Your search keyword '"groen gas"' showing total 25 results

1. Overheid moet gebruik schaars groen gas slimmer stimuleren

Subjects

groen gas, energy transition, climate policy, klimaatbeleid, green gas, energietransitie

Abstract

● Ambitieuze beleidsdoelen en diverse stimuleringsmaatregelen maken de vraag naar groen gas veel groter dan het aanbod is. ● Zonder prijsdempende maatregelen en innovatie in de productie van groen gas zal de prijs van groen gas fors stijgen tot 2030.

Published

2022

2. Overheid moet gebruik schaars groen gas slimmer stimuleren

Author

Smit, Annet Jantien, Paap, Ruud, and Life Sciences & Renewable Energy

Subjects

groen gas, energy transition, climate policy, klimaatbeleid, green gas, energietransitie

Abstract

● Ambitieuze beleidsdoelen en diverse stimuleringsmaatregelen maken de vraag naar groen gas veel groter dan het aanbod is. ● Zonder prijsdempende maatregelen en innovatie in de productie van groen gas zal de prijs van groen gas fors stijgen tot 2030.

Published

2022

3. Alternatives to natural gas

Subjects

groen gas, alternatieve gassen, energy transition, sng, biogas, juridisch kader, waterstof, law, energietransitie, juridisch onderzoek

Abstract

For centuries, natural gas has been one of humanity’s main energy sources. The gas sector is still heavily reliant on natural gas production; however, as natural gas fields contain only a finite quantity of gas, its continued extraction is leading to the resource’s depletion. Furthermore, natural gas production has become subject of debate, with many considering continued utilisation incompatible with the achievement of international and European climate goals. The need for alternative gases that are less damaging to the environment is becoming increasingly evident. Biomethane has shown itself to be a reliable alternative for natural gas, and if sourced and manufactured responsibly results in no new CO2 emissions. Another alternative, hydrogen, can, through the process of methanisation, be converted into Synthetic Natural Gas (SNG). This chapter discusses the legal aspects of the production and use of biomethane, hydrogen and SNG.

Published

2021

4. Alternatives to natural gas: the legal framework on synthetic natural gas and biomethane

Author

Tempelman, Daisy G., Roggenkamp, M.M., de Graaf, K.J., Fleming, R., and Energy Transition

Subjects

groen gas, alternatieve gassen, energy transition, sng, biogas, juridisch kader, waterstof, law, energietransitie, juridisch onderzoek

Abstract

For centuries, natural gas has been one of humanity’s main energy sources. The gas sector is still heavily reliant on natural gas production; however, as natural gas fields contain only a finite quantity of gas, its continued extraction is leading to the resource’s depletion. Furthermore, natural gas production has become subject of debate, with many considering continued utilisation incompatible with the achievement of international and European climate goals. The need for alternative gases that are less damaging to the environment is becoming increasingly evident. Biomethane has shown itself to be a reliable alternative for natural gas, and if sourced and manufactured responsibly results in no new CO2 emissions. Another alternative, hydrogen, can, through the process of methanisation, be converted into Synthetic Natural Gas (SNG). This chapter discusses the legal aspects of the production and use of biomethane, hydrogen and SNG.

Published

2021

5. Tools for professional practice to facilitate business model development and market adoption of improved bioP2methane technology

Author

Smit, Annet Jantien and Teisman, Joline

Subjects

Energy(All), Groen Gas, Energietransitie, Alternative Gasses And Hybrid Fuels, Energy Transition, Professional Practice &Amp; Society, New Business Models, New Economics, Labour Market And Legal Aspects In The Energy Sector, Biomethaan, Life Sciences undefined Renewable Energy, Business Models, Green Gas, No Hanze Research Focus Area Applicable, Energie (Alles), Alternatieve Gassen En Hybride Brandstoffen, Nieuwe Economie, Werk En Juridische Aspecten In De Energiesector, Bedrijfsmodellen

Published

2020

6. Groen gas verdient een eerlijk speelveld

Subjects

groen gas, energy transition, biogas, duurzame energie, hybride waterpompen, energietransitie

Abstract

Martien Visser is er klip en klaar over: transport, distributie en opslag van gas is vele malen goedkoper dan van elektriciteit of warmte.

Published

2020

7. Slotbijeenkomst Bio-P2G

Author

Nap, Jan Peter, Hofstede, Gert, Faber, Folkert, and Bekkering, Jan

Subjects

Chemische Technologie (Diversen), Energy, Groen Gas, Energietransitie, Alternative Gasses And Hybrid Fuels, Hybrid Energy System Design And Management, Science, Energy Engineering And Power Technology, Methaan, Energy Transition, Hernieuwbare Energie, Duurzaamheid En Het Milieu, Renewable Energy, Sustainability And The Environment, Professional Practice &Amp; Society, Education, Biologische Methanisering, Ontwerp En Beheer Van Hybride Energie Systemen, Energieopslag, Energietechniek En Krachttechnologie, Duurzaamheid, Alternatieve Gassen En Hybride Brandstoffen, Hybride Energie Systemen, Energie, Chemical Engineering (Miscellaneous)

Abstract

Ter afsluiting van het Bio-P2G project is een eindsymposium georganiseerd waarbij terug wordt geblikt op de afgelopen 4 jaar. De resultaten werden besproken maar ook samenwerkingspartners verzorgden presentaties rondom de energietransitie en biologische methanisering.

Published

2019

8. Plan B: Hybride warmtepompen

Subjects

groen gas, klimaatwetten, co2 emissies, hybrid energy systems, duurzame energie, warmtepompen, gedragsverandering, energietransitie

Abstract

Vervanging van aardgas in bestaande woonwijken vergt forse investeringen, doorzettingsmacht van de overheid en beknot haar burgers. Maatschappelijke weerstand ligt op de loer en het afbreukrisico is volgens Martien Visser groot. De resultaten van de proefwijken zijn nog ongewis. Het verdient volgens hem aanbeveling om een plan B met hybride warmtepompen te ontwikkelen.

Published

2019

9. CO2 capture and biomethane production : earthquake-free natural gas from Groningen?

Author

Nap, Jan Peter

Subjects

Energy, Groen Gas, Alternative Gasses And Hybrid Fuels, Hybrid Energy System Design And Management, Energy Engineering And Power Technology, Groningen (Province), Methaan, Biobased Economie, Hernieuwbare Energie, Duurzaamheid En Het Milieu, Biomassa, Renewable Energy, Sustainability And The Environment, Professional Practice &Amp; Society, Ontwerp En Beheer Van Hybride Energie Systemen, Energieopslag, Groningen (Provincie), Energietechniek En Krachttechnologie, Waterstof, Duurzaamheid, Co2, Alternatieve Gassen En Hybride Brandstoffen, Hybride Energie Systemen, Energie, Biomethane

Abstract

Presentatie over een aardbeving-vrij Groningen met natuurlijk gas.

Published

2018

10. G(r)een gas?! : positioning of green gas in the public debate

Author

Wiekens, Carina

Subjects

Environmental Science (Miscellaneous), Groen Gas, Toegepaste Psychologie, Weerstand, Biogas, Hernieuwbare Energie, Duurzaamheid En Het Milieu, Biomassa, Energy Interventions And Behaviour, Public Support And Communication, Milieuwetenschap (Diversen), Renewable Energy, Sustainability And The Environment, Professional Practice &Amp; Society, Energy Sustainable Communities And Local Initiatives, Duurzame Energie In De Samenleving En Lokale Initiatieven, Energie Interventies En Gedrag, Publieke Ondersteuning En Communicatie, Draagvlak, Biovergisting, Applied Psychology

Abstract

In deze presentatie stond het project Flexigas en de huidige positionering van groen gas in de samenleving centraal.

Published

2018

11. Innovation in the EU gas sector: injection of biomethane into the natural gas system

Author

Tempelman, Daisy, Roggenkamp, Martha, and Sandholt, Jacob

Subjects

biomethaan, duitsland, netherlands, denmark, germany, biomethane, legal framework, innovation, nederland, groen gas, gas sector, biogas, denemarken, eu, juridische aspecten

Abstract

In het hoofdstuk wordt ingegaan op de innovaties in de Europese gassector, met een speciale focus op de invoeding van groen gas (ook wel biomethaan) in het aardgassysteem. Er wordt een algemeen juridisch kader geschetst en er vindt een rechtsvergelijking plaats van de nationale rechtsordes aangaande Duitsland, Denemarken en Nederland.

Published

2018

12. A new approach for measuring the environmental sustainability of renewable energy production systems

Author

W. J. Th van Gemert, Jan Bekkering, René M.J. Benders, Henri Moll, Frank Pierie, Energy Transition, and Life Sciences & Renewable Energy

Subjects

IMPACTS, INDICATORS, Engineering, biomethaan, 020209 energy, Biogas, life cycle analysis, 02 engineering and technology, Management, Monitoring, Policy and Law, Energy engineering, DEPLOYMENT, groen gas, Life Cycle Analysis (LCA), Environmental impact, DIGESTION, 0202 electrical engineering, electronic engineering, information engineering, BIOGAS PRODUCTION, Life-cycle assessment, PART II, CONSEQUENCES, MANURE, business.industry, Mechanical Engineering, Material flow analysis, Environmental engineering, milieubelasting, levenscyclusanalyse, Building and Construction, Energy accounting, LIFE-CYCLE ASSESSMENT, General Energy, Green gas, Sustainability, Biochemical engineering, business, Embodied energy, Bio-methane, Efficient energy use, Energy returned on energy invested, GENERATION

Abstract

A transparent and comparable understanding of the energy efficiency, carbon footprint, and environmental impacts of renewable resources are required in the decision making and planning process towards a more sustainable energy system. Therefore, a new approach is proposed for measuring the environmental sustainability of anaerobic digestion green gas production pathways. The approach is based on the industrial metabolism concept, and is expanded with three known methods. First, the Material Flow Analysis method is used to simulate the decentralized energy system. Second, the Material and Energy Flow Analysis method is used to determine the direct energy and material requirements. Finally, Life Cycle Analysis is used to calculate the indirect material and energy requirements, including the embodied energy of the components and required maintenance. Complexity will be handled through a modular approach, which allows for the simplification of the green gas production pathway while also allowing for easy modification in order to determine the environmental impacts for specific conditions and scenarios. Temporal dynamics will be introduced in the approach through the use of hourly intervals and yearly scenarios. The environmental sustainability of green gas production is expressed in (Process) Energy Returned on Energy Invested, Carbon Footprint, and EcoPoints. The proposed approach within this article can be used for generating and identifying sustainable solutions. By demanding a clear and structured Material and Energy Flow Analysis of the production pathway and clear expression for energy efficiency and environmental sustainability the analysis or model can become more transparent and therefore easier to interpret and compare. Hence, a clear ruler and measuring technique can aid in the decision making and planning process towards a more sustainable energy system. (C) 2015 Elsevier Ltd. All rights reserved.

Published

2016

13. A new approach for measuring the environmental sustainability of renewable energy production systems

Subjects

groen gas, biomethaan, biogas, milieubelasting, bio-methane, life cycle analysis, levenscyclusanalyse, green gas, environmental impact

Abstract

A transparent and comparable understanding of the energy efficiency, carbon footprint, and environmental impacts of renewable resources are required in the decision making and planning process towards a more sustainable energy system. Therefore, a new approach is proposed for measuring the environmental sustainability of anaerobic digestion green gas production pathways. The approach is based on the industrial metabolism concept, and is expanded with three known methods. First, the Material Flow Analysis method is used to simulate the decentralized energy system. Second, the Material and Energy Flow Analysis method is used to determine the direct energy and material requirements. Finally, Life Cycle Analysis is used to calculate the indirect material and energy requirements, including the embodied energy of the components and required maintenance. Complexity will be handled through a modular approach, which allows for the simplification of the green gas production pathway while also allowing for easy modification in order to determine the environmental impacts for specific conditions and scenarios. Temporal dynamics will be introduced in the approach through the use of hourly intervals and yearly scenarios. The environmental sustainability of green gas production is expressed in (Process) Energy Returned on Energy Invested, Carbon Footprint, and EcoPoints. The proposed approach within this article can be used for generating and identifying sustainable solutions. By demanding a clear and structured Material and Energy Flow Analysis of the production pathway and clear expression for energy efficiency and environmental sustainability the analysis or model can become more transparent and therefore easier to interpret and compare. Hence, a clear ruler and measuring technique can aid in the decision making and planning process towards a more sustainable energy system.

Published

2016

14. Environmental and energy system analysis of bio-methane production pathways: A comparison between feedstocks and process optimizations

Author

W. J. Th van Gemert, C. E. J. van Someren, Reinerus Benders, Frank Pierie, Henri Moll, Jan Bekkering, Energy Transition, and Life Sciences & Renewable Energy

Subjects

Engineering, biomethaan, WASTE, Biomass, life cycle analysis, Management, Monitoring, Policy and Law, organisch afval, groen gas, DIGESTION, Natural gas, Anaerobic digestion, PART II, Life-cycle assessment, Organic waste, EMISSIONS, SCALE, CONSEQUENCES, MANURE, Waste management, Life cycle analysis (LCA), business.industry, Mechanical Engineering, Environmental engineering, NITROUS-OXIDE, levenscyclusanalyse, Building and Construction, Biodegradable waste, Energy crops, Energy crop, LIFE-CYCLE ASSESSMENT, Green gas, General Energy, anaerobe vergisting, Carbon footprint, business, Bio-methane, energiegewassen, GENERATION, Efficient energy use

Abstract

The energy efficiency and sustainability of an anaerobic green gas production pathway was evaluated, taking into account five biomass feedstocks, optimization of the green gas production pathway, replacement of current waste management pathways by mitigation, and transport of the feedstocks. Sustainability is expressed by three main factors: efficiency in (Process) Energy Returned On Invested (P)EROI, carbon footprint in Global Warming Potential GWP(100), and environmental impact in EcoPoints. The green gas production pathway operates on a mass fraction of 50% feedstock with 50% manure. The sustainability of the analyzed feedstocks differs substantially, favoring biomass waste flows over, the specially cultivated energy crop, maize. The use of optimization, in the shape of internal energy production, green gas powered trucks, and mitigation can significantly improve the sustainability for all feedstocks, but favors waste materials. Results indicate a possible improvement from an average (P) EROI for all feedstocks of 2.3 up to an average of 7.0 GJ/GJ The carbon footprint can potentially be reduced from an average of 40 down to 18 kgCO(2)eq/GJ. The environmental impact can potentially be reduced from an average of 5.6 down to 1.8 Pt/GJ. Internal energy production proved to be the most effective optimization. However, the use of optimization aforementioned will result in les green gas injected into the gas grid as it is partially consumed internally. Overall, the feedstock straw was the most energy efficient, where the feedstock harvest remains proved to be the most environmentally sustainable. Furthermore, transport distances of all feedstocks should not exceed 150 km or emissions and environmental impacts will surpass those of natural gas, used as a reference. Using green gas as a fuel can increase the acceptable transportation range to over 300 km. Within the context aforementioned and from an energy efficiency and sustainable point of view, the anaerobic digestion process should be utilized for processing locally available waste feedstocks with the added advantage of producing energy, which should first be used internally for powering the green gas production process. (C) 2015 Elsevier Ltd. All rights reserved.

Published

2015

15. Will implementation of green gas into the gas supply be feasible in the future?

Author

W.J.T. van Gemert, Antonius Broekhuis, Evert Jan Hengeveld, Jan Bekkering, Energy Transition, Engineering and Technology Institute Groningen, and Product Technology

Subjects

Optimization, Cost price, Primary energy, FUELS, Supply chain, DEMAND, Biogas, Management, Monitoring, Policy and Law, Methane, groen gas, ENERGY, chemistry.chemical_compound, Economics, METHANE EMISSIONS, BIOGAS PRODUCTION, CHAINS, optimalisatie, business.industry, energie, Mechanical Engineering, Environmental engineering, BIOMETHANE, Building and Construction, Greenhouse gas reduction, LIFE-CYCLE, Energy crop, General Energy, Green gas, Energy efficiency, chemistry, ENVIRONMENTAL SYSTEMS-ANALYSIS, Electricity, business, Efficient energy use, GENERATION

Abstract

The energy efficiency, greenhouse gas reduction and cost price of a green gas supply chain were evaluated. The considered supply chain is based on co-digestion of dairy cattle manure and maize, biogas upgrading and injection into a distribution gas grid. A reference scenario was defined which reflects the current state of practice, assuming that input energy is from fossil origin. Possible improvements of this reference scenario were investigated. For this analysis two new definitions for energy input-output ratio were introduced; one based on input of primary energy from all origin, and one related to energy from fossil origin only. The influence of the improvements on greenhouse gas reduction and cost price was assessed too. Results show that electricity (from fossil origin) is the major contributor to energy input in the reference scenario. Switching to green electricity significantly improves the energy efficiency (both definitions) and greenhouse gas reduction. Preventing methane leakage during digestion and upgrading, and re-using heat within the supply chain also show improvements on these parameters as well as on cost price, although their influence is smaller. Decreasing the share of energy crops in the substrate mix shows a negative effect. It is shown that greenhouse gas reduction of more than 80% is possible with current technology. To meet this high sustainability level, multiple improvement options will have to be implemented in the green gas supply chain. Doing so will result in a modest decrease of the green gas cost price. (C) 2014 Elsevier Ltd. All rights reserved.

Published

2015

16. Power-naar-methaan (P2M): het alternatief van de biologische route

Author

Nap, Jan Peter

Subjects

Hanzehogeschool, Energy, Groen Gas, Alternative Gasses And Hybrid Fuels, Waterstof, Biogas, Hernieuwbare Energie, Duurzaamheid En Het Milieu, Alternatieve Gassen En Hybride Brandstoffen, Renewable Energy, Sustainability And The Environment, Higher Education, Professional Practice &Amp; Society, Energie, Hydrogen

Abstract

Groene elektriciteit voor nieuw groen gas?

Published

2017

17. Modeling decentralized energy systems: a tool for analyzing, researching and modeling energy efficiency, sustainability and flexibility of biogas chains operating as load balancer within decentralized (smart) energy systems

Author

Pierie, Frank and Energy Transition

Subjects

groen gas, biomethaan, biogas, milieubelasting, bio-methane, life cycle analysis, levenscyclusanalyse, green gas, environmental impact

Abstract

During the opening of the Hanze Energy Transition Centre or EnTranCe posters were on display for the King and for the public. These posters where accompanied by the researchers to explain their research in more detail if questions did arise.

Published

2015

18. Modeling biogas production pathways

Subjects

groen gas, biomethaan, biogas, milieubelasting, bio-methane, life cycle analysis, levenscyclusanalyse, green gas, environmental impact

Abstract

During the opening of the Hanze Energy Transition Centre or EnTranCe (2015-10-13) posters were on display for the King and for the public. During the opening these posters where accompanied by the researchers to explain their research in more detail if questions did arise.

Published

2015

19. Modeling decentralized energy systems

Subjects

groen gas, biomethaan, biogas, milieubelasting, bio-methane, life cycle analysis, levenscyclusanalyse, green gas, environmental impact

Abstract

During the opening of the Hanze Energy Transition Centre or EnTranCe posters were on display for the King and for the public. These posters where accompanied by the researchers to explain their research in more detail if questions did arise.

Published

2015

20. Designing a green gas supply to meet regional seasonal demand: an operations research case study

Author

W.J.T. van Gemert, Jan Bekkering, Evert Jan Hengeveld, Antonius Broekhuis, Life Sciences & Renewable Energy, Energy Transition, Engineering and Technology Institute Groningen, and Product Technology

Subjects

Flexibility (engineering), Cost price, biomethaan, business.industry, Mechanical Engineering, Supply chain, Environmental engineering, Building and Construction, Management, Monitoring, Policy and Law, Grid, mixed integer linear programming, biomethane, groen gas, General Energy, Biogas, Natural gas, balancing supply and demand, Economics, Production (economics), business, green gas, Integer programming, optimization

Abstract

One of the issues concerning the replacement of natural gas by green gas is the seasonal pattern of the gas demand. When constant production is assumed, this may limit the injected quantity of green gas into a gas grid to the level of the minimum gas demand in summer. A procedure was proposed to increase the gas demand coverage in a geographical region, i.e., the extent to which natural gas demand is replaced by green gas. This was done by modeling flexibility into farm-scale green gas supply chains. The procedure comprises two steps. In the first step, the types and number of green gas production units are determined, based on a desired gas demand coverage. The production types comprise time-varying biogas production, non-continuous biogas production (only in winter periods with each digester having a specified production time) and constant production including seasonal gas storage. In the second step locations of production units and injection stations are calculated, using mixed integer linear programming with cost price minimization being the objective. Five scenarios were defined with increasing gas demand coverage, representing a possible future development in natural gas replacement. The results show that production locations differ for each scenario, but are connected to a selection of injection stations, at least in the considered geographical region under the assumed preconditions. The cost price is mainly determined by the type of digesters needed. Increasing gas demand coverage does not necessarily mean a much higher cost price.

Published

2015

21. Measuring sustainability: why? and how?

Author

Pierie, Frank, Bekkering, Jan, Benders, René M.J., van Gemert, Wim, and Moll, Henri C.

Subjects

Energy, Groen Gas, Lca, Anaerobic Digestion, Bio-Methane, Biogas, Measuring Methods, Techniek (Diversen), Biomethaan, Meetmethodiek, Green Gas, Sustainability, Duurzaamheid, Flexigas, Anaerobe Vergisting, Engineering (Miscellaneous), Energie

Abstract

Presentation given to a delegation from the University of Oldenburg and the Research company Next Energy to explore fields of collaboration in research topics.

Published

2015

22. Measuring sustainability: why? and how?

Author

Pierie, Frank, Bekkering, Jan, Benders, René M.J., van Gemert, Wim, and Moll, Henri C.

Subjects

Energy, Groen Gas, Vergisting, Lca, Anaerobic Digestion, Bio-Methane, Biogas, ComputingMilieux_LEGALASPECTSOFCOMPUTING, Measuring Methods, Techniek (Diversen), Biomethaan, Meetmethodiek, Green Gas, Sustainability, ComputerSystemsOrganization_MISCELLANEOUS, Duurzaamheid, Flexigas, Anaerobe Vergisting, Digestion, Engineering (Miscellaneous), Energie

Abstract

Presentation given for the public website Smart Citizen on the subject of sustainability.

Published

2015

23. 22nd European Biomass Conference & Exhibition (EUBCE) 2014

Author

Bekkering, Jan

Subjects

Optimization, Lineaire Programmering, Energy, Groen Gas, Green Gas, Science, Biogas, Optimalisatie, Engineering (Miscellaneous), Linear Programming, Professional Practice &Amp; Society, Techniek (Diversen), Energie

Abstract

Designing a green gas supply to meet a regional seasonal demand: a case study.One of the issues concerning the replacement of natural gas by green gas is the seasonal pattern of the gas demand. When constant production is assumed, this may limit the injected quantity of green gas into a gas grid to the level of the minimum gas demand in summer. A procedure was proposed to increase the gas demand coverage in a geographical region, i.e. the extent to which natural gas demand can be replaced by green gas. This was done by modeling flexibility into farm-scale green gas supply chains. The procedure comprises two steps. In the first step, the types and number of green gas production units are determined, based on a desired gas demand coverage. The production types comprise time-varying biogas production, non-continuous biogas production (only in winter periods with each digester having a specified production time) and constant production including seasonal gas storage. In the second step locations of production units and injection stations are calculated, using mixed integer linear programming with cost price minimization being the objective. Five scenarios were defined with increasing gas demand coverage, representing a possible future development in natural gas replacement. The results show that production locations differ for each scenario, but are connected to a selection of injection stations, at least in the considered geographical region under the assumed preconditions. The cost price is mainly determined by the type of digesters needed. Increasing gas demand coverage does not necessarily mean a much higher cost price.

Published

2014

24. Energy is key

Author

Pierie, Frank

Subjects

Energy, Groen Gas, Alternative Gasses And Hybrid Fuels, Bio-Methane, Biogas Productie, Professional Practice &Amp; Society, Techniek (Diversen), Biomethaan, Green Gas, Flexigas, Alternatieve Gassen En Hybride Brandstoffen, Biogas Production, Engineering (Miscellaneous), Energie

Abstract

Presentation held for the company BTG regarding the Flexigas project workpackage WPA2.

Published

2013

25. Sustainability of biogas production chain

Author

Pierie, Frank

Subjects

Biomethaan, Energy, Groen Gas, Green Gas, Lca, Bio-Methane, Biogas, Engineering (Miscellaneous), Mefa, Techniek (Diversen), Energie

Abstract

Presentation held at the company GDF SUEZ regarding the Anaerobic Digestion system.

Published

2011