Understanding the Differences between Cookstoves

Understanding the Differences between Cookstoves

The growing interest in clean cooking, with its potential benefits for human health, environmental protection, and climate change, has prompted development specialists to reconsider the quality and performance of cook stoves. Governments, donors, and development organizations want to ensure that the cook stoves they promote meet standards that will yield the greatest possible benefits over time, when adopted and used properly. Households need to understand differences in cook stove performance if they are to select those that represent the best value for money. In this context, the report presents problems of traditional cook stoves; benefits of fuel-efficient cook stoves; potential benefits of advanced combustion cook stoves; and can cook stove performance be measured?

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Bibliographic Details
Main Authors: Ekouevi, Koffi, Freeman, Kate Kennedy, Soni, Ruchi
Format: Brief biblioteca
Language:English
en_US
Published: Washington, DC: World Bank 2014-05-15
Subjects:ACCESS TO ELECTRICITY, AGRICULTURAL WASTE, AIR, AIR POLLUTION, AIR QUALITY, AVAILABILITY, BENZENE, BIOMASS, BIOMASS FUELS, BIOMASS GASIFIER, BIOMASS STOVE, BIOMASS STOVES, BLACK CARBON, BOTTOM LINE, BURN FUEL, CARBON CREDITS, CARBON DIOXIDE, CARBON FINANCING, CARBON MONOXIDE, CEMENT, CHARCOAL, CLEAN DEVELOPMENT, CLEAN FUELS, CLIMATE, CLIMATE CHANGE, CLIMATE CHANGE IMPACT, CLIMATE CHANGE MITIGATION, CLIMATE CHANGES, CLIMATE SYSTEM, CLOUDS, CO, CO2, COAL, COMBUSTION, COMBUSTION CHAMBER, COMBUSTION CHAMBERS, COMBUSTION EFFICIENCY, COMBUSTION OF FUELS, COOKING, CORN, DEFORESTATION, DIESEL, DUNG, DUST, EFFICIENT STOVES, ELECTRICITY, ELECTRICITY SUPPLY, EMISSION, EMISSION RATES, EMISSION-REDUCTION, EMISSIONS REDUCTIONS, ENERGY DEVELOPMENT, ENERGY ECONOMIST, ENERGY EFFICIENCY, ENERGY PRACTICE, ENERGY PROJECTS, ENERGY SECTOR, ENERGY SYSTEMS, ENERGY TECHNOLOGIES, ENERGY USE, ENVIRONMENTAL PROTECTION, FLUE GASES, FOREST, FOREST RESOURCES, FORMALDEHYDE, FOSSIL, FOSSIL FUEL, FOSSIL FUEL COMBUSTION, FOSSIL FUELS, FUEL CONSUMPTION, FUEL EFFICIENCY, FUEL QUALITY, FUEL REQUIREMENTS, FUEL TYPE, FUEL USE, FUELS, GAS, GASES, GASIFIER, GENERATION, GENERATION CAPACITY, GREENHOUSE, GREENHOUSE GASES, GREENHOUSE-GAS, GREENHOUSE-GAS EMISSIONS, HARMFUL EMISSIONS, HEALTH HAZARD, HEAT, HEAT TRANSFER, HOT GASES, HUMAN HEALTH, HYDROCARBONS, PARTICLES, PARTICULATE, PARTICULATE MATTER, PARTICULATES, PELLETS, PETROLEUM, POLLUTANTS, PROPANE, RENEWABLE ENERGY, RENEWABLE PORTFOLIO STANDARD, RENEWABLE SOURCES, RICE HUSKS, SMOKE, SOLID FUELS, SOURCE OF ELECTRICITY, SUSTAINABLE DEVELOPMENT, SUSTAINABLE ENERGY, TEMPERATURE, THERMAL EFFICIENCY, UTILITIES, WIND, WIND POWER, WIND POWER CAPACITY, WOOD,
Online Access:http://documents.worldbank.org/curated/en/2014/01/19539994/understanding-differences-between-cook-stoves
http://hdl.handle.net/10986/18411
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spelling dig-okr-10986184112021-06-14T10:18:46Z Understanding the Differences between Cookstoves Ekouevi, Koffi Freeman, Kate Kennedy Soni, Ruchi ACCESS TO ELECTRICITY AGRICULTURAL WASTE AIR AIR POLLUTION AIR QUALITY AVAILABILITY BENZENE BIOMASS BIOMASS FUELS BIOMASS GASIFIER BIOMASS STOVE BIOMASS STOVES BLACK CARBON BOTTOM LINE BURN FUEL CARBON CREDITS CARBON DIOXIDE CARBON FINANCING CARBON MONOXIDE CEMENT CHARCOAL CLEAN DEVELOPMENT CLEAN FUELS CLIMATE CLIMATE CHANGE CLIMATE CHANGE IMPACT CLIMATE CHANGE MITIGATION CLIMATE CHANGES CLIMATE SYSTEM CLOUDS CO CO2 COAL COMBUSTION COMBUSTION CHAMBER COMBUSTION CHAMBERS COMBUSTION EFFICIENCY COMBUSTION OF FUELS COOKING CORN DEFORESTATION DIESEL DUNG DUST EFFICIENT STOVES ELECTRICITY ELECTRICITY SUPPLY EMISSION EMISSION RATES EMISSION-REDUCTION EMISSIONS REDUCTIONS ENERGY DEVELOPMENT ENERGY ECONOMIST ENERGY EFFICIENCY ENERGY PRACTICE ENERGY PROJECTS ENERGY SECTOR ENERGY SYSTEMS ENERGY TECHNOLOGIES ENERGY USE ENVIRONMENTAL PROTECTION FLUE GASES FOREST FOREST RESOURCES FORMALDEHYDE FOSSIL FOSSIL FUEL FOSSIL FUEL COMBUSTION FOSSIL FUELS FUEL CONSUMPTION FUEL EFFICIENCY FUEL QUALITY FUEL REQUIREMENTS FUEL TYPE FUEL USE FUELS GAS GASES GASIFIER GENERATION GENERATION CAPACITY GREENHOUSE GREENHOUSE GASES GREENHOUSE-GAS GREENHOUSE-GAS EMISSIONS HARMFUL EMISSIONS HEALTH HAZARD HEAT HEAT TRANSFER HOT GASES HUMAN HEALTH HYDROCARBONS PARTICLES PARTICULATE PARTICULATE MATTER PARTICULATES PELLETS PETROLEUM POLLUTANTS PROPANE RENEWABLE ENERGY RENEWABLE PORTFOLIO STANDARD RENEWABLE SOURCES RICE HUSKS SMOKE SOLID FUELS SOURCE OF ELECTRICITY SUSTAINABLE DEVELOPMENT SUSTAINABLE ENERGY TEMPERATURE THERMAL EFFICIENCY UTILITIES WIND WIND POWER WIND POWER CAPACITY WOOD The growing interest in clean cooking, with its potential benefits for human health, environmental protection, and climate change, has prompted development specialists to reconsider the quality and performance of cook stoves. Governments, donors, and development organizations want to ensure that the cook stoves they promote meet standards that will yield the greatest possible benefits over time, when adopted and used properly. Households need to understand differences in cook stove performance if they are to select those that represent the best value for money. In this context, the report presents problems of traditional cook stoves; benefits of fuel-efficient cook stoves; potential benefits of advanced combustion cook stoves; and can cook stove performance be measured? 2014-05-27T20:04:07Z 2014-05-27T20:04:07Z 2014-05-15 Brief http://documents.worldbank.org/curated/en/2014/01/19539994/understanding-differences-between-cook-stoves http://hdl.handle.net/10986/18411 English en_US Live Wire, 2014/7 CC BY 3.0 IGO http://creativecommons.org/licenses/by/3.0/igo/ Washington, DC: World Bank Publications & Research :: Brief Publications & Research
institution Banco Mundial
collection DSpace
country Estados Unidos
countrycode US
component Bibliográfico
access En linea
databasecode dig-okr
tag biblioteca
region America del Norte
libraryname Biblioteca del Banco Mundial
language English
en_US
topic ACCESS TO ELECTRICITY
AGRICULTURAL WASTE
AIR
AIR POLLUTION
AIR QUALITY
AVAILABILITY
BENZENE
BIOMASS
BIOMASS FUELS
BIOMASS GASIFIER
BIOMASS STOVE
BIOMASS STOVES
BLACK CARBON
BOTTOM LINE
BURN FUEL
CARBON CREDITS
CARBON DIOXIDE
CARBON FINANCING
CARBON MONOXIDE
CEMENT
CHARCOAL
CLEAN DEVELOPMENT
CLEAN FUELS
CLIMATE
CLIMATE CHANGE
CLIMATE CHANGE IMPACT
CLIMATE CHANGE MITIGATION
CLIMATE CHANGES
CLIMATE SYSTEM
CLOUDS
CO
CO2
COAL
COMBUSTION
COMBUSTION CHAMBER
COMBUSTION CHAMBERS
COMBUSTION EFFICIENCY
COMBUSTION OF FUELS
COOKING
CORN
DEFORESTATION
DIESEL
DUNG
DUST
EFFICIENT STOVES
ELECTRICITY
ELECTRICITY SUPPLY
EMISSION
EMISSION RATES
EMISSION-REDUCTION
EMISSIONS REDUCTIONS
ENERGY DEVELOPMENT
ENERGY ECONOMIST
ENERGY EFFICIENCY
ENERGY PRACTICE
ENERGY PROJECTS
ENERGY SECTOR
ENERGY SYSTEMS
ENERGY TECHNOLOGIES
ENERGY USE
ENVIRONMENTAL PROTECTION
FLUE GASES
FOREST
FOREST RESOURCES
FORMALDEHYDE
FOSSIL
FOSSIL FUEL
FOSSIL FUEL COMBUSTION
FOSSIL FUELS
FUEL CONSUMPTION
FUEL EFFICIENCY
FUEL QUALITY
FUEL REQUIREMENTS
FUEL TYPE
FUEL USE
FUELS
GAS
GASES
GASIFIER
GENERATION
GENERATION CAPACITY
GREENHOUSE
GREENHOUSE GASES
GREENHOUSE-GAS
GREENHOUSE-GAS EMISSIONS
HARMFUL EMISSIONS
HEALTH HAZARD
HEAT
HEAT TRANSFER
HOT GASES
HUMAN HEALTH
HYDROCARBONS
PARTICLES
PARTICULATE
PARTICULATE MATTER
PARTICULATES
PELLETS
PETROLEUM
POLLUTANTS
PROPANE
RENEWABLE ENERGY
RENEWABLE PORTFOLIO STANDARD
RENEWABLE SOURCES
RICE HUSKS
SMOKE
SOLID FUELS
SOURCE OF ELECTRICITY
SUSTAINABLE DEVELOPMENT
SUSTAINABLE ENERGY
TEMPERATURE
THERMAL EFFICIENCY
UTILITIES
WIND
WIND POWER
WIND POWER CAPACITY
WOOD
ACCESS TO ELECTRICITY
AGRICULTURAL WASTE
AIR
AIR POLLUTION
AIR QUALITY
AVAILABILITY
BENZENE
BIOMASS
BIOMASS FUELS
BIOMASS GASIFIER
BIOMASS STOVE
BIOMASS STOVES
BLACK CARBON
BOTTOM LINE
BURN FUEL
CARBON CREDITS
CARBON DIOXIDE
CARBON FINANCING
CARBON MONOXIDE
CEMENT
CHARCOAL
CLEAN DEVELOPMENT
CLEAN FUELS
CLIMATE
CLIMATE CHANGE
CLIMATE CHANGE IMPACT
CLIMATE CHANGE MITIGATION
CLIMATE CHANGES
CLIMATE SYSTEM
CLOUDS
CO
CO2
COAL
COMBUSTION
COMBUSTION CHAMBER
COMBUSTION CHAMBERS
COMBUSTION EFFICIENCY
COMBUSTION OF FUELS
COOKING
CORN
DEFORESTATION
DIESEL
DUNG
DUST
EFFICIENT STOVES
ELECTRICITY
ELECTRICITY SUPPLY
EMISSION
EMISSION RATES
EMISSION-REDUCTION
EMISSIONS REDUCTIONS
ENERGY DEVELOPMENT
ENERGY ECONOMIST
ENERGY EFFICIENCY
ENERGY PRACTICE
ENERGY PROJECTS
ENERGY SECTOR
ENERGY SYSTEMS
ENERGY TECHNOLOGIES
ENERGY USE
ENVIRONMENTAL PROTECTION
FLUE GASES
FOREST
FOREST RESOURCES
FORMALDEHYDE
FOSSIL
FOSSIL FUEL
FOSSIL FUEL COMBUSTION
FOSSIL FUELS
FUEL CONSUMPTION
FUEL EFFICIENCY
FUEL QUALITY
FUEL REQUIREMENTS
FUEL TYPE
FUEL USE
FUELS
GAS
GASES
GASIFIER
GENERATION
GENERATION CAPACITY
GREENHOUSE
GREENHOUSE GASES
GREENHOUSE-GAS
GREENHOUSE-GAS EMISSIONS
HARMFUL EMISSIONS
HEALTH HAZARD
HEAT
HEAT TRANSFER
HOT GASES
HUMAN HEALTH
HYDROCARBONS
PARTICLES
PARTICULATE
PARTICULATE MATTER
PARTICULATES
PELLETS
PETROLEUM
POLLUTANTS
PROPANE
RENEWABLE ENERGY
RENEWABLE PORTFOLIO STANDARD
RENEWABLE SOURCES
RICE HUSKS
SMOKE
SOLID FUELS
SOURCE OF ELECTRICITY
SUSTAINABLE DEVELOPMENT
SUSTAINABLE ENERGY
TEMPERATURE
THERMAL EFFICIENCY
UTILITIES
WIND
WIND POWER
WIND POWER CAPACITY
WOOD
spellingShingle ACCESS TO ELECTRICITY
AGRICULTURAL WASTE
AIR
AIR POLLUTION
AIR QUALITY
AVAILABILITY
BENZENE
BIOMASS
BIOMASS FUELS
BIOMASS GASIFIER
BIOMASS STOVE
BIOMASS STOVES
BLACK CARBON
BOTTOM LINE
BURN FUEL
CARBON CREDITS
CARBON DIOXIDE
CARBON FINANCING
CARBON MONOXIDE
CEMENT
CHARCOAL
CLEAN DEVELOPMENT
CLEAN FUELS
CLIMATE
CLIMATE CHANGE
CLIMATE CHANGE IMPACT
CLIMATE CHANGE MITIGATION
CLIMATE CHANGES
CLIMATE SYSTEM
CLOUDS
CO
CO2
COAL
COMBUSTION
COMBUSTION CHAMBER
COMBUSTION CHAMBERS
COMBUSTION EFFICIENCY
COMBUSTION OF FUELS
COOKING
CORN
DEFORESTATION
DIESEL
DUNG
DUST
EFFICIENT STOVES
ELECTRICITY
ELECTRICITY SUPPLY
EMISSION
EMISSION RATES
EMISSION-REDUCTION
EMISSIONS REDUCTIONS
ENERGY DEVELOPMENT
ENERGY ECONOMIST
ENERGY EFFICIENCY
ENERGY PRACTICE
ENERGY PROJECTS
ENERGY SECTOR
ENERGY SYSTEMS
ENERGY TECHNOLOGIES
ENERGY USE
ENVIRONMENTAL PROTECTION
FLUE GASES
FOREST
FOREST RESOURCES
FORMALDEHYDE
FOSSIL
FOSSIL FUEL
FOSSIL FUEL COMBUSTION
FOSSIL FUELS
FUEL CONSUMPTION
FUEL EFFICIENCY
FUEL QUALITY
FUEL REQUIREMENTS
FUEL TYPE
FUEL USE
FUELS
GAS
GASES
GASIFIER
GENERATION
GENERATION CAPACITY
GREENHOUSE
GREENHOUSE GASES
GREENHOUSE-GAS
GREENHOUSE-GAS EMISSIONS
HARMFUL EMISSIONS
HEALTH HAZARD
HEAT
HEAT TRANSFER
HOT GASES
HUMAN HEALTH
HYDROCARBONS
PARTICLES
PARTICULATE
PARTICULATE MATTER
PARTICULATES
PELLETS
PETROLEUM
POLLUTANTS
PROPANE
RENEWABLE ENERGY
RENEWABLE PORTFOLIO STANDARD
RENEWABLE SOURCES
RICE HUSKS
SMOKE
SOLID FUELS
SOURCE OF ELECTRICITY
SUSTAINABLE DEVELOPMENT
SUSTAINABLE ENERGY
TEMPERATURE
THERMAL EFFICIENCY
UTILITIES
WIND
WIND POWER
WIND POWER CAPACITY
WOOD
ACCESS TO ELECTRICITY
AGRICULTURAL WASTE
AIR
AIR POLLUTION
AIR QUALITY
AVAILABILITY
BENZENE
BIOMASS
BIOMASS FUELS
BIOMASS GASIFIER
BIOMASS STOVE
BIOMASS STOVES
BLACK CARBON
BOTTOM LINE
BURN FUEL
CARBON CREDITS
CARBON DIOXIDE
CARBON FINANCING
CARBON MONOXIDE
CEMENT
CHARCOAL
CLEAN DEVELOPMENT
CLEAN FUELS
CLIMATE
CLIMATE CHANGE
CLIMATE CHANGE IMPACT
CLIMATE CHANGE MITIGATION
CLIMATE CHANGES
CLIMATE SYSTEM
CLOUDS
CO
CO2
COAL
COMBUSTION
COMBUSTION CHAMBER
COMBUSTION CHAMBERS
COMBUSTION EFFICIENCY
COMBUSTION OF FUELS
COOKING
CORN
DEFORESTATION
DIESEL
DUNG
DUST
EFFICIENT STOVES
ELECTRICITY
ELECTRICITY SUPPLY
EMISSION
EMISSION RATES
EMISSION-REDUCTION
EMISSIONS REDUCTIONS
ENERGY DEVELOPMENT
ENERGY ECONOMIST
ENERGY EFFICIENCY
ENERGY PRACTICE
ENERGY PROJECTS
ENERGY SECTOR
ENERGY SYSTEMS
ENERGY TECHNOLOGIES
ENERGY USE
ENVIRONMENTAL PROTECTION
FLUE GASES
FOREST
FOREST RESOURCES
FORMALDEHYDE
FOSSIL
FOSSIL FUEL
FOSSIL FUEL COMBUSTION
FOSSIL FUELS
FUEL CONSUMPTION
FUEL EFFICIENCY
FUEL QUALITY
FUEL REQUIREMENTS
FUEL TYPE
FUEL USE
FUELS
GAS
GASES
GASIFIER
GENERATION
GENERATION CAPACITY
GREENHOUSE
GREENHOUSE GASES
GREENHOUSE-GAS
GREENHOUSE-GAS EMISSIONS
HARMFUL EMISSIONS
HEALTH HAZARD
HEAT
HEAT TRANSFER
HOT GASES
HUMAN HEALTH
HYDROCARBONS
PARTICLES
PARTICULATE
PARTICULATE MATTER
PARTICULATES
PELLETS
PETROLEUM
POLLUTANTS
PROPANE
RENEWABLE ENERGY
RENEWABLE PORTFOLIO STANDARD
RENEWABLE SOURCES
RICE HUSKS
SMOKE
SOLID FUELS
SOURCE OF ELECTRICITY
SUSTAINABLE DEVELOPMENT
SUSTAINABLE ENERGY
TEMPERATURE
THERMAL EFFICIENCY
UTILITIES
WIND
WIND POWER
WIND POWER CAPACITY
WOOD
Ekouevi, Koffi
Freeman, Kate Kennedy
Soni, Ruchi
Understanding the Differences between Cookstoves
description The growing interest in clean cooking, with its potential benefits for human health, environmental protection, and climate change, has prompted development specialists to reconsider the quality and performance of cook stoves. Governments, donors, and development organizations want to ensure that the cook stoves they promote meet standards that will yield the greatest possible benefits over time, when adopted and used properly. Households need to understand differences in cook stove performance if they are to select those that represent the best value for money. In this context, the report presents problems of traditional cook stoves; benefits of fuel-efficient cook stoves; potential benefits of advanced combustion cook stoves; and can cook stove performance be measured?
format Brief
topic_facet ACCESS TO ELECTRICITY
AGRICULTURAL WASTE
AIR
AIR POLLUTION
AIR QUALITY
AVAILABILITY
BENZENE
BIOMASS
BIOMASS FUELS
BIOMASS GASIFIER
BIOMASS STOVE
BIOMASS STOVES
BLACK CARBON
BOTTOM LINE
BURN FUEL
CARBON CREDITS
CARBON DIOXIDE
CARBON FINANCING
CARBON MONOXIDE
CEMENT
CHARCOAL
CLEAN DEVELOPMENT
CLEAN FUELS
CLIMATE
CLIMATE CHANGE
CLIMATE CHANGE IMPACT
CLIMATE CHANGE MITIGATION
CLIMATE CHANGES
CLIMATE SYSTEM
CLOUDS
CO
CO2
COAL
COMBUSTION
COMBUSTION CHAMBER
COMBUSTION CHAMBERS
COMBUSTION EFFICIENCY
COMBUSTION OF FUELS
COOKING
CORN
DEFORESTATION
DIESEL
DUNG
DUST
EFFICIENT STOVES
ELECTRICITY
ELECTRICITY SUPPLY
EMISSION
EMISSION RATES
EMISSION-REDUCTION
EMISSIONS REDUCTIONS
ENERGY DEVELOPMENT
ENERGY ECONOMIST
ENERGY EFFICIENCY
ENERGY PRACTICE
ENERGY PROJECTS
ENERGY SECTOR
ENERGY SYSTEMS
ENERGY TECHNOLOGIES
ENERGY USE
ENVIRONMENTAL PROTECTION
FLUE GASES
FOREST
FOREST RESOURCES
FORMALDEHYDE
FOSSIL
FOSSIL FUEL
FOSSIL FUEL COMBUSTION
FOSSIL FUELS
FUEL CONSUMPTION
FUEL EFFICIENCY
FUEL QUALITY
FUEL REQUIREMENTS
FUEL TYPE
FUEL USE
FUELS
GAS
GASES
GASIFIER
GENERATION
GENERATION CAPACITY
GREENHOUSE
GREENHOUSE GASES
GREENHOUSE-GAS
GREENHOUSE-GAS EMISSIONS
HARMFUL EMISSIONS
HEALTH HAZARD
HEAT
HEAT TRANSFER
HOT GASES
HUMAN HEALTH
HYDROCARBONS
PARTICLES
PARTICULATE
PARTICULATE MATTER
PARTICULATES
PELLETS
PETROLEUM
POLLUTANTS
PROPANE
RENEWABLE ENERGY
RENEWABLE PORTFOLIO STANDARD
RENEWABLE SOURCES
RICE HUSKS
SMOKE
SOLID FUELS
SOURCE OF ELECTRICITY
SUSTAINABLE DEVELOPMENT
SUSTAINABLE ENERGY
TEMPERATURE
THERMAL EFFICIENCY
UTILITIES
WIND
WIND POWER
WIND POWER CAPACITY
WOOD
author Ekouevi, Koffi
Freeman, Kate Kennedy
Soni, Ruchi
author_facet Ekouevi, Koffi
Freeman, Kate Kennedy
Soni, Ruchi
author_sort Ekouevi, Koffi
title Understanding the Differences between Cookstoves
title_short Understanding the Differences between Cookstoves
title_full Understanding the Differences between Cookstoves
title_fullStr Understanding the Differences between Cookstoves
title_full_unstemmed Understanding the Differences between Cookstoves
title_sort understanding the differences between cookstoves
publisher Washington, DC: World Bank
publishDate 2014-05-15
url http://documents.worldbank.org/curated/en/2014/01/19539994/understanding-differences-between-cook-stoves
http://hdl.handle.net/10986/18411
work_keys_str_mv AT ekouevikoffi understandingthedifferencesbetweencookstoves
AT freemankatekennedy understandingthedifferencesbetweencookstoves
AT soniruchi understandingthedifferencesbetweencookstoves
_version_ 1756573594342653952

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