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Products 123

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Design of wind and solar energy supply, to match energy demand

Renewable energy sources have an intermittent character that does not necessarily match energy demand. Such imbalances tend to increase system cost as they require mitigation measures and this is undesirable when available resources should be focused on increasing renewable energy supply. Matching supply and demand should therefore be inherent to early stages of system design, to avoid mismatch costs to the greatest extent possible and we need guidelines for that. This paper delivers such guidelines by exploring design of hybrid wind and solar energy and unusual large solar installation angles. The hybrid wind and solar energy supply and energy demand is studied with an analytical analysis of average monthly energy yields in The Netherlands, Spain and Britain, capacity factor statistics and a dynamic energy supply simulation. The analytical focus in this paper differs from that found in literature, where analyses entirely rely on simulations. Additionally, the seasonal energy yield profile of solar energy at large installation angles is studied with the web application PVGIS and an hourly simulation of the energy yield, based on the Perez model. In Europe, the energy yield of solar PV peaks during the summer months and the energy yield of wind turbines is highest during the winter months. As a consequence, three basic hybrid supply profiles, based on three different mix ratios of wind to solar PV, can be differentiated: a heating profile with high monthly energy yield during the winter months, a flat or baseload profile and a cooling profile with high monthly energy yield during the summer months. It is shown that the baseload profile in The Netherlands is achieved at a ratio of wind to solar energy yield and power of respectively Ew/Es = 1.7 and Pw/Ps = 0.6. The baseload ratio for Spain and Britain is comparable because of similar seasonal weather patterns, so that this baseload ratio is likely comparable for other European countries too. In addition to the seasonal benefits, the hybrid mix is also ideal for the short-term as wind and solar PV adds up to a total that has fewer energy supply flaws and peaks than with each energy source individually and it is shown that they are seldom (3%) both at rated power. This allows them to share one cable, allowing “cable pooling”, with curtailment to -for example-manage cable capacity. A dynamic simulation with the baseload mix supply and a flat demand reveals that a 100% and 75% yearly energy match cause a curtailment loss of respectively 6% and 1%. Curtailment losses of the baseload mix are thereby shown to be small. Tuning of the energy supply of solar panels separately is also possible. Compared to standard 40◦ slope in The Netherlands, facade panels have smaller yield during the summer months, but almost equal yield during the rest of the year, so that the total yield adds up to 72% of standard 40◦ slope panels. Additionally, an hourly energy yield simulation reveals that: façade (90◦) and 60◦ slope panels with an inverter rated at respectively 50% and 65% Wp, produce 95% of the maximum energy yield at that slope. The flatter seasonal yield profile of “large slope panels” together with decreased peak power fits Dutch demand and grid capacity more effectively.

DOCUMENT

Design of wind and solar energy supply, to match energy demand

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The power to change

With the effects of climate change linked to the use of fossil fuels, as well as the prospect of their eventual depletion, becoming more noticeable, political establishment and society appear ready to switch towards using renewable energy. Solar power and wind power are considered to be the most significant source of global low-carbon energy supply. Wind energy continues to expand as it becomes cheaper and more technologically advanced. Yet, despite these expectations and developments, fossil fuels still comprise nine-tenths of the global commercial energy supply. In this article, the history, technology, and politics involved in the production and barriers to acceptance of wind energy will be explored. The central question is why, despite the problems associated with the use of fossil fuels, carbon dependency has not yet given way to the more ecologically benign forms of energy. Having briefly surveyed some literature on the role of political and corporate stakeholders, as well as theories relating to sociological and psychological factors responsible for the grassroots’ resistance (“not in my backyard” or NIMBYs) to renewable energy, the findings indicate that motivation for opposition to wind power varies. While the grassroots resistance is often fueled by the mistrust of the government, the governments’ reason for resisting renewable energy can be explained by their history of a close relationship with the industrial partners. This article develops an argument that understanding of various motivations for resistance at different stakeholder levels opens up space for better strategies for a successful energy transition. https://doi.org/10.30560/sdr.v1n1p11 LinkedIn: https://www.linkedin.com/in/helenkopnina/

MULTIFILE

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Power to methane

Power to methane provides a solution to a couple of two problems: unbalanced production and demand of wind plus solar power electricity and the low methane content of biogas by storing electricity via hydrogen into methane gas using carbon dioxide from biogas and methanogenic bacteria. The four-year project is performed by a consortium of three research institutes and five companies. In WP1 the-state-of- the-art of scientific knowledge on P2M technology is reviewed and evaluated.

DOCUMENT

People 1

person

Gerard Schepers

Professor

Projects 8

project

CONSOLE: Ontwikkeling van geconcentreerde zonne-energiesystemen voor commerciële toepassingen

Nederland streeft naar een verduurzaming van het energiesysteem. In 2020 moet 14% van onze energie duurzaam opgewekt zijn, waarbij de zon, naast wind, als belangrijkste duurzame energiebron gezien wordt. Systemen voor geconcentreerde zonne-energie kunnen worden ingezet voor het opwekken van elektrische en/of thermische energie. Grootschalige systemen (multi-MW) met spiegels worden reeds toegepast in zonnevelden. Het HAN Lectoraat Duurzame Energie werkt al enige jaren aan innovatieve systemen met lenzen waarbij naast het concentreren van direct licht het overblijvende diffuse licht beschikbaar is voor verlichting van de onderliggende ruimte. We willen de in eerdere projecten opgedane kennis en ervaring nu inzetten in een nieuw project, waarin we streven van prototype naar toepassing te komen. De bedrijven zijn benaderd over de nog openstaande vragen. Hieruit is een nieuwe onderzoeksvraag gevormd: Hoe kan voor systemen van geconcentreerde zonne-energie voor toepassingen in glastuinbouw en gebouwde omgevingen voor de productie van zowel elektriciteit als warmte, de energie-opbrengst verhoogd worden door een optimaler gebruik van de lichtinval en met een compacter en duurzamer systeem? In dit project, CONSOLE (acroniem voor CONcentrated SOLar Energy), gaan we werken aan het optimaliseren van de bestaande systemen en het ontwerpen van verbeterde (hybride) systemen voor het opwekken van warmte en elektriciteit in kassen en gebouwde omgeving. We gebruiken hiervoor zowel modellering als meten en testen en komen vanuit een inventarisatie tot een pakket van eisen wat uiteindelijk tot verbeterde prototypes leidt die geschikt zijn voor commerciële toepassing. We doen dit vanuit een nauwe samenwerking met 12 MKB’s, een branche-organisatie en een Centre of Expertise. Daarnaast is er een directe koppeling met het onderwijs, door de betrokkenheid van docent-onderzoekers en studenten in semesterprojecten, stages en afstudeerprojecten.

Finished

project

Enable MULti-ArticulaTed vehicle rEversing (EMULATE)

Road freight transport contributes to 75% of the global logistics CO2 emissions. Various European initiatives are calling for a drastic cut-down of CO2 emissions in this sector [1]. This requires advanced and very expensive technological innovations; i.e. re-design of vehicle units, hybridization of powertrains and autonomous vehicle technology. One particular innovation that aims to solve this problem is multi-articulated vehicles (road-trains). They have a smaller footprint and better efficiency of transport than traditional transport vehicles like trucks. In line with the missions for Energy Transition and Sustainability [2], road-trains can have zero-emission powertrains leading to clean and sustainable urban mobility of people and goods. However, multiple articulations in a vehicle pose a problem of reversing the vehicle. Since it is extremely difficult to predict the sideways movement of the vehicle combination while reversing, no driver can master this process. This is also the problem faced by the drivers of TRENS Solar Train’s vehicle, which is a multi-articulated modular electric road vehicle. It can be used for transporting cargo as well as passengers in tight environments, making it suitable for operation in urban areas. This project aims to develop a reverse assist system to help drivers reverse multi-articulated vehicles like the TRENS Solar Train, enabling them to maneuver backward when the need arises in its operations, safely and predictably. This will subsequently provide multi-articulated vehicle users with a sustainable and economically viable option for the transport of cargo and passengers with unrestricted maneuverability resulting in better application and adding to the innovation in sustainable road transport.

Finished

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NEON : New Energy and mobility Outlook for the Netherlands.

The change to sustainable energy and mobility in the Netherlands is faltering, in spite of numerous technological innovations and the clear economic benefits of such a transition. The Eindhoven University of Technology (TU/e) and four other universities in the Netherlands will therefore develop new methods and techniques to give the transition a major boost. They will work within the framework of NEON, a multidisciplinary research programme in which engineers cooperate closely with social scientists, NGOs and companies. The Dutch Research Council (NWO) supports the programme, which will run for five years, with a grant of almost 8.5 million euros.Collaborative partners:TU Eindhoven, TU Delft, Tilburg University, Dutch Research Insitute for Transitions (and affiliate of ERASMUS Universiteit Rotterdam), Hogeschool van Amsterdam, Universiteit Twente, Heliox, Brainport Development, European Supply Chain Forum, Damen Shipyards Gorinchem B.V., TNO, AMPYX Power, NKL, Zenmo, ElaadNL, RAI Automotive Industry NL, Liander N.V., Enexis, Atlas Technologies B.V., Solarge, Kitepower, IHC MTI BV, Pon, Solliance, Elestor, Provincie Noord-Brabant, Swov, NXP, Verkeersonderneming, Stad Rotterdam, Prodrive Technologies B.V., Dialogic, PBL, Metalot3C.

Finished

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Nul op de Trafo Analysis, Houtlaan, Assen

Based on the model outcomes, Houtlaan’s energy transition will likely result in congestion and curtailmentproblems on the local electricity grid within the next 5-7 years, possibly sooner if load imbalance between phasesis not properly addressed.During simulations, the issue of curtailment was observed in significant quantities on one cable, resulting in aloss of 8.292 kWh of PV production per year in 2030. This issue could be addressed by moving some of thehouses on the affects cable to a neighboring under-utilized cable, or by installing a battery system near the end ofthe affected cable. Due to the layout of the grid, moving the last 7 houses on the affected cable to the neighboringcable should be relatively simple and cost-effective, and help to alleviate issues of curtailment.During simulations, the issue of grid overloading occurred largely as a result of EV charging. This issue can bestbe addressed by regulating EV charging. Based on current statistics, the bulk of EV charging is expected to occurin the early evening. By prolonging these charge cycles into the night and early morning, grid overloading canlikely be prevented for the coming decade. However, such a control system will require some sort of infrastructureto coordinate the different EV charge cycles or will require smart EV chargers which will charge preferentiallywhen the grid voltage is above a certain threshold (i.e., has more capacity available).A community battery system can be used to increase the local consumption of produced electricity within theneighborhood. Such a system can also be complemented by charging EV during surplus production hours.However, due to the relatively high cost of batteries at present, and losses due to inefficiencies, such a systemwill not be financially feasible without some form of subsidy and/or unless it can provide an energy service whichthe grid operator is willing to pay for (e.g. regulating power quality or line voltage, prolonging the lifetime of gridinfrastructure, etc.).A community battery may be most useful as a temporary solution when problems on the grid begin to occur, untila more cost-effective solution can be implemented (e.g. reinforcing the grid, implementing an EV charge controlsystem). Once a more permanent solution is implemented, the battery could then be re-used elsewhere.The neighborhood of Houtlaan in Assen, the Netherlands, has ambitious targets for reducing the neighborhood’scarbon emissions and increasing their production of their own, sustainable energy. Specifically, they wish toincrease the percentage of houses with a heat pump, electric vehicle (EV) and solar panels (PV) to 60%, 70%and 80%, respectively, by the year 2030. However, it was unclear what the impacts of this transition would be onthe electricity grid, and what limitations or problems might be encountered along the way.Therefore, a study was carried out to model the future energy load and production patterns in Houtlaan. Thepurpose of the model was to identify and quantify the problems which could be encountered if no steps are takento prevent these problems. In addition, the model was used to simulate the effectiveness of various proposedsolutions to reduce or eliminate the problems which were identified

Finished

project

PQsim - Modeling and Simulation of Power Quality lssues

Power Quality, ofwel de kwaliteit van spanning en stroom, is momenteel een veelbesproken onderwerp. Door de sterke toename van niet-lineaire en energiebesparende belastingen (denk bijv. aan spaar- en ledverlichting, computervoedingen, frequentieregelaars, solaromvormers, etc.) verslechtert de kwaliteit van de netspanning terwijl diezelfde apparatuur juist gevoeliger worden voor verstoringen. Dit heeft nadelige economische en technische gevolgen voor de levensduur, efficiëntie, betrouwbaarheid en veiligheid van zowel de energie infrastructuur als de aangesloten apparatuur. Het belang van Power Quality blijkt ook uit het recent aantal publicaties en conferenties op dit vakgebied. Desondanks is de technische en wetenschappelijke analyse van Power Quality problemen voornamelijk fenomenologisch van aard. Problemen worden doorgaans beschreven aan de hand van metingen. Oplossingen worden meestal gezocht in het ad hoc plaatsen van commerciële power conditioners die de spanning en stroom beogen te verbeteren. De Power Quality problemen waar MKB-er Kanters al jaren mee worstelt zijn typerend voor de vele Power Quality problemen waar MKB-er HyTEPS, marktleider in Power Quality en Energy Efficiency, dagelijks mee te maken heeft. De installaties kunnen worden doorgemeten, maar het blijft lastig om de veroorzaker(s) van het Power Quality probleem met zekerheid vast te stellen. Het is meestal niet toegestaan om ‘verdachte’ apparaten af te schakelen in dit proces. De optimale plaatsing van de power conditioner(s) blijft daarmee een open vraag. Derhalve ontstaat de dringende behoefte aan computersimulaties om de oorzaak van verstoring te analyseren en de mogelijke oplossingen te valideren. PQsim onderzoekt of middels modellering en simulatie de bron van Power Quality problemen kan worden gealloceerd zodat er efficiënt oplossingen kunnen worden ontwikkeld en toegepast. De kennisassimilatie tussen HyTEPS, Kanters, RUG en de HAN beoogt een solide basis te vormen voor een unieke systematische en regeltechnische benadering van Power Quality problemen. De verworven inzichten dienen voorts als input voor toekomstige SiA-RAAK/TKI projecten.

Finished

project

Regeltechnische uitdagingen in de Power Quality problematiek

Alleen met een optimale Power Quality (de kwaliteit van spanning en stroom) wordt de betrouwbaarheid van onze elektriciteitsvoorziening gewaarborgd. Door de sterke toename van niet-lineaire en energiebesparende apparaten (denk bijvoorbeeld aan led- en spaarverlichting, frequentieregelaars, solar-omvormers, etc.) verslechtert de kwaliteit van de netspanning echter, terwijl diezelfde apparatuur juist gevoeliger wordt voor verstoringen. Dit leidt veelal tot zeer hoge kosten door levensduurverkorting van apparaten en schade in productieprocessen. Het belang van Power Quality blijkt ook uit het recent aantal publicaties en conferenties op dit vakgebied. Desondanks is de technische en wetenschappelijke analyse van Power Quality problemen voornamelijk beschrijvend van aard. Problemen worden doorgaans geanalyseerd aan de hand van metingen. Oplossingen worden meestal gezocht in het plaatsen van commerciële statische power conditioners die de spanning en stroom beogen te verbeteren. In dit onderzoek wordt Power Quality integraal benaderd vanuit een systeem- en regeltechnisch oogpunt. Als gevolg van deze nieuwe benadering richt het onderzoek zich op de volgende aspecten: Ontwikkeling van wiskundige modellen om, onder meer via simulaties, Power Quality problemen inzichtelijk te maken; Synthetiseren van systematische ontwerpmethoden om bestaande en toekomstige oplossingen te optimaliseren zodat de kwaliteit van energiesystemen wordt gewaarborgd, de levensduur van apparaten wordt verbeterd en de kosten aanzienlijk worden gereduceerd; Ontwerpen van illustratieve analogieën en animaties ten behoeve van bewustwording, onderwijsverrijking en voorlichting. De onderzoeks- en onderwijsactiviteiten van de postdoc-kandidaat hangen nauw samen met de doelstellingen van het lectoraat Meet- en Regeltechniek (MR), het bijzonder lectoraat Reliable Power Supply (RPS) en het HAN speerpunt Sustainable Energy & Environment (SEE). Om de continuïteit en inbedding van de postdoc-kandidaat te garanderen zullen de onderzoeksresultaten worden ingezet voor het opzetten van een unieke en solide onderzoekslijn binnen MR en RPS en het ontwikkelen van duurzaam toekomstgericht praktijkonderwijs op het gebied van Power Quality binnen de HAN.

Finished

Products 123

product

Design of wind and solar energy supply, to match energy demand

DOCUMENT

product

The power to change

MULTIFILE

product

Power to methane

DOCUMENT

People 1

person

Gerard Schepers

Professor

Projects 8

project

CONSOLE: Ontwikkeling van geconcentreerde zonne-energiesystemen voor commerciële toepassingen

Finished

project

Enable MULti-ArticulaTed vehicle rEversing (EMULATE)

Finished

project

NEON : New Energy and mobility Outlook for the Netherlands.

Finished

project

Nul op de Trafo Analysis, Houtlaan, Assen

Finished

project

PQsim - Modeling and Simulation of Power Quality lssues

Finished

project

Regeltechnische uitdagingen in de Power Quality problematiek

Finished

Search results

Products 123

Design of wind and solar energy supply, to match energy demand

The power to change

Power to methane

Power to methane.

Droop Control in DC Grids using the Universal Four Leg as Laboratory Setup

A practical application of DC Droop Control with IoT capabilities

Anthocyanin's power

Impacts of electric heat pumps and rooftop solar panels on residential electricity distribution grids

The “Electric Mondrian” as a Luminescent Solar Concentrator Demonstrator Case Study

People 1

Gerard Schepers

Projects 8

CONSOLE: Ontwikkeling van geconcentreerde zonne-energiesystemen voor commerciële toepassingen

Enable MULti-ArticulaTed vehicle rEversing (EMULATE)

NEON : New Energy and mobility Outlook for the Netherlands.

Novel materials for a more sustainable CO2 capture facility

Nul op de Trafo Analysis, Houtlaan, Assen

PhD Research - How can batteries be used to prevent overloading on the electricity grid

PQsim - Modeling and Simulation of Power Quality lssues

Regeltechnische uitdagingen in de Power Quality problematiek

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Products 123

Design of wind and solar energy supply, to match energy demand

The power to change

Power to methane

Power to methane.

Droop Control in DC Grids using the Universal Four Leg as Laboratory Setup

A practical application of DC Droop Control with IoT capabilities

Anthocyanin's power

Impacts of electric heat pumps and rooftop solar panels on residential electricity distribution grids

The “Electric Mondrian” as a Luminescent Solar Concentrator Demonstrator Case Study

People 1

Gerard Schepers

Projects 8

CONSOLE: Ontwikkeling van geconcentreerde zonne-energiesystemen voor commerciële toepassingen

Enable MULti-ArticulaTed vehicle rEversing (EMULATE)

NEON : New Energy and mobility Outlook for the Netherlands.

Novel materials for a more sustainable CO2 capture facility

Nul op de Trafo Analysis, Houtlaan, Assen

PhD Research - How can batteries be used to prevent overloading on the electricity grid

PQsim - Modeling and Simulation of Power Quality lssues

Regeltechnische uitdagingen in de Power Quality problematiek