Suzhou Electric Appliance Research Institute
期刊號(hào): CN32-1800/TM| ISSN1007-3175

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電力需求側(cè)對(duì)電力系統(tǒng)頻率質(zhì)量貢獻(xiàn)研究綜述

來源:電工電氣發(fā)布時(shí)間:2018-04-19 09:19 瀏覽次數(shù):697
電力需求側(cè)對(duì)電力系統(tǒng)頻率質(zhì)量貢獻(xiàn)研究綜述
 
李天寧
(江蘇大學(xué) 電氣信息工程學(xué)院,江蘇 鎮(zhèn)江 212013)
 
    摘 要:可再生能源的大規(guī)模接入給電力系統(tǒng)的穩(wěn)定運(yùn)行帶來了較大影響。介紹了需求側(cè)管理和響應(yīng)的基本原理,從需求側(cè)參與電網(wǎng)頻率調(diào)整的能力、成本效益、控制方法、技術(shù)支持等方面分析了需求側(cè)參與電網(wǎng)頻率調(diào)整的細(xì)節(jié)問題。展望了需求側(cè)參與多區(qū)域互聯(lián)電力系統(tǒng)頻率調(diào)整研究領(lǐng)域的工作前景,指出須加快需求側(cè)參與電網(wǎng)頻率調(diào)整建設(shè),盡快建立符合我國國情的需求側(cè)響應(yīng)機(jī)制。
    關(guān)鍵詞:需求側(cè)響應(yīng);頻率調(diào)整;集中式控制;分散式控制
    中圖分類號(hào):TM761+.2     文獻(xiàn)標(biāo)識(shí)碼:A     文章編號(hào):1007-3175(2018)04-0001-09
 
A Review on Electrical Demand Side Contribution to Frequency Quality in Power System
 
LI Tian-ning
(School of Electrical and Information Engineering, Jiangsu University, Zhenjiang 212013, China)
 
    Abstract: Large scale access of renewable energy sources will pose a huge challenge to the frequency stability of power system. Introduce was made to the fundamental principle of demand side management and response. This paper analyzed the detail problems of demand side participation and grid frequency from the capacity of demand side participation and grid frequency, cost-effectiveness, control method and technical support etc aspects. This paper expected the working prospect of demand side participation in the research field of multi-area interconnected power system frequency regulation. It is pointed out that the demand side participation and the construction regulation of grid frequency need to be fast to establish the demand side response mechanism conform to the national conditions as soon as possible.
    Key words: demand side response; frequency regulation; centralized control; decentralized control
 
參考文獻(xiàn)
[1] SIGRIST L, EGIDO I, MIGUELEZ E L, et al.Sizing and Controller Setting of Ultracapacitors for Frequency Stability Enhancement of Small Isolated Power Systems[J]. IEEE Transactions on Power Systems,2015,30(4):2130-2138.
[2] RESCHA G, HELD A, FABER T, et al. Potentials and prospects for renewable energies at global scale[J]. Energy Policy,2008,36(11):4048-4056.
[3] STRBAC G, SHAKOOR A, BLACK M, et al.Impact of wind generation on the operation and development of the UK electricity systems[J]. Electric Power Systems Research,2007,77(9):1214-1227.
[4] DOHERTY R, O’MALLEY M.A New Approach to Quantify Reserve Demand in Systems with Significant Installed Wind Capacity[J]. IEEE Transactions on Power Systems,2005,20(2):587-595.
[5] FARHANGI H.The path of the smart grid[J]. IEEE Power & Energy Magazine,2010,8(1):18-28.
[6] AMIN S M, WOLLENBERG B F.Toward a smart grid: power delivery for the 21st century[J]. IEEE Power & Energy Magazine,2005,3(5):34-41.
[7] MOSLEHI K, KUMAR R.A reliability perspective of the smart grid[J]. IEEE Transactions on Smart Grid,2010,1(1):57-64.
[8] GARULLI A, PAOLETTI S, VICINO A.Models and Techniques for Electric Load Forecasting in the Presence of Demand Response[J]. IEEE Transactions on Control Systems Technology,2015,23(3):1087-1097.
[9] VU T L, AYU A A, DHUPIA J S, et al.Power Management for Electric Tugboats Through Operating Load Estimation[J]. IEEE Transactions on Control Systems Technology,2015,23(6):2375-2382.
[10] THEKKEMADOM V, MOORE J D, SULTE R P, et al. Load estimation issues in real-time power system state estimation[C]//IEEE Power and Energy Society General Meeting,2012:1-4.
[11] GHORBANI N, BABAEI E. Exchange market algorithm for economic load dispatch[J]. International Journal of Electrical Power and Energy Systems,2016,75:19-27.
[12] RAN X H, MIAO S H, JIANG Z, et al. A framework for uncertainty quantification and economic dispatch model with wind-solar energy[J]. International Journal of Electrical Power and Energy Systems,2015,73:23-33.
[13] LAI X W, XIE L, XIA Q, et al. Decentralized Multi-Area Economic Dispatch via Dynamic Multiplier-Based Lagrangian Relaxation[J]. IEEE Transactions on Power Systems,2015,30(6):3225-3233.
[14] PALENSKY P, DIETRICH D. Demand Side Management:Demand Response, Intelligent Energy Systems, and Smart Loads[J]. IEEE Transactions on Industrial Informatics,2011,7(3):381-388.
[15] RAHIMI F, IPAKCHI A. Demand response as a market resource under the smart grid paradigm[J]. IEEE Transactions on Smart Grid,2010,1(1):82-88.
[16] KIM J H, SHCHERBAKOVA A. Common failures of demand response[J]. Energy,2011,36(2):873-880.
[17] KIRSCHEN D S. Demand-side view of electricity markets [J]. IEEE Transactions on Power Systems,2003,18(2):520-527.
[18] BRADLEY P, LEACH M, TORRITI J. A review of the costs and benefits of demand response for electricity in the UK[J]. Energy Policy,2013,52(3):312-327.
[19] WARREN P. A review of demand-side managementpolicy in the UK[J]. Renewable & Sustainable Energy Review,2014,29(7):941-951.
[20] PAULUS M, BORGGREFE F. The potential of demandside management in energy-intensive industries for electricity markets in Germany[J]. Applied Energy,2011,88(2):432-441.
[21] KLOBASA M. Analysis of demand response and wind integration in Germany’s electricity market[J]. IET Renewable Power Generation,2010,4(1):55-63.
[22] CAPPERS P, GOLDMAN C, KATHAN D. Demandresponse in US electricity markets:Empirical evidence[J].Energy,2010,35(4):1526-1535.
[23] ZARNIKAU J, LANDRETH G, HALLETT I, et al. Industrial customer response to wholesale prices in the restructured Texas electricity market[J]. Energy,2007,32(9):1715-1723.
[24] KANG L J, LIANG W P. Analysis on primary frequency regulation function tests for thermal power units[J]. Advanced Materials Research,2014,986-987:1187-1190.
[25] LIANG Z Y, LI S S. Research on influence factor of primary frequency regulation performance for thermal power plant[J]. Applied Mechanics and Materials,2013,448-453:2040-2044.
[26] ZHANG J B, LI H, XIE H P. Analysis and improvement on primary frequency regulation control system of hydro generator units[J]. Journal of Hydroelectric Engineering,2009,28(6):206-213.
[27] LIU H, HU Z C, SONG Y H, et al. Vehicle-to-Grid Control for Supplementary Frequency Regulation Considering Charging Demands[J]. IEEE Transactions on Power Systems,2015,30(6):3110-3119.
[28] ZHONG J, HE L N, LI C B, et al. Coordinatedcontrol for large-scale EV charging facilities and energy storage devices participating in frequency regulation[J]. Applied Energy,2014,123(12):253-262.
[29] MONGKOLTANATAS J, RIU D, LEPIVERT X. Energy storage design for primary frequency control for islanding micro grid[J]. 38th Annual Conference on IEEE Industrial Electronics Society,2012,2(1):5643-5649.
[30] JIANG H, LIN J, SONG Y H, et al. Demand side frequency control scheme in an isolated wind power system for industrial aluminum smelting production[J]. IEEE Transactions on Power Systems,2014,29(2):844-853.
[31] MOLINA-GARCIA A, BOUFFARD F, KIRSCHEN D S. Decentralized Demand-Side Contribution to Primary Frequency Control[J]. IEEE Transactions on Power Systems,2011,26(1):411-419.
[32] DOUGLASS P J, GARCIA-VALLE R, NYENG P, et al. Smart Demand for Frequency Regulation:Experimental Results[J]. IEEE Transactions on Smart Grid,2013,4(3):1713-1720.
[33] LU N, HAMMERSTORM D J. Design considerations for frequency responsive grid friendly appliances[C]//Proceedings of the IEEE Power Engineering Society Transmission and Distribution Conference,2006:647-652.
[34] U.S.Energy Information Administration. Office of energy consumption and efficiency statistics[R]. Form EIA-457A/G Residential Energy Consumption Survey,2009.
[35] ARTECONI A, HEWITT N J, POLONARA F. State of the art of thermal storage for demand-side management[J]. Applied Energy,2012,93(5):371-389.
[36] MARCUS M C. Demand as frequency controlled reserve analysis of technology and potentials student project report[R]. Copenhagen: Technical University of Denmark,2006.
[37] WARREN P. A review of demand-side management policy in the UK[J]. Renewable & Sustainable Energy Reviews,2014,29(7):941-951.
[38] KIRBY B. Spinning reserve from responsive loads[J]. Office of Scientific & Technical Information Technical Reports,2003,15(3):219-227.
[39] XU Z Z, ZENG M. Analysis on Electricity Market Development in US and Its Inspiration to Electricity Market Construction in China[J]. Power System Technology,2011,35(6):161-166.
[40] WANG J, REDONDO N E, GALIANA F D. Demand-Side Reserve Offers in Joint Energy/Reserve Electricity Markets[J]. IEEE Transactions on Power Systems,2003,18(4):1300-1306.
[41] YANG D, CHEN Y N. Demand Response and Market Performance in Power Economics[C]//IEEE Power and Energy Society General Meeting,2009:1-6.
[42] PAPAGIANNIS G, DAGOUMAS A, LETTAS N, et al. Economic and environmental impacts from theimplementation of an intelligent demand side management system at the European level[J]. Energy Policy,2008,36(1):163-180.
[43] WALAWALKAR R, BLUMSACK S, APT J, et al. An economic welfare analysis of demand response in the PJM electricity market[J]. Energy Policy,2008,36(10):3692-3702.
[44] ZHANG N, OCHOA L F, KIRSCHEN D S. Investigating the Impact of Demand Side Management on Residential Customers[C]//IEEE PES International Conference and Exhibition on Innovative Smart Grid Technologies,2011:1-6.
[45] ALMEIDA P M R, SOARES F J , LOPES J A P. Electric vehicles contribution for frequency control with inertial emulation[J]. Electric Power Systems Research,2015,127:141-150.
[46] KOOK K S, SON H J, SONG Y J. The Potential of V2G for Frequency Control in Power Systems for Applications in Korea[C]//IEEE Power and Energy Society General Meeting,2012:1-4.
[47] KIKUCHI H, ASANO H, BANDO S. Load frequency control by commercial air conditioners power consumption control with large penetration of renewable energy generation[J]. IEEJ Transactions on Power and Energy,2015,135(4):233-240.
[48] PEDRASA M A A, ORO M M, REYES N C R, et al. Demonstration of Direct Load Control of Air Conditioners in High Density Residential Buildings[C]//Innovative Smart Grid Technologies-Asia,2014:400-405.
[49] LAKSHMANAN V, MARINELLI M, KOSEK A M, et al. Domestic refrigerators temperature prediction strategy for the evaluation of the expected power consumption[J]. Innovative Smart Grid Technologies Europe,2014,7(1):1-5.
[50] O'CONNELL N, MADSEN H, PINSON P, et al. Regulating power from supermarket refrigeration[C]//IEEE PES Innovative Smart Grid Technologies Conference Europe,2015:1-6.
[51] RAUTIAINEN A, REPO S, JARVENTAUSTA P.Using frequency dependent electric space heating loads to manage frequency disturbances in power systems[C]//IEEE Bucharest Power Tech,2009:1-6.
[52] PAPAEFTHYMIOU G, HASCHE B, NABE C .Potential of Heat Pumps for Demand Side Management and Wind Power Integration in the German Electricity Market[J]. IEEE Transactions on Sustainable Energy,2012,3(4):636-642.
[53] RAZIEI S A, MOHSENIAN-RAD H. Optimal Demand Response Capacity of Automatic Lighting Control[J].Innovative Smart Grid Technologies,2013,19(2):1-6.
[54] ATIKOL U. A simple peak shifting DSM(demandside management)strategy for residential water heaters[J]. Energy,2013,62(6):435-440.
[55] SIEBERT L C, FERREIRA L R, YAMAKAWA E K, et al. Centralized and decentralized approaches to demand response using smart plugs[C]//IEEE/PES Transmission & Distribution Conference & Exposition,2014:1-5.
[56] YAAGOUBI N, MOUFTAH H T. User-aware game theoretic approach for demand management[J]. IEEE Transactions on Smart Grid,2015,6(2):716-725.
[57] LU N, ZHANG Z. Design considerations of a centralized load controller using thermostatically controlled appliances for continuous regulation reserves[J]. IEEE Transactions on Smart Grid,2013,4(2):914-921.
[58] BORSCHE T, MARKOVIC U, ANDERSSON G. A new algorithm for primary frequency control with cooling appliances[J]. Computer Science-Research and Development,2016,31(1-2):89-95.
[59] ETO J H. Demand response spinning reserve demonstration[C]//Lawrence Berkeley National Laboratory,2007.
[60] CHASSIN D P, DONNELLY M K, DAGLE J E. Electrical power distribution control methods, electrical energy demand monitoring methods, and power management devices:United States, 7149605[P].2006-12-12.
[61] TINDEMANS S H, TROVATO V, STRBAC G. Decentralized Control of  Thermostatic Loads for Flexible Demand Response[J].IEEE Transactions on Control Systems Technology,2015,23(5):1685-1700.
[62] RIVERSO S, SARZO F, FERRARI-TRECATE G. Voltage and frequency control of islanded microgrids:A plug-and-play approach[C]//IEEE International Conference on Smart Grid Communications,2014:73-78.
[63] DOUGLASS P J, VALLE R G, NYENG P, et al. Demand asfrequency controlled reserve:implementation and practical demonstration[C]//IEEE PES International Conference and Exhibition on Innovative Smart Grid Technologies,2012:1-7.
[64] LOPEZ A, MONTANO J C, CASTILLA M, et al. Power system frequency measurement under nonstationary situations[J]. IEEE Transactions on Power Delivery,2008,23(2):562-567.
[65] SALCIC Z, NGUANG S K, WU Y Z. An improved taylor method for frequency measurement in power systems[J]. IEEE Transactions on Instrumentation and Measurement,2009,58(9):3288-3294.
[66] SONDHI S, HOTE Y V. Fractional order PID controller for load frequency control[J]. Energy Conversion and Management,2014,85(9):343-353.
[67] MAK S, RADFORD D. Communication system requirements for implementation of a large scale demand side management and distribution automation[J]. IEEE Transactions on Power Delivery,1996,11(2):683-689.
[68] DEHGHANPOUR K, AFSHARNIA S. Electrical demand side contribution to frequency control in power systems:A review on technical aspects[J]. Renewable and Sustainable Energy Reviews,2015,41:1267-1276.