Готові списки джерел за темами / Electricity future

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Добірка наукової літератури з теми "Electricity future"

Автор: Grafiati
Опубліковано: 11 березня 2023

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Статті в журналах з теми "Electricity future"

1

Rüdig, Wolfgang. "Future electricity generation." Science and Public Policy 12, no. 3 (June 1985): 153–55. http://dx.doi.org/10.1093/spp/12.3.153.

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2

Jones, Philip. "Electricity — The Future." Industrial Management & Data Systems 85, no. 1/2 (January 1985): 6–9. http://dx.doi.org/10.1108/eb057387.

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3

Livingstone, Robert. "Meeting future electricity demand." Electronics and Power 33, no. 10 (1987): 645. http://dx.doi.org/10.1049/ep.1987.0385.

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4

Budhraja, Vikram S. "The Future Electricity Business." Electricity Journal 12, no. 9 (November 1999): 54–61. http://dx.doi.org/10.1016/s1040-6190(99)00078-0.

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5

Abelson, P. H. "Future Supplies of Electricity." Science 287, no. 5455 (February 11, 2000): 971. http://dx.doi.org/10.1126/science.287.5455.971.

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6

Zeman, Miro. "Developing the future electricity grid." Europhysics News 52, no. 5 (2021): 32–35. http://dx.doi.org/10.1051/epn/2021505.

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Анотація:
We are used to the continuous supply of electricity from a socket. Behind the socket lies a complex system of large power stations, high-voltage cables, transformers and a distribution network. Little has changed in the system over the last fifty years. The ambition to generate sustainable electricity from variable solar and wind energy has an immense impact on the electricity sector and requires major changes in our electricity grid and its operation.
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7

Dyśko, Adam, and Dimitrios Tzelepis. "Protection of Future Electricity Systems." Energies 15, no. 3 (January 19, 2022): 704. http://dx.doi.org/10.3390/en15030704.

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The electrical energy industry is undergoing dramatic changes; the massive deployment of renewables, an increasing share of DC networks at transmission and distribution levels, and at the same time, a continuing reduction in conventional synchronous generation, all contribute to a situation where a variety of technical and economic challenges emerge [...]
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8

HAYASHI, Yasuhiro. "Future Smart Society and Electricity." Journal of The Institute of Electrical Engineers of Japan 133, no. 12 (2013): 787. http://dx.doi.org/10.1541/ieejjournal.133.787.

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9

Stasiukynas, Andrius, Mantas Bileišis, and Vainius Smalskys. "Citizen participation and electricity sector governance in Lithuania: current state and future perspectives." Problems and Perspectives in Management 16, no. 3 (August 8, 2018): 189–96. http://dx.doi.org/10.21511/ppm.16(3).2018.15.

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The paper presents a study, which describes the current governance model of the electricity sector in Lithuania. Electricity and energy production and distribution is highly regulated worldwide. This is also true in Lithuania, where the electricity sector is highly politically prominent, and policy is highly centralized. There are geopolitical concerns towards Russia, which is an important supplier of electricity, and Lithuania’s grid is highly integrated with that of Russia. In addition, Lithuania is a small country dominated by a small number of large state-owned producers and has no regional administrations. Lithuania rhetorically has adopted increased citizen participation as a strategic policy goal. The study investigates how far the rhetorics are followed up by policy planning, implementation, and development of new governance modes. The authors base the study on interviews with 19 experts and regulation analysis. The study found that regulation process is transparent, but this causes lower public interest and consequently lower citizen participation. Existing stakeholder involvement at the policy level is highly arbitrary and favorable to large electricity producers. As production is set to decentralize, this has the potential to overburden the regulatory system and cause conflict between different producers.
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10

Jog, Mrs Pranjal. "Piezo-Electricity: A Future Energy Alternative." International Journal for Research in Applied Science and Engineering Technology 8, no. 11 (November 30, 2020): 329–32. http://dx.doi.org/10.22214/ijraset.2020.32133.

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Дисертації з теми "Electricity future"

1

Costley, Mitcham Hudson. "Prosumer-based decentralized unit commitment for future electricity grids." Diss., Georgia Institute of Technology, 2015. http://hdl.handle.net/1853/54890.

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The contributions of this research are a scalable formulation and solution method for decentralized unit commitment, experimental results comparing decentralized unit commitment solution times to conventional unit commitment methods, a demonstration of the benefits of faster unit commitment computation time, and extensions of decentralized unit commitment to handle system network security constraints. We begin with a discussion motivating the shift from centralized power system control architectures to decentralized architectures and describe the characteristics of such an architecture. We then develop a formulation and solution method to solve decentralized unit commitment by adapting an existing approach for separable convex optimization problems to the nonconvex domain of unit commitment. The potential computational speed benefits of the novel decentralized unit commitment approach are then further investigated through a rolling-horizon framework that represents how system operators make decisions and adjustments online as new information is revealed. Finally, the decentralized unit commitment approach is extended to include network contingency constraints, a crucial function for the maintenance of system security. The results indicate decentralized unit commitment holds promise as a way of coordinating system operations in a future decentralized grid and also may provide a way to leverage parallel computing resources to solve large-scale unit commitment problems with greater speed and model fidelity than is possible with conventional methods.
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2

Baker, John Leon. "Planning the future of the electricity supply industry 1935-48." Thesis, University of Birmingham, 1991. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.642947.

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Hernando, Gil Ignacio. "Integrated assessment of quality of supply in future electricity networks." Thesis, University of Edinburgh, 2014. http://hdl.handle.net/1842/9641.

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Although power system reliability analysis is a mature research area, there is a renewed interest in updating available network models and formulating improved reliability assessment procedures. The main driver of this interest is the current transition to a new flexible and actively controlled power supply system with a high penetration of distributed generation (DG) and energy storage (ES) technologies, wider implementation of demand-side management (DSM) and application of automated control, monitoring, protection and communication infrastructures. One of the aims of this new electricity supply network (’the smart grid’) is an improved reliability and power quality performance, realised through the delivery of an uninterrupted and high-quality supply of electrical energy. However, there is currently no integrated methodology to measure the effects of these changes on the overall system reliability performance. This PhD research aims to update the standard power system simulation engine with improved numerical software models offering new capabilities for the correct assessment of quality of supply in future electricity networks. The standard reliability analysis is extended to integrate some relevant power quality aspects, enabling the classification of short and long supply interruptions by the correct modelling of network protection and reconfiguration schemes. In addition, the work investigates the formulation and analysis of updated reliability indicators for a more accurate validation and benchmarking of both system and end-user performance. A detailed database with typical configurations and parameters of UK/European power systems is established, providing a set of generic models that can correctly represent actual distribution networks supplying a mix of residential, commercial and industrial demand for different load sectors. A general methodology for reducing system complexity by calculating both electrical and reliability equivalent models of LV and MV distribution networks is also presented. These equivalent models, based on the aggregation of individual component models, help to reduce calculation times while preserving the accuracy assessment of network’s reliability performance at bulk supply points. In addition, the aggregated counterparts (same and mixed-type) of different ’smart’ component models (DG, ES and DSM) are also included in the analysis, showing how their co-ordinated implementation and control could improve quality of supply. Conventional reliability assessment procedures are also extended in this thesis to include accurate reliability equivalent models, network contingency statistics, actual load profiles and empirical fault probability distributions, which are employed to assess the frequency and duration of interruptions in the supply system for different scenarios. Both analytical and probabilistic simulation techniques (Monte Carlo method) are developed to include up-to-date security of supply legislation, introducing a new methodology for calculating the standard set of indices reported annually to energy regulators.
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4

Babajide, Nathaniel Akinrinde. "The electricity crisis in Nigeria : building a new future to accommodate 20% renewable electricity generation by 2030." Thesis, University of Dundee, 2017. https://discovery.dundee.ac.uk/en/studentTheses/7c6df776-e790-4afc-8970-3877d91a2663.

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Анотація:
As part of efforts to curb the protracted electricity problem in Nigeria, the government enacted the National Renewable Energy and Energy Efficiency Policy (NREEEP) in 2014. Through this policy, the country plans to increase its electricity generation from renewables to 20% by 2030. This thesis investigates the economic feasibility of this lofty goal, and as well determine the best hybrid configuration for off-grid rural/remote power generation across the six geopolitical zones of Nigeria The economic feasibility results, using Long-range Energy Alternative Planning (LEAP) tool, show that the 20% renewables goal in the Nigerian power generation mix by 2030 is economically feasible but will require vast investment, appropriate supportive mechanisms, both fiscal and non-fiscal (especially for solar PV) and unalloyed commitment on the part of the government. Moreover, the techno-economic results with Hybrid Optimization Model for Electric Renewable (HOMER) reveal Small hydro/Solar PV/Diesel generator/Battery design as the most cost-effective combination for power supply in remote/rural areas of Nigeria. Findings also highlight the better performance of this system in terms of fuel consumption and GHGs emission reduction. Lastly, the study identifies factors influencing RE development, and offers strategic and policy suggestions to advance RE deployment in Nigeria.
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5

Themann, Michael. "A green future for European electricity? Energy sources, policies and further determinants of the household price of electricity." Master's thesis, NSBE - UNL, 2013. http://hdl.handle.net/10362/9771.

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A Work Project, presented as part of the requirements for the Award of a Masters Degree in Economics from the NOVA – School of Business and Economics
There is a controversial debate on how the transition towards electricity generation from re-newable energy sources (RES-E) affects European electricity markets in terms of prices and market efficiency. This thesis contributes to this debate by providing the first panel economet-ric analysis of how both different sources of electricity generation and electricity market poli-cies impact on the household price of electricity. Based on a sample of 29 European countries (EU-27 and two more), it finds that electricity production from combustible sources, natural gas, hydro and wind for the time span of 1991-2007 had a significant price lowering effect (ceteris paribus, on average). In contrast to that, results for the time span of 2004-2007 suggest that RES-E had a price increasing effect which can be related to its rapid growth in the 2000s. Results also suggest that Feed-in-Tariffs, regulatory reforms and the European emission trad-ing scheme play an important role, but their impact depends on country specific characteris-tics. The latter seem to be an important factor in determining the level of prices.
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6

Tumilty, Ryan M. "A study of adaptive protection methods for future electricity distribution systems." Thesis, University of Strathclyde, 2013. http://oleg.lib.strath.ac.uk:80/R/?func=dbin-jump-full&object_id=20408.

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The traditional transmission centric approach to generation connection using large-scale thermal units is evolving as the electricity supply industry and end users both move to play their part in tackling climate change. Government targets and financial incentive mechanisms have created a generation portfolio that is becoming more diverse as both large and small-scale distributed generation projects are commissioned. The net result of these events is that generation now appears across all voltage levels and is a trend that is almost certainly set to continue. Moreover, the manner in which networks are operated is also changing to become more flexible with novel management intended to facilitate the dispersed connection of generation, whilst at the same time improving the quality of supply for end users. As a consequence of the foregoing changes, new challenges emerge with regard to guaranteeing that the performance of power system protection is not degraded. This thesis documents research that has considered the myriad of issues arising throughout distribution networks. The concept of adaptive protection has been explored as a solution to many of these issues as a means of ensuring that protection better reflects the current state of the primary power system. Although adaptive protection has been a theoretical possibility for some time it has not generally been applied in practice. The emerging drivers that could change this have been considered along with the challenges of its application. It was concluded from this work that the concept and structure for adapting protection needs to be examined in abstraction from the underlying low level protection algorithms. A layered architecture has been proposed that helps to structure process of adaptation, define key functionality and ultimately clarify how it could be practically realised using currently available substation protection and automation equipment. To demonstrate the application of the architecture two examples have been used that cover both low and high voltage networks. The first considers a low voltage microgrid and the difficulties resulting from inverter interfaced microgeneration. As a second example, the problem of intentionally islanding an area of high voltage network is considered. Taken together, these two examples cover a range of future scenarios that could emerge within so called smart grids.
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7

Avagyan, Vitali. "Essays on risk and profitability in the future British electricity industry." Thesis, Imperial College London, 2016. http://hdl.handle.net/10044/1/49204.

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This thesis analyses risk and profitability issues in the future British electricity industry through three different studies. The first study develops a novel and fully endogenous portfolio investment model for firms in a competitive electricity industry when they face uncertainties from fuel prices, demand levels, carbon price and renewable penetration. This study finds that both risk aversion and carbon price are crucial factors for investments in nuclear technology. The second study analyses the impact of the cost of capital on optimal investments. Two distinct costs of capital of a project are considered: one in the pre-development and construction (pre-operation) phase and the other in the operation phase. The pre-operation cost of capital is based on the complex and capital-intensive nature of a project, which prevents potential investors from undertaking them under high costs – this is the first driving force for investment followed by the operation cost of capital. Operation cost of capital is based on a company’s ability to generate cash flows that cover debt requirements by varying the debt-equity ratio that a firm can attain. The greater the cash-flow risk, the lower is the level of debt that the firm can include in its financing, and hence, the higher the weighted average cost of capital, given that debt generally benefits from tax shield. The third study analyses the profit risk of energy storage when it faces fuel-price risk. Specifically, it assesses the future electricity industry with different levels of renewable penetration and storage energy capacity. The study shows that energy storage profits depend on the electricity price risk when it makes profits from arbitrage and reserve provision and also shows that storage profit has a positive correlation with that of other generators, especially with profits of gas stations, and this correlation is moderated with the level of electricity demand.
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8

Vaniš, Zdeněk. "Electricity Smart Metering in the Czech Republic: Status and Future Challenges." Master's thesis, Vysoká škola ekonomická v Praze, 2010. http://www.nusl.cz/ntk/nusl-73427.

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Анотація:
This work deals with technology and innovation management issues on the particular case of electricity smart metering in the Czech Republic. The popular literature on this topic is not reflecting on industries with high level of regulation in demand determination, which is the precise case of this industry. Positions of distribution network operators, technology suppliers, end-consumers and the regulatory players are analyzed. Comparison with other European countries is shown with market development predictions also taking part of the analysis. The outcome of this work reflects on the 2012 decision of the regulatory authority in the Czech Republic, which is to decide on a mandatory roll-out of this technology. This work presents the path towards this decision and discusses the potential outcomes.
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9

Atilgan, Burcin. "Assessing the sustainability of current and future electricity options for Turkey." Thesis, University of Manchester, 2016. https://www.research.manchester.ac.uk/portal/en/theses/assessing-the-sustainability-of-current-and-future-electricity-options-for-turkey(e6fb2e6f-bab4-47ac-a40a-0bef743ab867).html.

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Анотація:
This research has assessed the environmental, economic and social sustainability of electricity generation in Turkey to contribute towards a better understanding of the overall sustainability impacts of the electricity sector and of possible future scenarios. The assessment of environmental sustainability has been carried out using life cycle assessment; capital, annualised and levelised costs have been used for the economic sustainability and various social indicators along the life cycle of the technologies have been estimated for the social assessment. Multi-criteria decision analysis has been carried out to integrate the three dimensions of sustainability for current electricity generation and future scenarios as well as to help with decision-making. The sustainability assessment of current electricity generation considers all the options present in the Turkish electricity mix: coal (lignite, hard coal), gas, hydro (large and small scale reservoir, run-of-river), onshore wind and geothermal. Each technology has been assessed and compared using 20 sustainability indicators, addressing 11 environmental, three economic and six social aspects. The findings suggest that trade-offs are needed, as each technology is better for some sustainability indicators but worse for others. For example, coal has the highest environmental impacts, except for ozone depletion for which gas is the worst option; gas is the cheapest in terms of capital costs but it provides the lowest direct employment and has the highest levelised costs. Geothermal is the best option for six environmental impacts but has the highest capital cost. Large reservoir has the lowest depletion of elements and fossil resources as well as acidification. Moreover, large reservoir is the cheapest option in terms of levelised costs and the best option for worker injuries and fatalities but provides the lowest life cycle employment. The results for the current electricity sector show that electricity generation in Turkey is responsible for around 111 million tonnes of CO2 eq. emissions annually. Total capital costs of the current electricity sector of Turkey are estimated at US$69 billion, with hydropower, coal and gas plants contributing together to 96%. Total annualised costs are equal to US$26 billion per year, of which fuel costs contribute nearly 64%. The levelised costs for the Turkish electricity generation are estimated at 123 US$/MWh. The social assessment results indicate that the electricity sector in Turkey provided 57,000 jobs. A total of 3670 worker injuries and 15 fatalities are also estimated related to the electricity sector annually. A range of future electricity generation scenarios has been developed for the year 2050 considering different mixes, carbon emission targets and generation options, including fossil-fuel technologies with and without carbon capture and storage, nuclear and a range of renewable options. Overall, business-as-usual scenarios are the least sustainable options to meet the country’s electricity demand in the future. Despite the fact that these scenarios have the lowest costs, their poor environmental and social performances make them the worst options. Increasing the contribution from renewables and nuclear power translates to a better sustainability performance. The scenario with the highest penetration of these options (C-3) is found to be the most sustainable option in this work. Although the most renewable intensive scenario (C-4) scores as the second best option overall, it performs poorly for the economic categories. The trade-offs between the different sustainability indicators highlighted by the results of this research illustrate that assessments of a range of environmental, economic and social impacts from different electricity technologies and scenarios should be considered when planning sustainability strategies for the electricity sector.
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10

Saers, Pauline. "Future Impacts of Variable Renewable Power Production : An analysis of future scenarios effects on electricity supply and demand." Thesis, Uppsala universitet, Fasta tillståndets fysik, 2015. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-256790.

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Many scenarios try to describe a future of supply and demand for electricity in Sweden. All the studied scenarios contain an increased amount of variable renewable energy (VRE) power production. VRE power sources, such as solar and wind power, depend on weather conditions, like solar irradiance and wind speed. There are also scenarios predicting an increased amount of plug-in electrical vehicles (PEVs), which charge their batteries from the electricity grid and thereby changes the consumption patterns. In a future power system with less nuclear power and increased VRE power production it is of interest to investigate the scenarios impact on supply and demand. The scenarios were compiled into cases for the years 2030, 2050, and 2100. Simulations of each case VRE shares resulted in hourly power production data. Aggregating the data and comparing it with the consumption gives an understanding of the power and regulation need.  For Case 2030, a VRE share of 10.3% was calculated. The hydropower in Sweden could cover the power need for the whole year and even peaks in demand. For the larger shares of Case 2050 and 2100, hydropower was not able to cover peaks in power demand solemnly. The consumption of PEVs was small for all cases, reaching shares of 1.5% to 7.1%, compared to the consumption of all other sectors. Considering short-term statistics for wind power and the latest news that some of Sweden’s nuclear reactors might shut down in advance, it is possible that Case 2030 might occur sooner than predicted. If larger shares of VRE power have to be produced to meet consumer needs in the near future, grid-stabilizing measures has to be investigated.
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Книги з теми "Electricity future"

1

Energy, Ontario Ministry of. Ontario's Future Electricity Demand: Energy 2000: Electricity. S.l: s.n, 1987.

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2

Energy, Ontario Ministry of, ed. Ontario's future electricity demand. Ontario: Ministry of Energy, 1987.

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3

State Electricity Commission of Victoria. and Victoria. Treasury Dept. Office of State Owned Enterprises., eds. Reforming Victoria's electricity industry: A competitive future, electricity. Melbourne, Vic: Office of State Owned Enterprises, Dept. of the Treasury, 1994.

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4

Jamasb, Tooraj, and Michael Pollitt, eds. The Future of Electricity Demand. Cambridge: Cambridge University Press, 2011. http://dx.doi.org/10.1017/cbo9780511996191.

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5

Tooraj, Jamasb, Nuttall William J, and Pollitt Michael G, eds. Future electricity technologies and systems. Cambridge, UK: Cambridge University Press, 2006.

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6

State Electricity Commission of Victoria. and Victoria. Treasury Dept. Office of State Owned Enterprises., eds. The electricity supply industry in Victoria: A competitive future, electricity. Melbourne, Vic: Office of State Owned Enterprises, Dept. of the Treasury, 1993.

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7

Hatziargyriou, Nikos, and Iony Patriota de Siqueira, eds. Electricity Supply Systems of the Future. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-44484-6.

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Corporation, Saskatchewan Power, ed. Our future generation: Electricity for tomorrow. Regina, Sask: SaskPower, 1990.

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9

plc, Yorkshire Electricity Group. Looking to the future.... Leeds: Yorkshire Electricity Group, 1995.

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10

Michael, Johnson, Rix Stephen, and University of New South Wales. Public Sector Research Centre., eds. Powering the future: The electricity industry and Australia's energy future. Sydney: Pluto Press Australia in association with the Public Sector Research Centre, University of New South Wales, 1991.

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Частини книг з теми "Electricity future"

1

Schweppe, Fred C., Michael C. Caramanis, Richard D. Tabors, and Roger E. Bohn. "A Possible Future: Deregulation." In Spot Pricing of Electricity, 111–28. Boston, MA: Springer US, 1988. http://dx.doi.org/10.1007/978-1-4613-1683-1_5.

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2

Kopsakangas-Savolainen, Maria, and Rauli Svento. "The Future of Electricity Markets." In Modern Energy Markets, 119–32. London: Springer London, 2012. http://dx.doi.org/10.1007/978-1-4471-2972-1_10.

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Cruickshank, Alex, and Yannick Phulpin. "Electricity Markets and Regulation." In Electricity Supply Systems of the Future, 481–517. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-44484-6_14.

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4

Sauter, Raphael, and Dierk Bauknecht. "Distributed Generation: Transforming the Electricity Network." In Energy for the Future, 147–64. London: Palgrave Macmillan UK, 2009. http://dx.doi.org/10.1057/9780230235441_9.

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Heinberg, Richard, and David Fridley. "Renewable Electricity: Falling Costs, Variability, and Scaling Challenges." In Our Renewable Future, 47–80. Washington, DC: Island Press/Center for Resource Economics, 2016. http://dx.doi.org/10.5822/978-1-61091-780-3_4.

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6

Alexander, Bruce, Thomas Bonner, William Brady, Christopher Budzynski, Mark Derry, Scott Dupcak, Kimberly Long, David O’Dowd, and John Slocum. "Exelon Driving Innovation and the Grid of the Future." In Sustainable Electricity II, 75–96. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-95696-1_5.

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Norgard, Jorgen S., and Preben Buhl Pedersen. "Low Electricity Household for the Future." In Demand-Side Management and Electricity End-Use Efficiency, 449–57. Dordrecht: Springer Netherlands, 1988. http://dx.doi.org/10.1007/978-94-009-1403-2_28.

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Edomah, Norbert. "What should future electricity look like?" In Electricity and Energy Transition in Nigeria, 133–49. New York : Routledge, 2020.: Routledge, 2020. http://dx.doi.org/10.4324/9780367201456-13.

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MacTaggart, Tim. "Backcasting of the electricity industry from 2040." In The Corporation of the Future, 162–95. London: Routledge, 2022. http://dx.doi.org/10.4324/9781003183679-8.

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10

Fraunholz, Christoph, Andreas Bublitz, Dogan Keles, and Wolf Fichtner. "Impact of Electricity Market Designs on Investments in Flexibility Options." In The Future European Energy System, 199–218. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-60914-6_11.

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AbstractAgainst the background of several European countries implementing capacity remuneration mechanisms (CRM) as an extension to the energy-only market (EOM), this chapter provides a quantitative assessment of the long-term cross-border effects of CRMs in the European electricity system. For this purpose, several scenario analyses are carried out using the electricity market model PowerACE. Three different market design settings are investigated, namely, a European EOM, national CRM policies, and a coordinated CRM. The introduction of CRMs proves to be an effective measure substantially shifting investment incentives toward the countries implementing the mechanisms. However, CRMs increase generation adequacy also in the respective neighboring countries, indicating that free riding occurs. A coordinated approach therefore seems preferable in terms of both lower wholesale electricity prices and generation adequacy.
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Тези доповідей конференцій з теми "Electricity future"

1

Sasse, C. "Electricity networks of the future." In 2006 IEEE Power Engineering Society General Meeting. IEEE, 2006. http://dx.doi.org/10.1109/pes.2006.1709058.

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2

St Clair, R. "Load management technology - future challenges." In IEE Seminar on Electricity Trading. IEE, 2000. http://dx.doi.org/10.1049/ic:20000208.

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3

Zhe Lu and ZhaoYang Dong. "Electricity future market efficiency testing: the characteristics of electricity prices." In 2005 International Power Engineering Conference. IEEE, 2005. http://dx.doi.org/10.1109/ipec.2005.207030.

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4

Hoffmann, Winfried. "PV solar electricity: status and future." In Photonics Europe, edited by Ali Adibi, Shawn-Yu Lin, and Axel Scherer. SPIE, 2006. http://dx.doi.org/10.1117/12.683069.

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5

Bukhsh, W. A., G. S. Hawker, K. R. W. Bell, and Tim Bedford. "Adequacy assessment of future electricity networks." In 2016 Power Systems Computation Conference (PSCC). IEEE, 2016. http://dx.doi.org/10.1109/pscc.2016.7540959.

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6

Stephenson, P. M. "An uncertain future for U.K. Electricity?" In 2006 IEEE PES Power Systems Conference and Exposition. IEEE, 2006. http://dx.doi.org/10.1109/psce.2006.296187.

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7

Heyward, N. "Smarter Network Storage for Future Electricity Networks." In IET Conference on Power in Unity: a Whole System Approach. Institution of Engineering and Technology, 2013. http://dx.doi.org/10.1049/ic.2013.0130.

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Kjølle, G., K. Sand, and E. Gramme. "SCENARIOS FOR THE FUTURE ELECTRICITY DISTRIBUTION GRID." In CIRED 2021 - The 26th International Conference and Exhibition on Electricity Distribution. Institution of Engineering and Technology, 2021. http://dx.doi.org/10.1049/icp.2021.1527.

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9

Fraas, Lewis, and Leonid Minkin. "TPV History from 1990 to Present & Future Trends." In THERMOPHOTOVOLTAIC GENERATION OF ELECTRICITY: TPV7: Seventh World Conference on Thermophotovoltaic Generation of Electricity. AIP, 2007. http://dx.doi.org/10.1063/1.2711716.

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Kok, K., C. Warmer, R. Kamphuis, P. Mellstrand, and R. Gustavsson. "Distributed control in the electricity infrastructure." In 2005 International Conference on Future Power Systems. IEEE, 2005. http://dx.doi.org/10.1109/fps.2005.204233.

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Звіти організацій з теми "Electricity future"

1

Kahrl, Fredrich, Andrew Mills, Luke Lavin, Nancy Ryan, Arne Olsen, and Lisa Schwartz. The Future of Electricity Resource Planning. Office of Scientific and Technical Information (OSTI), September 2016. http://dx.doi.org/10.2172/1339559.

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2

Cappers, Peter, Sydney Forrester, and Andrew Satchwell. Disaggregating Future Retail Electricity Rate Growth. Office of Scientific and Technical Information (OSTI), September 2021. http://dx.doi.org/10.2172/1818485.

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3

Poudineh, Rahmatallah, and Donna Peng. Electricity market design for a decarbonised future. Oxford Institute for Energy Studies, October 2017. http://dx.doi.org/10.26889/9781784670948.

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4

Glazer, Craig, Jay Morrison, Paul Breakman, Allison Clements, and Lisa Schwartz. The Future of Centrally-Organized Wholesale Electricity Markets. Office of Scientific and Technical Information (OSTI), June 2017. http://dx.doi.org/10.2172/1364601.

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5

Darghouth, Naim, Galen Barbose, and Ryan Wiser. Electricity Bill Savings from Residential Photovoltaic Systems: Sensitivities to Changes in Future Electricity Market Conditions. Office of Scientific and Technical Information (OSTI), January 2013. http://dx.doi.org/10.2172/1168592.

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6

Tonn, B., E. Hirst, and D. Bauer. IRP and the electricity industry of the future: Workshop results. Office of Scientific and Technical Information (OSTI), September 1994. http://dx.doi.org/10.2172/10190448.

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7

Wake, Cameron, Matt Magnusson, Christine Foreman, and Fiona Wilson. Carsey Perspectives: New Hampshire's Electricity Future; Cost, Reliability, and Risk. University of New Hampshire Libraries, 2017. http://dx.doi.org/10.34051/p/2020.286.

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Miller, Jack. Overseas Electricity Interconnection. Parliamentary Office of Science and Technology, February 2018. http://dx.doi.org/10.58248/pn569.

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Electricity markets in the UK, Ireland and continental Europe are physically linked by ‘interconnector’ cables. These benefit energy system operators and consumers by reducing prices. They can also help integrate renewable electricity and ensure security of supply. This note discusses these benefits, proposals for future increases in interconnection and the potential effects of Brexit.
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Mallapragada, Dharik, Cristian Junge, Cathy Xun Wang, Johannes Pfeifenberger, Paul Joskow, and Richard Schmalensee. Electricity Price Distributions in Future Renewables-Dominant Power Grids and Policy Implications. Cambridge, MA: National Bureau of Economic Research, November 2021. http://dx.doi.org/10.3386/w29510.

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Frischknecht, Rolf, Rene Itten, Franziska Wyss, Isabelle Blanc, Garvin A. Heath, Marco Raugei, Parikhit Sinha, and Andreas Wade. Life Cycle Assessment of Future Photovoltaic Electricity Production from Residential-scale Systems Operated in Europe. Office of Scientific and Technical Information (OSTI), March 2015. http://dx.doi.org/10.2172/1561524.

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