Tag Archive: Waste to Energy


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 INNOVATIVE RESEARCH AND PRODUCTS, INC.

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 (203) 569-7909; marketing@innoresearch.net, www.innoresearch.net

 

PRESS RELEASE

 

THE GLOBAL MARKET FOR MUNICIPAL WASTE TO ENERGY TECHNOLOGIES TO EXPAND TO $41.5 BILLION BY 2021.

 

According to a new market research report published by Innovative Research and Products, titled ‘Municipal Waste to Energy – A Technology, Industry and Market Analysis’, the global market is expected to expand from $30.2 billion in 2016 to about $41.5 billion by 2021 at about a 6.5% compound annual growth rate (CAGR) over the next five years.

 

Technology processes that convert municipal waste to energy represent some of the most promising methods to solve environmental problems and to address increasing energy demand caused a growing human population coupled with increasing economic activity.

 

Municipal waste-to-energy (MWTE) is a renewable energy source which obtained from resources that are essentially unlimited, since it consists of human-generated solid waste that is produced in every country around the globe. MWTE can be used to generate thermal energy and/or electricity.

 

The municipal waste to energy (MWTE) technologies industry has sustained significant growth in the last decade and is likely to continue to expand in the future because of the increasing demands for energy and for environmental solutions. In addition to countries in Asia and in the Americas that are undergoing economic expansions, population growth is a major driver. Among the countries where we see increased human consumption, holding the potential for positively impacting the MWTE technologies industry, are China, India and Brazil.

 

Within the MWTE sector, there has been continuous innovation in the technologies for waste to energy conversion processes, which has resulted in systems having greater efficiencies.  In turn, this has increased the scope of waste to energy technology applications.

 

A number of MWTE technologies are available to communities in the United States and other global regions. These include combustion technologies, landfill gas technologies, plasma gasification technologies, pyrolysis gasification technologies and refuse-derived fuels.

 

According to the Irap report, Global market for Municipal Waste to Energy Technologies was estimated to have reached $30.2 billion in 2016 and will reach $41.5 billion by 2021 with a growth rate of 6.5% compound annual growth rate (CAGR) over the next five years.

 

In terms of region wise market share, the Asian region offers the greatest opportunities for growth, a trend that is expected to continue through 2021 followed by Europe and The Americas and The Middle East and Africa as distant 4th and 5th position. In terms of technologies used, the Combustion Technology dominates the market.

SUMMARY FIGURE

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Price:
$3,750.00 (Print Copy), $595 for second copy and $295 for 3rd copy onwards.
$3.950.00 (Single User License)
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Contact 203-569-7909 for faster service

 

Published: October 2017 Report ID: EN-108 Pages: 301  

 

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MUNICIPAL WASTE TO ENERGY – A TECHNOLOGY, INDUSTRY AND MARKET ANALYSIS

 

Technology processes that convert municipal waste to energy represent some of the most promising methods to solve environmental problems and to address increasing energy demand caused a growing human population coupled with increasing economic activity.

Municipal waste-to-energy (MWTE) is a renewable energy source which obtained from resources that are essentially unlimited, since it consists of human-generated solid waste that is produced in every country around the globe. MWTE can be used to generate thermal energy and/or electricity. While some renewable energy may have higher costs than energy from conventional sources, under the right conditions this is not necessarily the case. An increasing number of cities, states, provinces and countries are implementing MWTE production in order to reduce their overall energy costs.

If applied using current strategies, MWTE will generate other benefits that include:
• increasing the flexibility of power systems as electricity demand changes;
• reducing pollution and emissions from conventional energy systems; and
• reducing dependency and minimizing expenditure on imported fuels.
Moreover, some MWTE technologies are suited to small off-grid applications. Small energy systems can often contribute to the local economy by creating jobs in manufacturing, installation and servicing.

A number of MWTE technologies are available to communities in the United States and other global regions. These include combustion technologies, landfill gas technologies, plasma gasification technologies, pyrolysis gasification technologies and refuse-derived fuels. Detailed explanations of these key MWTE technologies are provided in the remainder of this report.

STUDY GOAL AND OBJECTIVES

This report focuses on the many new developments that have been taking place in MWTE technologies. Most of the market application sectors are growing at a good pace. In addition, there are new regions with dynamic economies that offer significant application opportunities for technologies used in the conversion of waste to energy.
Among the countries where we see good prospects for this industry are the growing economies of India, China and Brazil. The rapid economic expansions occurring in these evolving major economies, coupled with their large populations, has positioned MWTE among their top renewable energy options, and it is, as well, a key long-term future environmental solution. These developments have created the need for a proper analysis of market and business issues, trends in the MWTE industry, and international markets.

This report has been prepared to:
• provide an overview of MWTE technologies, industry and markets, product capabilities and applications;
• identify technical and business issues in the MWTE technologies industry;
• illustrate the market idiosyncrasies among the MWTE technology applications and analyze global economic and technological trends impacting the demand for these technologies;
• determine the current size and future growth of the world markets for MWTE technology applications;
• identify and profile key manufacturers and developers of MWTE technology; and
• identify global suppliers of MWTE technologies.
This study covers technical and industry overviews, MWTE technology processes, current and emerging MWTE technology methods, business and industry issues, current and emerging applications, and an extensive market analysis. The current size and future growth of transnational markets are estimated for 2016 and 2021.

FORMAT AND SCOPE

This report reviews the MWTE technology industry, including types of technologies, their applications, and current and anticipated demand for specific applications. For each market segment, the report provides an analysis of technology category, applications, international markets and competition.

The qualitative and quantitative judgments embodied in this report are a valuable contribution to the current knowledge of MWTE technologies, the prevailing economic and environmental conditions which require applications, the settings in which these technologies are used, and their markets. Moreover, this study has been conducted at a stage of market development when new applications hold the potential to revolutionize the industry. This is a consequence of the expanding utilization of waste to energy technologies – the need to continuously reduce gas emissions from landfills and increase energy production at a cost that consumers can afford, while still producing profitable returns to investors who must fund the high costs of electrical power plants, etc. This requires the application of new and innovative energy producing processes. The current study identifies all such applications.

METHODOLOGY AND INFORMATION SOURCES

The findings of this report are based on information derived from interviews with producers, distributors and major operators of waste to energy operations. Several industry experts were also contacted for this study.

Secondary data were obtained from government sources such as the U.S. Department of Energy and the U.S. Environmental Protection Agency, waste to energy equipment manufacturers, trade publications, technical journals, and government statistics from agencies such as the U.S. Department of Commerce, the U.S. Government Accountability Office and the European Commission.

CONTRIBUTIONS OF THE STUDY

This study provides the most complete accounting of the current market and future growth in municipal waste to energy country wise in Africa, Asia, Europe, The Middle East and The Americas. Further, the report provides global market according to technologies used for converting municipal waste to energy such as combustion, land fill gas technology, refuse derived fuels technology, plasma gasification and pyrolysis gasification. Markets are estimated for 2015, 2016 and 2021.

TO WHOM THE STUDY CATERS

This report is directed to companies that are interested in developments in this field, such as
• establishments involved in incinerator development and manufacturing;
• renewable energy technology suppliers and consultants, energy systems engineers, developers of energy infrastructure projects;
• producers and suppliers of boiler plant equipment;
• manufacturers and suppliers of systems and subsystems which incorporate waste recycling;
• builders and integrators of wastewater treatment technologies;
• investment institutions involved in the financing of energy resource and environmental solution projects;
• renewable technology research companies and institutions; and
• major energy utility companies interested in diversification.

 

REPORT SUMMARY

The municipal waste to energy (MWTE) technologies industry has sustained significant growth in the last decade and is likely to continue to expand in the future because of the increasing demands for energy and for environmental solutions. In addition to countries in Asia and in the Americas that are undergoing economic expansions, population growth is a major driver. Among the countries where we see increased human consumption, holding the potential for positively impacting the MWTE technologies industry, are China, India and Brazil.

Within the MWTE sector, there has been continuous innovation in the technologies for waste to energy conversion processes, which has resulted in systems having greater efficiencies. In turn, this has increased the scope of waste to energy technology applications.

Global market for Municipal Waste to Energy Technologies was estimated to have reached $30.2 billion in 2016 and will reach $41.5 billion by 2021 with a growth rate of 6.5% compound annual growth rate (CAGR) over the next five years.

In terms of region wise market share, the Asian region offers the greatest opportunities for growth, a trend that is expected to continue through 2021 followed by Europe and The Americas and The Middle East and Africa as distant 4th and 5th position. In terms of technologies used, the Combustion Technology dominates the market.

 

Price:

$3,750.00 (Print Copy), $595 for second copy and $295 for 3rd copy onwards.
$3.950.00 (Single User License)
$5,450.00 (Multi-User License at the Same Location)
$6,950.00 (Enterprise License)

Contact 203-569-7909 for faster service

Published: October 2017 Report ID: EN-108 Pages: 301

MUNICIPAL WASTE TO ENERGY – A TECHNOLOGY, INDUSTRY AND MARKET ANALYSIS

 

 

TABLE OF CONTENTS

INTRODUCTION 1
STUDY GOALS AND OBJECTIVES 1
FORMAT AND SCOPE 2
METHODOLOGY AND INFORMATION SOURCES 3
WHO SHOULD SUBSCRIBE? 3
AUTHOR’S CREDENTIALS 4
EXECUTIVE SUMMARY 5
SUMMARY TABLE A: GLOBAL MARKET FOR MUNICIPAL WASTE TO ENERGY                                            TECHNOLOGIES BY REGION THROUGH 2021 5
SUMMARY FIGURE A: GLOBAL MARKET FOR MUNICIPAL WASTE TO ENERGY                        TECHNOLOGIES BY REGION THROUGH 2021 6
SUMMARY TABLE B: GLOBAL MARKET FOR MUNICIPAL WASTE TO ENERGY BY                                       TECHNOLOGY THROUGH 2021 7
SUMMARY FIGURE B: GLOBAL MARKET FOR MUNICIPAL WASTE TO ENERGY BY                                     TECHNOLOGY THROUGH 2021 8
MUNICIPAL WASTE TO ENERGY: A GLOBAL PERSPECTIVE 9
WASTE AS FUEL SOURCE: ENERGY CONTENT 9
TABLE 1: AVERAGE HEAT CONTENT OF SELECTED BIOMASS FUELS 9
COST OF HARVESTING, COLLECTING, AND DELIVERING FEEDSTOCK 10
SOURCES OF WASTE 10
TABLE 2: U.S. MSW CONTENT BY MATERIAL, 2007 11
FIGURE 1: TOTAL U.S. MSW GENERATION BY MATERIAL 12
CONSTRUCTION AND DEMOLITION (C&D) WASTE 12
MINING AND QUARRYING (M&Q) WASTE 13
COMMERCIAL WASTE 13
HOUSEHOLD WASTE 13
INDUSTRIAL WASTE 13

AGRICULTURAL WASTE 13
SEWAGE WASTE 14
TABLE 3: AVERAGE MILLION BTU PER TON FOR MUNICIPAL SOLID WASTE (MSW) 15
TABLE 4: BIOGENIC AND NON-BIOGENIC CONTRIBUTIONS TO MUNICIPAL SOLID                                      WASTE (MSW) 16
LANDFILLS 16
WASTE TO ENERGY VALUE 17
TABLE 5: GLOBAL VALUE OF WASTE TO ENERGY ASSETS, 2016-2021 18
GLOBAL VALUE OF CAPITAL EXPENDITURES FOR WTE 19
TABLE 6: ESTIMATED CAPITAL EXPENDITURES IN MUNICIPAL WASTE TO ENERGY BY                          REGION, 2014-2021 20
TABLE 7: MSWTE TECHNOLOGIES 21
TABLE 8: ESTIMATED MSWTE GIGAWATTS OF POWER BY REGION 21
GLOBAL VALUE OF TOTAL TIPPING FEES TO SWTE 21
TABLE 9: VALUE OF TOTAL TIPPING FEES, 2014-2021 22
GLOBAL CARBON OFFSET VALUE 22
TABLE 10: TOTAL ESTIMATED VALUES OF CARBON OFFSETS 23
GLOBAL VALUE OF METAL RECOVERY: 23
TABLE 11: ESTIMATED TOTAL VALUE OF METAL RECOVERY BY REGION 24
VALUE OF OTHER WTE PRODUCTS 25
MUNICIPAL WASTE TO ENERGY IN THE U.S. 25
TABLE 12: SUMMARY VALUE OF MSWTE ASSETS U.S. 2014-2021 25
TABLE 13: U.S. WASTE-TO-ENERGY CAPACITY ESTIMATED PROFILE 26
TABLE 14: U.S. WASTE-TO-ENERGY SITES, 2014-2021 26
TABLE 15: MUNICIPAL WASTE SOURCE, VALUE AND PERCENT OF MSW MARKET 28
THE U.S. COMBUSTION MARKET 28
TABLE 16: US STATES RANKED ACCORDING TO ENERGY PRODUCED FROM WASTE-TO-     ENERGY PLANTS (1000S KWH) 29
OTHER WASTE TO ENERGY IN THE U.S. 30
TABLE 17: INDUSTRIAL WASTE TO ENERGY BY WASTE PRODUCT IN Kw HOURS 31
TABLE 18: INDUSTRIAL BIOMASS ELECTRICITY NET GENERATION BY U.S. REGIONS AND                    ENERGY SOURCES 32
TABLE 19: INDUSTRIAL BIOMASS ELECTRICITY NET GENERATION
BY U.S. REGIONS AND ENERGY SOURCES 32
EUROPEAN MSWTE: 33
TABLE 20: VALUE OF EUROPEAN MSWTE ASSETS, 2015-2021 33
TABLE 21: EUROPEAN LEADERS IN LANDFILLLING 35
TABLE 22: ELECTRICAL AND HEAT EFFICIENCY IN EUROPEAN WTE PLANTS 36
ASIA MSWTE 38
TABLE 23: ASIA’S ESTIMATED MSWTE ASSETT PROFILE, 2015-2021 39
TABLE 24: TREATMENT METHODS IN EAST ASIA 39
CHINA 39
TABLE 25: REPRESENTATIVE WASTE-TO-ENERGY PLANTS IN CHINA 40
INDIA 42
JAPAN 43
TABLE 26: JAPANESE WASTE-TO-ENERGY PLANTS 44
REST OF THE WORLD 44
AFRICA 44
BRAZIL 46
WASTE-TO-ENERGY TECHNOLOGIES 49
TABLE 27: MUNICIPAL SOLID WASTE- TO-ENERGY TECHNOLOGIES, FEEDSTOCKS AND                       PRODUCTS 50
COMBUSTION 51
FIGURE 2: WASTE-TO-ENERGY PLANT DIAGRAM 53
CO-FIRING 54
FIGURE 3: TYPICAL MSWTE PLANT CONFIGURATION 55
COMBUSTION PLANT COSTS 56
TABLE 28: LOW AND HIGH EFFICIENCY FOR MSW POWER PLANTS 57
TABLE 29: CARBON DIOXIDE OFFSET RATES 57
LANDFILL GAS 58
TABLE 30: LANDFILL GAS FACILITY EQUIPMENT 58
REFUSE-DERIVED FUEL (RDF): 58
FIGURE 4 DIAGRAM OF RDF PRODUCTION WITH NON-DEDICATED PLANT 60
FIGURE 5: BIOMASS TO FUELS CONVERSION PATHWAYS 62
ANAEROBIC DIGESTION (AD) 62
MECHANICAL BIOLOGICAL TREATMENT 64
GASIFICATION 64
TABLE 31: GASIFICATION FEEDSTOCKS BY MARKET PERCENT 65
FIGURE 6: BASIC GASIFICATION PROCESS 66
FIGURE 7: BIOMASS GASIFIER FLOW CHART 68
TABLE 32: BIOMASS GASIFICATION VERSUS SOLAR AND WIND POWER 69
PYROLYSIS 69
DEPOLYMERIZATION 70
TYPES OF GASIFIERS FOR MSW TREATMENT: 70
TABLE 33: THERMAL CAPACITY BY GASIFIER DESIGN 70
GASIFICATION WITH PURE OXYGEN OR HYDROGEN 72
PLASMA GASIFICATION 72
FIGURE 8: ILLUSTRATION OF PLASMA ARC 74
FIGURE 9: PLASMA GASIFICATION SCHEMATIC FOR MUNICIPAL
SOLID WASTE TO ENERGY 75
FIGURE 10: PLASMA PROCESSING OF MSW AT COAL-FIRED PLANTS 76
PLASMA ARC 76
GAS PLASMA PROCESS 77
ULTRA-HIGH TEMPERATURE (UHT) PLASMA GASIFICATION 78
FIGURE 11: PLASMA GAS VITRIFICATION PROCESS 78
TABLE 34: COMPARISON OF MUNICIPAL SOLID WASTE-TO-ENERGY PROCESSES FOR ELECTRICITY PRODUCTION 79
ADVANTAGES OF MUNICIPAL SOLID WASTE GASIFICATION 80
GREENHOUSE GAS REDUCTION 80
TABLE 35: POUNDS OF CO2 PER MWH BY FUEL SOURCE 81
CONVERSION TECHNOLOGIES 81
DISADVANTAGES OF GASIFICATION 81
LANDFILL GAS (LFG) 82
TABLE 36: EMISSIONS REDUCTIONS FROM A 1 MW LANDFILL GAS-TO-ENERGY PROJECT 84
TECHNOLOGY BENEFITS AND HURDLES OF WASTE-TO-ENERGY 84
CONSIDERATIONS FOR WTE IMPLEMENTATION 85
MATERIAL RECOVERY 85
TECHNOLOGY CHALLENGES 85
ENVIRONMENTAL BENEFITS 86
WASTE AS A RESOURCE 87
ENVIRONMENTAL IMPACTS 88
AIR EMISSIONS 88
TABLE 37: MSWTE POLLUTION CONTROLS 89
WATER RESOURCES 90
SOLID WASTE GENERATION 90
LAND RESOURCE USE 91
PERMITTING ISSUES FOR MASS BURN FACILITIES 91
GOVERNMENT REGULATIONS 92
ECONOMIC MECHANISMS FOR SUPPORTING RENEWABLE ENERGY 92
RENEWABLE ENERGY CREDITS (RECS) 92
CARBON CREDITS 92
THE CLEAN DEVELOPMENT MECHANISM FOR LANDFILL GAS RECOVERY 93
LAWS AND REGULATIONS REGARDING RENEWABLE ENERGY 95
ACTIONS IN THE EUROPEAN UNION AND ELSEWHERE 95
UNITED STATES LAWS AND REGULATIONS 95
FEDERAL LEGISLATION 96
PERMITTING ISSUES 101
PERMITTING ISSUES FOR LANDFILL GAS RECOVERY 101
PERMITTING ISSUES FOR MASS BURN/COMBUSTION FACILITIES 101
PERMITTING ISSUES FOR REFUSE-DERIVED FUEL COMBUSTION FACILITIES 102
PERMITTING ISSUES FOR PYROLYSIS/THERMAL GASIFICATION 102
ELECTRICAL SYSTEM INTERCONNECTION ISSUES 103
STATE REGULATIONS 104
STATE RENEWABLE PORTFOLIO STANDARDS (RPS) 104
FLORIDA DEPT. OF ENVIRONMENTAL PROTECTION WHITE PAPER ON PLASMA ARC 104
INTERNATIONAL REGULATIONS: CLEAN DEVELOPMENT MECHANISM AND WASTE-TO-ENERGY 105
EUROPEAN REGULATIONS 107
WORLD MUNICIPAL WASTE-TO-ENERGY INDUSTRY STRUCTURE 108
TABLE 38: LEADING MUNICIPAL WASTE-TO-ENERGY COMPANIES 109
TABLE 39: DISTRIBUTION OF TOP MUNICIPAL WASTE-TO-ENERGY 109
COMPANIES BY REGION 109
TABLE 40: DISTRIBUTION OF MUNICIPAL WASTE-TO-ENERGY 110
COMPANIES BY REGION 110
TABLE 41: NORTH AMERICAN MUNICIPAL WASTE-TO-ENERGY COMPANIES 111
TABLE 42: EUROPEAN MUNICIPAL WASTE-TO-ENERGY COMPANIES 112
TABLE 43: ASIAN MUNICIPAL WASTE-TO-ENERGY COMPANIES 113
TABLE 44: OCEANIA MUNICIPAL WASTE-TO-ENERGY COMPANIES 113
MARKET DRIVERS 114
TABLE 45: 2009 TOTAL U.S. MUNICIPAL WASTE BY MATERIAL 115
WORLD MUNICIPAL WASTE-TO-ENERGY TECHNOLOGIES MARKET 116
EUROPEAN MARKET FOR MUNICIPAL WASTE-TO-ENERGY TECHNOLOGIES 116
TABLE 46: WESTERN EUROPEAN MARKET FOR MUNICIPAL WASTE-TO-ENERGY                                      TECHNOLOGIES BY COUNTRY THROUGH 2021 117
TABLE 47: EASTERN EUROPEAN MARKET FOR MUNICIPAL WASTE TO ENERGY                                         TECHNOLOGIES BY COUNTRY THROUGH 2021 119
ASIA AND OCEANIA MARKETS FOR MUNICIPAL WASTE-TO-ENERGY TECHNOLOGIES 120
TABLE 48: ASIAN MARKET FOR MUNICIPAL WASTE-TO-ENERGY TECHNOLOGIES BY                              COUNTRY THROUGH 2021 120
TABLE 49: OCEANIAN MARKET FOR MUNICIPAL WASTE-TO-ENERGY TECHNOLOGIES BY                      COUNTRY THROUGH 2021 121
TABLE 50: SOUTHEAST ASIAN MARKET FOR MUNICIPAL WASTE-TO-ENERGY                                           TECHNOLOGIES BY COUNTRY THROUGH 2021 122
NORTH AMERICAN MARKET FOR MUNICIPAL WASTE-TO-ENERGY TECHNOLOGIES 123
TABLE 51: NORTH AMERICAN MARKET FOR MUNICIPAL WASTE TO ENERGY                                            TECHNOLOGIES BY COUNTRY THROUGH 2021 123
CENTRAL AND SOUTH AMERICAN MARKET FOR MUNICIPAL WASTE-TO-ENERGY                                   TECHNOLOGIES 124
TABLE 52: CENTRAL AND SOUTH AMERICAN MARKET FOR MUNICIPAL WASTE-TO-                              ENERGY TECHNOLOGIES BY COUNTRY THROUGH 2021 124
AFRICAN MARKET FOR MUNICIPAL WASTE-TO-ENERGY TECHNOLOGIES 125
TABLE 55: NORTH AFRICAN MARKET FOR MUNICIPAL WASTE-TO-ENERGY                                             TECHNOLOGIES BY COUNTRY THROUGH 2021 125
TABLE 54: SUB-SAHARAN AFRICAN MARKET FOR MUNICIPAL WASTE-TO-ENERGY                                TECHNOLOGIES BY COUNTRY THROUGH 2021 126
MIDDLE EASTERN MARKET FOR MUNICIPAL WASTE-TO-ENERGY TECHNOLOGIES 126
TABLE 55: MIDDLE EASTERN MARKET FOR MUNICIPAL WASTE-TO-ENERGY                                          TECHNOLOGIES BY COUNTRY THROUGH 2021 127
MARKET FOR MUNICIPAL WASTE-TO-ENERGY COMBUSTION TECHNOLOGY 129
TABLE 56: GLOBAL MARKET FOR MUNICIPAL WASTE-TO-ENERGY 129
COMBUSTION TECHNOLOGY BY REGION THROUGH 2021 129
EUROPEAN MARKET FOR MWTE COMBUSTION TECHNOLOGY 129
TABLE 57: WESTERN EUROPEAN MARKET FOR MUNICIPAL WASTE-TO-ENERGY                                    COMBUSTION TECHNOLOGY BY COUNTRY 130
TABLE 58: EASTERN EUROPEAN MARKET FOR MUNICIPAL WASTE-TO-ENERGY                                     COMBUSTION TECHNOLOGY BY COUNTRY 132
ASIAN MARKET FOR MWTE COMBUSTION TECHNOLOGY 133
TABLE 59: ASIAN MARKET FOR MWTE COMBUSTION TECHNOLOGY BY COUNTRY                               THROUGH 2021 133
TABLE 60: OCEANIAN MARKET FOR MWTE COMBUSTION TECHNOLOGY BY COUNTRY                       THROUGH 2021 134
TABLE 61: SOUTHEAST ASIAN MARKET FOR MWTE COMBUSTION TECHNOLOGY BY                           COUNTRY THROUGH 2021 135
NORTH AMERICAN MARKET FOR MWTE COMBUSTION TECHNOLOGY 136
TABLE 62: NORTH AMERICAN MARKET FOR MWTE COMBUSTION TECHNOLOGY BY                          COUNTRY THROUGH 2021 136
CENTRAL AND SOUTH AMERICAN MARKET FOR MWTE COMBUSTION                                                    TECHNOLOGY 136
TABLE 63: CENTRAL AND SOUTH AMERICAN MARKET FOR MWTE COMBUSTION                                TECHNOLOGY BY COUNTRY 137
AFRICAN DEMAND FOR MWTE COMBUSTION TECHNOLOGY 138
TABLE 64: NORTH AFRICAN DEMAND FOR MWTE COMBUSTION TECHNOLOGY BY                              COUNTRY THROUGH 2021 138
TABLE 65: SUB-SAHARAN AFRICA DEMAND FOR MWTE COMBUSTION TECHNOLOGY BY  COUNTRY THROUGH 2021 139
MIDDLE EAST DEMAND FOR COMBUSTION TECHNOLOGY APPLICATIONS 139
TABLE 66: MIDDLE EAST DEMAND FOR MWTE COMBUSTION TECHNOLOGY BY                                    COUNTRY THROUGH 2021 140
TABLE 67: GLOBAL MARKET FOR MWTE LANDFILL GAS TECHNOLOGY BY REGION                          THROUGH 2021 142
EUROPEAN MARKET FOR MWTE LANDFILL GAS TECHNOLOGY 142
TABLE 68: WESTERN EUROPEAN MARKET FOR MWTE LANDFILL GAS TECHNOLOGY BY                  COUNTRY THROUGH 2021 143
TABLE 69: EASTERN EUROPEAN MARKET FOR MWTE LANDFILL GAS TECHNOLOGY BY                 COUNTRY THROUGH 2021 145
ASIAN MARKET FOR MWTE LANDFILL GAS TECHNOLOGY 146
TABLE 70 ASIAN DEMAND FOR MWTE LANDFILL GAS TECHNOLOGY BY COUNTRY                        THROUGH 2021 146
TABLE 71: OCEANIAN DEMAND FOR MWTE LANDFILL GAS TECHNOLOGY BY COUNTRY                THROUGH 2021 147
TABLE 72 SOUTHEAST ASIAN MARKET FOR MWTE LANDFILL GAS TECHNOLOGY BY                      COUNTRY THROUGH 2021 148
NORTH AMERICAN MARKET FOR MWTE LANDFILL GAS TECHNOLOGY 149
TABLE 73: NORTH AMERICAN MARKET FOR MWTE LANDFILL GAS TECHNOLOGY BY                   COUNTRY THROUGH 2021 149
CENTRAL AND SOUTH AMERICAN MARKET FOR MWTE LANDFILL GAS                                  TECHNOLOGY 150
TABLE 74: CENTRAL AND SOUTH AMERICAN MARKET FOR MWTE LANDFILL GAS                 TECHNOLOGY BY COUNTRY THROUGH 2021 150
AFRICAN DEMAND FOR MWTE LANDFILL GAS TECHNOLOGY 151
TABLE 75: NORTH AFRICAN DEMAND FOR MWTE LANDFILL GAS TECHNOLOGY                   APPLICATIONS BY COUNTRY THROUGH 2021 151
TABLE 76: SUB-SAHARAN AFRICA DEMAND FOR MWTE LANDFILL GAS TECHNOLOGY BY COUNTRY THROUGH 2021 152
MIDDLE EAST DEMAND FOR MWTE LANDFILL GAS TECHNOLOGY 152
TABLE 77: MIDDLE EASTERN DEMAND FOR MWTE LANDFILL GAS TECHNOLOGY BY                    COUNTRY THROUGH 2021 153
WORLD MARKET FOR REFUSE-DERIVED FUEL TECHNOLOGY 155
TABLE 78: GLOBAL MARKET FOR REFUSE-DERIVED FUELS TECHNOLOGY BY REGION                   THROUGH 2021 155
EUROPEAN MARKET FOR REFUSE-DERIVED FUELS TECHNOLOGY 155
TABLE 79: WESTERN EUROPEAN MARKET FOR REFUSE DERIVED FUELS TECHNOLOGY BY COUNTRY, THROUGH 2021 156
TABLE 80: EASTERN EUROPEAN MARKET FOR REFUSE-DERIVED FUELS TECHNOLOGY BY COUNTRY THROUGH 2021 158
ASIAN MARKET FOR REFUSE DERIVED FUELS TECHNOLOGY 159
TABLE 81: ASIAN MARKET FOR REFUSE DERIVED FUELS TECHNOLOGY BY COUNTRY THROUGH 2021 159
TABLE 82: OCEANIAN MARKET FOR REFUSE-DERIVED FUELS TECHNOLOGY BY COUNTRY THROUGH 2021 160
TABLE 83: SOUTHEAST ASIAN MARKET FOR REFUSE-DERIVED FUELS TECHNOLOGY BY COUNTRY THROUGH 2021 161
NORTH AMERICAN MARKET FOR REFUSE-DERIVED FUELS TECHNOLOGY 162
TABLE 84: NORTH AMERICAN MARKET FOR REFUSE-DERIVED FUELS TECHNOLOGY BY COUNTRY THROUGH 2021 162
CENTRAL AND SOUTH AMERICAN MARKET FOR REFUSE-DERIVED FUELS TECHNOLOGY 163
TABLE 85: CENTRAL AND SOUTH AMERICAN MARKET FOR REFUSE DERIVED FUELS TECHNOLOGY BY COUNTRY THROUGH 2021 163
AFRICAN DEMAND FOR REFUSE-DERIVED FUELS TECHNOLOGY 164
TABLE 86: NORTH AFRICAN DEMAND FOR REFUSE-DERIVED FUELS TECHNOLOGY BY COUNTRY THROUGH 2021 164
TABLE 87: SUB-SAHARAN AFRICA DEMAND FOR REFUSE-DERIVED FUELS TECHNOLOGY BY COUNTRY THROUGH 2021 165
MIDDLE EAST DEMAND FOR REFUSE-DERIVED FUELS TECHNOLOGY 165
TABLE 88: MIDDLE EAST DEMAND FOR REFUSE-DERIVED FUELS TECHNOLOGY BY COUNTRY THROUGH 2021 166
WORLD MARKET FOR PLASMA GASIFICATION TECHNOLOGY 168
TABLE 89: GLOBAL MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY BY REGION THROUGH 2021 168
EUROPEAN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY 168
TABLE 90: WESTERN EUROPEAN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 169
TABLE 91: EASTERN EUROPEAN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 171
ASIAN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY 172
TABLE 92: ASIAN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 172
TABLE 93: OCEANIAN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 173
TABLE 94: SOUTHEAST ASIAN MARKET FOR MWTE PLASMA 174
GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 174
NORTH AMERICAN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY 175
TABLE 95: NORTH AMERICAN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY BY COUNTRY, THROUGH 2021 175
CENTRAL AND SOUTH AMERICAN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY 176
TABLE 96: CENTRAL AND SOUTH AMERICAN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY BY COUNTRY 176
AFRICAN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY 177
TABLE 97: NORTH AFRICAN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 177
TABLE 98: SUB-SAHARAN AFRICA MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 178
MIDDLE EASTERN MARKET FOR MWTE PLASMA GASIFICATION TECHNOLOGY 178
TABLE 99: MIDDLE EASTERN MARKET FOR MWTE FROM PLASMA GASIFICATION TECHNOLOGY BY COUNTRY, THROUGH 2021 179
WORLD MARKET FOR PYROLYSIS GASIFICATION TECHNOLOGY APPLICATIONS IN MUNICIPAL WASTE TO ENERGY 180
TABLE 100: GLOBAL MARKET FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY BY REGION THROUGH 2021 181
EUROPEAN MARKET FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY 181
TABLE 101: WESTERN EUROPEAN MARKET FOR MWTE PYROLYSIS 182
GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 182
TABLE 102: EASTERN EUROPEAN MARKET FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 184
ASIAN AND OCEANIAN MARKETS FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY 185
TABLE 103: ASIAN MARKET FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 185
TABLE 104: OCEANIAN MARKET FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 186
TABLE 105: SOUTHEAST ASIAN MARKET FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 187
NORTH AMERICAN MARKET FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY 188
TABLE 106: NORTH AMERICAN MARKET FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 188
CENTRAL AND SOUTH AMERICAN MARKET FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY 189
TABLE 107: CENTRAL AND SOUTH AMERICAN MARKET FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY BY COUNTRY 189
AFRICAN DEMAND FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY 190
TABLE 108: NORTH AFRICA DEMAND FOR MWTE PYROLYSIS 190
GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 190
TABLE 109: SUB-SAHARAN AFRICA DEMAND FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY BY COUNTRY 191
MIDDLE EASTERN DEMAND FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY 192
TABLE 110: MIDDLE EAST DEMAND FOR MWTE PYROLYSIS GASIFICATION TECHNOLOGY BY COUNTRY THROUGH 2021 192
NEW DEVELOPMENTS 194
WASTE TO ENERGY 194
DRY ANAEROBIC CO-DIGESTION OF ORGANIC FRACTION OF MUNICIPAL WASTE WITH PAPERBOARD MILL SLUDGE AND GELATIN SOLID WASTE FOR ENHANCEMENT OF HYDROGEN PRODUCTION 194
LIFE CYCLE ASSESSMENT OF THERMAL WASTE-TO-ENERGY TECHNOLOGIES: REVIEW AND RECOMMENDATIONS 195
ASSESSMENT OF WASTE DERIVED GASES AS A RENEWABLE ENERGY 195
BIOELECTROCHEMICAL TREATMENT OF MUNICIPAL WASTE LIQUOR IN MICROBIAL FUEL CELLS FOR ENERGY VALORIZATION 196
PROCESSING AND PROPERTIES OF A SOLID ENERGY FUEL FROM MUNICIPAL SOLID WASTE (MSW) AND RECYCLED PLASTICS 196
EXTRACTION OF MEDIUM CHAIN FATTY ACIDS FROM ORGANIC MUNICIPAL WASTE AND SUBSEQUENT PRODUCTION OF BIO-BASED FUELS 197
HYDROGEN-RICH GAS PRODUCTION BY THE GASIFICATION OF \WET MSW (MUNICIPAL SOLID WASTE) COUPLED WITH CARBON DIOXIDE CAPTURE 198
EXTRACTION OF SOLUBLE SUBSTANCES FROM ORGANIC SOLID MUNICIPAL WASTE TO INCREASE METHANE PRODUCTION 199
POTENTIAL OF BIOHYDROGEN PRODUCTION FROM ORGANIC FRACTION OF MUNICIPAL SOLID WASTE (OFMSW) USING PILOT-SCALE DRY ANAEROBIC REACTOR 199
A REVIEW OF TECHNOLOGIES AND PERFORMANCES OF THERMAL TREATMENT SYSTEMS FOR ENERGY RECOVERY FROM WASTE 199
WASTE TO ENERGY: EXPLOITATION OF BIOGAS FROM ORGANIC WASTE IN A 500 WEL SOLID OXIDE FUEL CELL (SOFC) STACK 200
TECHNOLOGICAL ASSESSMENT OF EMERGING TECHNOLOGIES IN CONVERSION OF MUNICIPAL SOLID WASTE TO ENERGY 201
ENERGY PRODUCTION THROUGH ORGANIC FRACTION OF MUNICIPAL SOLID WASTE—A MULTIPLE REGRESSION MODELING APPROACH 201
CO-DIGESTION OF MUNICIPAL SLUDGE AND EXTERNAL ORGANIC WASTES FOR ENHANCED BIOGAS PRODUCTION UNDER REALISTIC PLANT CONSTRAINTS 202
PLASMA GASIFICATION OF MUNICIPAL SOLID WASTE 203
ADVANCED SOLUTIONS IN COMBUSTION-BASED WTE TECHNOLOGIES 203
REPOWERING EXI WITH GAS TURBINES 204
PATENTS AND PATENT ANALYSIS 206
TABLE 111: SAMPLE OF CURRENT U.S. PATENT GENERATION TRENDS IN WASTE-TO-ENERGY TECHNOLOGY BY YEAR 206
TABLE 112: U.S. PATENTS IN WASTE-TO-ENERGY TECHNOLOGY 207
TABLE 113: U.S. PATENTS BY TECHNOLOGY, 2013–2015 208
SAMPLE OF U.S. PATENT ABSTRACTS 208
BATCH WASTE GASIFICATION PROCESS 208
PRODUCING LIQUID FUEL FROM ORGANIC MATERIAL SUCH AS BIOMASS AND WASTE RESIDUES 208
PROCESSING BIOMASS AND PETROLEUM CONTAINING MATERIALS 209
PLASMA-ASSISTED WASTE GASIFICATION SYSTEM 209
PLASMA ASSISTED GASIFICATION SYSTEM WITH AN INDIRECT VACUUM SYSTEM 210
APPARATUS AND METHOD FOR CONVERSION OF SOLID WASTE INTO SYNTHETIC OIL, GAS, AND FERTILIZER 210
METHODS OF PRODUCING LIQUID HYDROCARBON FUELS FROM SOLID PLASTIC WASTES 211
PROCESSING BIOMASS 211
PROCESS AND SYSTEM FOR PRODUCING ENGINEERED FUEL 211
PHOTONIC RADIOLYSIS OF WASTE MATERIALS 211
MECHANIZED SEPARATION AND RECOVERY SYSTEM FOR SOLID WASTE 212
PROCESS FOR THE PRODUCTION OF BIO-OIL FROM SOLID URBAN WASTE 213
METHOD FOR CONVERTING BIOMASS TO METHANE 213
U.S. REGISTERED PATENTS 213
TABLE 114: SAMPLE OF LATEST U.S. WASTE TO ENERGY TECHNOLOGY PATENTS, 2013-2015 217
COMPANY PROFILES 216
AALBORG ENERGIE TECHNIK A/S 216
ADI SYSTEMS INC. 217
AEROTHERMAL GROUP 218
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WESTINGHOUSE ELECTRIC CORPORATION 300
WMT-LBS GMBH 301
ZERO WASTE ENERGY, LLC (ZWE) 301
 

 

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Published: October 2017 Report ID: EN-108 Pages: 301
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