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La gestion de l’énergie est un sujet d’actualité dans la lutte contre le dérèglement clima- tique. En effet, l’Union Européenne s’est fixé des objectifs de transitions énergétiques dans de nombreux domaines. L’un d’entre-eux est la mobilité, avec une volonté de réduire de 30% les émissions de gaz à effet de serre en 2030, par rapport à celles de 2005 [Climat.be, 2019]. Pour atteindre cet objectif, le Luxembourg doit réaliser d’importants efforts car son secteur du transport représente 57,3 % des émissions globales du pays [Environnement luxembourgeois, 2021]. Afin de réduire ces émissions, la politique énergétique du pays veut transiter vers une augmen- tation de l’utilisation d’hydrogène vert. En effet, son utilisation tend à se démocratiser dans le futur grâce à ses avantages : ses propriétés de stockage, sa haute réactivité, sa légèreté et sa grande densité énergétique massique [Nalbant and Colpan, 2020]. Cependant, de nombreux défis s’imposent quant à sa production, son stockage et son approvisionnement dans le pays. Afin de développer la production d’hydrogène vert au Luxembourg, de nombreux projets se développent. Deux d’entre-eux sont en étude sur le site de Naturgas Kielen, une entreprise de biométhanisation. Un premier, nommé VaBHyoGaz, veut convertir une partie du biogaz produit par Naturgas Kielen en hydrogène (reforming). Le second, géré par l’entreprise GPSS, est un projet d’électrolyse alimenté par des énergies renouvelables. Une étude technique basée sur la littérature est dès lors réalisée dans ce travail. Ensuite, des études économiques ont été réalisées via l’indicateur de la valeur actuelle nette afin de déter- miner si les projets sont viables financièrement. Cette étude a permis de prouver que les deux projets pouvaient être rentables, sans toutefois concurrencer la production actuelle via des éner- gies fossiles. Pour le projet de reforming, il sera impératif de réduire le coût de production du biogaz afin d’assurer une certaine rentabilité. Pour le projet d’électrolyse, il a été prouvé que l’utilisation de batteries n’était pas nécessaire pour l’électrolyseur PEM. De plus, le bon déroulement du projet va nécessiter des gestions optimales de la production et du stockage afin d’éviter toute fuite et accident. Enfin, l’utilisation de l’hydrogène sera cruciale quant à l’impact de son utilisation sur l’envi- ronnement. Il est démontré grâce à la littérature que si le transport veut être décarbonné grâce à l’hydrogène, alors il faut privilégier son utilisation dans la mobilité lourde.
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Bioenergy is renewable energy obtained from biomass—any organic material that has stored sunlight in the form of chemical energy. Biogas is among the biofuels that can be obtained from biomass resources, including biodegradable wastes like manure, sewage sludge, the organic fraction of municipal solid wastes, slaughterhouse waste, crop residues, and more recently lignocellulosic biomass and algae. Within the framework of the circular economy, biogas production from biodegradable waste is particularly interesting, as it helps to save resources while reducing environmental pollution. Besides, lignocellulosic biomass and algae do not compete for arable land with food crops (in contrast with energy crops). Hence, they constitute a novel source of biomass for bioenergy.Biogas plants may involve both high-tech and low-tech digesters, ranging from industrial-scale plants to small-scale farms and even households. They pose an alternative for decentralized bioenergy production in rural areas. Indeed, the biogas produced can be used in heaters, engines, combined heat and power units, and even cookstoves at the household level. Notwithstanding, digesters are considered to be a sustainable technology that can improve the living conditions of farmers by covering energy needs and boosting nutrient recycling. Thanks to their technical, socio-economic, and environmental benefits, rural biogas plants have been spreading around the world since the 1970s, with a large focus on farm-based systems and households. However, several challenges still need to be overcome in order to improve the technology and financial viability.
Technology: general issues --- Environmental science, engineering & technology --- Mixing --- optimised --- household digester --- Chinese dome digester (CDD) --- self-agitation --- blank --- mixing --- Chinese dome digester --- impeller mixed digester --- unstirred digester --- hydraulically mixed --- total solids (TS) concentration --- plug-flow reactor --- anaerobic digestion --- animal manures --- biogas --- unconfined gas injection mixing --- mixing recirculation --- biomethane potential tests --- Italy --- manure --- energy crops --- agriculture residues --- digestate --- biochemical methane potential --- micro-aeration --- iron --- bioenergy --- H2S scrubber --- methane --- fermentation --- dairy --- poultry --- absorbent --- ammonia --- inhibition --- acclimatization --- trace elements --- anaerobic treatment --- energy assessment --- rural sanitation --- sludge --- wastewater --- agricultural runoff --- biomethane --- biorefinery --- microalgae --- photobioreactor --- pretreatment --- low cost digester --- psychrophilic anaerobic digestion --- thermal behavior --- anaerobic co-digestion --- slaughterhouse wastewater --- synergistic effects --- kinetic modeling --- biodegradability
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Bioenergy is renewable energy obtained from biomass—any organic material that has stored sunlight in the form of chemical energy. Biogas is among the biofuels that can be obtained from biomass resources, including biodegradable wastes like manure, sewage sludge, the organic fraction of municipal solid wastes, slaughterhouse waste, crop residues, and more recently lignocellulosic biomass and algae. Within the framework of the circular economy, biogas production from biodegradable waste is particularly interesting, as it helps to save resources while reducing environmental pollution. Besides, lignocellulosic biomass and algae do not compete for arable land with food crops (in contrast with energy crops). Hence, they constitute a novel source of biomass for bioenergy.Biogas plants may involve both high-tech and low-tech digesters, ranging from industrial-scale plants to small-scale farms and even households. They pose an alternative for decentralized bioenergy production in rural areas. Indeed, the biogas produced can be used in heaters, engines, combined heat and power units, and even cookstoves at the household level. Notwithstanding, digesters are considered to be a sustainable technology that can improve the living conditions of farmers by covering energy needs and boosting nutrient recycling. Thanks to their technical, socio-economic, and environmental benefits, rural biogas plants have been spreading around the world since the 1970s, with a large focus on farm-based systems and households. However, several challenges still need to be overcome in order to improve the technology and financial viability.
Mixing --- optimised --- household digester --- Chinese dome digester (CDD) --- self-agitation --- blank --- mixing --- Chinese dome digester --- impeller mixed digester --- unstirred digester --- hydraulically mixed --- total solids (TS) concentration --- plug-flow reactor --- anaerobic digestion --- animal manures --- biogas --- unconfined gas injection mixing --- mixing recirculation --- biomethane potential tests --- Italy --- manure --- energy crops --- agriculture residues --- digestate --- biochemical methane potential --- micro-aeration --- iron --- bioenergy --- H2S scrubber --- methane --- fermentation --- dairy --- poultry --- absorbent --- ammonia --- inhibition --- acclimatization --- trace elements --- anaerobic treatment --- energy assessment --- rural sanitation --- sludge --- wastewater --- agricultural runoff --- biomethane --- biorefinery --- microalgae --- photobioreactor --- pretreatment --- low cost digester --- psychrophilic anaerobic digestion --- thermal behavior --- anaerobic co-digestion --- slaughterhouse wastewater --- synergistic effects --- kinetic modeling --- biodegradability
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Bioenergy is renewable energy obtained from biomass—any organic material that has stored sunlight in the form of chemical energy. Biogas is among the biofuels that can be obtained from biomass resources, including biodegradable wastes like manure, sewage sludge, the organic fraction of municipal solid wastes, slaughterhouse waste, crop residues, and more recently lignocellulosic biomass and algae. Within the framework of the circular economy, biogas production from biodegradable waste is particularly interesting, as it helps to save resources while reducing environmental pollution. Besides, lignocellulosic biomass and algae do not compete for arable land with food crops (in contrast with energy crops). Hence, they constitute a novel source of biomass for bioenergy.Biogas plants may involve both high-tech and low-tech digesters, ranging from industrial-scale plants to small-scale farms and even households. They pose an alternative for decentralized bioenergy production in rural areas. Indeed, the biogas produced can be used in heaters, engines, combined heat and power units, and even cookstoves at the household level. Notwithstanding, digesters are considered to be a sustainable technology that can improve the living conditions of farmers by covering energy needs and boosting nutrient recycling. Thanks to their technical, socio-economic, and environmental benefits, rural biogas plants have been spreading around the world since the 1970s, with a large focus on farm-based systems and households. However, several challenges still need to be overcome in order to improve the technology and financial viability.
Technology: general issues --- Environmental science, engineering & technology --- Mixing --- optimised --- household digester --- Chinese dome digester (CDD) --- self-agitation --- blank --- mixing --- Chinese dome digester --- impeller mixed digester --- unstirred digester --- hydraulically mixed --- total solids (TS) concentration --- plug-flow reactor --- anaerobic digestion --- animal manures --- biogas --- unconfined gas injection mixing --- mixing recirculation --- biomethane potential tests --- Italy --- manure --- energy crops --- agriculture residues --- digestate --- biochemical methane potential --- micro-aeration --- iron --- bioenergy --- H2S scrubber --- methane --- fermentation --- dairy --- poultry --- absorbent --- ammonia --- inhibition --- acclimatization --- trace elements --- anaerobic treatment --- energy assessment --- rural sanitation --- sludge --- wastewater --- agricultural runoff --- biomethane --- biorefinery --- microalgae --- photobioreactor --- pretreatment --- low cost digester --- psychrophilic anaerobic digestion --- thermal behavior --- anaerobic co-digestion --- slaughterhouse wastewater --- synergistic effects --- kinetic modeling --- biodegradability --- Mixing --- optimised --- household digester --- Chinese dome digester (CDD) --- self-agitation --- blank --- mixing --- Chinese dome digester --- impeller mixed digester --- unstirred digester --- hydraulically mixed --- total solids (TS) concentration --- plug-flow reactor --- anaerobic digestion --- animal manures --- biogas --- unconfined gas injection mixing --- mixing recirculation --- biomethane potential tests --- Italy --- manure --- energy crops --- agriculture residues --- digestate --- biochemical methane potential --- micro-aeration --- iron --- bioenergy --- H2S scrubber --- methane --- fermentation --- dairy --- poultry --- absorbent --- ammonia --- inhibition --- acclimatization --- trace elements --- anaerobic treatment --- energy assessment --- rural sanitation --- sludge --- wastewater --- agricultural runoff --- biomethane --- biorefinery --- microalgae --- photobioreactor --- pretreatment --- low cost digester --- psychrophilic anaerobic digestion --- thermal behavior --- anaerobic co-digestion --- slaughterhouse wastewater --- synergistic effects --- kinetic modeling --- biodegradability
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For a sustainable future, the need to use renewable sources to produce electricity is inevitable. Some of these sources—particularly the widely available solar power—are weather-dependent; therefore, utility-scale energy storage will be more and more important. These solar and wind power fluctuations range from minutes (passing cloud) to whole seasons (winter/summer differences). Short-term storage can be solved (at least theoretically) with batteries; however, seasonal storage—due to the amount of storable energy and the self-discharging of some storage methods—is still a challenge to be solved in the near future. We believe that biological Power-to-Methane technology—especially combined with biogas refinement—will be a significant player in the energy storage market within less than a decade. The technology produces high-purity methane, which can be considered—by using green energy and carbon dioxide of biological origin—as a Renewable Natural Gas, or RNG. The ease of storage and use of methane, as well as the effective carbon-freeness, can make it a competitor for batteries or hydrogen-based storage, especially for storage times exceeding several months.
Technology: general issues --- History of engineering & technology --- seasonal energy storage --- power-to-methane --- wastewater treatment plants --- techno-economic assessment --- power-to-gas --- regulation --- energy storage --- biogas --- biomethane --- disruptive technology --- decarbonization --- innovation --- Power-to-Gas --- Power-to-Fuel --- P2M --- P2G --- P2F --- biomethanization --- biomethanation --- competitiveness --- hydrogen utilization --- Hungary --- Power-to-X --- Power-to-Hydrogen --- Power-to-Methane --- hydrogen --- methanation --- sector coupling --- sectoral integration --- energy transition --- eFuels --- electric fuels --- 100% renewable energy scenarios --- thermophilic biogas --- fed-batch reactor --- Methanothermobacter --- metagenome --- starvation --- H2 and CO2 conversion --- methane --- acetate --- seasonal energy storage --- power-to-methane --- wastewater treatment plants --- techno-economic assessment --- power-to-gas --- regulation --- energy storage --- biogas --- biomethane --- disruptive technology --- decarbonization --- innovation --- Power-to-Gas --- Power-to-Fuel --- P2M --- P2G --- P2F --- biomethanization --- biomethanation --- competitiveness --- hydrogen utilization --- Hungary --- Power-to-X --- Power-to-Hydrogen --- Power-to-Methane --- hydrogen --- methanation --- sector coupling --- sectoral integration --- energy transition --- eFuels --- electric fuels --- 100% renewable energy scenarios --- thermophilic biogas --- fed-batch reactor --- Methanothermobacter --- metagenome --- starvation --- H2 and CO2 conversion --- methane --- acetate
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For a sustainable future, the need to use renewable sources to produce electricity is inevitable. Some of these sources—particularly the widely available solar power—are weather-dependent; therefore, utility-scale energy storage will be more and more important. These solar and wind power fluctuations range from minutes (passing cloud) to whole seasons (winter/summer differences). Short-term storage can be solved (at least theoretically) with batteries; however, seasonal storage—due to the amount of storable energy and the self-discharging of some storage methods—is still a challenge to be solved in the near future. We believe that biological Power-to-Methane technology—especially combined with biogas refinement—will be a significant player in the energy storage market within less than a decade. The technology produces high-purity methane, which can be considered—by using green energy and carbon dioxide of biological origin—as a Renewable Natural Gas, or RNG. The ease of storage and use of methane, as well as the effective carbon-freeness, can make it a competitor for batteries or hydrogen-based storage, especially for storage times exceeding several months.
seasonal energy storage --- power-to-methane --- wastewater treatment plants --- techno-economic assessment --- power-to-gas --- regulation --- energy storage --- biogas --- biomethane --- disruptive technology --- decarbonization --- innovation --- Power-to-Gas --- Power-to-Fuel --- P2M --- P2G --- P2F --- biomethanization --- biomethanation --- competitiveness --- hydrogen utilization --- Hungary --- Power-to-X --- Power-to-Hydrogen --- Power-to-Methane --- hydrogen --- methanation --- sector coupling --- sectoral integration --- energy transition --- eFuels --- electric fuels --- 100% renewable energy scenarios --- thermophilic biogas --- fed-batch reactor --- Methanothermobacter --- metagenome --- starvation --- H2 and CO2 conversion --- methane --- acetate --- n/a
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La production de biométhane par digestion anaérobie de matières organiques est, aussi bien chez les écologistes que chez les pouvoirs publics, la mal aimée des "techniques douces". C'est fort dommage, car à l'exposé des différents aspects de cette technique les réserves paraissent, pour la plupart, peu fondées. Ce qui ne veut pas dire que les possibilités ou applications sont illimitées. L'auteur - militant du réseau NRJ - a toutefois, par une description détaillée des différents aspects de la production de biométhane, prouvé qu'elle n'est pas très difficile à maîtriser, et qu'elle est parfaitement compatible avec une agriculture écologique : c'est d'ailleurs la plus grande qualité de cette technique que de pouvoir offrir un carburant aux outils qui travailleront la terre, elle-même nourrie par les sous-produits de la digestion. Produire un combustible inépuisable tout en maintenant la qualité de l'environnement est le fait de cette technologie appropriée à l'instauration d'une société basée sur le recyclage et non plus sur le gaspillage.
Biogas. --- Biogaz --- Energie verte --- Biogas --- Méthane --- Methane --- Matière organique --- organic matter --- Source d'énergie --- energy sources --- Agriculture --- agriculture --- Géographie économique --- Economic geography --- Technologie appropriée --- Appropriate technology --- Bioconversion --- bioconversion --- 662 --- 620.9 --- 620.91 --- Alternatieve energie (Hernieuwbare energie) --- Bio-energie --- GG Geochemistry --- Gobar gas --- Biomass chemicals --- Explosives. Fuels --- Agrotechnology and Food Sciences. Engineering --- Energy --- Bioenergy --- CON Bioconservation --- bioconservation --- biogas --- biomethane --- energy --- industrial cultures --- Bioenergy. --- 662 Explosives. Fuels --- Digestion --- Anaerobiosis --- Fermentation --- fuels --- fertilizers --- Compost --- Composts --- Animal feeding --- Wastewater --- Methane. --- Composts. --- agriculture. --- bioconversion. --- Manure gases --- Gaz de fumier
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For a sustainable future, the need to use renewable sources to produce electricity is inevitable. Some of these sources—particularly the widely available solar power—are weather-dependent; therefore, utility-scale energy storage will be more and more important. These solar and wind power fluctuations range from minutes (passing cloud) to whole seasons (winter/summer differences). Short-term storage can be solved (at least theoretically) with batteries; however, seasonal storage—due to the amount of storable energy and the self-discharging of some storage methods—is still a challenge to be solved in the near future. We believe that biological Power-to-Methane technology—especially combined with biogas refinement—will be a significant player in the energy storage market within less than a decade. The technology produces high-purity methane, which can be considered—by using green energy and carbon dioxide of biological origin—as a Renewable Natural Gas, or RNG. The ease of storage and use of methane, as well as the effective carbon-freeness, can make it a competitor for batteries or hydrogen-based storage, especially for storage times exceeding several months.
Technology: general issues --- History of engineering & technology --- seasonal energy storage --- power-to-methane --- wastewater treatment plants --- techno-economic assessment --- power-to-gas --- regulation --- energy storage --- biogas --- biomethane --- disruptive technology --- decarbonization --- innovation --- Power-to-Gas --- Power-to-Fuel --- P2M --- P2G --- P2F --- biomethanization --- biomethanation --- competitiveness --- hydrogen utilization --- Hungary --- Power-to-X --- Power-to-Hydrogen --- Power-to-Methane --- hydrogen --- methanation --- sector coupling --- sectoral integration --- energy transition --- eFuels --- electric fuels --- 100% renewable energy scenarios --- thermophilic biogas --- fed-batch reactor --- Methanothermobacter --- metagenome --- starvation --- H2 and CO2 conversion --- methane --- acetate --- n/a
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Climate change mitigation and adaptation are key challenges of the 21st century. These challenges include global energy consumption and dependence on fossil fuels, which are addressed in global energy policies. About two-thirds of global greenhouse gas emissions are linked to the burning of fossil fuels used for heating, electricity, transport, and industry. Therefore, the world is looking for the most reliable, cost-effective, and environmentally friendly energy sources coupled with energy saving, which is a clean and low-cost solution to the growing demand for energy. As a clear example of this, cities are integrating renewable energies into their smart city plans. This book aims to advance the contribution of the use of renewable energies and energy saving in order to achieve a more sustainable world.
Technology: general issues --- History of engineering & technology --- BIPV window --- WWR --- overall energy --- tilt angle --- visual comfort --- energy saving --- semi-arid --- wind power generation --- artificial neural networks --- chargeability factor --- reactive power capacity --- wind speed and demand curves --- energy management systems --- multi-objective function --- optimal set-points --- stochastic optimization --- wind farm operation --- expert survey --- renewable energy --- biogas --- biomethane --- biogas plant --- business model --- political support system --- building performance --- value co-creation --- value add --- maintenance management --- hospital buildings --- optimal power flow --- power flow --- optimization algorithms --- DC networks --- electrical energy --- optimization --- willingness to pay --- minigrids --- rural electrification --- Ghana --- hospital building maintenance --- critical success factor --- value-based practices --- importance-performance matrix analysis --- renewable energy sources --- non-conventional renewable energy sources --- RES --- NCRES --- electric power system --- information environment --- BIPV window --- WWR --- overall energy --- tilt angle --- visual comfort --- energy saving --- semi-arid --- wind power generation --- artificial neural networks --- chargeability factor --- reactive power capacity --- wind speed and demand curves --- energy management systems --- multi-objective function --- optimal set-points --- stochastic optimization --- wind farm operation --- expert survey --- renewable energy --- biogas --- biomethane --- biogas plant --- business model --- political support system --- building performance --- value co-creation --- value add --- maintenance management --- hospital buildings --- optimal power flow --- power flow --- optimization algorithms --- DC networks --- electrical energy --- optimization --- willingness to pay --- minigrids --- rural electrification --- Ghana --- hospital building maintenance --- critical success factor --- value-based practices --- importance-performance matrix analysis --- renewable energy sources --- non-conventional renewable energy sources --- RES --- NCRES --- electric power system --- information environment
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The negative impacts of global warming and global environmental pollution due to fossil fuels mean that the main challenge of modern society is finding alternatives to conventional fuels. In this scenario, biofuels derived from renewable biomass represent the most promising renewable energy sources. Depending on the biomass used by the fermentation technologies, it is possible to obtain first-generation biofuels produced from food crops, second-generation biofuels produced from non-food feedstock, mainly starting from renewable lignocellulosic biomasses, and third-generation biofuels, represented by algae or food waste biomass.Although biofuels appear to be the closest alternative to fossil fuels, it is necessary for them to be produced in competitive quantities and costs, requiring both improvements to production technologies and the diversification of feedstock. This Special Issue is focused on technological innovations, including the utilization of different feedstocks, with a particular focus on biethanol production from food waste; different biomass pretreatments; fermentation strategies, such as simultaneous saccharification and fermentation (SSF) or separate hydrolysis and fermentation (SHF); different applied microorganisms used as a monoculture or co-culture; and different setups for biofuel fermentation processes.The manuscripts collected represent a great opportunity for adding new knowledge to the scientific community as well as industry.
Technology: general issues --- Biotechnology --- biofuels --- corn --- extraction --- enzyme-assisted --- protein --- soybean --- molecular sieve --- water removal --- rotary shaking --- electromagnetic stirring --- biofuel --- gasohol --- trend analysis --- promotion policy --- regulatory measure --- bottleneck --- synthesis gas fermentation --- volumetric mass transfer coefficient --- Tween 80® surfactant --- gasification --- multi-objective optimization --- bioethanol --- syngas fermentation --- modeling --- sustainability --- soapberry pericarp --- carbonization --- biochar --- pore property --- surface chemistry --- biomethane --- food waste --- co-production --- biorefinery --- bioelectrochemical system (BES) --- carbon dioxide sequestration --- extracellular electron transfer (EET) --- electroactive microorganisms --- microbial biocatalyst --- electro-fermentation --- circular economy --- downstream processing (DSP) --- gene manipulation --- biogas --- compost leachate --- pressurized anaerobic digestion --- ethanol --- simultaneous saccharification and fermentation --- Saccharomyces cerevisiae --- single cell protein --- pineapple waste --- cell wall sugar --- fermentation --- spent sugar beet pulp --- model --- economics --- pretreatment --- saccharification --- B. ceiba --- biomass --- second-generation biofuel --- bioenergy --- biodiesel --- non-fossil fuel --- empty fruit bunches --- response surface methodology --- central composite design --- biofuel production technologies --- downstream processing --- energy --- bioethanol production --- agroforest and industrial waste feedstock valorization --- microorganisms for biofuel
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