended concentric spiral leadline rods
Figure 3.102: Application flow diagram for carbon fiber tow sheet
Figure 3.103: Technology roadmap for CFRP applications
Figure 3.104: Status of US bridges
Figure 3.105: Carbon fiber potential scenarios in bridge rehabilitation
Figure 3.106: CFRP placement in bridge decks
Figure 3.107: Carbon fiber in bridge repair
Figure 3.108: XXsys Technologies corrosion retrofit process
Figure 3.109: Comparison between conventional concrete and carbon fiber reinforced concrete
Figure 3.110: Key success factors for carbon fiber in construction markets
Figure 3.111: Fuel cell stack
Figure 3.112: Carbon Fiber Cloth in GDL
Figure 3.113: SGL’s GDL and Bipolar Plates
Figure 3.114: CeTech’s N Series Carbon Paper
Figure 3.115: Bipolar plate for fuel cell
Figure 3.116: Gas diffusion layer
Figure 3.117: Neoplan’s fuel cell bus
Figure 3.118: Fuel cell cost distribution
Figure 3.119: Technology roadmap for fuel cell commercialization
Figure 3.120: Technology roadmap for use of carbon fiber in fuel cell
Figure 3.121: Trend in fuel cell megawatts shipped globally, 2008-2010
Figure 3.122: Fuel cell shipments by region
Figure 3.123: Expected launch year of fuel cell vehicle
Figure 3.124: Fuel cell shipment projections in transportation
Figure 3.125: Vehicle cost comparison with different power sources
Figure 3.126: Key success factors for carbon fiber in fuel cell markets
 
Chapter 4
Figure 4.1: Tabletops for various applications
Figure 4.2: X-ray transparency comparison – CFRP vs. traditional materials
Figure 4.3: CFRP applications in oncology
Figure 4.4: CFRP surgical table
Figure 4.5: A typical artificial limb: an above-the-knee prosthesis
Figure 4.6: CFRP artificial limbs
Figure 4.7: CFRP socket manufacturing process
Figure 4.8: Oscar Pistorius uses carbon fiber prosthetics in place of the lower legs
Figure 4.9: Endolite translaminar pins, intermedullary nails/screws
 
Chapter 5
Figure 5.1: Boeing and Airbus commercial aircraft delivery trend and forecast
Figure 5.2: Boeing and Airbus backlogs
Figure 5.3: Boeing and Airbus aircraft composites content by structural weight
Figure 5.4: Shift in Boeing aircraft composites content by structural weight
Figure 5.5: Shift in Airbus aircraft composites content by structural weight
Figure 5.6: CFRP applications in Airbus aircraft
Figure 5.7: Major CFRP applications in commercial aircraft
Figure 5.8: Technology roadmap for composites content in commercial aircraft
Figure 5.9: Technology roadmap for material development in commercial aircraft
Figure 5.10: Carbon fiber supply chain for commercial aerospace
Figure 5.11: Aircraft cost of ownership
Figure 5.12: Lifetime fuel savings by aircraft type
Figure 5.13: Corrosion-prone areas in an aircraft
Figure 5.14: Lower lobe frame shear-tie drainage
Figure 5.15: Lower lobe stringer drainage and sealing
Figure 5.16: CFRP benefits in aircraft
Figure 5.17: Fuel consumption rate by aircraft type
Figure 5.18: CFRP consumption trends in aircraft
Figure 5.19: Current opportunities in commercial aerospace industry
Figure 5.20: Boeing aircraft backlogs
Figure 5.21: Airbus aircraft backlogs
Figure 5.22: Airbus A350 XWB delivery forecasts
Figure 5.23: Airbus A350 XWB aircraft fuselage sections
Figure 5.24: Schematic diagram of Airbus A350 XWB fuselage
Figure 5.25: Airbus A350 XWB rear fuselage barrel
Figure 5.26: Key success factors for carbon fiber in aircraft structures
 
Chapter 6
Figure 6.1: Carbon fiber credit card
Figure 6.2: Carbon fiber scanning biometric door
Figure 6.3: Carbon fiber LCD television
Figure 6.4: GPS optical tube assembly
Figure 6.5: Carbon fiber optical tube
Figure 6.6: CFRP tunnel in baggage scanner
Figure 6.7: Front view of XOX audio tools guitar
Figure 6.8: Side view of XOX audio tools guitar
Figure 6.9: Gus G1 silver carbon fiber guitar
Figure 6.10: Carbon fiber audio video racks
Figure 6.11: B-120 Wraith bike
Figure 6.12: Honda CB 750 Motorcycle
Figure 6.13: Carbon fiber tripod
Figure 6.14: Carbon fiber in gun grip
Figure 6.15: Carbon fiber shin guard
Figure 6.16: Carbon fiber in exercise bike
Figure 6.17: Carbon fiber in tables
Figure 6.18: Carbon fiber trophies
Figure 6.19: Mercedes F-cell
Figure 6.20: Carbon fiber in Goodyear tire
Figure 6.21: Carbon fiber Rock Band pedal
Figure 6.22: Carbon fiber wrist watch
Figure 6.23: Carbon fiber fins
Figure 6.24: Carbon fiber computer case
Figure 6.25: V12 monster
Figure 6.26: Carbon fiber snowboard
Figure 6.27: Carbon fiber key chain
Figure 6.28: Carbon fiber ring
Figure 6.29: Carbon fiber in mouse pad
Figure 6.30: Carbon fiber electric razor
Figure 6.31: Carbon fiber in Xbox game controllers
Figure 6.32: Carbon fiber staircase
Figure 6.33: Carbon fiber in Puma shoes
Figure 6.34: Carbon fiber helmet
Figure 6.35: Carbon fiber toilet bowl
Figure 6.36: Carbon fiber tissue box
Figure 6.37: Carbon fiber car wheel
Figure 6.38: 2011 Kawasaki Ninja 1000 R-77 Slip-on systems made using carbon fiber
Figure 6.39: Alpinestars SMX-2 air carbon glove
Figure 6.40: Lumma Design carbon fiber side mirror for BMW 7 series
Figure 6.41: Construction of Ashby West Road Bridge
Figure 6.42: Carbon fiber athletic footwear
Figure 6.43: Carbon fiber Prius X Parlee Bicycle
Figure 6.44: Carbon fiber canoe
 
 
List of Tables
 
Chapter 1
Table 1.1: Summary of emerging applications
 
Chapter 2
Table 2.1: Carbon fiber applications timeline
 
Chapter 
Table 3.1: CFRP production riser specifications
Table 3.2: Drilling riser with choke and kill lines specifications and performance comparison
 

Reinforcement Materials Market by Material Type (Glass Fiber, Carbon Fiber, Aramid Fiber, Natural Fiber, and Steel Rebar), and End-User (Construction,...

Publisher:        Allied Market Research

# of Pages:        174

Rating: 

1 User License $5,769

Publication Date:  May, 2020

Price:       $5,769 / User License




CHAPTER 1:INTRODUCTION

1.1.Report description
1.2.Key benefits for stakeholders
1.3.Key market segments
1.4.Research methodology

1.4.1.Secondary research
1.4.2.Primary research

1.5.Analyst tools and models

CHAPTER 2:EXECUTIVE SUMMARY

2.1.Key findings of the study
2.2.CXO perspective

CHAPTER 3:MARKET OVERVIEW

3.1.Market definition and scope
3.2.Key findings

3.2.1.Top investment pockets

3.3.Porter’s five forces analysis
3.4.Market dynamics

3.4.1.Drivers

3.4.1.1.Growing Construction Activities Globally
3.4.1.2.Emerging End-Use Applications of Fiber Composites
3.4.1.3.Advantages Associated with GRFM

3.4.2.Restraint

3.4.2.1.Expensive and Complex Carbon Fiber Manufacturing Process

3.4.3.Opportunity

3.4.3.1.Increasing Adoption of Reinforced Materials from Automotive Industry

3.5.Parent peer market overview
3.6.Patent analysis, 2015–2018

3.6.1.Patent analysis by country
3.6.2.Patent analysis by applicant, 2015–2018
3.6.3.Patent analysis by inventors, 2015–2018

3.7.Impact of government rules and regulations
3.8.Impact of corona (COVID 19) outbreak on the global reinforcement materials market
3.9.Pricing analysis

CHAPTER 4:REINFORCEMENT MATERIALS MARKET, BY MATERIAL TYPE

4.1.Overview

4.1.1.Market size and forecast

4.2.Glass Fiber

4.2.1.Key market trends, growth factors, and opportunities
4.2.2.Market size and forecast, by region
4.2.3.Market share analysis, by country
4.2.4.Market size and forecast, by glass fiber type
1.2.4. Rovings
1.2.5. Woven Roving
1.2.6. Fabrics
1.2.7. CSM/CFM
1.2.8.Chopped Strand
1.2.9.Others

4.3.Carbon Fiber

4.3.1.Key market trends, growth factors, and opportunities
4.3.2.Market size and forecast, by region
4.3.3.Market share analysis, by country
4.3.4.Market size and forecast, by carbon fiber type
4.3.5.By Precursor

4.3.5.1.Polyacrylonitrile (PAN)
4.3.5.2.Pitch, Rayon & Others
4.3.6.By Fiber Type

4.3.6.1.Woven Fabric
4.3.6.2.Thermoset UD Prepreg
4.3.6.3.Thermoset Fabric Prepreg
4.3.6.4.Thermoplastic Prepreg
4.3.6.5.Raw Fiber
4.3.6.6.Molding Compounds

4.4.Aramid Fiber

4.4.1.Key market trends, growth factors, and opportunities
4.4.2.Market size and forecast, by region
4.4.3.Market share analysis, by country
4.4.4.Market size and forecast, by aramid fiber type
4.4.5.Para-Aramid Fiber
4.4.6.Meta-Aramid Fiber & Others

4.5.Natural Fiber

4.5.1.Key market trends, growth factors, and opportunities
4.5.2.Market size and forecast, by region
4.5.3.Market share analysis, by country
4.5.4.Market size and forecast, by natural fiber type
4.5.5.Hemp
4.5.6.Flax
4.5.7.Kenaf
4.5.8.Jute
4.5.9.Others

4.6.Steel Rebar

4.6.1.Key market trends, growth factors, and opportunities
4.6.2.Market size and forecast, by region
4.6.3.Market share analysis, by country

CHAPTER 5:REINFORCEMENT MATERIALS MARKET, BY END-USER

5.1.Overview

5.1.1.Market size and forecast

5.2.Construction

5.2.1.Key market trends, growth factors, and opportunities
5.2.2.Market size and forecast, by region
5.2.3.Market share analysis, by country

5.3.Aerospace & Defense

5.3.1.Key market trends, growth factors, and opportunities
5.3.2.Market size and forecast, by region
5.3.3.Market share analysis, by country

5.4.Transportation

5.4.1.Key market trends, growth factors, and opportunities
5.4.2.Market size and forecast, by region
5.4.3.Market share analysis, by country

5.5.Wind Energy

5.5.1.Key market trends, growth factors, and opportunities
5.5.2.Market size and forecast, by region
5.5.3.Market share analysis, by country

5.6.Consumer Goods

5.6.1.Key market trends, growth factors, and opportunities
5.6.2.Market size and forecast, by region
5.6.3.Market share analysis, by country

5.7.Industrial

5.7.1.Key market trends, growth factors, and opportunities
5.7.2.Market size and forecast, by region
5.7.3.Market share analysis, by country

5.8.Others

5.8.1.Key market trends, growth factors, and opportunities
5.8.2.Market size and forecast, by region
5.8.3.Market share analysis, by country

CHAPTER 6:REINFORCEMENT MATERIALS MARKET, BY REGION

6.1.Overview

6.1.1.Market size and forecast, by region

6.2.North America

6.2.1.Key market trends, growth factors, and opportunities
6.2.2.Market size and forecast, by material type
6.2.3.Market size and forecast, by end-user
6.2.4.Market size and forecast by country
6.2.5.U.S.

6.2.5.1.Market size and forecast, by material type
6.2.5.2.Market size and forecast, by end-user

6.2.6.Canada

6.2.6.1.Market size and forecast, by material type
6.2.6.2.Market size and forecast, by end-user

6.2.7.Mexico

6.2.7.1.Market size and forecast, by material type
6.2.7.2.Market size and forecast, by end-user

6.3.Europe

6.3.1.Key market trends, growth factors, and opportunities
6.3.2.Market size and forecast, by material type
6.3.3.Market size and forecast, by end-user
6.3.4.Market size and forecast by country
6.3.5.Germany

6.3.5.1.Market size and forecast, by material type
6.3.5.2.Market size and forecast, by end-user

6.3.6.UK

6.3.6.1.Market size and forecast, by material type
6.3.6.2.Market size and forecast, by end-user

6.3.7.France

6.3.7.1.Market size and forecast, by material type
6.3.7.2.Market size and forecast, by end-user

6.3.8.Italy

6.3.8.1.Market size and forecast, by material type
6.3.8.2.Market size and forecast, by end-user

6.3.9.Spain

6.3.9.1.Market size and forecast, by material type
6.3.9.2.Market size and forecast, by end-user

6.3.10.Rest of Europe

6.3.10.1.Market size and forecast, by material type
6.3.10.2.Market size and forecast, by end-user

6.4.Asia-Pacific

6.4.1.Key market trends, growth factors, and opportunities
6.4.2.Market size and forecast, by material type
6.4.3.Market size and forecast, by end-user
6.4.4.Market size and forecast by country
6.4.5.China

6.4.5.1.Market size and forecast, by material type
6.4.5.2.Market size and forecast, by end-user

6.4.6.Japan

6.4.6.1.Market size and forecast, by material type
6.4.6.2.Market size and forecast, by end-user

6.4.7.India

6.4.7.1.Market size and forecast, by material type
6.4.7.2.Market size and forecast, by end-user

6.4.8.South Korea

6.4.8.1.Market size and forecast, by material type
6.4.8.2.Market size and forecast, by end-user

6.4.9.Australia

6.4.9.1.Market size and forecast, by material type
6.4.9.2.Market size and forecast, by end-user

6.4.10.Rest of Asia-Pacific

6.4.10.1.Market size and forecast, by material type
6.4.10.2.Market size and forecast, by end-user

6.5.LAMEA

6.5.1.Key market trends, growth factors, and opportunities
6.5.2.Market size and forecast, by material type
6.5.3.Market size and forecast, by end-user
6.5.4.Market size and forecast by country
6.5.5.Brazil

6.5.5.1.Market size and forecast, by material type
6.5.5.2.Market size and forecast, by end-user

6.5.6.Saudi Arabia

6.5.6.1.Market size and forecast, by material type
6.5.6.2.Market size and forecast, by end-user

6.5.7.South Africa

6.5.7.1.Market size and forecast, by material type
6.5.7.2.Market size and forecast, by end-user

6.5.8.Rest of LAMEA

6.5.8.1.Market size and forecast, by material type
6.5.8.2.Market size and forecast, by end-user

CHAPTER 7:COMPETITIVE LANDSCAPE

7.1.INTRODUCTION

7.1.1.MARKET PLAYER POSITIONING, 2018

7.2.TOP WINNING STRATEGIES

7.2.1.Top winning strategies, by year
7.2.2.Top winning strategies, by development
7.2.3.Top winning strategies, by company

7.3.PRODUCT MAPPING OF TOP 10 PLAYER
7.4.COMPETITIVE DASHBOARD
7.5.COMPETITIVE HEATMAP
7.6.KEY DEVELOPMENTS

7.6.1.New product launches
7.6.2.Expansions
7.6.3.Acquisition
7.6.4.Collaboration
7.6.5.Agreement

CHAPTER 8:COMPANY PROFILES:

8.1.BASF SE

8.1.1.Company overview
8.1.2.Company snapshot
8.1.3.Operating business segments
8.1.4.Product portfolio
8.1.5.Business performance
8.1.6.Key strategic moves and developments

8.2.Bast Fibers LLC

8.2.1.Company overview
8.2.2.Company snapshot
8.2.3.Product portfolio

8.3.Binani Industries

8.3.1.Company overview
8.3.2.Company snapshot
8.3.3.Operating business segments
8.3.4.Product portfolio
8.3.5.Business performance

8.4.DuPont

8.4.1.Company overview
8.4.2.Company snapshot
8.4.3.Operating business segments
8.4.4.Product portfolio
8.4.5.Business performance

8.5.Honeywell International Inc.

8.5.1.Company overview
8.5.2.Company snapshot
8.5.3.Operating business segments
8.5.4.Product portfolio
8.5.5.Business performance
8.5.6.Key strategic moves and developments

8.6.Hyosung Corporation

8.6.1.Company overview
8.6.2.Company snapshot
8.6.3.Product portfolio
8.6.4.Business performance
8.6.5.Key strategic moves and developments

8.7.NFC Fibers GmbH

8.7.1.Company overview
8.7.2.Company snapshot
8.7.3.Product portfolio

8.8.Owens Corning

8.8.1.Company overview
8.8.2.Company snapshot
8.8.3.Operating business segments
8.8.4.Product portfolio
8.8.5.Business performance
8.8.6.Key strategic moves and developments

8.9.Teijin Limited

8.9.1.Company overview
8.9.2.Company snapshot
8.9.3.Operating business segments
8.9.4.Product portfolio
8.9.5.Business performance
8.9.6.Key strategic moves and developments

8.10.Toray Industries Inc.

8.10.1.Company overview
8.10.2.Company snapshot
8.10.3.Operating business segments
8.10.4.Product portfolio
8.10.5.Business performance
8.10.6.Key strategic moves and developments

Carbon Fiber in the Aerospace and Defense Market Report: Trends, Forecast and Competitive Analysis

Trends, opportunities and forecast for carbon fiber in the aerospace and defense market to 2025 by aircraft (commercial aerospace, regional jets, general aviation, helicopter, military aircraft and UAV), by precursor type (PAN based, pitch based), by tow size (small tow, large tow), by modulus (st..

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Publication Date:  May, 2020

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Table of Contents
 
 
1. Executive Summary
 
2. Market Background and Classifications
2.1: Introduction, Background, and Classification
2.2: Supply Chain
2.3: Industry Drivers and Challenges
 
3. Market Trends and Forecast Analysis from 2014 to 2025
3.1: Macroeconomic Trends and Forecast
3.2: Carbon Fiber in the  Aerospace and Defense Market Trends and Forecast
3.3: Carbon Fiber in the  Aerospace and Defense Market by Aircraft Type
3.3.1: Commercial Aerospace
3.3.2: Regional Jets
3.3.3: General Aviation
3.3.4: Helicopters
3.3.5: Military Aircraft
3.3.6: UAVs
3.4: Carbon Fiber in the  Aerospace and Defense Market by Component
3.4.1: Primary
3.4.2: Interior
3.4.3: Engine
3.4.4: Others
3.5: Carbon Fiber in the  Aerospace and Defense Market by Precursor Type
3.5.1: Pan Type
3.5.2: Pitch Type
3.6: Carbon Fiber in the  Aerospace and Defense Market by TOW Size
3.6.1: Small Tow (<24k)
3.6.2: Large Tow (>24k)
3.7: Carbon Fiber in the  Aerospace and Defense Market by Modulus
3.7.1: Standard
3.7.2: Intermediate
3.7.3: High
 
4. Market Trends and Forecast Analysis by Region
4.1: Carbon Fiber in the  Aerospace and Defense Market by Region
4.2: North American Carbon Fiber in the Aerospace and Defense Market
4.3: European Carbon Fiber in Aerospace and Defense market
4.4: ROW (Including APAC) Carbon Fiber in the Aerospace and Defense Market
 
5. Competitor Analysis
5.1: Market Share Analysis
5.2: Operational Integration
5.3: Geographical Reach
5.4: Porter’s Five Forces Analysis
 
6. Growth Opportunities and Strategic Analysis
6.1: Growth Opportunity Analysis
6.1.1: Growth Opportunities for Carbon Fiber in the  Aerospace and Defense Market by Aircraft Type
6.1.2: Growth Opportunities for Carbon Fiber in the  Aerospace and Defense Market by Component
6.1.3: Growth Opportunities for Carbon Fiber in the  Aerospace and Defense Market by Precursor Type
6.1.4: Growth Opportunities for Carbon Fiber in the  Aerospace and Defense Market by Region
6.2: Emerging Trends of Carbon Fiber in the  Aerospace and Defense Market
6.3: Strategic Analysis
6.3.1: New Product Development
6.3.2: Capacity Expansion of Carbon Fiber in the  Aerospace and Defense Market
6.3.3: Mergers, Acquisitions, and Joint Ventures of Carbon Fiber in the  Aerospace and Defense Market
6.3.4: Certification and Licensing
 
7. Company Profiles of Leading Players
7.1: Toray Industries Inc.
7.2: Hexcel Corporation
7.3: Mitsubishi Rayon Corporation Limited
7.4: Cytec Solvay Group
7.5: SGL Carbon Group
7.6: Teijin Limited
 
 
 
List of Figures
 
Chapter 2. Market Background and Classifications
Figure 2.1: Evolution in Carbon Fiber Applications
Figure 2.2: Different Types of Carbon Fiber
Figure 2.3: Typical Continuous Carbon Fiber
Figure 2.4: Typical Chopped Carbon Fiber
Figure 2.5: Typical Metal-Coated Carbon Fiber
Figure 2.6: Comparison of Tensile Modulus for Different Types of Continuous Carbon Fiber
Figure 2.7: Comparison of Tensile Strength for Different Types of Continuous Carbon Fiber
Figure 2.8: Comparison of Elongation at Break for Different Types of Continuous Carbon Fiber
Figure 2.9: Comparison of Density for Different Types of Continuous Carbon Fiber
Figure 2.10: Comparison of Tensile Modulus for Different Types of Chopped Carbon Fiber
Figure 2.11: Comparison of Tensile Strength for Different Types of Chopped Carbon Fiber
Figure 2.12: Comparison of Density for Various Chopped Carbon Fibers
Figure 2.13: Comparison of Elongation at Break for Different Types of Chopped Carbon Fiber
Figure 2.14: Comparison of Tensile Strength for Different Types of Milled Carbon Fiber
Figure 2.15: Comparison of Filament Diameter for Different Types of Milled Carbon Fibers
Figure 2.16: Comparison of Density for Different Types of Milled Carbon Fiber
Figure 2.17: Comparison of Tensile Modulus for Different Types of Metal-Coated Carbon Fiber
Figure 2.18: Comparison of Tensile Strength for Different Metal-Coated Carbon Fibers
Figure 2.19: Comparison of Elongation at Break for Different Types of Metal-Coated Carbon Fiber
Figure 2.20: Comparison Chart of Tensile Modulus Per Unit Price for Various Carbon Fibers
Figure 2.21: Comparison Chart of Tensile Strength Per Unit Price for Various Carbon Fibers
Figure 2.22: Comparison of Tensile Modulus Per Unit Price for Different Kinds of Fiber
Figure 2.23: Comparison of Tensile Strength Per Unit Price for Different Kinds of Fiber
Figure 2.24: Classification of the  Carbon Fiber in Aerospace and Defense Market
Figure 2.25: Carbon Fiber Composite Fuselage
Figure 2.26: Carbon Fiber Wings
Figure 2.27: Carbon Fiber Control Surface
Figure 2.28: Carbon Fiber Composite Door
Figure 2.29: Carbon Fiber Composite Pressure Bulkhead
Figure 2.30: Carbon Fiber Composite Seat
Figure 2.31: Carbon Fiber Composite Window Frames
Figure 2.32: Commercial Aircraft
Figure 2.33: Regional Aircraft
Figure 2.34: General Aviation
Figure 2.35: Commercial Helicopter
Figure 2.36: Fighter Plane
Figure 2.37: Transporter Plane
Figure 2.38: Defense Helicopter
Figure 2.39: Manufacturing Process Schematic for PAN-Based Carbon Fibers
Figure 2.40: Manufacturing Process Schematic for Pitch-Based Carbon Fibers
Figure 2.41: Manufacturing Process Schematic for Rayon-Based Carbon Fibers
Figure 2.42: Supply Chain of the  Carbon Fiber in Aerospace and Defense Market
Figure 2.43: Major Drivers and Challenges for Carbon Fiber in the Gloabl Aerospace and Defense Market
 
Chapter 3. Market Trends and Forecast Analysis from 2014 to 2025
Figure 3.1: Trends of the  GDP Growth Rate
Figure 3.2: Trends of the Regional GDP Growth Rate
Figure 3.3: Forecast for the  GDP Growth Rate
Figure 3.4: Forecast for the Regional GDP Growth Rate
Figure 3.5: Trends and Forecast for Carbon Fiber in the  Aerospace and Defense Market (2014-2025)
Figure 3.6: Trends of Carbon Fiber in the  Aerospace and Defense Market ($M) by Aircraft Type (2014-2019)
Figure 3.7: Forecast for Carbon Fiber in the  Aerospace and Defense Market ($M) by Aircraft Type (2020-2025)
Figure 3.8: Trends of Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Aircraft Type (2014-2019)
Figure 3.9: Forecast for Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Aircraft Type (2020-2025)
Figure 3.10: Trends and Forecast for Carbon Fiber in Commercial Aerospace in the  Aerospace and Defense Market (2014-2025)
Figure 3.11: Trends and Forecast for Carbon Fiber in Regional Jets in the  Aerospace and Defense Market (2014-2025)
Figure 3.12: Trends and Forecast for Carbon fiber in General Aviation in the  Aerospace and Defense Market (2014-2025)
Figure 3.13: Trends and Forecast for Carbon fiber in Helicopters in the  Aerospace and Defense Market (2014-2025)
Figure 3.14: Trends and Forecast for Carbon fiber in Military Aircraft in the  Aerospace and Defense Market (2014-2025)
Figure 3.15: Trends and Forecast for Carbon fiber in UAVs in the  Aerospace and Defense Market (2014-2025)
Figure 3.16: Trends of Carbon fiber in the  Aerospace and Defense Market ($M) by Component (2014-2019)
Figure 3.17: Forecast for Carbon fiber in the  Aerospace and Defense Market ($M) by Component (2020-2025)
Figure 3.18: Trends of Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Component (2014-2019)
Figure 3.19: Forecast for Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Component (2020-2025)
Figure 3.20: Trends and Forecast for Carbon Fiber Primary Component in the  Aerospace and Defense Market (2014-2025)
Figure 3.21: Trends and Forecast for Carbon Fiber Interior Component in the  Aerospace and Defense Market (2014-2025)
Figure 3.22: Trends and Forecast for Carbon Fiber Engine Component in the  Aerospace and Defense Market (2014-2025)
Figure 3.23: Trends and Forecast for Others Carbon fiber Component  in the  Aerospace and Defense Market (2014-2025)
Figure 3.24: Trends of Carbon Fiber in the  Aerospace and Defense Market ($M) by Precursor Type (2014-2019)
Figure 3.25: Forecast for Carbon Fiber in the  Aerospace and Defense Market ($M) by Precursor Type (2020-2025)
Figure 3.26: Trends of Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Precursor Type (2014-2019)
Figure 3.27: Forecast for Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Precursor Type (2020-2025)
Figure 3.28: Trends and Forecast for PAN Based Carbon Fiber in the  Aerospace and Defense Market (2014-2025)
Figure 3.29: Trends and Forecast for Pitch Based Carbon Fiber in the  Aerospace and Defense Market (2014-2025)
Figure 3.30: Trends of Carbon fiber in the  Aerospace and Defense Market (M lbs) by Tow Size (2014-2019)
Figure 3.31: Forecast for Carbon fiber in the  Aerospace and Defense Market (M lbs) by Tow Size (2020-2025)
Figure 3.32: Trends and Forecast for Small Tow Carbon Fiber in the  Aerospace and Defense Market (M lbs) (2014-2025)
Figure 3.33: Trends and Forecast for Large Tow Carbon Fiber in the  Aerospace and Defense Market (2014-2025)
Figure 3.34: Trends of Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Modulus (2014-2019)
Figure 3.35: Forecast for Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Modulus (2020-2025)
Figure 3.36: Trends and Forecast for Standard Modulus Carbon fiber in the  Aerospace and Defense Market (2014-2025)
Figure 3.37: Trends and Forecast for Glass Intermediate Modulus Carbon fiber in the  Aerospace and Defense Market (2014-2025)
Figure 3.38: Trends and Forecast for Glass High Modulus Carbon fiber in the  Aerospace and Defense Market (2014-2025)
 
Chapter 4. Market Trends and Forecast Analysis by Region
Figure 4.1: Trends of Carbon Fiber in the  Aerospace and Defense Market ($M) by Region (2014-2019)
Figure 4.2: Forecast for Carbon Fiber in the  Aerospace and Defense Market ($M) by Region (2020-2025)
Figure 4.3: Trends of Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Region (2014-2019)
Figure 4.4: Forecast for Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Region (2020-2025)
Figure 4.5: Trends and Forecast for North American Carbon Fiber in the Aerospace and Defense Market (2014-2025)
Figure 4.6: Trends and Forecast for European Carbon Fiber in the Aerospace and Defense Market (2014-2025)
Figure 4.7: Trends and Forecast for ROW (Including APAC) Carbon Fiber in the Aerospace and Defense Market (2014-2025)
 
Chapter 5. Competitor Analysis
Figure 5.1: Market Share Analysis of Carbon Fiber in the  Aerospace and Defense Market in 2019
Figure 5.2: Market Share Analysis of Top Five Players of Carbon Fiber in the  Aerospace and Defense Market in 2019
Figure 5.3: Geographical Footprint of Competitors in Carbon Fiber in the  Aerospace and Defense Market
Figure 5.4: Porter’s Five Forces Industry Analysis for Carbon Fiber in the  Aerospace and Defense Market
 
Chapter 6. Growth Opportunities and Strategic Analysis
Figure 6.1: Growth Opportunities for Carbon fiber in the  Aerospace and Defense Market by Aircraft Type (2020-2025)
Figure 6.2: Growth Opportunities for Carbon Fiber in the  Aerospace and Defense Market by Component (2020-2025)
Figure 6.3: Growth Opportunities for Carbon Fiber in the  Aerospace and Defense Market by Precursor Type (2020-2025)
Figure 6.4: Growth Opportunities for Carbon Fiber in the  Aerospace and Defense Market by Region (2020-2025)
Figure 6.5: Emerging Trends of Carbon Fiber in the  Aerospace and Defense Market
Figure 6.6: Recent Carbon Fiber Innovations Focused on High Tensile Strength
Figure 6.7: Carbon Fiber Innovation Trends Focused on High Tensile Modulus
Figure 6.8: Strategic Initiatives by Major Competitors of Carbon Fiber in the  Aerospace and Defense Market (2017-2019)
Figure 6.9: Capacity Building by Major Players during Trend Period
 
Chapter 7. Company Profiles of Leading Players
Figure 7.1: Major Plant Locations of Toray’s Carbon Fiber Business
Figure 7.2: Major Plant Locations of Hexcel’s Carbon Fiber Business
Figure 7.3: Major Plant Locations of Mitsubishi Rayon Corporation Limited’s Carbon Fiber Business
Figure 7.4: Major Plant Locations of Cytec Solvay’s Carbon Fiber Business
Figure 7.5: Major Plant Locations of SGL Carbon Group’s Carbon Fiber Business
Figure 7.6: Major Plant Locations of Teijin Limited’s Carbon Fiber Business
 
 
 
 
List of Tables
 
Chapter 1. Executive Summary
Table 1.1: Carbon fiber in the  Aerospace and Defense Market Parameters and Attributes
 
Chapter 2 . Market Background and Classifications
Table 2.1:  Evolution of Carbon Fiber Applications in Different Segments by Year
Table 2.2: Comparison of Applications of Carbon Fiber Material by Suppliers
Table 2.3: Typical Properties for Thornel® Carbon Fibers
Table 2.4: Typical Properties of GrafilTM Carbon Fiber
Table 2.5: Typical Properties of PyrofilTM Carbon Fiber
Table 2.6: Properties of Hexcel Continuous Fiber
Table 2.7: Properties of DialeadTM Standard Grades Carbon Fiber
Table 2.8: Properties of PANOX® Carbon Fiber
Table 2.9: Properties of SIGRAFIL® T Carbon Fiber
Table 2.10: Properties of SIGRAFIL® C Carbon Fiber
Table 2.11: Properties of Tenax® Carbon Fiber
Table 2.12: Properties of Pyromex® Carbon Fiber
Table 2.13: Properties of Tenax® Carbon Fiber
Table 2.14: Properties of Panex® Single and Multi-Ply Yarns
Table 2.15: Properties of Nippon – GranocTM Continuous Fiber
Table 2.16: Properties of Thermalgraph® Fiber
Table 2.17:  Uses of Hexcel PAN-based Chopped Carbon Fiber
Table 2.18:  Properties of GrafilTM Chopped Fiber
Table 2.19: Properties of PyrofilTM Chopped Fiber
Table 2.20:  Properties of DialeadTM Chopped Carbon Fiber
Table 2.21: Properties of Tenax® Chopped Carbon Fiber
Table 2.22: Properties of Tenax® Chopped Carbon Fiber
Table 2.23: Properties of Panex® 35 Chopped Carbon Fiber
Table 2.24: Properties of Nippon – GranocTM Chopped Fiber
Table 2.25: Properties of PANOX® Milled Fiber
Table 2.26: Properties of SIGRAFIL® C Milled Fiber
Table 2.27:  Properties of DialeadTM Milled Fiber
Table 2.28: Properties of HTA Nickel-coated Filament Yarn
Table 2.29: Properties of Tenax® Nickel-Coated Filament Yarn
Table 2.30: Typical Properties of Common Structural Materials
Table 2.31: Price and Property Comparison of Carbon Fiber Supplied by Different Companies in 2017
Table 2.32: Price and Property Comparison for Different Kinds of Fiber
Table 2.33: Composite Materials for Military Aircraft Applications
Table 2.34: Carbon Fiber Applications Combined with Other Materials in Various Markets
 
Chapter 3. Market Trends and Forecast Analysis from 2014 to 2025
Table 3.1: Trends of Carbon Fiber in the  Aerospace and Defense Market (2014-2019)
Table 3.2: Forecast for Carbon Fiber in the  Aerospace and Defense Market (2020-2025)
Table 3.3: Market Size and CAGR of Carbon Fiber in the  Aerospace and Defense Market by Aircraft Type ($M) (2014-2019)
Table 3.4: Market Size and CAGR for Carbon Fiber in the  Aerospace and Defense Market by Aircraft Type ($M) (2020-2025)
Table 3.5: Market Size and CAGR of Carbon Fiber in the  Aerospace and Defense Market by Aircraft Type (M lbs) (2014-2019)
Table 3.6: Market Size and CAGR for Carbon Fiber in the  Aerospace and Defense Market by Aircraft Type (M lbs) (2020-2025)
Table 3.7: Trends of Carbon Fiber in Commercial Aerospace in the  Aerospace and Defense Market (2014-2019)
Table 3.8: Forecast for Carbon Fiber in Commercial Aerospace in the  Aerospace and Defense Market (2020-2025)
Table 3.9: Trends of Carbon Fiber in Regional Jets in the  Aerospace and Defense Market (2014-2019)
Table 3.10: Forecast for Carbon Fiber in Regional Jets in the  Aerospace and Defense Market (2020-2025)
Table 3.11: Trends of the  Carbon fiber in General Aviation in the  Aerospace and Defense Market (2014-2019)
Table 3.12: Forecast for the  Carbon fiber in General Aviation in the  Aerospace and Defense Market (2020-2025)
Table 3.13: Trends of Carbon fiber in Helicopters in the  Aerospace and Defense Market (2014-2019)
Table 3.14: Forecast for Carbon fiber in Helicopters in the  Aerospace and Defense Market (2020-2025)
Table 3.15: Trends of Carbon fiber in Military Aircraft in the  Aerospace and Defense Market (2014-2019)
Table 3.16: Forecast for Carbon fiber in Military Aircraft in the  Aerospace and Defense Market (2020-2025)
Table 3.17: Trends of Carbon fiber in UAVs in the  Aerospace and Defense Market (2014-2019)
Table 3.18: Forecast for Carbon fiber in UAVs in the  Aerospace and Defense Market (2020-2025)
Table 3.19: Market Size and CAGR of Carbon fiber in the  Aerospace and Defense Market ($M) by Component (2014-2019)
Table 3.20: Market Size and CAGR for Carbon fiber in the  Aerospace and Defense Market ($M) by Component (2020-2025)
Table 3.21: Market Size and CAGR of Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Component (2014-2019)
Table 3.22: Market Size and CAGR for Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Component (2020-2025)
Table 3.23: Trends of Carbon Fiber Primary Component in the  Aerospace and Defense Market (2014-2019)
Table 3.24: Forecast for Carbon Fiber Primary Component in the  Aerospace and Defense Market (2020-2025)
Table 3.25: Trends of Carbon Fiber Interior Component in the  Aerospace and Defense Market (2014-2019)
Table 3.26: Forecast for Carbon Fiber Interior Component in the  Aerospace and Defense Market (2020-2025)
Table 3.27: Trends of  Carbon Fiber Engine Component in the  Aerospace and Defense Market (2014-2019)
Table 3.28: Forecast for  Carbon Fiber Engine Component in the  Aerospace and Defense Market (2020-2025)
Table 3.29: Trends of Others Carbon fiber Component in the  Aerospace and Defense Market (2014-2019)
Table 3.30: Forecast for Others Carbon fiber Component in the  Aerospace and Defense Market (2020-2025)
Table 3.31: Trends of Carbon Fiber in the  Aerospace and Defense Market by Precursor Type ($M) (2014-2019)
Table 3.32: Forecast for Carbon Fiber in the  Aerospace and Defense Market by Precursor Type ($M) (2020-2025)
Table 3.33: Trends of Carbon Fiber in the  Aerospace and Defense Market by Precursor Type (M lbs) (2014-2019)
Table 3.34: Forecast for Carbon Fiber in the  Aerospace and Defense Market by Precursor Type (M lbs) (2020-2025)
Table 3.35:  Trends of PAN Based Carbon Fiber in the  Aerospace and Defense Market (2014-2019)
Table 3.36: Forecast for PAN Based Carbon Fiber in the  Aerospace and Defense Market (2020-2025)
Table 3.37:  Trends of Pitch Based Carbon Fiber in the  Aerospace and Defense Market (2014-2019)
Table 3.38: Forecast for Pitch Based Carbon Fiber in the  Aerospace and Defense Market (2020-2025)
Table 3.39: Trends of Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Tow Size (2014-2019)
Table 3.40: Forecast for Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Tow Size (2020-2025)
Table 3.41:  Trends of Small Tow Carbon Fiber in the  Aerospace and Defense Market (2014-2019)
Table 3.42: Forecast for Small Tow Carbon Fiber in the  Aerospace and Defense Market (2020-2025)
Table 3.43:  Trends of Large Tow Carbon Fiber in the  Aerospace and Defense Market (2014-2019)
Table 3.44: Forecast for Large Tow Carbon Fiber in the  Aerospace and Defense Market (2020-2025)
Table 3.45: Trends of Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Modulus (2014-2019)
Table 3.46: Forecast for Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Modulus (2020-2025)
Table 3.47:  Trends of Standard Modulus Carbon fiber in the  Aerospace and Defense Market (2014-2019)
Table 3.48: Forecast for Standard Modulus Carbon fiber in the  Aerospace and Defense Market (2020-2025)
Table 3.49:  Trends of Intermediate Modulus Carbon fiber in the  Aerospace and Defense Market (2014-2019)
Table 3.50: Forecast for Intermediate Modulus Carbon fiber in the  Aerospace and Defense Market (2020-2025)
Table 3.51:  Trends of High Modulus Carbon fiber in the  Aerospace and Defense Market (2014-2019)
Table 3.52: Forecast for High Modulus Carbon fiber in the  Aerospace and Defense Market (2020-2025)
 
Chapter 4. Market Trends and Forecast Analysis by Region
Table 4.1: Trends of Carbon Fiber in the  Aerospace and Defense Market ($M) by Region (2014-2019)
Table 4.2: Forecast for Carbon Fiber in the  Aerospace and Defense Market ($M) by Region (2020-2025)
Table 4.3: Trends of Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Region (2014-2019)
Table 4.4: Forecast for Carbon Fiber in the  Aerospace and Defense Market (M lbs) by Region (2020-2025)
Table 4.5: Trends of North American Carbon Fiber in the Aerospace and Defense Market (2014-2019)
Table 4.6: Forecast for North American Carbon Fiber in the Aerospace and Defense Market (2020-2025)
Table 4.7: Trends of European Carbon Fiber in the Aerospace and Defense Market (2014-2019)
Table 4.8: Forecast for European Carbon Fiber in the Aerospace and Defense Market (2020-2025)
Table 4.9: Trends of ROW (Including APAC) Carbon Fiber in the Aerospace and Defense Market (2014-2019)
Table 4.10: Forecast for ROW (Including APAC) Carbon Fiber in the  Aerospace and Defense Market (2020-2025)
 
Chapter 5. Competitor Analysis
Table 5.1: Product Mapping of Carbon Fiber Suppliers Based on Markets Served
Table 5.2: Industry-wide Carbon Fiber Product Map Based on Tow Size
Table 5.3: Industry-wide Carbon Fiber Product Map Based on Modulus
Table 5.4: Rankings of Suppliers Based on Carbon Fiber in the  Aerospace and Defense Market Revenue
Table 5.5: Operational Integration of Carbon Fiber Suppliers
 
Chapter 6. Growth Opportunities and Strategic Analysis
Table 6.1: Average Tensile Strength and Innovation Trend of Carbon Fiber
Table 6.2: Recent Carbon Fiber Innovations Focused on High Tensile Strength by Different Company
Table 6.3: Average Tensile Modulus and Innovation Trend of Carbon Fiber
Table 6.4: Recent Carbon Fiber Innovations Focused on High Tensile Modulus by Different Company
Table 6.5: New Product Launches by Major Carbon Fiber Producers (2014-2019) (Source: Lucintel)
Table 6.6: Certification and Licenses Acquired by Major Competitors of Carbon Fiber in the  Aerospace and Defense Market