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Title: Efficient System Design and Sustainable Finance for China's Village Electrification Program


No abstract prepared.

; ;
Publication Date:
Research Org.:
National Renewable Energy Lab. (NREL), Golden, CO (United States)
Sponsoring Org.:
OSTI Identifier:
DOE Contract Number:
Resource Type:
Resource Relation:
Conference: Proceedings of the Solar 2006 Conference, 9-13 July 2006, Denver, Colorado (CD-ROM); Including Proceedings of 35th ASES Annual Conference, Proceedings of 31st National Passive Solar Conference, Proceedings of the 1st Renewable Energy Policy and Marketing Conference, and Proceedings of the ASME 2006 International Solar Energy Conference
Country of Publication:
United States

Citation Formats

Shenghong, M., Huanying, Y., and Kline, D. M.. Efficient System Design and Sustainable Finance for China's Village Electrification Program. United States: N. p., 2006. Web.
Shenghong, M., Huanying, Y., & Kline, D. M.. Efficient System Design and Sustainable Finance for China's Village Electrification Program. United States.
Shenghong, M., Huanying, Y., and Kline, D. M.. Sun . "Efficient System Design and Sustainable Finance for China's Village Electrification Program". United States. doi:.
title = {Efficient System Design and Sustainable Finance for China's Village Electrification Program},
author = {Shenghong, M. and Huanying, Y. and Kline, D. M.},
abstractNote = {No abstract prepared.},
doi = {},
journal = {},
number = ,
volume = ,
place = {United States},
year = {Sun Jan 01 00:00:00 EST 2006},
month = {Sun Jan 01 00:00:00 EST 2006}

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  • This paper describes a joint effort of the Institute for Electrical Engineering of the Chinese Academy of Sciences (IEE), and the U.S. National Renewable Energy Laboratory (NREL) to support China's rural electrification program. This project developed a design tool that provides guidelines both for off-grid renewable energy system designs and for cost-based tariff and finance schemes to support them. This tool was developed to capitalize on lessons learned from the Township Electrification Program that preceded the Village Electrification Program. We describe the methods used to develop the analysis, some indicative results, and the planned use of the tool in themore » Village Electrification Program.« less
  • This work has two main goals: First, it provides for the analysis of data collected from systems developed in the previous phase of China's rural power program, the Township Electrification Program Second, it will comprise joint IEE-NREL work in support of the upcoming phase, 'Electrification of Unelectrified Areas'.
  • This paper describes the strategies and process used by the U.S. Department of Energy’s (DOE) nuclear Material Protection, Control and Accounting (MPC&A) Regulatory Development Project (RDP) to restructure its support for MPC&A regulations in the Russian Federation. The RDP adopted a project management approach to defining, implementing, and managing an effective nuclear regulatory structure. This approach included defining and developing the regulatory documents necessary to provide the Russian Federation with a comprehensive regulatory structure that supports an effective and sustainable MPC&A Program in Russia. This effort began in February 2005, included a series of three multi-agency meetings in April, June,more » and July, and culminated in August 2005 in a mutually agreed-upon plan to define and populate the nuclear regulatory system in the Russian Federation for non-military, weapons-usable material. This nuclear regulatory system will address all non-military Category I and II nuclear material at the Russian Federal Atomic Energy Agency (Rosatom), the Russian Agency for Industry (Rosprom), and the Federal Agency for Marine and River Transport (FAMRT) facilities; nuclear material in transport and storage; and nuclear material under the oversight of the Federal Environmental, Industrial and Nuclear Supervisory Service of Russia (Rostechnadzor). The Russian and U.S. MPC&A management teams approved the plan, and the DOE National Nuclear Security Administration’s (NNSA) NA-255, Office of Infrastructure and Sustainability (ONIS), is providing funding. The Regulatory Development Project is managed by the Pacific Northwest National Laboratory (PNNL) for the U.S. Department of Energy’s (DOE) NNSA.« less
  • With the congressionally mandated January 1, 2013 deadline for the U.S. Department of Energy’s (DOE) Nuclear Material Protection, Control and Accounting (MPC&A) program to complete its transition of MPC&A responsibility to the Russian Federation, National Nuclear Security Administration (NNSA) management directed its MPC&A program managers and team leaders to demonstrate that work in ongoing programs would lead to successful and timely achievement of these milestones. In the spirit of planning for successful project completion, the NNSA review of the Russian regulatory development process confirmed the critical importance of an effective regulatory system to a sustainable nuclear protection regime and calledmore » for an analysis of the existing Russian regulatory structure and the identification of a plan to ensure a complete MPC&A regulatory foundation. This paper describes the systematic process used by DOE’s MPC&A Regulatory Development Project (RDP) to develop an effective and sustainable MPC&A regulatory structure in the Russian Federation. This nuclear regulatory system will address all non-military Category I and II nuclear materials at State Corporation for Atomic Energy “Rosatom,” the Federal Service for Ecological, Technological, and Nuclear Oversight (Rostechnadzor), the Federal Agency for Marine and River Transport (FAMRT, within the Ministry of Transportation), and the Ministry of Industry and Trade (Minpromtorg). The approach to ensuring a complete and comprehensive nuclear regulatory structure includes five sequential steps. The approach was adopted from DOE’s project management guidelines and was adapted to the regulatory development task by the RDP. The five steps in the Regulatory Development Process are: 1) Define MPC&A Structural Elements; 2) Analyze the existing regulatory documents using the identified Structural Elements; 3) Validate the analysis with Russian colleagues and define the list of documents to be developed; 4) Prioritize and schedule the development of documents; 5) Identify and develop processes to measure effectiveness of regulations. Utilizing this process is resulting in an effective regulatory process that is understood and is being adopted by the four RF organizations. It is anticipated that the current regulatory development process will continue after U.S. support ends. Utilization of the systematic methodology will ensure regulatory development is based on required MPC&A structural elements and will support the continued maintenance and development of an effective regulatory base.« less
  • It is estimated that two billion people live without electricity and its services worldwide. In addition, there is a sizeable number of rural villages that have limited electrical service, with either part-day operation by diesel generator or partial electrification. For many villages connected to the grid, power is often sporadically available and of poor quality. The US National Renewable Energy Laboratory (NREL) in Golden, Colorado, has initiated a program that involves hybrid systems, to address these potential electricity opportunities in rural villages through the application of renewable energy technologies.1 The objective of this program is to develop and implement applicationsmore » that demonstrate the technical performance, economic competitiveness, operational viability, and environmental benefits of renewable rural electric solutions, compared to the conventional options of line extension and isolated diesel mini-grids. Hybrid systems are multi-disciplinary, multi-technology, multi-application programs composed of six activities, including village applications development, computer model development, systems analysis, pilot project development, technical assistance, and Internet-based village power project data base. While the current program emphasizes wind, photovoltaics (PV), and their hybrids with diesel generator, micro-hydro and micro-biomass technologies may be integrated in the future. Thirteen countries are actively engaged in hybrid systems for rural and remote applications and another dozen countries have requested assistance in exploring wind/PV hybrid systems within their territories. At present rural/remote site application of renewable technologies is the fastest growing aspect of renewable energy worldwide.« less