Integration of renewable energy sources in the distribution network

Tato práce uvádí obecné informace o obnovitelných zdrojích energie, typech elektráren a jejich pracovních principech. Práce je zaměřena na větrné elektrárny (principy, typy, komponenty, výhody a nevýhody). Obsahuje také pravidla pro připojování rozptýlených zdrojů energie k distribuční soustavě. V praktické části je řešena případová studie, která demonstruje napěťové charakteristiky pro síť vysokého napětí před a po připojení větrné elektrárny do distribuční sítě se dvěma různými hodnotami účiníku.This thesis will provide general information about renewable energy sources, types of power plants and their working principles. The thesis is focused on wind power plants (principles, types, components, advantages and disadvantages). It also includes the rules for connecting dispersed energy sources to the distribution system. In practical part, a case study demonstrates voltage characteristics before and after connection of a wind power plant to a distribution network with two different values of power factor

Connection of renewable energy sources to the power grid

Diplomová práce se zabývá obnovitelnými zdroji energie a druhy, které se nejvíce využívají. Teoretická část je věnována obecným informacím o obnovitelných zdrojích energie, typech elektráren a v další části se zaměřuje na fotovoltaické elektrárny. Praktická část ilustruje připojení fotovoltaické elektrárny do sítě vysokého napětí (22kV) ve Středočeském kraji. Dále jsou v práci uvedena pravidla pro připojení rozptýlených výroben elektřiny z obnovitelných zdrojů energie do distribuční sítě, napěťový profil podél vedení před a po připojení FVE do distribuční sítě.This thesis deals with the renewable energy and its main types. The theoretical part is about the general information on renewable energy sources, types of power plants, focusing on photovoltaic power plants. The practical part illustrates the connection of photovoltaic power plant to a medium voltage network (22kV) in Central Bohemia region. The following part is devoted to the rules for connecting dispersed energy sources to the distribution network, voltage profile along the lines before and after connecting the PVPP's into the distribution network

Department of Trade and Industry Energy Review Consultation 2006: Submission by Open University Energy & Environment Research Unit

The Open University Energy and Environment Research Unit has, since its foundation in 1986, focussed on a range of sustainable energy technologies on a variety of scales, from large to small, in the belief that a sustainable energy system will require contributions at all scales. So while we support, for example, the development of microgeneration and improvements in energy efficiency in buildings, we also believe that larger-scale projects, in particular offshore wind and city-wide combined heat and power (CHP), have a major role to play in a sustainable energy future. This submission is in two parts: Part One proposes a major expansion in the UK's offshore wind programme. Part Two proposes a major expansion in Combined Heat and Power (CHP)

A new tri-generation system: thermodynamical analysis of a micro compressed air energy storage

There is a growing interest in the electrical energy storage system, especially for matching intermittent sources of renewable energy with customers’ demand. Furthermore, it is possible, with these system, to level the absorption peak of the electric network (peak shaving) and the advantage of separating the production phase from the exertion phase (time shift). CAES (compressed air energy storage systems) are one of the most promising technologies of this field, because they are characterized by a high reliability, low environmental impact and a remarkable energy density. The main disadvantage of big systems is that they depend on geological formations which are necessary to the storage. The micro-CAES system, with a rigid storage vessel, guarantees a high portability of the system and a higher adaptability even with distributed or stand-alone energy productions. This article carries out a thermodynamical and energy analysis of the micro-CAES system, as a result of the mathematical model created in a Matlab/Simulink® environment. New ideas will be discussed, as the one concerning the quasi-isothermal compression/expansion, through the exertion of a biphasic mixture, that will increase the total system efficiency and enable a combined production of electric, thermal and refrigeration energies. The exergy analysis of the results provided by the simulation of the model reports that more than one third of the exergy input to the system is lost. This is something promising for the development of an experimental device

Alaska Energy Statistics 1960-2011 Final Report

This twenty-sixth edition of the Alaska Energy Statistics reconciles energy data from public sources and makes that data more easily available to the public and stakeholders. It primarily presents 2011 data on electricity produced by certified utilities in Alaska. It includes a brief introduction, highlights, and summary data tables. The first major section describes basic statistical indicators for Alaska utilities, and the second discusses renewable energy in Alaska. After that we look more broadly at the big picture of energy in Alaska, describing production and consumption of various energy sources. A series of appendixes defines terms, lists references, and describes data sources. This report presents data for the state and for the 11 Alaska Energy Authority energy regions. In an accompanying workbook, we also present data by U.S. census areas, Alaska Native corporation regions, and regions used in earlier Alaska Electric Energy Statistics reports.8 Unlike the preliminary version of this report, issued in fall 2012, this final report includes installed capacity data tables for 2011, as well as additional chapters on renewable energy and other Alaska energy information.Alaska Energy AuthorityTable of Contents / List of Tables / List of Figures / Summary and Highlights / Introduction / Electric Sector / Renewable-Sourced Energy in Alaska / Energy in Alaska / Appendix A/ Glossary of Terms / Appendix B. References / Appendix C. RCA Utility Regulatory Codes Summary / Appendix D. Data Sources for Electric Energy Statistics / Appendix E. Reporting Requirement

An Intelligent Fuse-box for use with Renewable Energy Sources integrated within a Domestic Environment

This paper outlines a proposal for an intelligent fuse-box that can replace existing fuse-boxes in a domestic context such that a number of renewable energy sources can easily be integrated into the domestic power supply network, without the necessity for complex islanding and network protection. The approach allows intelligent control of both the generation of power and its supply to single or groups of electrical appliances. Energy storage can be implemented in such a scheme to even out the power supplied and simplify the control scheme required, and environmental monitoring and load analysis can help in automatically controlling the supply and demand profiles for optimum electrical and economic efficiency. Simulations of typical scenarios are carried out to illustrate the concept in operation

Dispersed storage and generation case studies

Three installations utilizing separate dispersed storage and generation (DSG) technologies were investigated. Each of the systems is described in costs and control. Selected institutional and environmental issues are discussed, including life cycle costs. No unresolved technical, environmental, or institutional problems were encountered in the installations. The wind and solar photovoltaic DSG were installed for test purposes, and appear to be presently uneconomical. However, a number of factors are decreasing the cost of DSG relative to conventional alternatives, and an increased DSG penetration level may be expected in the future

Alaska Energy Statistics 1960-2011 Preliminary Report

Prior to 1985, the federal Alaska Power Administration published the Alaska Electric Power Statistics. Then, the Alaska Energy Authority (formerly the Alaska Power Authority) began gathering statistical data and publishing this annual report. In 1988, the Alaska Electric Power Statistics report became a combined effort between the Alaska Systems Coordinating Council and the Alaska Energy Authority. Beginning in 1993, the report became a joint effort between the Alaska Systems Coordinating Council and the Alaska Department of Community and Regional Affairs, Division of Energy. After the 1995 report, no further reports were published until 2003 when a report was prepared by the Institute of Social and Economic Research (ISER), University of Alaska Anchorage (UAA), with funding provided by the Alaska Energy Authority (AEA), the Regulatory Commission of Alaska (RCA), and the Denali Commission. Beginning in 2008, Alaska Electric Energy Statistics updates have been prepared by ISER in partnership with AEA. The purpose of this report is to present electric power reference data for Alaska; it is not intended to provide detailed analysis of energy production, consumption or uses.Alaska Energy Authority.Introduction / Summary and Highlight

Potential for Solar Energy in Food Manufacturing, Distribution and Retail

The overall aim of the study was to assess the potential for increasing the use of solar energy in the food sector. For comparative purposes the study also included an assessment of the benefits that could arise from the use of other renewable energy sources, and the potential for more effective use of energy in food retail and distribution. Specific objectives were to: i) establish the current state of the art in relevant available solar technology; ii) identify the barriers for the adoption of solar technology; iii) assess the potential for solar energy capture; iv) appraise the potential of alternative relevant technologies for providing renewable energy; v) assess the benefits from energy saving technologies; vi) compare the alternative strategies for the next 5-10 years and vii) Consider the merits of specific research programmes on solar energy and energy conservation in the food sector. To obtain the views of the main stakeholders in the relevant food and energy sectors on the opportunities and barriers to the adoption of solar energy and other renewable energy technologies by the food industry, personal interviews and structured questionnaires tailored to the main stakeholders (supermarkets, consultants for supermarket design; energy and equipment suppliers) were used. The main findings from the questionnaires and interviews are: - Key personnel in supermarkets and engineers involved in the design of supermarkets are aware of the potential contribution of renewable energy technologies and other energy conservation measures to energy conservation and environmental impact reduction in the food industry. A number of supermarket chains have implemented such technologies at pilot scale to gain operating experience, and more importantly, for marketing reasons, to gain competitive advantage through a green image. - From installations to date in the UK the most notable are a 600 kW wind turbine at a Sainsbury's distribution centre in East Kilbride and a 60 kWp photovoltaic array at a Tesco store in Swansea. - The main barrier to the application of renewable energy technologies in the food sector is the capital cost. Even though significant progress has been made towards the improvement of the energy conversion efficiencies of photovoltaic technologies (PVs) and reduction in their cost, payback periods are still far too long, for them to become attractive to the food industry. - Wind energy can be more attractive than PVs in areas of high wind speed. Apart from relatively high cost, the main barrier to the wide application of wind turbines for local power generation is planning restrictions. This technology is more attractive for application in food distribution centres that are normally located outside build-up areas where planning restrictions can be less severe than in urban areas. In these applications it is likely that preference will be for large wind turbines of more than 1.0 MW power generation capacity as the cost of generation per unit power reduces with the size of the turbine

Alaska Energy Statistics 1960‐2009

This report has had various publishers. Before 1985, the federal Alaska Power Administration published Alaska Electric Power Statistics. Then, the Alaska Energy Authority (formerly the Alaska Power Authority) began gathering statistical data and publishing this annual report. In 1988, the Alaska Electric Power Statistics report became a combined effort of the Alaska Systems Coordinating Council and the Alaska Energy Authority. Beginning in 1993, the report became a joint effort of the Alaska Systems Coordinating Council and the Alaska Department of Community and Regional Affairs, Division of Energy. After the 1995 report, no reports were issued until 2003, when the Institute of Social and Economic Research (ISER) at the University of Alaska Anchorage (UAA), published a report, with funding from the Alaska Energy Authority (AEA), the Regulatory Commission of Alaska (RCA), and the Denali Commission. ISER prepared this twenty‐fourth edition of the Alaska Electric Energy Statistics in collaboration with the Alaska Energy Authority. Unlike previous reports, data tables are presented solely in digital form in an MS Excel file. The workbook containing the data tables is available on the ISER website at http://iser.uaa.alaska.edu/Publications/AlaskaEnergyStatisticsCY2009Tables.xlsx) and the AEA website (http://www.akenergyauthority.org/).The data tables are presented in a dataset format for convenient use and manipulation. All data presented are identified by the geographic regions used in previous Alaska Electric Energy Statistics,1 as well as AEA energy regions, Alaska Native corporation regions, and census areas.Alaska Energy Authority.Introduction / Summary and Highlight