Relevant bibliographies by topics / Planing of an energy production

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  2. Dissertations / Theses
  3. Books
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Academic literature on the topic 'Planing of an energy production'

Author: Grafiati
Published: 4 June 2021
Last updated: 11 February 2022

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Journal articles on the topic "Planing of an energy production"

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Burggräf, P., M. Dannapfel, J, Utsch, J. Uelpenich, and M. Kasalo. "Integrierte Produktions- und Energiesystemplanung*/Integrated production and energy system planning." wt Werkstattstechnik online 107, no. 04 (2017): 207–12. http://dx.doi.org/10.37544/1436-4980-2017-04-11.

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In der Produktionstechnik bestehen hohe Potenziale, um den Energieverbrauch zu senken und die Energieeffizienz zu steigern. Eine integrierte Planung von Produktions- und Energiesystem verspricht die Erreichung dieser Optimierungspotenziale. Der Beitrag beschreibt eine Methodik, welche eine Einteilung der Beziehungsintensitäten zwischen den beiden Planungsbereichen ermöglicht. Daraus ergibt sich die Grundlage für die Schnittstellenanalyse zwischen der Planung auf Informations- und Parameterebene.   At present, there is still high potential to reduce energy consumption and to increase energy efficiency. An integrated planning of production and energy systems promises to rise these optimization potentials. This paper describes a methodology that allows a classification of the relationship intensities between planning activities of production and energy system planning. This provides the basis for an interface analysis between the planning activities on an information and parameter level.
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Johannes, Christoph, Matthias G. Wichmann, and Thomas S. Spengler. "Energy-oriented production planning with time-dependent energy prices." Procedia CIRP 80 (2019): 245–50. http://dx.doi.org/10.1016/j.procir.2019.01.010.

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Keller, F., and G. Reinhart. "Produktionsplanung unter Berücksichtigung des Energiebezugs*/Production planning with energy supply restrictions." wt Werkstattstechnik online 105, no. 03 (2015): 141–47. http://dx.doi.org/10.37544/1436-4980-2015-03-65.

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Der Energiebedarf einer Fabrik wird – neben den Energieverbräuchen der eingesetzten Produktionsressourcen – wesentlich von der zeitlich vorauslaufenden Planung beeinflusst. Mithilfe eines Energiebezugsplans sowie einer energieorientierten Produktionsplanung kann die kostengünstige Abstimmung von Energieangebot und -nachfrage einer Fabrik umgesetzt werden. Dabei gilt es, die Planungssysteme einer Fabrik zu befähigen, sich an die Bedingungen des Energiemarktes beziehungsweise der Erzeugung flexibel anzupassen.   The energy demand of a factory is determined by the specific energy consumption of the resources used as well as by advance production planning. An energy supply plan in combination with an energy-oriented production planning process aims for a cost-efficient adjustment of the energy demand and supply. The specific goal is to enable flexibility within the fatory’s planning systems in order to adapt the production processes to the volatile energy market and to the conditions of energy generation.
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Keller, Fabian, and Gunther Reinhart. "Energy Supply Orientation in Production Planning Systems." Procedia CIRP 40 (2016): 244–49. http://dx.doi.org/10.1016/j.procir.2016.01.113.

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van der Linde, Andries. "Bio-energy resources: Planning production and utilisation." Renewable Energy 7, no. 2 (February 1996): 215. http://dx.doi.org/10.1016/s0960-1481(96)90005-1.

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Stetter, Ralf, Andreas Paczynski, Piotr Witczak, and Benjamir Staiger. "Advanced Trajectory Planning for Production Energy Estimation." Pomiary Automatyka Robotyka 18, no. 2 (February 20, 2014): 70–77. http://dx.doi.org/10.14313/par_204/70.

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Poltroniere, Sônia Cristina, Angelo Aliano Filho, Amanda Suellen Caversan, Antonio Roberto Balbo, and Helenice de Oliveira Florentino. "Integrated planning for planting and harvesting sugarcane and energy-cane for the production of sucrose and energy." Computers and Electronics in Agriculture 184 (May 2021): 105956. http://dx.doi.org/10.1016/j.compag.2020.105956.

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Bohlayer, Markus, Markus Fleschutz, Marco Braun, and Gregor Zöttl. "Energy-intense production-inventory planning with participation in sequential energy markets." Applied Energy 258 (January 2020): 113954. http://dx.doi.org/10.1016/j.apenergy.2019.113954.

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Zhang, Jessica, Sarah Palmer, and David Pimentel. "Energy production from corn." Environment, Development and Sustainability 14, no. 2 (August 27, 2011): 221–31. http://dx.doi.org/10.1007/s10668-011-9318-4.

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Fiorese, G., E. Cozzolino, G. Guariso, and G. Paris. "Planning biomass energy production in a farming area." Renewable Energy and Power Quality Journal 1, no. 08 (April 2010): 1345–50. http://dx.doi.org/10.24084/repqj08.664.

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Dissertations / Theses on the topic "Planing of an energy production"

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Waldemarsson, Martin. "Energy and Production Planning for Process Industry Supply Chains." Licentiate thesis, Linköpings universitet, Produktionsekonomi, 2012. http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-84990.

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This thesis addresses industrial energy issues from a production economic perspective. During the past decade, the energy issue has become more important, partly due to rising energy prices in general, but also from a political pressure on environmental awareness concerning the problems with climate change. As a large user of energy the industry sector is most likely responsible for a lot of these problems. Things need to change and are most likely to do so considering current and assumed future governmental regulations. Thus, the energy intensive process industries studied and focused on in this thesis exemplify the importance of introducing a strategic perspective on energy, an appropriate approach for planning, as well as the possibilities of including energy issues in a production and supply chain planning model. The thesis aims to provide models, methods and decision support tools for energy related production and supply chain planning issues of relevance for process industries as well as for other energy intensive industries. The overall objectives are to analyze the strategic importance of energy management, production and supply chain planning, and the opportunities provided when energy is included in a production and supply chain planning model. Three different studies are carried out, analyzed, and presented as in this thesis. The first study is a case study at a specialty chemicals company and resulted in the first paper. Since the energy issue is not only a cost issue driven by supply and demand, but also a political issue due to its environmental aspects, it is likely to believe that political influence and especially continuity will have escalating effect on the energy intensive process industry sector. Thus, the strategic dimension of energy is highly relevant in this thesis. The importance of organizational integration, having a main responsible person, locating core business, and political continuity are addressed as prerequisites for including energy into the corporate strategy. Regarding long term profitability, the importance of correctly utilizing the energy system by appropriate energy planning and with respect to energy efficiency and effectiveness in both flexibility and investment issues are addressed. Further on, the quest of finding alternative revenue while striving for a proper exergy usage is addressed. The second study is a multiple case study with four different case companies involved; pulp, specialty chemicals, specialty oils, as well as a pulp and paper company. The need for improved production and supply chain planning is also addressed where for instance the lack of planning support for process industries is still an area of improvement. The production and supply chain planning in process industries is found to be rather poor compared to regular manufacturing companies. The planning methods found are often tailor made and adapted to the individual characteristics that are typical for many process industries. It has further on been difficult to distinguish similarities and differences among process industries regarding these planning issues and thus hard to generalize. The third study focuses on mathematical modelling and programming developing a combined supply chain and energy optimization model for a pulp company. Taking the first papers together there are reasons to believe that a planning and optimization model that take energy aspects in consideration, as a previously missing link, will contribute to improve the operations in process industries. A clear impact of involving energy issues into the supply chain planning is shown. The results show that a different production schedule is optimal when the energy issues are applied, and depend on, for instance, variations in energy prices such as the one for electricity. This is shown by using a model for a supply chain where the energy flow, and especially the utilization of by-products, also is involved.
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Palhinhas, Alexandre Galrito. "Landscape and energy: from planning to landscape integration of infrastructures for renewable energy production." Master's thesis, Universidade de Évora, 2012. http://hdl.handle.net/10174/15525.

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Esta dissertação é uma reflexão sobre os distúrbios climáticos devido à actividade humana e sua dependência histórica dos combustíveis fósseis para produzir energia. Chama a atenção para a necessidade do uso de energia renovável e que medidas podem ser tomadas para tal, respondendo a algumas questões neste contexto: que tipo de estruturas existem para produzir diferentes tipos de energia renovável? E no caso específico dos parques eólicos: que impactos podem ter na paisagem? O objectivo da tese é identificar os critérios mais importantes a considerar no planeamento de áreas destinadas à instalação de parques eólicos. Assumindo que a produção de energia renovável exige a instalação de estruturas, é importante uma análise cuidada no planeamento destas áreas. A tese não estabelece regras aplicáveis a todos os casos. Cada paisagem tem as suas próprias características e é percebida de forma diferente por cada pessoa; ABSTRACT:The study is a reflection on the climate disturbances due to human activity and its historic dependence on fossil fuels to produce energy. It notes the need for the use of renewable energy and what steps can be taken for such, addressing some issues in this context: what kind of structures exists to produce different types of renewable energy? And in the specific case of wind farms: what impacts have in the landscape? The aim of this thesis is to identify the most important criteria to consider when thinking about planning an area for a wind farm installation. Assuming that the production of renewable energy requires the installation of structures, is important to care on the planning of these places. The thesis does not establish any formula that applies anywhere. Each landscape has its own characteristics and is perceived differently by the people.
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Waldemarsson, Martin. "Planning production and supply chain in energy intensive process industries." Doctoral thesis, Linköpings universitet, Produktionsekonomi, 2014. http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-112289.

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To make a difference among the energy intensive process industries, this dissertation addresses production planning and supply chain planning problems related to industrial energy management issues. The energy issue is turning more and more important from different angles, involving price as well as environmental problems due to climate change leading to political pressure on all energy users. The process industry sector is one of the largest users of energy, and thus important to analyse. Process industries are also capital intensive and operate on large and expensive process equipment, making it imperative to plan their production well in order to reach preferable capacity utilisation. Therefore this dissertation strives to locate the most important energy management issues for the long term profitability of process industries, and investigates the  symbiotic effects of including energy issues in production and supply chain planning. Three different studies at three case companies are carried out, analysed, and presented in five papers. The cases represent the process industry sectors: chemicals, pulp, and steel. Both qualitative case study methodologies as well as quantitative mathematical modelling and optimisation approaches have been practiced. The research questions are analysed from both an energy system and from a production process point of view, separately as well as combined. Energy is somewhat considered to be the main workforce for process industries and this dissertation exemplifies some of its most important dimensions in this context. Several prerequisites for putting energy management on the strategic agenda are located in a specialty chemical industry where the importance of introducing a strategic perspective on energy, the way energy is used, and the possibilities of increasing alternative revenue from utilising by- and/or co-products differently are pinpointed. Approaches for including energy issues in planning processes are also suggested in terms of a MILP model for the entire supply chain of a pulp company, including decisions on purchase and transportation of raw maerials, production allocation, energy mix, and distribution. Another example is presented based on the perspectives of economics of scale and lot sizing through economic order quantity principles in a steel company. By using real company data, energy smart approaches in planning and scheduling are developed with respect to the most important intersections between the production processes and their supporting energy system. The accumulated resource intensity and embedded energy could, and probably should, hence be more fairly  reflected in the product price. The research finally shows some possible impact with including energy issues in a production and supply chain planning model. By planning differently, production prioritisations can be done, and it is not only possible without any large investments, but also prosperous with savings on both energy and money within reach. To conclude, planning of production and supply chain has either a direct or an indirect impact on the energy cost-effectiveness of a company. This dissertation argues that such impact also exists in its mutual form, and is very important when the energy issues are large enough, as they often are in the energy intensive process industry sector. Decision makers should thus beware of the short end of the stick that might be  devastating in the long run, but also aware of all the possibilities that can bring success and prosperity when the future begins.
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Labrik, Rachid. "Integration of energy management and production planning : Application to steelmaking industry." Thesis, KTH, Optimeringslära och systemteori, 2014. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-141432.

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Steelmaking industry, one of the most electricity-intensive industrial processes, is seeking for new approaches to improve its competitiveness in terms of energy savings by taking advantage of the volatile electricity prices. This fluctuation in the price is mainly caused by the increasing share of renewable energy sources, the liberalization of energy markets and the growing demand of the energy. Therefore, making the production scheduling of steelmaking processes with knowledge about the cost of the energy may lead to significant cost savings in the electricity bills. With this aim in mind, different models are developed in this project in order to improve the existing monolithic models (continuous-time based scheduling) to find an efficient formulation of accounting for electricity consumption and also to expand them with more detailed scheduling of Electric Arc Furnace stage in the production process. The optimization of the energy cost with multiple electricity sources and contracts and the production planning are usually done as stand-alone optimizers due to their complexity, therefore as a new approach in addition to the monolithic model an iterative framework is developed in this work. The idea to integrate the two models in an iterative manner has potential to be useful in the industry due to low effort for reformulation of existing models. The implemented framework uses multiparametric programming together with bilevel programming in order to direct the schedule to find a compromise between the production constraints and goals, and the energy cost. To ensure applicability heuristic approaches are also examined whenever full sized models are not meeting computational performance requirements. The results show that the monolithic model implemented has a considerable advantage in terms of computational time compared to the models in the literature and in some cases, the solution can be obtained in a few minutes instead of hours. In the contrary, the iterative framework shows a bad performance in terms of computational time when dealing with real world instances. For that matter a heuristic approach, which is easy to implement, is investigated based on coordination theory and the results show that it has a potential since it provides solutions close to the optimal solutions in a reasonable amount of time. Multiparametric programming is the main core of the iterative framework developed in this internship and it is not able to give the solutions for real world instances due to computational time limitations. This computational problem is related to the nature of the algorithm behind mixed integer multiparametric programming and its ability to handle the binary variables. Therefore, further work to this project is to develop new approaches to approximate multiparametric technique or develop some heuristics to approximate the mp-MILP solutions.
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Kadleček, Vít. "Efektivní využití energie při spalování odpadů." Master's thesis, Vysoké učení technické v Brně. Fakulta strojního inženýrství, 2015. http://www.nusl.cz/ntk/nusl-231794.

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The diploma thesis deals with an increasing of utilization of energy during a combustion of waste. The introductory part deals with a presentation of the specific waste to energy unit and its combined heat and power production. In the next part is described a computing tool and the principle of its function. The main part od the thesis deals with a description of cumputing tool testing and with a summary of achieved results.
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Youngblood, Elizabeth A. "Tracking Electricity Production Patterns for Residential Solar Electric Systems in Massachusetts." Thesis, Harvard University, 2015. http://nrs.harvard.edu/urn-3:HUL.InstRepos:24078372.

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The number of residential small-scale solar electric, or photovoltaic (PV) systems installed in Massachusetts has increased over the past five years. However, expanded deployment of residential solar PV may be hindered by lack of awareness of expected electricity generation of solar PV systems, and corresponding financial return. Policymakers are also interested in using limited state resources to support the installation of well-producing solar PV systems that will help meet state greenhouse gas reduction goals. Operational residential solar PV systems may provide a key to understanding electricity production that can inform prospective system owners and policymakers. This research utilizes monthly electricity production data for 5,400 residential solar PV systems in Massachusetts that were installed between 2010 and 2013. The analysis first focuses on understanding the aggregate dataset and distribution of systems, then explores the impact of fifteen different variables on residential solar PV system electricity production. These variables include shading, rebate eligibility, equipment type, ownership model, date in service year, system cost, selected installer, PTS reporting method, and others. When controlling for system size, production over all systems was normally distributed. Through a multiple regression analysis, percent shading, roof inclination and azimuth, rebate eligibility and county were variables that had the greatest impact on system production, with shading being key among them, while other variables showed a more nuanced impact. Ultimately, the full regression resulted in an r2 value of 34.2, leaving a majority of the system production variability unexplained. The data also provide insight into the impact of state policy measures surrounding system siting, validation of production data, and forecasting as part of the production based SREC incentive. Ultimately, quantifying the impact of the variables on electricity production patterns can be an effective tool to provide guidance for both prospective system owners and policymakers.
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Biel, Konstantin [Verfasser], Christoph [Akademischer Betreuer] Glock, and Anne [Akademischer Betreuer] Lange. "Multi-stage production planning with special consideration of energy supply and demand / Konstantin Biel ; Christoph Glock, Anne Lange." Darmstadt : Universitäts- und Landesbibliothek Darmstadt, 2017. http://d-nb.info/1147968519/34.

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Bakhiet, Arig G. "Investigation of Agricultural Residues Gasification for Electricity Production in Sudan as an Example for Biomass Energy Utlization under Arid Climate Conditions in Developing Countries." Doctoral thesis, Saechsische Landesbibliothek- Staats- und Universitaetsbibliothek Dresden, 2008. http://nbn-resolving.de/urn:nbn:de:bsz:14-ds-1211207352814-40782.

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This study examines the possibility of electricity production through gasification of agricultural residues in Sudan. The study begins in Chapter 1, by providing general contextual analysis of the energy situation (production and consumption patterns) in Sudan with specific focus on electricity. It proceeded to study the potential of Petroleum, Biomass and other renewable sources for electricity production. Dramatic increase in electricity production was found to be essential especially through decentralised power plants as the current electricity production services cover ~ 13 % of the population of Sudan. Biomass potential in Sudan justifies the use of agricultural residues as energy source; its potential was estimated by ~ 350000 TJ/a. Further, the urban centres of arid regions in western Sudan were identified as the target group for this study. In chapter 2, specific investigations for selected study area through field work using statistical tools such as questionnaires, interviews and field observation show that income is highly correlated to electricity consumption. The flat rate system did not result in higher consumption thus the assumption that this consumption will not drastically change in the next 10 years could be accepted. As orientation value for BGPP, 8000 tons of GN.S are available annually, the average electricity consumption is ~ 4 kWh/day/family while acceptable price could be 40 SDD/kWh (0.15 €). In chapter 3, literature review was carried to spot out the comparative merits of the gasification technology and the most optimum gasifying and electricity production system. As a result downdraft gasifier and ICE were suggested as suitable systems. In chapter 4, fuel properties and fuel properties of agricultural residues were studied, different samples were tested and the results were presented. The main conclusions derived were: fuel properties of agricultural residues are modifiable properties, so utlization planning is possible as for any other energy resource. In Sudan, Baggase, Groundnuts shells and Roselle stalks could be considered as possible fuels. The experimental work done in chapter 5 showed that GN.S could be gasified in down draft gasifiers, which are less costly and simpler to operate than circulating systems. Acceptable values of gas thermal properties (c.v.~ 4 MJ/Nm3, 30 % of burnable gases) at fairly continuing processes were obtained. In chapter 6, a concept for biomass power plant was drafted, the main components are: downdraft, air based gasifier connected to ICE, multi-stage gas cleaning system (cyclones, washer and filters) mechanical ash removal and semi closed water cycle. Main operation measures are: electricity is the sole product; working time is 150 day/year between mid Novembermid Mars. Environmental hazards of waste management e.g. flue gas emission and waste water management are the limiting factors. In the last part of chapter 6 an economic analysis was carried out. At a value of 3000 €/kW for the initial system and fuel price of 100000 €/year for ~6 GWh then a price of 0.23 €/kWh and a return period of 24 years could be obtained. The study concludes in chapter 7 that biomass gasification under the local conditions has its comparative merits however a high institutional support is needed at the beginning
Diese Studie untersucht die Möglichkeit der Elektrizitätsproduktion durch Vergasung von landwirtschaftlichen Abfällen im Sudan. Die Untersuchung beginnt im Kapitel 1 mit der Bereitstellung einer allgemeinen zusammenhängenden Analyse der Energiesituation (Produktions- und Verbrauchsmuster) im Sudan mit dem besonderen Fokus auf Elektrizität, gefolgt von einer Studie des Potentials von Petroleum, Biomasse und anderer erneuerbarer Quellen für die Produktion von Elektrizität. Eine starke Zunahme bei der Elektrizitätsproduktion wurde als nötig bewertet, da dezentrale Kraftwerke, als die gegenwärtigen Elektrizitätsproduktionsbetriebe, nur die Versorgung von 13 % der Bevölkerung im Sudan abdecken. Das geschätzte Potential der landwirtschaftlichen Abfälle liegt bei ca. 350.000 TJ/Jahre damit kommen sie als Energiequelle in Frage. Weiterhin wurden urbane Zentren der ariden Regionen in Westsudan als Zielgruppe für die Untersuchung ausgewählt. In Kapitel 2 werden detaillierte Untersuchungen für das ausgewählte Studiengebiet durch Feldstudien unter Verwendung von statistischen Werkzeugen, wie Fragebögen, Interviews und Felduntersuchungen dargestellt. Das Ergebnis zeigt, dass das Einkommen im höchsten Maße mit dem Elektrizitätsverbrauch korreliert ist. Das Flat rate System hatte keinen höheren Verbrauch zur Folge, folglich kann die Annahme akzeptiert werden, dass sich der Verbrauch in den nächsten 10 Jahren nicht drastisch ändern wird. Als Orientierungswert für Biomasse Kraftwerk: 8.000 t/Jahr Erdnussschalen sind verfügbar. Der durchschnittliche Elektrizitätsverbrauch beträgt ca. 4 kWh/Tag/Familie betrachtet für 10.000 Familien. Im Kapitel 3 wird eine Literaturrecherche für die Vergasungstechnologie durchgeführt, zum Vergleich ihrer Vorteile und zur Auswahl des optimalen Vergasungs- und Gasumwandlungssystems. Als Ergebnis wurden der Festbett-Gleichstrom-Vergaser und gas Motor als passende Systeme vorgeschlagen. In Kapitel 4 werden Brennstoff Eigenschaften von landwirtschaftlichen Abfällen untersucht, verschiedene Proben getestet und die Ergebnisse präsentiert. Die Hauptschlussfolgerung daraus ist: Brennstoff Eigenschaften von landwirtschaftlichen Abfällen sind veränderbare Eigenschaften, welche eine bessere Planung erlauben und somit ihre Verwendung favorisieren. Im Sudan können Bagasse, Erdnussschalen und Rosellenstiele als optimaler Brennstoff gelten. Die experimentelle Arbeit in Kapitel 5 zeigt, dass Erdnussschalen im 75 kW Festbett-Gleichstrom-Systemen vergast werden können, welche weniger kostenintensiv und einfach zu bedienen sind als zirkulierende Systeme. Akzeptable Werte der Gaseigenschaften (c.v. ca. 4 MJ/Nm³, 35 % von brennbaren Gasen) wurden in kontinuierlichen Prozessen erreicht. In Kapitel 6 wurde ein Konzept für Biomassekraftwerke entworfen. Deren Hauptkomponenten sind: Festbett-Gleichstrom-Vergaser in Verbindung mit ICE, mehrstufige Gasreinigungssysteme (Zyklone, Wäscher und Filter), mechanische Aschensysteme und ein teilweise geschlossener Wasserkreislauf. Hauptbetriebsmaßnahmen sind: Elektrizität als das einzige Produkt, die Arbeitszeit beträgt 150 Tage pro Jahr zwischen November und April. Umweltrisiken des Abfallmanagements z.B. Rauchgas und Abwassermanagement sind die limitierenden Faktoren. Im letzten Teil von Kapitel 6 wurde eine ökonomische Analyse durchgeführt. Ein Wert von 3000 €/kW für das Anfangssystem und ein Kraftstoffpreis von 100.000 €/Jahr für 6 GWh dann ein Preis von 0,23 €/kWh und eine Amortisationszeit von 24 Jahren können angenommen werden. Die Studie schlussfolgert, dass die Vergasung unter den Bedingungen des Studiengebietes ihre Vorteile hat, jedoch ist institutionelle Unterstützung am Anfang nötig
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Juhlin, Henrik. "Planering, förutsättningar ocheffekter av implementering avsolceller i stadsutvecklingsprojekt." Thesis, Uppsala universitet, Fasta tillståndets elektronik, 2011. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-148976.

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Today, buildings utilize 40 % of the total energy consumption. New energyrestrictions and directives have entered the construction industry. Photovoltaic is asustainable, clean and quiet solution that integrates well in the urban environment buthave not yet reached a breakthrough on the Swedish market. The conditions for solarenergy production are often set in the early planning stages where they rarely arebeing prioritized.This master of engineering project focuses on identifying problems regardingimplementation of photovoltaic in city development projects and giving suggestions topossible improvements in the planning- and construction process. It also givesrecommendations on how the conditions for energy production can be optimized inthe early zoning stage.By conducting simulations with PVsystV5.21, on three ongoing city developmentprojects in Umeå, Malmö and Stockholm and by carry out and analyzing interviewswith city planners, constructors and architects, some conclusions have been made.Several improvements, both politically, with changes in the subsidization systemand/or instatement of a new law with feed-in tariffs, and within the solar- andconstruction industry itself, with better communication between different parts of theprocess as well as better use of experience, can be made. By including photovoltaic inthe local plan it is possible to give a region large areas with orientation toward south,increasing the solar energy potential with up to 50 % which also increase themotivation for implementing photovoltaic in the project. These are essential for asignificant increase of photovoltaic in city development.
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Fujii, Ricardo Junqueira. "Sustentabilidade energética: uma análise do equilíbrio econômico, humano e natural." Universidade de São Paulo, 2015. http://www.teses.usp.br/teses/disponiveis/3/3143/tde-18122015-113716/.

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O desenvolvimento sustentável e a própria sobrevivência da humanidade dependem da compatibilização da demanda por recursos energéticos com as limitações ambientais e necessidades humanas. Dessa maneira, torna-se fundamental compreender e mensurar a sustentabilidade energética. Para tanto, esse trabalho vale-se de princípios da economia ecológica e do planejamento integrado de recursos para identificar e analisar os fatores que afetam a sustentabilidade energética de um dado sistema. A partir desses fatores são definidos indicadores de sustentabilidade, os quais compõem uma metodologia concebida para avaliar o grau de sustentabilidade da produção de energia. Tal metodologia é testada em um estudo de caso da matriz elétrica paulista, a qual mostrou um nível próximo da sustentabilidade, mas com a necessidade de aprimoramentos. Por fim, são feitas reflexões sobre a robustez, a flexibilidade e as limitações da metodologia proposta, assim como recomendações para ajustes da composição da matriz estudada com o propósito de torná-la mais sustentável.
Sustainable development and the very survival of humanity depends on the compatibility of the demand for energy resources with environmental constraints and human needs. Thus, it is essential to understand and define metrics for energy sustainability. For that reason, this work draws on principles of ecological economics and integrated resource planning to identify and analyze the factors affecting energy sustainability of a given system. From these factors are defined sustainability indicators, which are the foundations for a methodology designed to assess the degree of sustainability of energy production. The methodology is tested on a case study of the electricity matrix of the State of Sao Paulo, which is close to a sustainable level even though requiring improvements in some aspects. Finally, reflections on the sturdiness, flexibility and limitations of the proposed methodology, as well as recommendations for adjustments in the composition of the case study matrix in order to make it more sustainable are made.
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Books on the topic "Planing of an energy production"

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Bioenergy resources: Planning, production, and utilization. New Delhi: Concept Pub. Co., 1995.

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Funk, Markus. Industrielle Energieversorgung als betriebswirtschaftliches Planungsproblem. Heidelberg: Physica, 1991.

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Hosni, Djehane A. Manpower for energy production: An international guide to sources with annotations. New York: Greenwood Press, 1986.

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Meeting future energy needs draft demand/supply planning strategy. [Toronto]: Ontario Hydro, System Planning Division, 1987.

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Moskovitz, David. Stabilizing electricity production and use: Barriers and strategies. Washington, D.C: American Council for an Energy-Efficient Economy, 1992.

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Ireland. Department of the Environment. Wind farm development: Guidelinesfor planning authorities. Dublin: Stationery Office, 1996.

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G, Scott Walter, ed. Distributed power generation: Planning and evaluation. New York: Marcel Dekker, 2000.

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The strategy quest: Releasing the energy of manufacturing within a market driven strategy : 'a dynamic business story'. London: Pitman, 1994.

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Bubenzer, Achim. Photovoltaics Guidebook for Decision-Makers: Technological Status and Potential Role in Energy Economy. Berlin, Heidelberg: Springer Berlin Heidelberg, 2003.

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United States. Congress. House. Committee on Science and Technology. Subcommittee on Energy Development and Applications. Least cost utility planning initiative: Hearing before the Subcommittee on Energy Development and Applications of the Committee on Science and Technology, U.S. House of Representatives, Ninety-ninth Congress, first session, September 26, 1985. Washington: U.S. G.P.O., 1986.

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Book chapters on the topic "Planing of an energy production"

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Upton, Connor, Fergus Quilligan, Carlos García-Santiago, and Asier González-González. "Energy Efficient Production Planning." In IFIP Advances in Information and Communication Technology, 88–95. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013. http://dx.doi.org/10.1007/978-3-642-40352-1_12.

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Bettoni, Laura, and Simone Zanoni. "Energy Implications of Production Planning Decisions." In Advances in Production Management Systems. Value Networks: Innovation, Technologies, and Management, 9–17. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012. http://dx.doi.org/10.1007/978-3-642-33980-6_2.

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Franch, Torben, Max Scheidt, and Günter Stock. "Current and Future Challenges for Production Planning Systems." In Optimization in the Energy Industry, 5–17. Berlin, Heidelberg: Springer Berlin Heidelberg, 2009. http://dx.doi.org/10.1007/978-3-540-88965-6_1.

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Römisch, Werner, and Stefan Vigerske. "Recent Progress in Two-stage Mixed-integer Stochastic Programming with Applications to Power Production Planning." In Energy Systems, 177–208. Berlin, Heidelberg: Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-642-02493-1_8.

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Mummel, Jan, Michael Kurrat, Ole Roesky, Jürgen Köhler, and Lorenz Soleymani. "Planning of the Energy Supply of Electric Vehicles." In Sustainable Production, Life Cycle Engineering and Management, 41–59. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-72724-0_4.

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Kunapareddy, Aditya, and Gopichand Allaka. "An Improved Genetic Algorithm for Production Planning and Scheduling Optimization Problem." In Intelligent Manufacturing and Energy Sustainability, 157–71. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-1616-0_15.

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Giamalva, Mike J., and Stephen J. Clarke. "A Case Study of a Commercial Planting and Processing of Sweet Sorghum for Alcohol Production." In Biomass Energy Development, 601–6. Boston, MA: Springer US, 1986. http://dx.doi.org/10.1007/978-1-4757-0590-4_48.

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Flum, Dominik, Max Burkhardt, Daniel Moog, Johannes Sossenheimer, José Sanchez, and Eberhard Abele. "Tool for Simulation-Based Planning of Energy-Optimised Cooling Supply System Configuration for Manufacturing Facilities." In Advances in Production Research, 510–21. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-030-03451-1_50.

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Wolf, Johannes. "Regulation of the Purchase of Pipe- and Line-Based Sources of Energy in Industrial Companies." In Essays on Production Theory and Planning, 85–103. Berlin, Heidelberg: Springer Berlin Heidelberg, 1988. http://dx.doi.org/10.1007/978-3-642-73748-0_6.

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Fandel, Günter, and Joachim Reese. "Optimal Heat-Matched Cogeneration of Energy in a Firm Owned Power Station A Case Study." In Essays on Production Theory and Planning, 107–20. Berlin, Heidelberg: Springer Berlin Heidelberg, 1988. http://dx.doi.org/10.1007/978-3-642-73748-0_7.

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Conference papers on the topic "Planing of an energy production"

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Floysand, Ingve, and Jan-Erik Nordtvedt. "Production Planning In An Operation Center Environment." In Intelligent Energy Conference and Exhibition. Society of Petroleum Engineers, 2006. http://dx.doi.org/10.2118/99928-ms.

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Davidson, Shelley Sylvia, Sander Matthijs Mos, and Susie Coppock. "Planning for a Sustainable Production Optimisation Solution." In SPE Intelligent Energy Conference and Exhibition. Society of Petroleum Engineers, 2010. http://dx.doi.org/10.2118/128674-ms.

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Hamper, Martin J. "SPCC Planning for Oil Drilling, Workover, and Production Facilities." In Shale Energy Engineering Conference 2014. Reston, VA: American Society of Civil Engineers, 2014. http://dx.doi.org/10.1061/9780784413654.051.

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Erlingsen, Espen, Torgeir Strat, Vidar Gunnerud, Bjorn Nygreen, and Marta Duenas Diez. "Decision Support in Long Term Planning of Petroleum Production Fields." In SPE Intelligent Energy International. Society of Petroleum Engineers, 2012. http://dx.doi.org/10.2118/148861-ms.

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Benyoucef, Dirk, Thomas Bier, and Philipp Klein. "Planning of energy production and management of energy resources with Smart Meters." In 2010 International Conference on Advances in Energy Engineering (ICAEE). IEEE, 2010. http://dx.doi.org/10.1109/icaee.2010.5557587.

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Wu, Run. "The application of dynamic programming in production planning." In MATERIALS SCIENCE, ENERGY TECHNOLOGY, AND POWER ENGINEERING I: 1st International Conference on Materials Science, Energy Technology, Power Engineering (MEP 2017). Author(s), 2017. http://dx.doi.org/10.1063/1.4982520.

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Vardanyan, Yelena, Mikael Amelin, and Mohammad Hesamzadeh. "Short-term hydropower planning with uncertain wind power production." In 2013 IEEE Power & Energy Society General Meeting. IEEE, 2013. http://dx.doi.org/10.1109/pesmg.2013.6672693.

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Charkhonmattaku, Jariyaporn, and Charoenchai Khompatraporn. "Optimal VPP Energy Production Planning with Renewable Energy Sources and Small Dispatchable Generators." In 2021 6th International Conference for Convergence in Technology (I2CT). IEEE, 2021. http://dx.doi.org/10.1109/i2ct51068.2021.9417953.

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Spiegelberg, M. "Serving the underserved: the water–energy–food nexus in in socio-ecological production landscapes." In SUSTAINABLE DEVELOPMENT AND PLANNING 2015, edited by S. Hoshino and S. Hashimoto. Southampton, UK: WIT Press, 2015. http://dx.doi.org/10.2495/sdp150151.

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Ali, Izaz, and Ajay K. Jaiswal. "Energy auditing and production planning for a tire manufacturing plant." In 2019 7th International Youth Conference on Energy (IYCE). IEEE, 2019. http://dx.doi.org/10.1109/iyce45807.2019.8991559.

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Reports on the topic "Planing of an energy production"

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Friedrich, S., and R. Kolagani. Total Energy CMR Production. Office of Scientific and Technical Information (OSTI), August 2008. http://dx.doi.org/10.2172/945555.

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Ulibarri, C. A., H. S. Seely, D. B. Willis, and D. M. Anderson. Water, energy, and farm production. Office of Scientific and Technical Information (OSTI), April 1996. http://dx.doi.org/10.2172/236268.

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Klasson, KT. Energy Production from Zoo Animal Wastes. Office of Scientific and Technical Information (OSTI), April 2003. http://dx.doi.org/10.2172/885878.

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Woodworth, J. G., and W. Meier. Target production for inertial fusion energy. Office of Scientific and Technical Information (OSTI), March 1995. http://dx.doi.org/10.2172/125415.

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Brown, D., M. Johnson, and P. Navratil. High Energy Neutron Induced Gamma Production. Office of Scientific and Technical Information (OSTI), September 2007. http://dx.doi.org/10.2172/924180.

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Hites, R. A. Toxic organic compounds from energy production. Office of Scientific and Technical Information (OSTI), November 1990. http://dx.doi.org/10.2172/6150097.

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Hites, R. A. Toxic organic compounds from energy production. Office of Scientific and Technical Information (OSTI), September 1991. http://dx.doi.org/10.2172/6263915.

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A. Glaser and R.J. Goldston. Proliferation Risks of Magneetic Fusion Energy: Clandestine Production, Covert Production and Breakout. Office of Scientific and Technical Information (OSTI), March 2012. http://dx.doi.org/10.2172/1036304.

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Sethi, Vijay. Sorbent-based Oxygen Production for Energy Systems. Office of Scientific and Technical Information (OSTI), January 2017. http://dx.doi.org/10.2172/1352448.

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Cooke, William E. Sustainable Algal Energy Production and Environmental Remediation. Office of Scientific and Technical Information (OSTI), July 2012. http://dx.doi.org/10.2172/1348189.

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