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市場調查報告書

環境與能源應用的催化劑

Catalysts for Environmental and Energy Applications

出版商 BCC Research
出版日期 2010年06月 商品編碼 124287
內容資訊 英文 190 Pages
價格
US $ 4850 PDF by E-mail ( Single User License)
US $ 5950 PDF by E-mail (Business Unit License)
US $ 8500 PDF by E-mail (Enterprise License)


環境與能源應用的催化劑 是由出版商BCC Research在2010年06月所出版的。 這份英文市場調查報告書包含190 Pages 價格從美金4850起跳。

簡介

本報告針對用於環境及能源領域中的催化劑市場進行調查分析,在環境及能源領域中催化劑的使用現況、應用、主要趨勢、到2015年為止的市場成長預測、影響需求因子、技術開發動態、主要企業的市佔率、主要企業簡介等內容,亦一同整理摘記如下。

第1章 前言

第2章 實施概要

第3章 摘要

  • 定義
  • 歷史性的里程碑
  • 催化劑的普遍爭議與挑戰
  • 市場區隔

第4章 催化劑於能源領域的使用

  • 製造初級能源
    • 合成燃料
    • 生物性燃料
    • 太陽能發電
    • 提煉/回收
    • 能源轉換

第5章 催化劑於環境保護中的使用

  • 綠色加工
    • 製造化學品
    • 纖維
    • 紡織品、造紙
    • 食品加工
  • 產業廢棄物處理的改善
    • 概要
  • 都市廢棄物的處理
    • 固體廢棄物
    • 廢水
  • 大氣的固定污染源
    • 概要
  • 大氣的移動污染源
    • 汽車排放廢氣
    • 非道路使用機具引擎

第6章 全球市場:2009-2015年

  • 摘要
  • 各領域、市場區隔、終端用戶產業市場

第7章 產業結構

  • 市佔率
    • 能源催化劑
    • 環境催化劑

第8章 企業簡介

圖表

目錄

Abstract

  • The global market for energy and environmental catalysts was worth an estimated $15.1 billion in 2009. The market is projected to grow to more than $16.3 billion in 2010 and nearly $22.5 billion in 2015 at a compound annual growth rate (CAGR) of 6.6% from 2010 to 2015.
  • Energy catalyst sales will experience the highest compound annual growth rate (CAGR) over the forecast period of 8.1%. This sector is worth $4 billion in 2010 and is expected to reach nearly $6 billion in 2015.
  • The total market for environmental catalysts is projected to grow from $12.3 billion in 2010 to $16.5 billion in 2015, a compound annual growth rate (CAGR) of 6%. The two fastest-growing segments of the environmental catalyst market are catalysts used in municipal waste treatment and the remediation of stationary source air pollution.

INTRODUCTION

STUDY BACKGROUND

This report is an update of an earlier BCC report published in 2007. Meeting rising energy requirements and protecting the environment are among the most important applications of catalyst technology. Broadly speaking, a catalyst is a substance that increases the rate of a chemical reaction by reducing the required activation energy, but which is left unchanged by the reaction.

The petroleum industry is the largest single user of catalysts, especially in producing refined products such as gasoline and diesel fuel. Catalysts also contribute to increasing the supply of petroleum by making it commercially possible to produce oil from sources once regarded as uneconomical, such as tar sands and heavy oil deposits. Catalysts are also being used to produce increasing quantities of synthetic oil and gas from coal and oil shale.

In addition to increasing supplies of naturally occurring and synthetic oil and gas, catalysts are in the forefront of technologies such as fuel cells and photovoltaic cells being developed to replace conventional fossil fuels. Catalysts also indirectly contribute to increasing energy supplies by increasing the efficiency with which hydrocarbon and other fuels are utilized.

Energy consumption is a major source of pollution (e.g., auto and industrial emissions), along with other waste-generating activities. Many people consider the prevention of global warming and other forms of environmental degradation to be a greater priority than increasing energy supplies.

Catalysts are indispensable to many types of environmental remediation, from vehicle emissions control systems to industrial effluent and municipal waste treatment. Catalysts also contribute indirectly to reducing pollution and other adverse environmental impacts, for example, through cleaner-burning fuels and the production of products such as refrigerants that pollute less than the substances they replace.

REPORT GOALS AND OBJECTIVES

The goal of this report is to provide the reader with an up-to-date understanding of how catalysts contribute to meeting the energy needs of the U.S. and world economies while helping to prevent environmental degradation and remediating adverse environmental impacts as they occur. Specific objectives include the following:

  • Characterizing the current energy and environmental catalyst market in quantitative as well as qualitative terms.
  • Identifying segments of the energy and environmental markets with the greatest commercial potential in the near to mid-term (2010 to 2015).
  • Identifying and, where possible, quantifying the major demand drivers of energy and environmental catalysts.
  • Describing existing and new catalyst technologies under development to meet market requirements.
  • Projecting future demand for different types of energy and environmental catalysts.
  • Evaluating the technical and other challenges that must be overcome for the market to realize its full potential.

INTENDED AUDIENCE

This report is intended especially for manufacturers and vendors of catalysts used in energy and environmental applications. Other readers who should find the report particularly useful include entrepreneurs, investors, venture capitalists, and other readers with a need to know where these key segments of the catalyst market are headed over the next 5 years.

This report should also be of interest to end users such as motor vehicle manufacturers, whose technology road maps may make critical assumptions about the availability and performance of different types of catalysts. The same is true of government agencies and officials responsible for monitoring energy production, consumption, and pollution levels.

Other readers who should find the report particularly useful include members of technical and professional organizations such as the American Chemical Society. Finally, the report' s findings and conclusions should also be of interest to the nanotechnology community, including government nanotechnology programs such as the U.S. National Nanotechnology Initiative, inasmuch as many of the most promising energy and environmental catalysts are nanocatalysts.

SCOPE OF REPORT

This report addresses the global market for energy and environmental catalysts, including catalysts used in the following:

  • Production of crude oil and gas from nonconventional sources such as tar sands and heavy oil reservoirs
  • Synfuels production (e.g., coal liquefaction/gasification, shale oil)
  • Oil recycling
  • Alternative fuels production (e.g., hydrogen)
  • Other emerging energy technologies such as fuel cells and photovoltaic cells
  • Increasing fuel efficiency (e.g., fuel additives that increase burn efficiency)
  • Avoiding or reducing environmental damage
  • Mitigating or remediating adverse environmental impacts after they occur.
  • This report also covers the market for catalysts used in petroleum refining. However, the market for refinery catalysts is covered in less detail because it is already analyzed in a separate BCC report, CHM027C - Petrochemical (Petroleum and Chemical) Catalysts.

The study is organized around the following major topics:

  • Executive Summary
  • Overview (definitions, history, market segmentation)
  • Characteristics of energy and environmental catalysts (existing as well as under development)
  • Current and potential catalyst applications in energy and environment
  • Patent analysis
  • Global market trends from 2009 to 2015
  • Factors that will influence the long-term development of the market
  • Industry structure and market shares.

METHODOLOGY AND INFORMATION SOURCES

The findings and conclusions of this report are based on information gathered from a cross-section of catalyst developers, manufacturers, distributors, end users, and other informed sources. Interview data were combined with information gathered through an extensive review of secondary sources, such as trade publications, trade associations, company literature, and online databases, to produce the baseline market estimates contained in this report.

With 2009 as a baseline, market projections for each market segment were developed for 2010 to 2015. The projections are based on a combination of a consensus among the primary contacts combined with our understanding of the key market drivers and their impact from a historical and analytical perspective. The analytical methodologies used to generate the market estimates are described in detail in the section on Detailed Market Projections.

All dollar projections presented in this report are in 2009 constant dollars.

Table of Contents

Chapter- 1: INTRODUCTION -- Complimentary 5

  • STUDY BACKGROUND 1
  • REPORT GOALS AND OBJECTIVES 1
  • INTENDED AUDIENCE 2
  • SCOPE OF REPORT 2
  • METHODOLOGY AND INFORMATION SOURCES 3
  • ANALYST CREDENTIALS 4
  • RELATED BCC RESEARCH REPORTS 4
  • BCC ONLINE SERVICES 5
  • DISCLAIMER 5

Chapter-2: EXECUTIVE SUMMARY 2

  • SUMMARY TABLE GLOBAL FORECAST FOR ENERGY AND ENVIRONMENTAL CATALYST MARKET, THROUGH 2015 ($ MILLIONS) 6
  • SUMMARY FIGURE GLOBAL FORECAST FOR ENERGY AND ENVIRONMENTAL CATALYST MARKET, 2009-2015 ($ MILLIONS) 6
  • EXECUTIVE SUMMARY (CONTINUED) 7

Chapter-3: OVERVIEW 6

  • DEFINITION 8
  • HISTORICAL MILESTONES 8
  • HISTORICAL MILESTONES (CONTINUED) 9
  • HISTORICAL MILESTONES (CONTINUED) 10
  • GENERAL ISSUES AND CHALLENGES IN CATALYSIS 11
  • MARKET SEGMENTATION 11
  • MARKET SEGMENTATION (CONTINUED) 12
  • MARKET SEGMENTATION (CONTINUED) 13

Chapter-4: CATALYST APPLICATIONS IN ENERGY 66

  • PRIMARY ENERGY PRODUCTION 14
  • SYNFUELS 14
  • Coal/Natural Gas Liquefaction 14
  • Description 14
  • Description (Continued) 15
  • Technologies 16
  • Direct Coal Liquefaction 16
  • Indirect Processes 17
  • Fischer-Tropsch Process 17
  • FIGURE 1 FISCHER-TROPSCH PROCESS FLOW DIAGRAM 18
  • Sasol Process 18
  • ExxonMobil AGC-21 (Advanced Gas Conversion for the 21st Century) 19
  • Syntroleum Air Blown Autothermal Process 19
  • Syntroleum ...(Continued) 20
  • British Petroleum Co. Compact Steam Reformer 21
  • Rentech Process 21
  • Shell Middle Distillate Process 22
  • Statoil Cobalt Catalyst/Slurry Bubble Column Reactor 23
  • Velocys' Microchannel Reactor 23
  • Micro-GTL 24
  • Other Developments 24
  • Catalysts 25
  • Coal Liquefaction Catalysts 25
  • Gas-to-Liquids Catalysts 25
  • Syngas Catalysts 25
  • Fischer-Tropsch Catalysts 26
  • TABLE 1 FISCHER-TROPSCH CATALYSTS USED IN VARIOUS PROCESSES BY COMPANY 27
  • Fischer-... (Continued) 28
  • TABLE 2 FISCHER-TROPSCH CATALYST SUPPLIERS 29
  • Recent Developments in GTL Catalysis 29
  • Patent Analysis 29
  • FIGURE 2 U.S. PATENTS RELATED TO FISCHER-TROPSCH (% OF PATENTS ISSUED THROUGH APRIL 25, 2010) 30
  • Oil Shale 31
  • Description 31
  • Technological Developments 31
  • Oil Shale Catalysis 32
  • Patent Analysis 33
  • FIGURE 3 U.S. PATENTS RELATED TO OIL SHALE CATALYSTS BY COMPANY (% OF PATENTS ISSUED THROUGH APRIL 25, 2010) 33
  • Methanol 34
  • Description 34
  • Methanol Production Technology 35
  • Current Technology 35
  • Technologies under Development 36
  • Biomass-Based Methanol Production 37
  • Producing Methanol from Landfill Gas 38
  • Producing Methanol from Atmospheric CO2 38
  • Methanol Catalysis 39
  • Syngas Production 39
  • Syngas Decontamination 39
  • Methanol Production 39
  • Patent Analysis 40
  • BIOFUELS 40
  • Biodiesel 40
  • Description 40
  • Technological Developments 41
  • Biomass Catalysis 41
  • Patent Analysis 42
  • Ethanol 42
  • Description 42
  • Technological Developments 43
  • Fermentation Ethanol 43
  • FIGURE 4 FERMENTATION ETHANOL FEEDSTOCKS 2009 (% OF GLOBAL ETHANOL PRODUCTION) 44
  • Cellulosic Ethanol 45
  • Cellulosic ... (Continued) 46
  • Ethanol Catalysis 47
  • Ethanol Catalysis 48
  • Patent Analysis 49
  • PHOTOVOLTAIC CELLS 49
  • Description 49
  • Technological Developments 50
  • FIGURE 5 DYE-SENSITIZED SOLAR CELL 51
  • Catalysis 51
  • Patent Analysis 51
  • HYDROGEN 52
  • Description 52
  • Technological Developments 52
  • Thermal Processes 52
  • Steam Reformation of Natural Gas 52
  • Partial Oxidation 53
  • Thermal Partial Oxidation 54
  • Catalytic Partial Oxidation 54
  • Autothermal Reforming 55
  • Reforming Renewable Liquid Fuels 55
  • Electrolytic Processes 56
  • Electrolysis of Methanol 56
  • Photolytic Processes 57
  • Photoelectrochemical Water Splitting 57
  • Catalysis 57
  • Reforming Catalysts 57
  • Partial Oxidation Catalysts 58
  • Autothermal Reforming Catalysts 58
  • Methanol Electrolysis Catalysts 58
  • Photocatalysts 59
  • Patents 60
  • REFINING/RECYCLING 60
  • Description 60
  • Technology 61
  • Fluid Cracking 61
  • Hydrocracking 61
  • Hydrotreating 62
  • Alkylation 62
  • Isomerization 63
  • Catalytic Reforming 64
  • Catalysis 64
  • TABLE 3 MAJOR REFINING CATALYSTS 64
  • FCC Catalysts 64
  • Hydrocracking Catalysts 65
  • Hydroprocessing Catalysts 66
  • Alkylation Catalysts 66
  • Isomerization Catalysts 67
  • Catalytic Reforming Catalysts 67
  • Refining Catalyst Manufacturers 67
  • TABLE 4 REFINERY CATALYST MANUFACTURERS 68
  • Patents 68
  • FIGURE 6 U.S. PATENTS RELATED TO REFINING CATALYSTS BY TYPE OF PROCESS (PERCENT OF PATENTS ISSUED THROUGH APRIL 25, 2010) 68
  • FIGURE 6 (CONTINUED) 69
  • FIGURE 7 U.S. PATENTS RELATED TO REFINING CATALYSTS BY ASSIGNEE (PERCENT BY ASSIGNEE) 69
  • FIGURE 7 (CONTINUED) 70
  • ENERGY CONVERSION 70
  • Fuel Cells 70
  • Description 70
  • FIGURE 8 FUEL CELL PRINCIPLES 71
  • Technological Developments 71
  • Phosphoric Acid Fuel Cells 71
  • Polymer Electrolyte Membrane Fuel Cells 72
  • Molten Carbonate Fuel Cells 73
  • Solid Oxide Fuel Cells

Chapter-5: CATALYST APPLICATIONS IN ENVIRONMENTAL PROTECTION 34

  • GREEN PROCESSING 80
  • TABLE 6 GREEN PROCESSING CATALYST APPLICATIONS 81
  • CHEMICAL PRODUCTION 81
  • Description 81
  • Technologies 82
  • Catalysis 83
  • Solid Acid Catalysts 83
  • Biocatalysts 84
  • Patents 84
  • FIGURE 10 U.S. PATENTS RELATED TO SOLID ACID CATALYSTS (PERCENT ISSUED THROUGH APRIL 25, 2010) 85
  • TEXTILES 85
  • Description 85
  • Technology 86
  • Bioscouring 86
  • Biopolishing 86
  • Biostoning 86
  • Catalysis 86
  • Patents 87
  • FIGURE 11 U.S. PATENTS RELATED TO TEXTILE CATALYSTS (PERCENT ISSUED THROUGH APRIL 25, 2010) 87
  • FIGURE 11 (CONTINUED) 88
  • PULP AND PAPER MANUFACTURING 88
  • Description 88
  • Technology 88
  • Catalysis 89
  • Patent Analysis 89
  • FIGURE 12 U.S. PATENT RELATED TO PULP AND PAPER CATALYSTS (PERCENT ISSUED THROUGH APRIL 25, 2010) 90
  • FOOD PROCESSING 90
  • Description 90
  • Technology 91
  • Catalysis 91
  • Patent Analysis 91
  • INDUSTRIAL PROCESS WASTE REMEDIATION 91
  • DESCRIPTION 91
  • Technology 92
  • Oxidation 92
  • Catalytic Wet Air Oxidation 92
  • Photocatalytic Oxidation 93
  • Bioremediation 93
  • Catalysis 93
  • Chemical Oxidation Catalysts 93
  • TABLE 7 CATALYSTS USED IN CATALYTIC WET AIR OXIDATION OF INDUSTRIAL WASTE 94
  • Photocatalysts 94
  • Enzymes for Industrial Waste Remediation 94
  • Patent Analysis 94
  • MUNICIPAL WASTE TREATMENT 95
  • SOLID WASTES 95
  • Description 95
  • Technologies 95
  • Recycling 95
  • Plastics Recycling 96
  • Fuel Production from Recycled Plastics 96
  • Landfill 97
  • Precombustion Treatment 98
  • Post-Combustion Treatment 98
  • Incineration 98
  • Selective Catalytic Reduction 99
  • Catalytic Oxidation 99
  • Catalysis 99
  • Conversion of Plastic and Other Wastes to Fuel 99
  • Treatment of Landfill Gases 99
  • Incineration 100
  • Patent Analysis 100
  • WASTEWATER 100
  • Description 100
  • Technologies 101
  • Increasing Effectiveness of Secondary Treatment 101
  • Biogas Scrubbing 101
  • Photo-Oxidation of Wastewater 102
  • Catalysis 102
  • Increasing Effectiveness of Secondary Treatment 102
  • Digester Biogas Scrubbing 103
  • Photo-Oxidation of Wastewater 103
  • Patent Analysis 103
  • STATIONARY SOURCE AIR POLLUTION 103
  • DESCRIPTION 103
  • Technology 104
  • Catalysis 104
  • Patent Analysis 105
  • FIGURE 13 U.S. PATENTS RELATED TO SCR CATALYSTS (PERCENT ISSUED THROUGH APRIL 25, 2010) 105
  • MOBILE-SOURCE AIR POLLUTION 105
  • VEHICLE EMISSIONS 106
  • Description 106
  • Technology 106
  • Catalytic Converter Technology 106
  • Advanced Vehicle Emissions Control Systems 106
  • Advanced ... (Continued) 107
  • Catalysis 108
  • Catalytic Converters 108
  • Three-Way Catalytic Converters 108
  • Two-Way (Diesel) Catalytic Converters 109
  • Diesel NOx Emission Control Systems 109
  • Selective Catalytic Reduction 109
  • Lean NOX Catalyst Technology 109
  • Lean NOX ... (Continued) 110
  • Patent Analysis 111
  • FIGURE 14 U.S. PATENTS RELATED TO CATALYTIC CONVERTER CATALYSTS (PERCENT ISSUED THROUGH APRIL 25, 2010) 111
  • NON-ROAD ENGINES 112
  • Description 112
  • Technological Developments 113
  • Catalysis 113
  • Patent Analysis 113

Chapter-6: GLOBAL MARKET FOR ENERGY AND ENVIRONMENTAL CATALYSTS 2009 - 2015 59

  • SUMMARY 114
  • TABLE 8 GLOBAL ENERGY AND ENVIRONMENTAL CATALYST MARKET, THROUGH 2015 ($ MILLIONS) 114
  • FIGURE 15 TRENDS IN THE GLOBAL ENERGY AND ENVIRONMENTAL CATALYST MARKET, 2009 - 2015 ($ MILLIONS) 115
  • FIGURE 16 ENERGY VS. ENVIRONMENTAL CATALYST GLOBAL MARKET SHARES, 2009 VS. 2015 (PERCENT OF TOTAL) 116
  • MARKET BY SECTOR, SEGMENT, AND USER INDUSTRY 116
  • ENERGY SECTOR 117
  • TABLE 9 GLOBAL FORECAST FOR ENERGY CATALYST CONSUMPTION BY SEGMENT, THROUGH 2015 ($ MILLIONS) 117
  • FIGURE 17 GLOBAL MARKET SHARES OF ENERGY CATALYSTS BY SEGMENT, 2009 VS. 2015 (PERCENT OF TOTAL MARKET) 118
  • Primary Energy Segment 118
  • TABLE 10 GLOBAL FORECAST FOR PRIMARY ENERGY SECTOR CATALYST CONSUMPTION BY SEGMENT, THROUGH 2015 ($ MILLIONS) 119
  • FIGURE 18 GLOBAL MARKET SHARES OF PRIMARY ENERGY CATALYSTS, 2009 VS. 2015 (PERCENT OF TOTAL MARKET) 120
  • Synfuels Subsegment 120
  • TABLE 11 GLOBAL FORECAST FOR SYNFUELS SEGMENT CATALYST CONSUMPTION BY INDUSTRY, THROUGH 2015 ($ MILLIONS) 121
  • Direct Coal-to-Liquid 121
  • TABLE 12 GLOBAL FORECAST FOR DIRECT CTL CATALYST CONSUMPTION, THROUGH 2015 ($ MILLIONS) 122
  • Gas-to-Liquid (GTL) Fuel Production 122
  • TABLE 13 GLOBAL FORECAST FOR GTL CATALYST CONSUMPTION, THROUGH 2015 ($ MILLIONS) 122
  • Shale Oil 123
  • Methanol 124
  • TABLE 14 GLOBAL PRODUCTION OF METHANOL VS. PRODUCTION FOR FUEL PURPOSES, THROUGH 2015 (MILLION TONS) 124
  • FIGURE 19 GLOBAL TRENDS IN METHANOL PRODUCTION, 2009 - 2015 (MILLION METRIC TONS) 125
  • TABLE 15 METHANOL PRODUCTION CATALYST REQUIREMENTS 126
  • TABLE 16 GLOBAL FORECAST FOR FUEL-RELATED METHANOL CATALYST CONSUMPTION, THROUGH 2015 126
  • Biofuels 127
  • TABLE 17 GLOBAL FORECAST FOR BIOFUELS SEGMENT CATALYST CONSUMPTION BY INDUSTRY, THROUGH 2015 ($ MILLIONS) 127
  • Biodiesel 127
  • TABLE 18 GLOBAL BIODIESEL PRODUCTION, THROUGH 2015 (MILLION METRIC TONS) 127
  • FIGURE 20 GLOBAL TRENDS IN BIODIESEL PRODUCTION, 2009 - 2015 (MILLION METRIC TONS) 128
  • TABLE 19 GLOBAL CATALYST CONSUMPTION IN BIODIESEL PRODUCTION, 2009 - 2015 ($ MILLIONS/MILLION METRIC TONS) 129
  • Ethanol Production 129
  • TABLE 20 WORLD OUTPUT OF ETHANOL FROM CORN AND GRAIN (MILLION METRIC TONS) 130
  • FIGURE 21 TRENDS IN WORLD OUTPUT OF FUEL ETHANOL PRODUCED VIA CATALYTIC PROCESSES, 2009 - 2015 (MILLION METRIC TONS) 130
  • TABLE 21 GLOBAL ENZYME CATALYST CONSUMPTION IN FUEL ETHANOL PRODUCTION, THROUGH 2015 ($ MILLIONS) 131
  • Hydrogen 131
  • TABLE 22 GLOBAL CONSUMPTION OF CATALYSTS USED TO PRODUCE HYDROGEN FOR ENERGY APPLICATIONS, THROUGH 2015 ($ MILLIONS) 132
  • Centralized Production 132
  • FIGURE 22 GLOBAL MARKET FOR CATALYSTS USED TO PRODUCE HYDROGEN FOR ENERGY APPLICATIONS, 2009 (PERCENT OF CONSUMPTION) 132
  • FIGURE 22 (CONTINUED) 133
  • Existing Hydrogen Plants 133
  • New Construction 133
  • TABLE 23 GLOBAL FORECAST FOR CATALYST CONSUMPTION FOR CENTRALIZED PRODUCTION OF HYDROGEN, 2009 - 2015 ($ MILLIONS) 134
  • Decentralized Production 135
  • TABLE 24 GLOBAL CATALYST CONSUMPTION IN EXTERNAL FUEL CELL EXTERNAL REFORMERS, THROUGH 2015 ($ MILLIONS) 135
  • Solar Cells 136
  • TABLE 25 GLOBAL PROJECTED CONSUMPTION OF DSSC CATALYSTS, THROUGH 2015 ($ MILLIONS) 136
  • Refining Segment 137
  • Historical Catalyst Consumption 137
  • FIGURE 23 GLOBAL REFINERY CATALYST CONSUMPTION, 2009 (%) 137
  • Market Drivers 138
  • Macroeconomic Trends 138
  • TABLE 26 GLOBAL ECONOMIC OUTLOOK (PERCENT OF ANNUAL CHANGE) 139
  • Regulatory Trends 139
  • Other Market Drivers 139
  • TABLE 27 GLOBAL FORECAST FOR REFINERY CATALYST DEMAND, THROUGH 2015 ($ MILLIONS) 140
  • Energy Conversion Sector 141
  • Fuel Cells 141
  • FIGURE 24 GLOBAL FUEL CELL SALES BY TECHNOLOGY TYPE, 2009 (PERCENT OF GLOBAL SALES) 142
  • TABLE 28 GLOBAL FUEL CELL CATALYST CONSUMPTION, 2009 ($ MILLIONS) 143
  • TABLE 29 GLOBAL FUEL CELL SALES BY TECHNOLOGY TYPE, THROUGH 2015 ($ MILLIONS) 143
  • TABLE 30 PROJECTED GLOBAL MARKET FOR FUEL CELL CATALYSTS, THROUGH 2015 ($ MILLIONS) 144
  • TABLE 31 GLOBAL FUEL CELL CONSUMPTION OF PLATINUM CATALYSTS, THROUGH 2015 ($ MILLIONS) 144
  • TABLE 32 GLOBAL FUEL CELL CONSUMPTION OF NONPRECIOUS METAL CATALYSTS, THROUGH 2015 ($ MILLIONS) 145
  • ENVIRONMENTAL SECTOR 145
  • TABLE 33 GLOBAL ENVIRONMENTAL CATALYST CONSUMPTION BY SEGMENT, THROUGH 2015 ($ MILLIONS) 146
  • FIGURE 25 GLOBAL ENVIRONMENTAL CATALYST MARKET SHARES BY SEGMENT, 2009 VS. 2015 (%) 147
  • Green Processing Segment 147
  • TABLE 34 GLOBAL FORECAST FOR GREEN PROCESSING CATALYST CONSUMPTION BY SUBSEGMENT, THROUGH 2015 ($ MILLIONS) 148
  • Chemicals 148
  • Historical Catalyst Consumption 148
  • Historical (Continued) 149
  • TABLE 35 GLOBAL FORECAST FOR CATALYST CONSUMPTION IN GREEN CHEMICAL PRODUCTION, THROUGH 2015 ($ MILLIONS) 150
  • Textile Processing 150
  • Historical Catalyst Consumption 150
  • TABLE 36 GLOBAL FORECAST FOR CATALYST CONSUMPTION IN GREEN PROCESSING OF TEXTILES, THROUGH 2015 ($ MILLIONS) 150
  • Paper and Pulp Manufacturing 151
  • Historical Catalyst Consumption 151
  • TABLE 37 GLOBAL FORECAST FOR CATALYST CONSUMPTION IN GREEN PROCESSING OF PULP AND PAPER PRODUCTS, THROUGH 2015 ($ MILLIONS) 151
  • Food Processing 151
  • TABLE 38 GLOBAL FORECAST FOR CATALYST CONSUMPTION IN GREEN PROCESSING OF FOOD PRODUCTS, THROUGH 2015 ($ MILLIONS) 152
  • Industrial Process Waste Segment 152
  • TABLE 39 GLOBAL FORECAST FOR CATALYST CONSUMPTION IN INDUSTRIAL WASTE REMEDIATION, THROUGH 2015 ($ MILLIONS) 153
  • Municipal Waste Treatment Segment 153
  • TABLE 40 GLOBAL FORECAST FOR MUNICIPAL WASTE TREATMENT CATALYST CONSUMPTION BY SUB-SEGMENT, THROUGH 2015 ($ MILLIONS) 153
  • Municipal Solid Wastes 153
  • TABLE 41 GLOBAL FORECAST FOR MSW CATALYST CONSUMPTION BY APPLICATION, THROUGH 2015 ($ MILLIONS) 154
  • Fuel Production from Recycled Plastics 154
  • TABLE 42 GLOBAL PRODUCTION OF DIESEL FUEL FROM RECYCLED PLASTICS, THROUGH 2015 (MILLION LITERS) 155
  • TABLE 43 GLOBAL CONSUMPTION OF CATALYST FOR RECYCLING PLASTIC WASTES, THROUGH 2015 ($ MILLIONS) 156
  • Landfill Gas Amelioration 156
  • TABLE 44 GLOBAL ESTIMATED LFGTE PLANT DESULFURIZATION CATALYST CONSUMPTION ($) 156
  • TABLE 45 GLOBAL CONSUMPTION OF CATALYST FOR DESULFURIZING LANDFILL GAS, THROUGH 2015 ($ MILLIONS) 157
  • Incinerator Emissions Cleanup 157
  • FIGURE 26 GLOBAL MUNICIPAL WASTE INCINERATOR POPULATION*, 2009 (%) 158
  • TABLE 46 GLOBAL TRENDS IN THE NUMBER OF MUNICIPAL WASTE INCINERATORS, THROUGH 2015 (NO. OF INCINERATORS) 159
  • TABLE 47 GLOBAL FORECAST FOR MSW INCINERATOR CATALYST CONSUMPTION FOR NOX EMISSIONS CONTROL, THROUGH 2015 160
  • Wastewater Treatment 160
  • TABLE 48 GLOBAL FORECAST FOR WASTEWATER TREATMENT CATALYST CONSUMPTION BY APPLICATION, THROUGH 2015 ($ MILLIONS) 160
  • Catalysts to Enhance Secondary Treatment 161
  • TABLE 49 GLOBAL FORECAST FOR CONSUMPTION OF CATALYST FOR INCREASING SECONDARY TREATMENT EFFECTIVENESS, THROUGH 2015 ($ MILLIONS) 161
  • Catalysts Used in Biogas Scrubbing 161
  • TABLE 50 GLOBAL FORECAST FOR CONSUMPTION OF CATALYST FOR DESULFURIZING LANDFILL GAS, THROUGH 2015 (NO./$ MILLIONS) 162
  • Photo-Oxidation Catalysts 162
  • TABLE 51 PHOTOCATALYST CONSUMPTION FOR WASTEWATER SECONDARY TREATMENT, THROUGH 2015 ($ MILLIONS) 163
  • Stationary Source Air Pollution Segment 163
  • TABLE 52 GLOBAL UTILITY AND INDUSTRIAL SCR CATALYST CONSUMPTION, THROUGH 2015 ($ MILLIONS) 164
  • Mobile Source Air Pollution Segment 164
  • TABLE 53 GLOBAL FORECAST FOR MOBILE SOURCE AIR POLLUTION CATALYST CONSUMPTION BY SUB-SEGMENT, THROUGH 2015 164
  • Motor Vehicles 165
  • TABLE 54 GLOBAL MOTOR VEHICLE CATALYST CONSUMPTION, THROUGH 2015 ($ MILLIONS) 165
  • Three-Way (Gasoline) Catalytic Converters 165
  • FIGURE 27 GLOBAL CATALYTIC CONVERTER CONSUMPTION BY TYPE OF CATALYST, 2009 (PERCENT OF TOTAL KG CONSUMED) 166
  • TABLE 55 GLOBAL CATALYTIC CONVERTER DEMAND FOR CATALYSTS, 2009 ($ MILLIONS) 166
  • TABLE 56 WORLDWIDE LIGHT VEHICLE PRODUCTION, THROUGH 2015 (MILLION VEHICLES) 167
  • TABLE 57 GLOBAL FORECAST FOR PRECIOUS METAL CATALYST PRICES, THROUGH 2009 ($/KG) 167
  • TABLE 58 GLOBAL FORECAST FOR CATALYTIC CONVERTER CATALYST REQUIREMENTS, THROUGH 2015 (MILLIONS) 168
  • TABLE 59 GLOBAL FORECAST FOR CATALYTIC CONVERTER MARKET FOR NEW CATALYST MATERIALS, THROUGH 2015 ($ MILLIONS) 168
  • Advanced Diesel Emission Control Systems 169
  • FIGURE 28 GLOBAL DIESEL VEHICLE FLEET, 2009 (%) 169
  • Advanced ...(Continued) 170
  • TABLE 60 GLOBAL MARKET FOR DIESEL VEHICLE EMISSIONS CONTROL CATALYSTS, THROUGH 2015 ($ MILLIONS) 171
  • Non-Road Engine Emission Control Systems 171
  • TABLE 61 GLOBAL SALES OF CATALYSTS USED IN NON-ROAD CATALYTIC CONVERTERS, THROUGH 2015 ($ MILLIONS) 172

Chapter-7: INDUSTRY STRUCTURE 2

  • MARKET SHARES 173
  • ENERGY CATALYSTS 173
  • FIGURE 29 GLOBAL ENERGY CATALYST MARKET SHARES, 2009 (%) 173
  • ENVIRONMENTAL CATALYSTS 174
  • FIGURE 30 GLOBAL ENVIRONMENTAL CATALYST MARKET SHARES, 2009 (%) 174

Chapter-8: COMPANY PROFILES 16

  • ALBEMARLE CORP. 175
  • AXENS NA 175
  • CATALYTIC SOLUTIONS, INC. 175
  • CRITERION CATALYSTS AND TECHNOLOGIES 176
  • FUELCELL ENERGY, INC. 176
  • GAS TECHNOLOGY PRODUCTS, LLC 177
  • GENENCOR INTERNATIONAL, INC. 177
  • HALDOR TOPSOE SA 178
  • HEADWATERS, INC. 179
  • HEADWATERS NANOKINETIX, INC. 179
  • HYDROCARBON TECHNOLOGIES, INC. 180
  • HYRADIX, INC. 181
  • IOGEN CORP. 181
  • JOHNSON MATTHEY, PLC 182
  • KONARKA TECHNOLOGIES, INC. 182
  • NEXTECH MATERIALS, LTD. 183
  • NIPPON KETJEN, LTD. 184
  • NOVOZYMES A/S 184
  • RENTECH 184
  • RENTECH (CONTINUED) 185
  • RHODIA SA 186
  • SACHTLEBEN CHEMIE GMBH 186
  • SASOL, LTD. 186
  • SUD-CHEMIE AG 187
  • SYNTROLEUM CORP. 187
  • UOP, LLC 188
  • VERENIUM CORP. 188
  • W.R. GRACE/DAVISON CHEMICALS 189
  • ZEOLYST INTERNATIONAL 190

Press Release

2015年的環境及能源用觸媒全球市場將達到225億美元規模

2010年09月03日

Global Information, Inc.已開始銷售美國調查公司BCC Research所發行的報告書「Catalysts for Environmental and Energy Applications (環境與能源應用的催化劑 )」

依據該調查報告,環境及能源用觸媒的全球市場在2010年時約為163億美元。預估2015年時將約達到225億美元,最近的年平均成長率為6.6%。

其中規模最大環境用觸媒市場,被預測今後5年將維持6%的年平均成長率,2010年時為123億美元左右的市場規模,預計在2015年時約擴大到165億美元。

另一方面,能源用觸媒市場預估將從2010年的40億美元擴大到2015年接近60億美元的規模,最近的年平均成長率為8.1%。

觸媒技術的最重要用途,是因應擴大的能源需求與環境保護。所謂觸媒乃指使發生化學反應的必要能源減少、提高化學反應速度的物質,化學反應不會使觸媒本身產生變化。

最大量使用觸媒的是石油產業,尤其使用在生產汽油與柴油燃料精製品上。此外,如使用觸媒,瀝青砂岩和重質油沉澱物等以往認為不划算的原料,在商業基礎上就可以生產石油,對擴大石油的供給貢獻頗大。觸媒對以煤或油頁岩作為原料的合成石油和合成天然氣的生產量擴大亦有所助益。

本調查報告主要的讀者是在能源及環境用途使用觸媒的製造廠與銷售者。對想知道是觸媒市場支柱的這些重要領域今後5年如何發展的企業家、投資家和創業投資公司等而言,也是極有助益的。

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