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市場調查報告書

熱障塗層(TBC):全球市場

Thermal Barrier Coatings: Global Markets

出版商 BCC Research 商品編碼 447096
出版日期 內容資訊 英文 166 Pages
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熱障塗層(TBC):全球市場 Thermal Barrier Coatings: Global Markets
出版日期: 2017年02月21日 內容資訊: 英文 166 Pages
簡介

全球熱障塗層(TBC) 市場規模2016年達8億3,490萬美元預計2021年將達約11億美元、至2021年的5年CAGR (年複合成長率) 預估為5.6%。

本報告針對全球熱障塗層(TBC) 市場、提供全球市場概要、實績數據、推算數據、CAGR預測全球市場動向、熱障塗層技術市場詳細調查、未來展望、專利動向與主要企業檔案。

第1章 介紹

第2章 摘要整理

第3章 概要

  • 競爭狀況、主要供應商
    • 飛機產業
    • 發電產業、燃氣渦輪產業用途
    • 船舶用柴油引擎

第4章 市場區分

  • 熱障塗層市場:架構分類
  • 熱障塗層市場:應用產業分類
  • TBC產業用途市場規模基本計算
  • 熱障塗層市場:沉積流程分類
  • 熱障塗層市場:供應商種類分類
  • 飛機用途:供應商種類分類
  • 發電用途:供應商種類分類
  • 船舶用柴油引擎用途的熱障塗層:供應商種類分類
  • 飛機燃氣渦輪高溫部份零件TBC用途:溫度分類
  • 用途區分:地域分類
  • 發電用燃氣渦輪、產業用燃氣渦輪高溫部份TBC用途:溫度分類
  • 用途區分:地域分類
  • 船舶用柴油引擎用途TBC用途:溫度分類
  • 用途區分:地域分類

第5章 技術概要

  • 為了獲得高效率燃氣渦輪的大量天然氣溫度
  • 燃氣渦輪引擎概念與高溫部份零件構成
  • 酸化、腐蝕的操作機械與燃氣渦輪的高溫部份零件TBC角色

第6章 熱障塗層用途

  • 飛機燃氣渦輪引擎用途的熱障塗層
  • 範例分析:PRATT & WHITNEY
  • 熱障塗層的厚度
  • 範例分析:ROLLS-ROYCE
  • 範例分析:MTU AERO ENGINES-CERAMIC COATING CENTER、法國
  • 範例分析:ELECTRIC WELDING INSTITUTE OF THE NATIONAL ACADEMY OF SCIENCE 、烏克蘭
  • 發電用天然氣、產業用燃氣渦輪 (IGT) 引擎使用的熱障塗層
  • 柴油引擎熱障塗層

第7章 專利

  • 概要
  • TBC技術美國專利活動:委託國家分類
  • 熱障塗層技術相關美國專利

第8章 產業構造

  • 競合情勢、主要供應商
  • 船舶用柴油引擎
  • 產業發展

第9章 企業檔案

  • 飛機燃氣渦輪OEM供應商
  • 發電用燃氣渦輪OEM供應商
  • 飛機用燃氣渦輪MRO服務供應商
  • 發電用燃氣渦輪MRO供應商
  • 飛機、發電用燃氣渦輪雙方MRO供應商
  • 飛機零件PMA供應商
  • 發電用燃氣渦輪零件PMA供應商
  • 飛機、發電用燃氣渦輪雙方獨立TBC塗裝業者

圖表列表

目錄
Product Code: AVM139A

Report Highlights

The global market for thermal barrier coatings (TBCs) totaled $834.9 million in 2016 and should total nearly $1.1 billion in 2021 at a five-year compound annual growth rate (CAGR) of 5.6%, through 2021.

Report Includes:

  • An overview of the global markets for thermal barrier coatings (TBC)
  • Analyses of global market trends, with data from 2015 and 2016, and projections of compound annual growth rates (CAGRs) through 2021
  • Provide a detailed and comprehensive multi-client study of the market for thermal barrier coating technologies
  • Extensive quantification of the important facets of market developments in the industry
  • Discussion of the merits and future prospects of the thermal barrier coating technologies business
  • Overview of international U.S. patents pertaining to TBC technology
  • Profiles of major manufacturers and suppliers related to TBC

Report Scope

The scope of this report is comprehensive, covering the present status of and future prospects for thermal barrier coating technologies. The scope of the report includes thermal barrier coating technologies applied to gas turbines for aircraft, gas turbines for power generation and industrial gas turbines and diesel engines for marine and other application.

The report identifies and evaluates thermal barrier coating technology markets with keen potential for growth. The study also provides extensive quantification of the many important facets of market developments for advanced thermal barrier coating technologies development.

In addition to thermal barrier coating technologies, it also covers the many issues concerning the merits and future prospects of the thermal barrier coating technologies business, including corporate strategies, information technologies and the means for providing these highly advanced products and service offerings. It also covers in detail the economic and technological issues regarded by many as critical to the industry's current state of change.

The report provides a review of the thermal barrier coating technologies industry and its structure, and the OEMs, MROs, manufacturers of PMA equipment and surface technology expert coaters involved in providing these coatings. The competitive position of the main players in the TBC market is well protected due to license restrictions by OEMs (e.g., GE Aviation, Pratt & Whitney, Rolls-Royce, Safran) for sharing TBC solutions for hot section gas turbine for aircraft, particularly the high-pressure blades and vanes.

Manufacturers of PMA parts have received approval through aircraft regulating agencies such as the Federal Aviation Administration (FAA), European Aviation Safety Agency (EASA) and National Aero and Defense Contractors Accreditation Program (Nadcap). This has narrowed down the competition in TBC related solutions applied to gas turbines used in aircraft. On the other hand, gas turbines used in the power generation industry and other industrial stationary applications have a large number of approved MROs globally to repair and recoat the thermal barrier coatings on the hot section of gas turbines that undergo high-pressure blade/vane repair. These MROs follow approved quality certification procedures of OEMs (e.g., GE, Siemens, Rolls-Royce) for the bond coat and top coat.

The forecast tables represent the estimated value of the thermal barrier coating technologies added to the components of gas turbines and diesel engines as manufactured by the OEMs, MROs, PMA parts companies and coaters. In this report, the term revenue is equivalent to, and is used interchangeably with purchases, demand and sales. All growth rates mentioned in the tables and text are based on compound annual growth rates (CAGRs) from 2016 through 2021. Because current 2016 dollar measures are used, these growth rates thus reflect the growth in volume or real growth, including the effects of price changes and changes in product/service mix.

Analyst Credentials

Since 2004, BL Gupta had authored more than 34 market research reports on cutting edge technology pertaining to the emerging technologies connected with piezoelectric actuators, piezo motors, piezo sensors, PVDF sensors, automotive semiconductors, energy storage devices such as lithium ion batteries, ultracapacitors and electrical equipment such as power and distributing transformers, materials such as permanent magnets, soft magnetic materials and the Internet of Things (IoT) related to manufacturing and other topics focused on the U.S. and global market.

During 2011-2012, BL Gupta was appointed as a national consultant to machine tool manufacturing companies in North India through the TUPE program (Technology Upgradation and Productivity Enhancement) under UNIDO (United Nations Industrial Development Organization)-a joint effort between the United Nations and the government of India. He has been a fellow of the Institution of Engineers of India as well as a Charter Engineer of the Institution of Engineers (India) since 2001. Mr. Gupta holds a Bachelor of Engineering (BE) in Mechanical Engineering from the Malaviya National Institute of Technology, Jaipur, India.

Table of Contents

CHAPTER 1 - INTRODUCTION

  • STUDY GOAL AND OBJECTIVES
  • REASONS FOR DOING THE STUDY
  • INTENDED AUDIENCE
  • SCOPE OF THE REPORT
  • METHODOLOGY
  • INFORMATION SOURCES
  • ANALYST'S CREDENTIALS
  • RELATED BCC RESEARCH REPORTS
  • BCC RESEARCH WEBSITE
  • DISCLAIMER
  • COMPETITIVE LANDSCAPE AND KEY VENDORS

CHAPTER 2 - EXECUTIVE SUMMARY

  • SUMMARY TABLE GLOBAL MARKET FOR THERMAL BARRIER COATING TECHNOLOGIES BY APPLICATION INDUSTRY, THROUGH 2021 ($ MILLIONS)
  • SUMMARY FIGURE GLOBAL MARKET FOR THERMAL BARRIER COATING TECHNOLOGIES BY APPLICATION INDUSTRY, 2015-2021 ($ MILLIONS)

CHAPTER 3 - OVERVIEW

  • COMPETITIVE LANDSCAPE AND KEY VENDORS
    • AIRCRAFT INDUSTRY
      • OEMs
      • MROs
      • PMA Parts Providers
    • POWER GENERATION INDUSTRY AND INDUSTRY USE OF GAS TURBINES
      • OEMs
      • MROs
      • PMA Parts Providers
    • MARINE DIESEL ENGINES

CHAPTER 4 - MARKET SEGMENTATION

  • THERMAL BARRIER COATING MARKET BY ARCHITECTURE
    • TABLE 1: GLOBAL MARKET FOR THERMAL BARRIER COATINGS BY ARCHITECTURE, THROUGH 2021 ($ MILLIONS)
    • FIGURE 1: GLOBAL MARKET SHARE FOR THERMAL BARRIER COATINGS BY ARCHITECTURE, 2016 AND 2021 (%)
  • THERMAL BARRIER COATING MARKET BY APPLICATION INDUSTRY
    • TABLE 3: GLOBAL MARKET FOR TBC TECHNOLOGIES BY APPLICATION INDUSTRY, THROUGH 2021 ($ MILLIONS)
    • FIGURE 2: GLOBAL MARKET SHARE FOR TBC TECHNOLOGIES BY APPLICATION INDUSTRY, 2016 AND 2021 (%)
  • BASIS OF THE CALCULATION OF THE MARKET SIZES OF INDUSTRY APPLICATIONS OF TBC IN 2016
    • Aircraft Industry
      • TABLE 4: BASIS OF THE CALCULATION OF THE MARKET SIZE OF THERMAL BARRIER COATING APPLICATIONS IN AIRCRAFT GAS TURBINES, 2016 ($ MILLIONS)
    • Power Generation Industry and Industrial Gas Turbines
      • TABLE 5: BASIS OF THE CALCULATION OF THE MARKET FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES, 2016 ($ MILLIONS)
    • Marine Diesel Engine Industry
      • TABLE 6: BASIS OF THE CALCULATION OF THE MARKET FOR THERMAL BARRIER COATING APPLICATIONS IN SPECIAL DIESEL ENGINES, 2016 ($ MILLIONS)
  • THERMAL BARRIER COATING MARKET BY DEPOSITION PROCESS
    • TABLE 7: GLOBAL MARKET FOR THERMAL BARRIER COATINGS BY DEPOSITION PROCESS, THROUGH 2021 ($ MILLIONS)
    • FIGURE 3: GLOBAL MARKET SHARE FOR THERMAL BARRIER COATING BY DEPOSITION PROCESS, 2016 AND 2021 (%)
  • THERMAL BARRIER COATING MARKET BY DEPOSITION PROCESS
    • EB-PVD Thermal Barrier Coatings
      • TABLE 8: GLOBAL MARKET FOR EB-PVD THERMAL BARRIER COATINGS BY APPLICATION INDUSTRY, THROUGH 2021 ($ MILLIONS)
    • LPPS Thermal Barrier Coatings
      • TABLE 9: GLOBAL MARKET FOR LPPS THERMAL BARRIER COATINGS BY APPLICATION INDUSTRY, THROUGH 2021 ($ MILLIONS)
    • APS Thermal Barrier Coatings
      • TABLE 10: GLOBAL MARKET FOR APS THERMAL BARRIER COATINGS BY APPLICATION INDUSTRY, THROUGH 2021 ($ MILLIONS)
    • HVOF Thermal Barrier Coatings
      • TABLE 11: GLOBAL MARKET FOR HVOF THERMAL BARRIER COATINGS BY INDUSTRY APPLICATION, THROUGH 2021 ($ MILLIONS)
  • THERMAL BARRIER COATING MARKET BY TYPE OF PROVIDER
  • AIRCRAFT APPLICATIONS BY TYPE OF PROVIDER
    • Global Market
      • TABLE 12: GLOBAL MARKET FOR THERMAL BARRIER COATINGS IN AIRCRAFT GAS TURBINE APPLICATIONS BY TYPE OF PROVIDER, THROUGH 2021 ($ MILLIONS)
      • FIGURE 4: GLOBAL MARKET SHARE FOR TBC IN AIRCRAFT GAS TURBINE APPLICATIONS BY TYPE OF PROVIDER, 2016 AND 2021 (%)
    • Regional Markets
      • TABLE 13: REGIONAL MARKETS FOR THERMAL BARRIER COATINGS IN AIRCRAFT GAS TURBINE APPLICATIONS, THROUGH 2021 ($ MILLIONS)
      • FIGURE 5: REGIONAL MARKETS FOR THERMAL BARRIER COATINGS IN AIRCRAFT GAS TURBINE APPLICATIONS, 2016 AND 2021 (%)
  • POWER GENERATION APPLICATIONS BY TYPE OF PROVIDER
    • Global Market
      • TABLE 14: GLOBAL MARKET FOR THERMAL BARRIER COATINGS IN POWER GENERATION GAS TURBINE APPLICATIONS BY TYPE OF PROVIDER, THROUGH 2021 ($ MILLIONS)
      • FIGURE 6: GLOBAL MARKET FOR THERMAL BARRIER COATINGS IN POWER GENERATION GAS TURBINE APPLICATIONS BY TYPE OF PROVIDER, 2016 AND 2021 (%)
    • Regional Markets
      • TABLE 15: REGIONAL MARKETS FOR THERMAL BARRIER COATINGS IN POWER GENERATION GAS TURBINE APPLICATIONS, THROUGH 2021 ($ MILLIONS)
      • FIGURE 7: REGIONAL MARKETS FOR THERMAL BARRIER COATINGS IN POWER GENERATION GAS TURBINE APPLICATIONS, 2016 AND 2021 (%)
  • THERMAL BARRIER COATINGS IN MARINE DIESEL ENGINE APPLICATIONS BY TYPE OF PROVIDER
    • Global Market
      • TABLE 16: GLOBAL MARKET FOR THERMAL BARRIER COATINGS IN MARINE DIESEL ENGINE APPLICATIONS BY TYPE OF PROVIDER, THROUGH 2021 ($ MILLIONS)
    • Regional Markets
      • TABLE 17: REGIONAL MARKETS FOR THERMAL BARRIER COATINGS IN MARINE DIESEL ENGINE APPLICATIONS, THROUGH 2021 ($ MILLIONS)
      • FIGURE 8: REGIONAL MARKETS FOR THERMAL BARRIER COATINGS IN MARINE DIESEL ENGINE APPLICATIONS, 2016 AND 2021 (%)
  • TBC APPLICATIONS IN THE HOT SECTION COMPONENTS OF AIRCRAFT GAS TURBINES BY FIRING TEMPERATURE
    • GLOBAL MARKET
      • TABLE 18: GLOBAL MARKET FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES BY FIRING TEMPERATURE, THROUGH 2021 ($ MILLIONS)
  • APPLICATION SEGMENTS BY REGION
    • Aircraft Turbine Engines with a Firing Temperature of 1,400C
      • TABLE 19: REGIONAL MARKETS FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES WITH A FIRING TEMPERATURE 1,400°C, THROUGH 2021 ($ MILLIONS)
    • Aircraft Engines with a Firing Temperature of 1,350C
      • TABLE 20: REGIONAL MARKETS FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES WITH A FIRING TEMPERATURE OF 1,350°C, THROUGH 2021 ($ MILLIONS)
    • Aircraft Engines with a Firing Temperature of 1,300C
      • TABLE 21: REGIONAL MARKETS FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES WITH A FIRING TEMPERATURE OF 1,300°C, THROUGH 2021 ($ MILLIONS)
    • Aircraft Engines with a Firing Temperature of 1,250C
      • TABLE 22: REGIONAL MARKETS FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES WITH A FIRING TEMPERATURE OF 1,250°C, THROUGH 2021 ($ MILLIONS)
    • Aircraft Engines with a Firing Temperature of 1,200C
      • TABLE 23: REGIONAL MARKETS FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES WITH A FIRING TEMPERATURE OF 1,200°C, THROUGH 2021 ($ MILLIONS)
    • Aircraft Engines with a Firing Temperature below 1,200C
      • TABLE 24: REGIONAL MARKETS FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES WITH A FIRING TEMPERATURE BELOW 1,200°C, THROUGH 2021 ($ MILLIONS)
  • TBC APPLICATIONS IN THE HOT SECTION OF POWER GENERATION GAS TURBINES AND INDUSTRIAL GAS TURBINES BY FIRING TEMPERATURE
    • GLOBAL MARKET
      • TABLE 25: GLOBAL MARKET FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES BY FIRING TEMPERATURE, THROUGH 2021 ($ MILLIONS)
  • APPLICATION SEGMENTS BY REGION
    • Power Generation Gas Turbine Engines with a Firing Temperature of 1,800C
      • TABLE 26: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,800°C, THROUGH 2021 ($ MILLIONS)
    • Power Generation Gas Turbine Engines with a Firing Temperature of 1,750C
      • TABLE 27: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,750°C, THROUGH 2021 ($ MILLIONS)
    • Power Generation Gas Turbine Engines with a Firing Temperature of 1,700C
      • TABLE 28: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,700°C, THROUGH 2021 ($ MILLIONS)
    • Power Generation Gas Turbine Engines with a Firing Temperature of 1,650C
      • TABLE 29: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,650°C, THROUGH 2021 ($ MILLIONS)
    • Power Generation Gas Turbine Engines with a Firing Temperature of 1,600C
      • TABLE 30: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,600°C, THROUGH 2021 ($ MILLIONS)
    • Power Generation Gas Turbine Engines with a Firing Temperature of 1,550C
      • TABLE 31: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,550°C, THROUGH 2021 ($ MILLIONS)
    • Power Generation Gas Turbine Engines with a Firing Temperature of 1,500C
      • TABLE 32: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,500°C, THROUGH 2021 ($ MILLIONS)
    • Power Generation Gas Turbine Engines with a Firing Temperature of 1,450C
      • TABLE 33: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,450°C, THROUGH 2021 ($ MILLIONS)
    • Power Generation Gas Turbine Engines with a Firing Temperature of 1,400C
      • TABLE 34: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,400°C, THROUGH 2021 ($ MILLIONS)
    • Power Generation Turbine Engines with a Firing Temperature below 1,400C
      • TABLE 35: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE BELOW 1,400°C, THROUGH 2021 ($ MILLIONS)
  • TBC APPLICATIONS IN MARINE DIESEL ENGINES BY FIRING TEMPERATURE
    • TABLE 36: GLOBAL MARKET FOR TBC APPLICATIONS IN MARINE DIESEL ENGINES BY FIRING TEMPERATURE, THROUGH 2021 ($ MILLIONS)
  • APPLICATION SEGMENTS BY REGION
    • Marine Diesel Engines with a Firing Temperature of 650C
      • TABLE 37: GLOBAL MARKET FOR TBC APPLICATIONS IN MARINE DIESEL ENGINE TURBINES WITH A FIRING TEMPERATURE OF 650°C THROUGH 2021 ($ MILLIONS)
    • Marine Diesel Engines with a Firing Temperature of 600C
      • TABLE 38: REGIONAL MARKETS FOR TBC APPLICATIONS IN MARINE DIESEL ENGINES WITH A FIRING TEMPERATURE OF 600°C, THROUGH 2021 ($ MILLIONS)
    • Marine Diesel Engines with a Firing Temperature of 550C
      • TABLE 39: REGIONAL MARKETS FOR TBC APPLICATIONS IN MARINE DIESEL ENGINES WITH A FIRING TEMPERATURE OF 550°C, THROUGH 2021 ($ MILLIONS)
    • Marine Diesel Engines with a Firing Temperature of 500C
      • TABLE 40: REGIONAL MARKETS FOR TBC APPLICATIONS IN MARINE DIESEL ENGINES WITH A FIRING TEMPERATURE OF 500°C, THROUGH 2021 ($ MILLIONS)
    • Marine Diesel Engines with a Firing Temperature below 500C
      • TABLE 41: REGIONAL MARKETS FOR TBC APPLICATIONS IN MARINE DIESEL ENGINES WITH A FIRING TEMPERATURE BELOW 500°C, THROUGH 2021 ($ MILLIONS)

CHAPTER 5 - TECHNOLOGY OVERVIEW

  • ROLE OF HIGH INTAKE GAS TEMPERATURE TO OBTAIN HIGHER GAS TURBINE EFFICIENCY
    • FIGURE 9: EVOLUTION OF ALLOWABLE GAS TEMPERATURE AT THE ENTRY TO THE GAS TURBINE
  • GAS TURBINE ENGINES CONCEPT AND CONSTRUCTION HOT SECTION COMPONENTS
    • STAGES
    • COMBUSTION HARDWARE
      • FIGURE 10: COMBUSTION LINER WITH SIX NOZZLES*
      • FIGURE 11: TRANSITION PIECE*
      • Nozzles and Vanes
        • Stage 1 Vanes
        • Stage 2 Vanes
        • Stage 3 Vanes
        • Stage 4 Vanes
        • GE Gas Turbine
          • FIGURE 12: VANES OR NOZZLES*
    • BLADES AND BUCKETS
      • Stage 1 Blades
      • Stage 2 Blades
      • Stage 3 Blades
      • Stage 4 Blades
      • GE Gas Turbine
        • FIGURE 13: HEAVY DUTY INDUSTRIAL BLADE
        • FIGURE 14: AERODERIVATIVE BLADE OR BUCKET
  • OPERATING MECHANISM OF OXIDATION AND CORROSION AND ROLE OF TBC IN THE HOT SECTION COMPONENTS OF GAS TURBINES
    • DIFFUSION COATING VERSUS OVERLAY COATINGS
    • ROLE OF EACH ELEMENT OF HIGH TEMPERATURE OXIDATION AND CORROSION RESISTANT COATINGS
    • TYPES AND STRUCTURES OF TBC IN AEROSPACE GAS TURBINE ENGINES
    • BOND COAT MATERIAL OPTIONS AND PROPERTIES
      • Major Types of Bond Coats
        • Aluminide Bond Coat
        • MCrAlY Bond Coat
        • Cobalt-Cermet-Based Coatings
        • Nickel-Chromium Bond Coat
    • TOP COAT MATERIAL OPTIONS AND PROPERTIES
      • Yttria-Stabilized Zirconia
      • Mullite
      • Alumina
      • CeO2 + YSZ
      • Rare-Earth Zirconates
      • Rare-Earth Oxides
      • Metal-Glass Composites
    • ROLE OF THERMALLY GROWN OXIDES
    • PROCESS OPTIONS FOR BOND COAT AND TOP COAT
      • Air Plasma Spraying
        • FIGURE 15: AIR PLASMA SPRAYING
      • High-Velocity Oxygen Fuel
        • FIGURE 16: HIGH VELOCITY OXYGEN FUEL
      • Low Pressure Plasma Spray
      • Electron Beam-Physical Vapor Deposition
        • Process Description
        • Advantages and Disadvantages of EB-PVD
        • Description of EB-PVD Production Systems Coating Machines
        • Process Control
    • FUTURE ADVANCES
    • COMPARATIVE ANALYSIS OF BOND COAT PROCESSES
    • COMPARATIVE ANALYSIS OF TOP COAT PROCESSES
    • DEGRADATION OF HOT SECTION COMPONENTS
      • Creep
      • Thermal Mechanical Fatigue
      • Metallurgical Embrittlement
      • Environmental Attack and Coating Degradation
        • FIGURE 17: APPROXIMATE REGIMES OF HIGH TEMPERATURE ENVIRONMENTAL ATTACK
      • Oxidation
      • Hot Corrosion
      • Coating Degradation
        • FIGURE 18: HIGH TEMPERATURE COATING PROTECTION OF THE BASE METAL
    • REPAIR OF HOT SECTION COMPONENTS
    • RECOATING

CHAPTER 6 - THERMAL BARRIER COATING APPLICATIONS

  • THERMAL BARRIER COATINGS IN AIRCRAFT GAS TURBINE ENGINE APPLICATIONS
    • TABLE 42: COMMERCIAL MODELS/MAKES OF AERO ENGINE GAS TURBINES THAT REQUIRE THERMAL BARRIER COATINGS
  • CASE STUDY-PRATT & WHITNEY
    • TABLE 43: REPRESENTATIVE SAMPLE OF TBC SYSTEMS IN PRATT & WHITNEY GAS TURBINE ENGINES
  • ROLE OF THICKNESS OF THERMAL BARRIER COATING
    • TABLE 44: REPRESENTATIVE SAMPLE OF TBC ARCHITECTURES FOR AIRCRAFT TURBINE HOT SECTION COMPONENTS ADOPTED BY PRATT & WHITNEY
  • CASE STUDY-ROLLS-ROYCE
    • FIGURE 19: GAS ENGINE SHOWING DIFFERENT SECTIONS ALONG THE ENGINE WITH CORRESPONDING PRESSURE AND TEMPERATURE PROFILES
    • FIGURE 20: EXAMPLE OF A CROSS-SECTIONAL IMAGE OF A TBC SYSTEM ON AN AERO TURBINE BLADE
    • TABLE 45: TBC ARCHITECTURE OF AIRCRAFT GAS TURBINES ADOPTED BY NASA
  • CASE STUDY-MTU AERO ENGINES-CERAMIC COATING CENTER, FRANCE
    • TABLE 46: TBC ARCHITECTURE OF AIRCRAFT GAS TURBINES ADOPTED BY MTU GERMANY
  • CASE STUDY-ELECTRIC WELDING INSTITUTE OF THE NATIONAL ACADEMY OF SCIENCE OF UKRAINE
    • TABLE 46: TBC ARCHITECTURE OF AIRCRAFT GAS TURBINES ADOPTED BY MTU GERMANY
  • THERMAL BARRIER COATINGS USED IN POWER GENERATION GAS AND INDUSTRIAL GAS TURBINE (IGT) ENGINES
    • CRITERION FOR CHOOSING THE TBC ARCHITECTURE FOR POWER GENERATION GAS TURBINES
      • Quality of Fuels
      • Oxide Scale
      • Coating Life
        • TABLE 48: DESCRIPTIONS OF SULZER POWER GENERATION GAS TURBINE COMPONENTS EQUIVALENT TO SIEMENS AND GE MODELS
    • TBC APPLICATIONS IN POWER GENERATION GAS TURBINE ENGINES
      • Combustor of Gas Turbine for Power Generation
      • Vane Airfoils
      • Vane Platforms
    • BLADE AIRFOILS AND PLATFORMS
      • TABLE 49: REPRESENTATIVE SAMPLE OF TBC SYSTEMS IN GAS TURBINE ENGINES USED FOR POWER GENERATION AND INDUSTRIAL GAS TURBINES
    • MULTILAYERED CERAMIC TBC
    • LANTHANUM ZIRCONATE
    • GADOLINIUM ZIRCONATE
      • FIGURE 21: MUTILAYER TBCS USED IN THE HOT SECTIONS OF IGCC OR GAS TURBINE GTCC TURBINES IN THE POWER GENERATION INDUSTRY
    • CASE STUDIES
      • Cooling Technology for Hot Section of Gas Turbine Adopted for Power Generation by Mitsubishi Hitachi Power Systems
      • GTCC Power Generation
      • Cooling Technology of Hot Section of GTCC Gas Turbine
        • TABLE 50: THERMAL BARRIER COATINGS ARCHITECTURE ADOPTED FOR GAS TURBINES WITH A FIRING TEMPERATURE OF 1,500°C ADOPTED BY MITSUBISHI HITACHI POWER SYSTEMS
    • SIEMENS INDUSTRIAL TURBOMACHINERY AB
      • TABLE 51: THERMAL BARRIER COATING ARCHITECTURE IN POWER GENERATION AND INDUSTRIAL GAS TURBINES ADOPTED BY SIEMENS INDUSTRIAL TURBOMACHINERY AB
      • Coating Solutions at Sulzer Turbo Services Venlo BV, Netherland
      • Combined Role of TBC and Cooling Technologies in HP Blades of Gas Turbines Used in IGCC at MHI
      • GTCC-Related Turbine Features
        • TABLE 52: TBC ARCHITECTURE FOR GAS TURBINES WITH A FIRING TEMPERATURE OF 1,600°C ADOPTED BY MITSUBISHI HEAVY CORP. AND MITSUBISHI HITACHI POWER CORP
      • Gas Turbine with a Firing Temperature of 1,600°C-Forschungszentrum Julich GmbH Germany
        • TABLE 53: TBC ARCHITECTURE ADOPTED BY FORSCHUNGSZENTRUM JULICH GMBH GERMANY FOR GAS TURBINES* WITH A FIRING TEMPERATURE OF 1,600°C
  • THERMAL BARRIER COATINGS IN DIESEL ENGINES
    • MARINE APPLICATIONS
    • OEM APPLICATIONS
    • HOW EMISSION REDUCTIONS ARE ACHIEVED WITH TBC?
      • TABLE 54: TBC ARCHITECTURE ADOPTED IN DIESEL ENGINES FOR MARINE APPLICATIONS
      • TABLE 55: APPLICATION OF CURRENT TBC SYSTEMS DIESEL ENGINES FOR MARINE AND OTHER APPLICATIONS (PEAK TEMPERATURE MAX 600°C)
      • TABLE 56: OPERATING TEMPERATURE AND STRESS STATE COMPARISON BETWEEN DIESEL ENGINE AND TURBINE (°C/%)
    • ADVANTAGES OF TBC IN DIESEL ENGINES
      • FIGURE 22: LIFETIME IMPROVEMENTS WITH THE USE OF THERMAL BARRIER COATINGS IN CYCLIC DIESEL ENGINE TESTS

CHAPTER 7 - PATENTS

  • OVERVIEW
    • TABLE 57: U.S. PATENTS GRANTED FOR TBC TECHNOLOGY, JAN. 2012 TO JULY 2016 (NO.)
  • U.S. PATENT ACTIVITY IN TBC TECHNOLOGY BY ASSIGNEE COUNTRY
    • TABLE 58: U.S. TBC TECHNOLOGY PATENTS BY ASSIGNEE COUNTRY, JAN. 2012 TO JULY 2016 (NO.)
    • TABLE 59: TOP U.S. TBC TECHNOLOGY PATENT HOLDERS, JAN. 2012 TO JULY 2016 (NO.)
  • U.S. PATENTS ON THERMAL BARRIER COATING TECHNOLOGY
    • PATENT TITLE: COMBUSTOR RESONATOR SECTION WITH AN INTERNAL THERMAL BARRIER COATING AND METHOD OF FABRICATING THE SAME
    • PATENT TITLE: PROCESS OF FABRICATING THERMAL BARRIER COATINGS
    • PATENT TITLE: METHOD OF FABRICATING A THERMAL BARRIER
    • PATENT TITLE: GERMANATE-CONTAINING THERMAL BARRIER COATING
    • PATENT TITLE: THERMAL BARRIER COATINGS INCLUDING CMAS-RESISTANT THERMAL BARRIER COATING LAYERS
    • PATENT TITLE: THERMAL BARRIER COATINGS AND METHODS OF APPLICATION
    • PATENT TITLE: THERMAL BARRIER COATING SYSTEM, COMPONENTS COATED THEREWITH AND METHOD FOR APPLYING A THERMAL BARRIER COATING SYSTEM TO COMPONENTS
    • PATENT TITLE: METHOD FOR MANUFACTURING A THERMAL-BARRIER PROTECTION AND MULTILAYER COATING SUITABLE FOR FORMING A THERMAL BARRIER
    • PATENT TITLE: TECHNIQUES FOR REMOVING A CONTAMINANT LAYER FROM A THERMAL BARRIER COATING AND ESTIMATING REMAINING LIFE OF THE COATING
    • PATENT TITLE: METHOD FOR COATING A BLADE AND BLADE OF A GAS TURBINE
    • PATENT TITLE: METHOD AND APPARATUS FOR FABRICATION AND REPAIR OF THERMAL BARRIERS
    • PATENT TITLE: HIGH PURITY ZIRCONIA-BASED THERMALLY SPRAYED COATINGS AND PROCESSES FOR THE PREPARATION THEREOF
    • PATENT TITLE: THERMAL BARRIER COATING METHOD, MASKING PIN AND COMBUSTOR TRANSITION PIECE
    • PATENT TITLE: ARTICLE HAVING THERMAL BARRIER COATING
    • PATENT TITLE: THERMAL BARRIER COATING SYSTEMS AND PROCESSES THEREFOR
    • PATENT TITLE: TRI-BARRIER CERAMIC COATING
    • PATENT TITLE: PLASMA-SPRAY POWDER MANUFACTURE TECHNIQUE
    • PATENT TITLE: METHODS AND SYSTEMS FOR CONTROLLING THERMAL DIFFERENTIAL IN TURBINE SYSTEMS
    • PATENT TITLE: THERMAL BARRIER COATING METHOD, MASKING PIN AND COMBUSTOR TRANSITION PIECE
    • PATENT TITLE: METHOD FOR REFURBISHING PTAL COATING TO TURBINE HARDWARE REMOVED FROM SERVICE
    • PATENT TITLE: LASER DRILLING METHODS OF SHALLOW-ANGLED HOLES
    • PATENT TITLE: DAMAGE RESISTANT THERMAL BARRIER COATING AND METHOD
    • PATENT TITLE: METHODS AND SYSTEMS TO THERMALLY PROTECT FUEL NOZZLES IN COMBUSTION SYSTEMS
    • PATENT TITLE: HIGH-PURITY FUSED AND CRUSHED ZIRCONIA ALLOY POWDER AND METHOD OF PRODUCING SAME
    • PATENT TITLE: THERMAL BARRIER COATING MEMBER, METHOD FOR PRODUCING THE SAME, THERMAL BARRIER COATING MATERIAL, GAS TURBINE, AND SINTERED BODY
    • PATENT TITLE: LAYERED THERMAL BARRIER COATING WITH BLENDED TRANSITION AND METHOD OF APPLICATION
    • PATENT TITLE: OXIDE COATING FOUNDATION FOR PROMOTING TBC ADHERENCE
    • PATENT TITLE: THERMAL BARRIER COATING APPLICATION PROCESSES
    • PATENT TITLE: EROSION BARRIER FOR THERMAL BARRIER COATINGS
    • PATENT TITLE: APPLICATION OF DENSE VERTICALLY CRACKED AND POROUS THERMAL BARRIER COATING TO A GAS TURBINE COMPONENT
    • PATENT TITLE: LIFE MANAGEMENT SYSTEM AND METHOD FOR GAS TURBINE THERMAL BARRIER COATINGS
    • PATENT TITLE: METHOD FOR APPLYING A THERMAL BARRIER COATING
    • PATENT TITLE: MULTILAYER THERMAL BARRIER COATINGS
    • PATENT TITLE: HIGH-TEMPERATURE RESISTANT COMPONENT AND GAS TURBINE HOT PART
    • PATENT TITLE: METHOD FOR FORMING THERMAL BARRIER COATING ON HOT GAS-PATH COMPONENTS OF GAS TURBINE DURING OPERATION
    • PATENT TITLE: HIGH PURITY ZIRCONIA-BASED THERMALLY SPRAYED COATINGS
    • PATENT TITLE: METHODS AND APPARATUS FOR THERMAL BARRIER COATINGS WITH IMPROVED OVERALL THERMAL INSULATION CHARACTERISTICS
    • PATENT TITLE: SEGMENTED THERMAL BARRIER COATING
    • PATENT TITLE: METHODS FOR THE PROTECTION OF A THERMAL BARRIER COATING SYSTEM AND METHODS FOR THE RENEWAL OF SUCH A PROTECTION
    • PATENT TITLE: THERMAL BARRIER COATINGS AND ARTICLES MADE THEREFROM
    • PATENT TITLE: PROCESS FOR EXTENDING THE CYCLIC SERVICE LIFE OF THERMAL BARRIER COATINGS, IN PARTICULAR ON GAS TURBINE COMPONENTS
    • PATENT TITLE: PYROCHLORE MATERIALS AND A THERMAL BARRIER COATING WITH THESE PYROCHLORE MATERIALS

CHAPTER 8 - INDUSTRY STRUCTURE

  • COMPETITIVE LANDSCAPE AND KEY VENDORS
    • AIRCRAFT INDUSTRY
      • OEMs
      • Ceramic Coating Center SAS
        • MROs
        • Pratt & Whitney Global Material Solutions
        • Chromalloy
        • CTS Engines
        • MTU Repair Services
        • Lufthansa Technik AG
      • Manufacturers of PMA Parts for Aircraft Gas Turbines
    • POWER GENERATION INDUSTRY
      • OEMs
      • MROs
        • PW Power Systems Inc.
      • Mitsubishi Hitachi Power Systems
      • PMA Parts
        • Sulzer
  • MARINE DIESEL ENGINES
  • INDUSTRY DEVELOPMENTS
    • JOINT VENTURES
    • MERGERS AND ACQUISITIONS
      • TABLE 60: THERMAL BARRIER COATING COMPANY ACQUISITIONS AND MERGERS, 2011-2016
    • RECENT TBC COMPANY EXPANSIONS
      • TABLE 61: RECENT EXPANSIONS MADE BY THERMAL BARRIER COATING COMPANIES, 2011-2016

CHAPTER 9 - COMPANY PROFILES

  • OEM SUPPLIERS OF AIRCRAFT GAS TURBINES
    • CERAMIC COATING CENTER SAS
    • GE AVIATION
      • GE Aviation Plant 2
    • MTU AERO ENGINES AG
    • PRATT & WHITNEY
    • ROLLS-ROYCE CORP.
    • TURBOCOATING S.P.A.
  • OEM SUPPLIERS OF POWER GENERATION GAS TURBINES
    • ANSALDO ENERGIA
    • GENERAL ELECTRIC (SWITZERLAND) GMBH
    • MITSUBISHI HITACHI POWER SYSTEMS LTD. (MHPS)
    • SIEMENS INDUSTRIAL TURBOMACHINERY AB
    • SOLAR TURBINES INC.
    • TURBINE AIRFOIL COATING AND REPAIR GMBH (TACR GMBH)
    • U.S. Facility
    • TOSHIBA CORP.
  • MRO SERVICE PROVIDERS FOR AIRCRAFT GAS TURBINES
    • CTS ENGINES
    • LUFTHANSA TECHNIK AG
    • MTU MAINTENANCE HANNOVER GMBH
    • PRATT & WHITNEY GLOBAL SERVICE PARTNERS (GSP)
    • SNECMA AMERICA ENGINE SERVICES (SAMES)
    • SIA ENGINEERING CO. LTD. (SIAEC)
  • MRO PROVIDERS FOR POWER GENERATION GAS TURBINES
    • ALLIED POWER GROUP LLC
    • ETHOSENERGY
    • LIBURDI ENGINEERING
    • OERLIKON METCO AG
    • PW POWER SYSTEMS INC.
    • SULZER TURBO SERVICES HOUSTON INC.
    • SULZER TURBO SERVICES VENLO BV
  • MRO PROVIDERS FOR BOTH AIRCRAFT AND POWER GENERATION GAS TURBINES
    • MTU AEROENGINES AG
  • PMA PROVIDERS OF AIRCRAFT PARTS
    • BELAC LLC
    • CHROMALLOY
  • PMA PROVIDERS OF PARTS FOR POWER GENERATION GAS TURBINES
    • MAPNA TURBINE BLADE ENG. & MFG.-PARTO
    • PT. SULZER INDONESIA
  • INDEPENDENT TBC COATERS OF BOTH AIRCRAFT AND POWER GENERATION GAS TURBINES
    • BODYCOTE
    • CHROMALLOY
    • ELLISON SURFACE TECHNOLOGIES
    • FLAME SPRAY TECHNOLOGIES B.V.
    • JARVIS AIRFOIL INC.
    • PRAXAIR SURFACE TECHNOLOGIES GMBH
    • SWAIN TECH COATINGS INC.
    • MANUFACTURERS/SUPPLIERS OF TBC MATERIALS AND COATING EQUIPMENT
    • ALD VACUUM TECHNOLOGIES GMBH
    • BASF CATALYSTS LLC
    • ETS POWER GROUP INC.
    • H.C. STARCK GMBH
    • PROGRESSIVE SURFACE
    • RGE (RAJPUROHIT GROUP OF ENTERPRISES)
    • SAINT-GOBAIN CERAMIC MATERIALS GMBH
    • SANDVIK OSPREY LTD.
    • ZIRCOTEC LTD.

LIST OF TABLES

  • SUMMARY TABLE: GLOBAL MARKET FOR THERMAL BARRIER COATING TECHNOLOGIES BY APPLICATION INDUSTRY, THROUGH 2021 ($ MILLIONS)
    • TABLE 1: GLOBAL MARKET FOR THERMAL BARRIER COATINGS BY ARCHITECTURE, THROUGH 2021 ($ MILLIONS)
    • TABLE 3: GLOBAL MARKET FOR TBC TECHNOLOGIES BY APPLICATION INDUSTRY, THROUGH 2021 ($ MILLIONS)
    • TABLE 4: BASIS OF THE CALCULATION OF THE MARKET SIZE OF THERMAL BARRIER COATING APPLICATIONS IN AIRCRAFT GAS TURBINES, 2016 ($ MILLIONS)
    • TABLE 5: BASIS OF THE CALCULATION OF THE MARKET FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES, 2016 ($ MILLIONS)
    • TABLE 6: BASIS OF THE CALCULATION OF THE MARKET FOR THERMAL BARRIER COATING APPLICATIONS IN SPECIAL DIESEL ENGINES, 2016 ($ MILLIONS)
    • TABLE 7: GLOBAL MARKET FOR THERMAL BARRIER COATINGS BY DEPOSITION PROCESS, THROUGH 2021 ($ MILLIONS)
    • TABLE 8: GLOBAL MARKET FOR EB-PVD THERMAL BARRIER COATINGS BY APPLICATION INDUSTRY, THROUGH 2021 ($ MILLIONS)
    • TABLE 9: GLOBAL MARKET FOR LPPS THERMAL BARRIER COATINGS BY APPLICATION INDUSTRY, THROUGH 2021 ($ MILLIONS)
    • TABLE 10: GLOBAL MARKET FOR APS THERMAL BARRIER COATINGS BY APPLICATION INDUSTRY, THROUGH 2021 ($ MILLIONS)
    • TABLE 11: GLOBAL MARKET FOR HVOF THERMAL BARRIER COATINGS BY INDUSTRY APPLICATION, THROUGH 2021 ($ MILLIONS)
    • TABLE 12: GLOBAL MARKET FOR THERMAL BARRIER COATINGS IN AIRCRAFT GAS TURBINE APPLICATIONS BY TYPE OF PROVIDER, THROUGH 2021 ($ MILLIONS)
    • TABLE 13: REGIONAL MARKETS FOR THERMAL BARRIER COATINGS IN AIRCRAFT GAS TURBINE APPLICATIONS, THROUGH 2021 ($ MILLIONS)
    • TABLE 14: GLOBAL MARKET FOR THERMAL BARRIER COATINGS IN POWER GENERATION GAS TURBINE APPLICATIONS BY TYPE OF PROVIDER, THROUGH 2021 ($ MILLIONS)
    • TABLE 15: REGIONAL MARKETS FOR THERMAL BARRIER COATINGS IN POWER GENERATION GAS TURBINE APPLICATIONS, THROUGH 2021 ($ MILLIONS)
    • TABLE 16: GLOBAL MARKET FOR THERMAL BARRIER COATINGS IN MARINE DIESEL ENGINE APPLICATIONS BY TYPE OF PROVIDER, THROUGH 2021 ($ MILLIONS)
    • TABLE 17: REGIONAL MARKETS FOR THERMAL BARRIER COATINGS IN MARINE DIESEL ENGINE APPLICATIONS, THROUGH 2021 ($ MILLIONS)
    • TABLE 18: GLOBAL MARKET FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES BY FIRING TEMPERATURE, THROUGH 2021 ($ MILLIONS)
    • TABLE 19: REGIONAL MARKETS FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES WITH A FIRING TEMPERATURE 1,400<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 20: REGIONAL MARKETS FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES WITH A FIRING TEMPERATURE OF 1,350<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 21: REGIONAL MARKETS FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES WITH A FIRING TEMPERATURE OF 1,300<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 22: REGIONAL MARKETS FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES WITH A FIRING TEMPERATURE OF 1,250<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 23: REGIONAL MARKETS FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES WITH A FIRING TEMPERATURE OF 1,200<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 24: REGIONAL MARKETS FOR TBC APPLICATIONS IN AIRCRAFT GAS TURBINES WITH A FIRING TEMPERATURE BELOW 1,200<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 25: GLOBAL MARKET FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES BY FIRING TEMPERATURE, THROUGH 2021 ($ MILLIONS)
    • TABLE 26: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,800<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 27: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,750<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 28: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,700<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 29: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,650<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 30: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,600<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 31: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,550<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 32: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,500<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 33: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,450<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 34: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE OF 1,400<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 35: REGIONAL MARKETS FOR TBC APPLICATIONS IN POWER GENERATION GAS TURBINES WITH A FIRING TEMPERATURE BELOW 1,400<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 36: GLOBAL MARKET FOR TBC APPLICATIONS IN MARINE DIESEL ENGINES BY FIRING TEMPERATURE, THROUGH 2021 ($ MILLIONS)
    • TABLE 37: GLOBAL MARKET FOR TBC APPLICATIONS IN MARINE DIESEL ENGINE TURBINES WITH A FIRING TEMPERATURE OF 650<C THROUGH 2021 ($ MILLIONS)
    • TABLE 38: REGIONAL MARKETS FOR TBC APPLICATIONS IN MARINE DIESEL ENGINES WITH A FIRING TEMPERATURE OF 600<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 39: REGIONAL MARKETS FOR TBC APPLICATIONS IN MARINE DIESEL ENGINES WITH A FIRING TEMPERATURE OF 550<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 40: REGIONAL MARKETS FOR TBC APPLICATIONS IN MARINE DIESEL ENGINES WITH A FIRING TEMPERATURE OF 500<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 41: REGIONAL MARKETS FOR TBC APPLICATIONS IN MARINE DIESEL ENGINES WITH A FIRING TEMPERATURE BELOW 500<C, THROUGH 2021 ($ MILLIONS)
    • TABLE 42: COMMERCIAL MODELS/MAKES OF AERO ENGINE GAS TURBINES THAT REQUIRE THERMAL BARRIER COATINGS
    • TABLE 43: REPRESENTATIVE SAMPLE OF TBC SYSTEMS IN PRATT & WHITNEY GAS TURBINE ENGINES
    • TABLE 44: REPRESENTATIVE SAMPLE OF TBC ARCHITECTURES FOR AIRCRAFT TURBINE HOT SECTION COMPONENTS ADOPTED BY PRATT & WHITNEY
    • TABLE 45: TBC ARCHITECTURE OF AIRCRAFT GAS TURBINES ADOPTED BY NASA
    • TABLE 46: TBC ARCHITECTURE OF AIRCRAFT GAS TURBINES ADOPTED BY MTU GERMANY
    • TABLE 46: TBC ARCHITECTURE OF AIRCRAFT GAS TURBINES ADOPTED BY MTU GERMANY
    • TABLE 48: DESCRIPTIONS OF SULZER POWER GENERATION GAS TURBINE COMPONENTS EQUIVALENT TO SIEMENS AND GE MODELS
    • TABLE 49: REPRESENTATIVE SAMPLE OF TBC SYSTEMS IN GAS TURBINE ENGINES USED FOR POWER GENERATION AND INDUSTRIAL GAS TURBINES
    • TABLE 50: THERMAL BARRIER COATINGS ARCHITECTURE ADOPTED FOR GAS TURBINES WITH A FIRING TEMPERATURE OF 1,500<C ADOPTED BY MITSUBISHI HITACHI POWER SYSTEMS
    • TABLE 51: THERMAL BARRIER COATING ARCHITECTURE IN POWER GENERATION AND INDUSTRIAL GAS TURBINES ADOPTED BY SIEMENS INDUSTRIAL TURBOMACHINERY AB
    • TABLE 52: TBC ARCHITECTURE FOR GAS TURBINES WITH A FIRING TEMPERATURE OF 1,600<C ADOPTED BY MITSUBISHI HEAVY CORP. AND MITSUBISHI HITACHI POWER CORP
    • TABLE 53: TBC ARCHITECTURE ADOPTED BY FORSCHUNGSZENTRUM JULICH GMBH GERMANY FOR GAS TURBINES* WITH A FIRING TEMPERATURE OF 1,600<C
    • TABLE 54: TBC ARCHITECTURE ADOPTED IN DIESEL ENGINES FOR MARINE APPLICATIONS
    • TABLE 55: APPLICATION OF CURRENT TBC SYSTEMS DIESEL ENGINES FOR MARINE AND OTHER APPLICATIONS (PEAK TEMPERATURE MAX 600<C)
    • TABLE 56: OPERATING TEMPERATURE AND STRESS STATE COMPARISON BETWEEN DIESEL ENGINE AND TURBINE (<C/%)
    • TABLE 57: U.S. PATENTS GRANTED FOR TBC TECHNOLOGY, JAN. 2012 TO JULY 2016 (NO.)
    • TABLE 58: U.S. TBC TECHNOLOGY PATENTS BY ASSIGNEE COUNTRY, JAN. 2012 TO JULY 2016 (NO.)
    • TABLE 59: TOP U.S. TBC TECHNOLOGY PATENT HOLDERS, JAN. 2012 TO JULY 2016 (NO.)
    • TABLE 60: THERMAL BARRIER COATING COMPANY ACQUISITIONS AND MERGERS, 2011-2016
    • TABLE 61: RECENT EXPANSIONS MADE BY THERMAL BARRIER COATING COMPANIES, 2011-2016

LIST OF FIGURES

  • SUMMARY FIGURE: GLOBAL MARKET FOR THERMAL BARRIER COATING TECHNOLOGIES BY APPLICATION INDUSTRY, 2015-2021 ($ MILLIONS)
    • FIGURE 1: GLOBAL MARKET SHARE FOR THERMAL BARRIER COATINGS BY ARCHITECTURE, 2016 AND 2021 (%)
    • FIGURE 2: GLOBAL MARKET SHARE FOR TBC TECHNOLOGIES BY APPLICATION INDUSTRY, 2016 AND 2021 (%)
    • FIGURE 3: GLOBAL MARKET SHARE FOR THERMAL BARRIER COATING BY DEPOSITION PROCESS, 2016 AND 2021 (%)
    • FIGURE 4: GLOBAL MARKET SHARE FOR TBC IN AIRCRAFT GAS TURBINE APPLICATIONS BY TYPE OF PROVIDER, 2016 AND 2021 (%)
    • FIGURE 5: REGIONAL MARKETS FOR THERMAL BARRIER COATINGS IN AIRCRAFT GAS TURBINE APPLICATIONS, 2016 AND 2021 (%)
    • FIGURE 6: GLOBAL MARKET FOR THERMAL BARRIER COATINGS IN POWER GENERATION GAS TURBINE APPLICATIONS BY TYPE OF PROVIDER, 2016 AND 2021 (%)
    • FIGURE 7: REGIONAL MARKETS FOR THERMAL BARRIER COATINGS IN POWER GENERATION GAS TURBINE APPLICATIONS, 2016 AND 2021 (%)
    • FIGURE 8: REGIONAL MARKETS FOR THERMAL BARRIER COATINGS IN MARINE DIESEL ENGINE APPLICATIONS, 2016 AND 2021 (%)
    • FIGURE 9: EVOLUTION OF ALLOWABLE GAS TEMPERATURE AT THE ENTRY TO THE GAS TURBINE
    • FIGURE 10: COMBUSTION LINER WITH SIX NOZZLES*
    • FIGURE 11: TRANSITION PIECE*
    • FIGURE 12: VANES OR NOZZLES*
    • FIGURE 13: HEAVY DUTY INDUSTRIAL BLADE
    • FIGURE 14: AERODERIVATIVE BLADE OR BUCKET
    • FIGURE 15: AIR PLASMA SPRAYING
    • FIGURE 16: HIGH VELOCITY OXYGEN FUEL
    • FIGURE 17: APPROXIMATE REGIMES OF HIGH TEMPERATURE ENVIRONMENTAL ATTACK
    • FIGURE 18: HIGH TEMPERATURE COATING PROTECTION OF THE BASE METAL
    • FIGURE 19: GAS ENGINE SHOWING DIFFERENT SECTIONS ALONG THE ENGINE WITH CORRESPONDING PRESSURE AND TEMPERATURE PROFILES
    • FIGURE 20: EXAMPLE OF A CROSS-SECTIONAL IMAGE OF A TBC SYSTEM ON AN AERO TURBINE BLADE
    • FIGURE 21: MUTILAYER TBCS USED IN THE HOT SECTIONS OF IGCC OR GAS TURBINE GTCC TURBINES IN THE POWER GENERATION INDUSTRY
    • FIGURE 22: LIFETIME IMPROVEMENTS WITH THE USE OF THERMAL BARRIER COATINGS IN CYCLIC DIESEL ENGINE TESTS
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