Solid Waste Management Holistic Decision Modeling
This study provides support to the Bank's ability to conduct client dialogue on solid waste management technology selection, and will contribute to client decision-making. The goal of the study was to fully explore the use of the United States...
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| Format: | Other Environmental Study |
| Language: | English en_US |
| Published: |
Washington, DC
2013
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| Subjects: | |
| Online Access: | http://documents.worldbank.org/curated/en/2008/06/16371282/global-study-purpose-global-world-bank-guidance-development-solid-waste-management-holistic-decision-modeling http://hdl.handle.net/10986/12903 |
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okr-10986-12903 |
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| recordtype |
oai_dc |
| repository_type |
Digital Repository |
| institution_category |
Foreign Institution |
| institution |
Digital Repositories |
| building |
World Bank Open Knowledge Repository |
| collection |
World Bank |
| language |
English en_US |
| topic |
AIR EMISSIONS AIR POLLUTANTS AIR POLLUTION ALUMINUM ANAEROBIC DIGESTION ANIMAL MANURE ANIMAL WASTE ASH ATMOSPHERE AVERAGE TEMPERATURE BACTERIA BALERS BARGE TRANSFER BIOCHEMICAL OXYGEN DEMAND BIOGAS BOD BOILERS BONES BRITISH THERMAL UNIT BTU BULKY WASTE CARBON CARBON DIOXIDE CARBON EMISSIONS CARBON MONOXIDE CHEMICAL INDUSTRY CLIMATE CHANGE COAL COLLECTED WASTE COLLECTION FREQUENCY COLLECTION SYSTEMS COLLECTION VEHICLES COMBUSTION COMBUSTION ACTIVITIES COMBUSTION FACILITIES COMBUSTION PROCESS COMMERCIAL WASTE COMMINGLED RECYCLABLES COMPACTOR TRUCKS COMPOST COMPOST PRODUCT COMPOSTABLE MATERIALS COMPOSTING COMPOSTING FACILITIES COMPOSTING PROCESS CONSUMPTION OF ENERGY DAILY WASTE COLLECTION DIESEL FUEL DISPOSAL DISPOSAL COST DISPOSAL METHOD DISPOSAL OF WASTE DISPOSAL SITE DISPOSAL SITES ELECTRIC POWER ELECTRICITY ELECTRICITY PRODUCTION EMISSION EMISSION DATA EMISSION FACTORS EMISSION REDUCTION ENERGY CONSUMPTION ENERGY PRODUCTION ENERGY SAVINGS ENERGY TECHNOLOGIES ENVIRONMENTAL ASPECTS ENVIRONMENTAL ASSESSMENT ENVIRONMENTAL CONTROLS ENVIRONMENTAL IMPACT ENVIRONMENTAL MANAGEMENT ENVIRONMENTAL PROTECTION ENVIRONMENTAL PROTECTION AGENCY ENVIRONMENTAL SANITATION FINAL DISPOSAL FINAL DISPOSAL SITE FIRES FOOD WASTE FOSSIL FUELS FUEL FUEL COMBUSTION FUEL TYPE FUELS FURNITURE GARBAGE GAS COLLECTION GAS EMISSIONS GAS FLARING GAS VENTING GHG GLASS GREENHOUSE GREENHOUSE EFFECT GREENHOUSE GAS GREENHOUSE GASES HAZARDOUS SUBSTANCES HDPE HEAT HIGH DENSITY POLYETHYLENE HUMUS HYDROGEN SULFIDE INCINERATION INCINERATION FACILITIES INCINERATION FACILITY INCINERATION WITH ENERGY INCINERATION WITH ENERGY RECOVERY INCINERATORS INCOME IRRIGATION IRRIGATION WATER LAND USE LANDFILL LANDFILL DISPOSAL LANDFILL FACILITY LANDFILL GAS LANDFILL GAS RECOVERY LANDFILL OPERATIONS LANDFILL SITE LANDFILL SITES LANDFILLING LANDFILLS LEACHATE LEACHATE TREATMENT LIQUID WASTES METALS METHANE METHANE GAS METROPOLITAN AREA METROPOLITAN CITY MINING MRF MSW MUNICIPAL SOLID MUNICIPAL SOLID WASTE MUNICIPAL SOLID WASTE MANAGEMENT MUNICIPAL WASTE MUNICIPAL WASTE STREAM NATURAL GAS NITROGEN OXIDES OPEN BURNING ORGANIC MATERIALS OXYGEN PAPER WASTE PARTICULATE PLASTIC PM POLLUTION PROBLEMS POST-CLOSURE PRECIPITATION RAINFALL RAW MATERIALS RECYCLABLE MATERIAL RECYCLABLE MATERIALS RECYCLABLE WASTE RECYCLING REFUSE REFUSE COLLECTION REFUSE COLLECTION VEHICLES RESIDENTIAL WASTE RUNOFF SANITARY ENGINEERS SANITARY LANDFILL SANITARY LANDFILL SITE SCREENING SOLID WASTE SOLID WASTE ASSOCIATION SOLID WASTE COLLECTION SOLID WASTE DATA SOLID WASTE MANAGEMENT SOLID WASTE SYSTEM SOLID WASTE SYSTEMS SOLID WASTE TECHNOLOGY SOURCE REDUCTION STRAW SURFACE WATER SUSTAINABLE DEVELOPMENT SWM TOTAL WASTE GENERATION TRANSFER POINTS TRANSFER STATIONS UNIT PROCESS WASTE COLLECTION WASTE COLLECTION VEHICLES WASTE COMBUSTION WASTE COMPOSITION WASTE DISPOSAL WASTE GENERATION WASTE GENERATION RATE WASTE MANAGEMENT ACTIVITIES WASTE MANAGEMENT SYSTEM WASTE MANAGEMENT SYSTEMS WASTE PAPER WASTE PLASTICS WASTE TO ENERGY WASTE TREATMENT WASTES WASTEWATER WASTEWATER TREATMENT WATER POLLUTANTS WATER POLLUTION WINDROW WTE YARD TRIMMINGS YARD WASTE YARD WASTES |
| spellingShingle |
AIR EMISSIONS AIR POLLUTANTS AIR POLLUTION ALUMINUM ANAEROBIC DIGESTION ANIMAL MANURE ANIMAL WASTE ASH ATMOSPHERE AVERAGE TEMPERATURE BACTERIA BALERS BARGE TRANSFER BIOCHEMICAL OXYGEN DEMAND BIOGAS BOD BOILERS BONES BRITISH THERMAL UNIT BTU BULKY WASTE CARBON CARBON DIOXIDE CARBON EMISSIONS CARBON MONOXIDE CHEMICAL INDUSTRY CLIMATE CHANGE COAL COLLECTED WASTE COLLECTION FREQUENCY COLLECTION SYSTEMS COLLECTION VEHICLES COMBUSTION COMBUSTION ACTIVITIES COMBUSTION FACILITIES COMBUSTION PROCESS COMMERCIAL WASTE COMMINGLED RECYCLABLES COMPACTOR TRUCKS COMPOST COMPOST PRODUCT COMPOSTABLE MATERIALS COMPOSTING COMPOSTING FACILITIES COMPOSTING PROCESS CONSUMPTION OF ENERGY DAILY WASTE COLLECTION DIESEL FUEL DISPOSAL DISPOSAL COST DISPOSAL METHOD DISPOSAL OF WASTE DISPOSAL SITE DISPOSAL SITES ELECTRIC POWER ELECTRICITY ELECTRICITY PRODUCTION EMISSION EMISSION DATA EMISSION FACTORS EMISSION REDUCTION ENERGY CONSUMPTION ENERGY PRODUCTION ENERGY SAVINGS ENERGY TECHNOLOGIES ENVIRONMENTAL ASPECTS ENVIRONMENTAL ASSESSMENT ENVIRONMENTAL CONTROLS ENVIRONMENTAL IMPACT ENVIRONMENTAL MANAGEMENT ENVIRONMENTAL PROTECTION ENVIRONMENTAL PROTECTION AGENCY ENVIRONMENTAL SANITATION FINAL DISPOSAL FINAL DISPOSAL SITE FIRES FOOD WASTE FOSSIL FUELS FUEL FUEL COMBUSTION FUEL TYPE FUELS FURNITURE GARBAGE GAS COLLECTION GAS EMISSIONS GAS FLARING GAS VENTING GHG GLASS GREENHOUSE GREENHOUSE EFFECT GREENHOUSE GAS GREENHOUSE GASES HAZARDOUS SUBSTANCES HDPE HEAT HIGH DENSITY POLYETHYLENE HUMUS HYDROGEN SULFIDE INCINERATION INCINERATION FACILITIES INCINERATION FACILITY INCINERATION WITH ENERGY INCINERATION WITH ENERGY RECOVERY INCINERATORS INCOME IRRIGATION IRRIGATION WATER LAND USE LANDFILL LANDFILL DISPOSAL LANDFILL FACILITY LANDFILL GAS LANDFILL GAS RECOVERY LANDFILL OPERATIONS LANDFILL SITE LANDFILL SITES LANDFILLING LANDFILLS LEACHATE LEACHATE TREATMENT LIQUID WASTES METALS METHANE METHANE GAS METROPOLITAN AREA METROPOLITAN CITY MINING MRF MSW MUNICIPAL SOLID MUNICIPAL SOLID WASTE MUNICIPAL SOLID WASTE MANAGEMENT MUNICIPAL WASTE MUNICIPAL WASTE STREAM NATURAL GAS NITROGEN OXIDES OPEN BURNING ORGANIC MATERIALS OXYGEN PAPER WASTE PARTICULATE PLASTIC PM POLLUTION PROBLEMS POST-CLOSURE PRECIPITATION RAINFALL RAW MATERIALS RECYCLABLE MATERIAL RECYCLABLE MATERIALS RECYCLABLE WASTE RECYCLING REFUSE REFUSE COLLECTION REFUSE COLLECTION VEHICLES RESIDENTIAL WASTE RUNOFF SANITARY ENGINEERS SANITARY LANDFILL SANITARY LANDFILL SITE SCREENING SOLID WASTE SOLID WASTE ASSOCIATION SOLID WASTE COLLECTION SOLID WASTE DATA SOLID WASTE MANAGEMENT SOLID WASTE SYSTEM SOLID WASTE SYSTEMS SOLID WASTE TECHNOLOGY SOURCE REDUCTION STRAW SURFACE WATER SUSTAINABLE DEVELOPMENT SWM TOTAL WASTE GENERATION TRANSFER POINTS TRANSFER STATIONS UNIT PROCESS WASTE COLLECTION WASTE COLLECTION VEHICLES WASTE COMBUSTION WASTE COMPOSITION WASTE DISPOSAL WASTE GENERATION WASTE GENERATION RATE WASTE MANAGEMENT ACTIVITIES WASTE MANAGEMENT SYSTEM WASTE MANAGEMENT SYSTEMS WASTE PAPER WASTE PLASTICS WASTE TO ENERGY WASTE TREATMENT WASTES WASTEWATER WASTEWATER TREATMENT WATER POLLUTANTS WATER POLLUTION WINDROW WTE YARD TRIMMINGS YARD WASTE YARD WASTES World Bank Solid Waste Management Holistic Decision Modeling |
| description |
This study provides support to the
Bank's ability to conduct client dialogue on solid
waste management technology selection, and will contribute
to client decision-making. The goal of the study was to
fully explore the use of the United States Environmental
Protection Agency and the Research Triangle Institute
(EPA/RTI) holistic decision model to study alternative solid
waste systems in a wide array of waste management
conditions, using data collected from cities selected in
each region of the world. Seven cities were selected from
the different regions of development countries served by the
World Bank. Their data was considered to be competent, and
they cooperated with the study teams. They were: Buenos
Aires, Argentina; Conakry, Guinea; Shanghai, China;
Kathmandu, Nepal; Lahore, Pakistan; Amman, Jordan; and
Sarajevo, Bosnia and Herzegovina. These cities represented a
range of economic development factors, income, commercial,
and industrial activity, in addition to their different
physical settings and climate conditions. The cities were
selected to see how such divergent variables would affect
the outcome of the modeling analysis. Each of the selected
cities is one of the largest within its country. In addition
to the 7 target cities from developing countries, Kawasaki,
Japan, and Atlanta, Georgia, were selected for comparative
purposes. The resulting scenarios for each city, and cities
in comparison to others, are shown in detail. While this
report found the level of analysis adequate to indicate how
technologies and scenarios compare, more detail would be
required for deciding on the most cost-effective technology.
The results of this study can be considered a useful guide
for many cities, in understanding the waste disposal options
most appropriate to their conditions. |
| format |
Economic & Sector Work :: Other Environmental Study |
| author |
World Bank |
| author_facet |
World Bank |
| author_sort |
World Bank |
| title |
Solid Waste Management Holistic Decision Modeling |
| title_short |
Solid Waste Management Holistic Decision Modeling |
| title_full |
Solid Waste Management Holistic Decision Modeling |
| title_fullStr |
Solid Waste Management Holistic Decision Modeling |
| title_full_unstemmed |
Solid Waste Management Holistic Decision Modeling |
| title_sort |
solid waste management holistic decision modeling |
| publisher |
Washington, DC |
| publishDate |
2013 |
| url |
http://documents.worldbank.org/curated/en/2008/06/16371282/global-study-purpose-global-world-bank-guidance-development-solid-waste-management-holistic-decision-modeling http://hdl.handle.net/10986/12903 |
| _version_ |
1764420825584238592 |
| spelling |
okr-10986-129032021-04-23T14:03:03Z Solid Waste Management Holistic Decision Modeling World Bank AIR EMISSIONS AIR POLLUTANTS AIR POLLUTION ALUMINUM ANAEROBIC DIGESTION ANIMAL MANURE ANIMAL WASTE ASH ATMOSPHERE AVERAGE TEMPERATURE BACTERIA BALERS BARGE TRANSFER BIOCHEMICAL OXYGEN DEMAND BIOGAS BOD BOILERS BONES BRITISH THERMAL UNIT BTU BULKY WASTE CARBON CARBON DIOXIDE CARBON EMISSIONS CARBON MONOXIDE CHEMICAL INDUSTRY CLIMATE CHANGE COAL COLLECTED WASTE COLLECTION FREQUENCY COLLECTION SYSTEMS COLLECTION VEHICLES COMBUSTION COMBUSTION ACTIVITIES COMBUSTION FACILITIES COMBUSTION PROCESS COMMERCIAL WASTE COMMINGLED RECYCLABLES COMPACTOR TRUCKS COMPOST COMPOST PRODUCT COMPOSTABLE MATERIALS COMPOSTING COMPOSTING FACILITIES COMPOSTING PROCESS CONSUMPTION OF ENERGY DAILY WASTE COLLECTION DIESEL FUEL DISPOSAL DISPOSAL COST DISPOSAL METHOD DISPOSAL OF WASTE DISPOSAL SITE DISPOSAL SITES ELECTRIC POWER ELECTRICITY ELECTRICITY PRODUCTION EMISSION EMISSION DATA EMISSION FACTORS EMISSION REDUCTION ENERGY CONSUMPTION ENERGY PRODUCTION ENERGY SAVINGS ENERGY TECHNOLOGIES ENVIRONMENTAL ASPECTS ENVIRONMENTAL ASSESSMENT ENVIRONMENTAL CONTROLS ENVIRONMENTAL IMPACT ENVIRONMENTAL MANAGEMENT ENVIRONMENTAL PROTECTION ENVIRONMENTAL PROTECTION AGENCY ENVIRONMENTAL SANITATION FINAL DISPOSAL FINAL DISPOSAL SITE FIRES FOOD WASTE FOSSIL FUELS FUEL FUEL COMBUSTION FUEL TYPE FUELS FURNITURE GARBAGE GAS COLLECTION GAS EMISSIONS GAS FLARING GAS VENTING GHG GLASS GREENHOUSE GREENHOUSE EFFECT GREENHOUSE GAS GREENHOUSE GASES HAZARDOUS SUBSTANCES HDPE HEAT HIGH DENSITY POLYETHYLENE HUMUS HYDROGEN SULFIDE INCINERATION INCINERATION FACILITIES INCINERATION FACILITY INCINERATION WITH ENERGY INCINERATION WITH ENERGY RECOVERY INCINERATORS INCOME IRRIGATION IRRIGATION WATER LAND USE LANDFILL LANDFILL DISPOSAL LANDFILL FACILITY LANDFILL GAS LANDFILL GAS RECOVERY LANDFILL OPERATIONS LANDFILL SITE LANDFILL SITES LANDFILLING LANDFILLS LEACHATE LEACHATE TREATMENT LIQUID WASTES METALS METHANE METHANE GAS METROPOLITAN AREA METROPOLITAN CITY MINING MRF MSW MUNICIPAL SOLID MUNICIPAL SOLID WASTE MUNICIPAL SOLID WASTE MANAGEMENT MUNICIPAL WASTE MUNICIPAL WASTE STREAM NATURAL GAS NITROGEN OXIDES OPEN BURNING ORGANIC MATERIALS OXYGEN PAPER WASTE PARTICULATE PLASTIC PM POLLUTION PROBLEMS POST-CLOSURE PRECIPITATION RAINFALL RAW MATERIALS RECYCLABLE MATERIAL RECYCLABLE MATERIALS RECYCLABLE WASTE RECYCLING REFUSE REFUSE COLLECTION REFUSE COLLECTION VEHICLES RESIDENTIAL WASTE RUNOFF SANITARY ENGINEERS SANITARY LANDFILL SANITARY LANDFILL SITE SCREENING SOLID WASTE SOLID WASTE ASSOCIATION SOLID WASTE COLLECTION SOLID WASTE DATA SOLID WASTE MANAGEMENT SOLID WASTE SYSTEM SOLID WASTE SYSTEMS SOLID WASTE TECHNOLOGY SOURCE REDUCTION STRAW SURFACE WATER SUSTAINABLE DEVELOPMENT SWM TOTAL WASTE GENERATION TRANSFER POINTS TRANSFER STATIONS UNIT PROCESS WASTE COLLECTION WASTE COLLECTION VEHICLES WASTE COMBUSTION WASTE COMPOSITION WASTE DISPOSAL WASTE GENERATION WASTE GENERATION RATE WASTE MANAGEMENT ACTIVITIES WASTE MANAGEMENT SYSTEM WASTE MANAGEMENT SYSTEMS WASTE PAPER WASTE PLASTICS WASTE TO ENERGY WASTE TREATMENT WASTES WASTEWATER WASTEWATER TREATMENT WATER POLLUTANTS WATER POLLUTION WINDROW WTE YARD TRIMMINGS YARD WASTE YARD WASTES This study provides support to the Bank's ability to conduct client dialogue on solid waste management technology selection, and will contribute to client decision-making. The goal of the study was to fully explore the use of the United States Environmental Protection Agency and the Research Triangle Institute (EPA/RTI) holistic decision model to study alternative solid waste systems in a wide array of waste management conditions, using data collected from cities selected in each region of the world. Seven cities were selected from the different regions of development countries served by the World Bank. Their data was considered to be competent, and they cooperated with the study teams. They were: Buenos Aires, Argentina; Conakry, Guinea; Shanghai, China; Kathmandu, Nepal; Lahore, Pakistan; Amman, Jordan; and Sarajevo, Bosnia and Herzegovina. These cities represented a range of economic development factors, income, commercial, and industrial activity, in addition to their different physical settings and climate conditions. The cities were selected to see how such divergent variables would affect the outcome of the modeling analysis. Each of the selected cities is one of the largest within its country. In addition to the 7 target cities from developing countries, Kawasaki, Japan, and Atlanta, Georgia, were selected for comparative purposes. The resulting scenarios for each city, and cities in comparison to others, are shown in detail. While this report found the level of analysis adequate to indicate how technologies and scenarios compare, more detail would be required for deciding on the most cost-effective technology. The results of this study can be considered a useful guide for many cities, in understanding the waste disposal options most appropriate to their conditions. 2013-03-25T17:11:27Z 2013-03-25T17:11:27Z 2008-06 http://documents.worldbank.org/curated/en/2008/06/16371282/global-study-purpose-global-world-bank-guidance-development-solid-waste-management-holistic-decision-modeling http://hdl.handle.net/10986/12903 English en_US CC BY 3.0 IGO http://creativecommons.org/licenses/by/3.0/igo/ World Bank Washington, DC Economic & Sector Work :: Other Environmental Study Economic & Sector Work |