Skip to main content
Fachgebiete
Automobil + Motoren Bauwesen + Immobilien Business IT + Informatik Elektrotechnik + Elektronik Energie + Nachhaltigkeit Finance + Banking Management + Führung Marketing + Vertrieb Maschinenbau + Werkstoffe Versicherung + Risiko
DE
EN
Bücher
Zeitschriften
Themenseiten
Organisationspsychologie Projektmanagement Marketing Smart Manufacturing
Weitere Formate
Podcasts Webinare Technik Webinare Wirtschaft Kongresse Veranstaltungskalender Awards
Jetzt Einzelzugang starten
Zugang für Unternehmen
Referenzkunden
SLX-Digitalkonferenz: Zukunftswerkstatt 2024

Mehr Umsatz mit Top-Kontakten

Am 7. Mai erfahren Sie, wie Vertriebsteams Leadgenerierung, Leadnurturing und Leadstrategien effizient steuern können.
Erweiterte Suche
Anmelden
nach oben
Electrical Engineering
Erschienen in: Electrical Engineering 3/2018

06.10.2017 | Original Paper

Transient stability improvement: a review and comparison of conventional and renewable-based techniques for preventive and emergency control

verfasst von: Michael Pertl, Tilman Weckesser, Michel Rezkalla, Mattia Marinelli

Erschienen in: Electrical Engineering | Ausgabe 3/2018

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config
loading …

Abstract

This paper aims at reviewing and summarizing the vast variety of techniques to improve transient stability of power systems. A qualitative comparison of the techniques is presented and the future outlook is discussed. The techniques are categorized into conventional and renewable-based techniques. Conventional techniques are well established and have been employed in the past. Renewable techniques investigate how generators based on renewable energy sources (RES) can contribute to improving stability. Moreover, it is distinguished between techniques applying preventive and emergency controls. For preventive control, re-dispatch of generators and series compensation are extensively used in practice, whereas for emergency control, a great share of the techniques aim at voltage support during fault conditions. Regarding preventive control using RES-based generation, one approach which temporarily increases the voltage set point of the units in order to increase the synchronizing power, is reported. Regarding renewable energy source-based emergency control, low-voltage ride-through capability including voltage support is a well-established method. Nevertheless, it is also highlighted that high-voltage ride-through capability plays a critical role. The findings show that distributed generation must be included in existing control schemes for preventive control, and new improvement techniques taking full advantage of them need to be developed.
Vorheriger Artikel Hybrid fault diagnosis algorithms for transmission lines
Nächster Artikel The aspects of usage of four-layer windings in open-slot induction machines

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

  • über 102.000 Bücher
  • über 537 Zeitschriften

aus folgenden Fachgebieten:

  • Automobil + Motoren
  • Bauwesen + Immobilien
  • Business IT + Informatik
  • Elektrotechnik + Elektronik
  • Energie + Nachhaltigkeit
  • Finance + Banking
  • Management + Führung
  • Marketing + Vertrieb
  • Maschinenbau + Werkstoffe
  • Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

  • über 67.000 Bücher
  • über 390 Zeitschriften

aus folgenden Fachgebieten:

  • Automobil + Motoren
  • Bauwesen + Immobilien
  • Business IT + Informatik
  • Elektrotechnik + Elektronik
  • Energie + Nachhaltigkeit
  • Maschinenbau + Werkstoffe




 

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Wirtschaft"

Online-Abonnement

Mit Springer Professional "Wirtschaft" erhalten Sie Zugriff auf:

  • über 67.000 Bücher
  • über 340 Zeitschriften

aus folgenden Fachgebieten:

  • Bauwesen + Immobilien
  • Business IT + Informatik
  • Finance + Banking
  • Management + Führung
  • Marketing + Vertrieb
  • Versicherung + Risiko




Jetzt Wissensvorsprung sichern!

Jetzt informieren
Literatur
1.
Consulting KEMA (2014) Integration of renewable energy in Europe. Technical report, Imperial College London
2.
Miller NW, Shao M, Pajic S, D’Aquila R (2014) Western wind and solar integration study phase 3: frequency response and transient stability. Technical report, National Renewable Energy Laboratory (NREL), DenverCrossRef
3.
Kundur P, Paserba J, Ajjarapu V, Anderson G, Bose A, Canizares C, Hatziargyriou N, Hill D, Stankovic A, Taylor C, Van Vutsem T, Vittal V (2004) Definition and classification of power system stability. IEEE Trans Power Syst 21(3):1387–1401
4.
Adzic E, Porobic V, Dumnic B, Celanovic N, Katic V (2013) PLL synchronization in grid-connected converters. In: 6th PSU-UNS international conference on engineering and technology (ICET), Novi Sad, pp 1–5
5.
Bobrowska-Rafal M, Rafal K, Jasinski M, Kazmierkowski MP (2011) Grid synchronization and symmetrical components extraction with PLL algorithm for grid connected power electronic converters a review. Bull Pol Acad Sci 59(4):485–497
6.
Guo X-Q, Wu W-Y, Gu H-R (2011) Phase locked loop and synchronization methods for grid-interfaced converters: a review. Prz Elektrotech 87(4):182–187
7.
Atputharajah A, Saha TK (2009) Power system blackouts—literature review. In: International conference on industrial and information systems (ICIIS), Sri Lanka, pp 460–465
8.
Miller NW (2015) Transient stability in a world of wind and solar generation. IEEE Power and energy magazine, pp 31–39
9.
Naik PK, Nair N-KC, Swain AK (2016) Impact of reduced inertia on transient stability of networks with asynchronous generation. Int Trans Electr Energy Syst 26:175–191CrossRef
10.
Keller J, Kroposki B (2010) Understanding fault characteristics of inverter-based distributed energy resources. Technical report, National Renewable Energy Laboratory (NREL), DenverCrossRef
11.
Siddiqui SA, Verma K, Niazi KR, Fozdar M (2016) A unified control scheme for power system transient stability enhancement through preventive and emergency control. Int Trans Electr Energy Syst 26:365–383CrossRef
12.
Dahl OGC (1938) Electric circuits: theory and applications, 2nd edn. McGraw Hill, Madison
13.
Kundur P (1994) Power system stability and control. McGraw Hill, Madison
14.
Alam A, Makram EB (2006) Transient stability constrained optimal power flow. In: IEEE power and energy society general meeting, Montreal, pp 1–6
15.
Nguyen TT, Nguyen VL, Karimishad A (2011) Transient stability-constrained optimal power flow for online dispatch and nodal price evaluation in power systems with flexible AC transmission system devices. IET Gener Transm Distrib 5(3):332CrossRef
16.
Castronuovo ED, Ledesma P, Calle IA (2015) Advanced application of transient stability constrained-optimal power flow to a transmission system including an HVDC-LCC link. IET Gener Transm Distrib 9(13):1765–1772CrossRef
17.
Pertl M, Weckesser JTG, Rezkalla MN, Heussen K, Marinelli M (2017) A decision support tool for transient stability preventive control. Electr Power Syst Res 147:88–96CrossRef
18.
Wang Z, Song X, Xin H, Gan D, Wong KP (2013) Risk-based coordination of generation rescheduling and load shedding for transient stability enhancement. IEEE Trans Power Syst 28(4):4674–4682CrossRef
19.
Grünbaum R, Pernot J (2001) Thyristor-controlled series compensation: a state of the art approach for optimization of transmission over power links. Technical report, ABB
20.
Sen KK (1998) SSSC-static synchronous series compensator: theory, modelling, and applications. IEEE Trans Power Deliv 13(1):241–246CrossRef
21.
Mozina CJ (2011) Power system instability—what relay engineers need to know. In: 64th annual conference for protective relay engineers, College Station, pp 103–112
22.
Ramirez JM, Arroyave FV, Gutierrez REC (2011) Transient stability improvement by nonlinear controllers based on tracking. Int J Electr Power Energy Syst 33(2):315–321CrossRef
23.
Hossain J, Mahmud A, Roy NK, Pota HR (2013) Enhancement of transient stability limit and voltage regulation with dynamic loads using robust excitation control. Int J Emerg Electr Power Syst 14(6):561–570
24.
Mahmud MA, Pota HR, Aldeen M, Hossain MJ (2014) Partial feedback linearizing excitation controller for multimachine power systems to improve transient stability. IEEE Trans Power Syst 29(2):561–571CrossRef
25.
Saluja R, Ali MH (2013) Novel braking resistor models for transient stability enhancement in power grid system. In: IEEE PES innovative smart grid technologies conference (ISGT), Washington, DC, pp 1–6
26.
Saluja R, Ghosh S, Ali MH (2013) Transient stability enhancement of multi-machine power system by novel braking resistor models. IEEE Southeastcon. Jacksonville, FL, pp 1–6
27.
Ali MH, Murata T, Tamura J (2005) Augmentation of transient stability by fuzzy-logic controlled braking resistor in multi-machine power system. In: IEEE power tech, St. Petersburg, pp 1–7
28.
Park RH (1973) Fast turbine valving. IEEE Trans Power Appar Syst 92(3):1065–1073CrossRef
29.
Patel R, Bhatti TS, Kothari DP (2001) Improvement of power system transient stability using fast valving: a review. Electr Power Compon Syst 29(10):927–938CrossRef
30.
Patel R, Bhatti TS, Kothari DP (2003) Improvement of power system transient stability by coordinated operation of fast valving and braking resistor. IEE Proc Gener Transm Distrib 150(3):311–316CrossRef
31.
Ohura Y, Matsuzawa K, Ohtsuka H, Nagai N, Gouda T, Oshida H, Takeda S, Nishida S (1986) Development of a generator tripping system for transient stability augmentation based on the energy function method. IEEE Trans Power Deliv 1(3):68–77CrossRef
32.
Baydokhty ME, Eidiani M, Zeynal H, Torkamani H, Mortazavi H (2012) Efficient generator tripping approach with minimum generation curtailment based on fuzzy system rotor angle prediction. Prz Elektrotech 88(9):266–271
33.
Karady GG, Jun G (2002) A hybrid method for generator tripping. IEEE Trans Power Syst 17(4):1102–1107CrossRef
34.
Karady GG, Kattamesh MA (2002) Improving transient stability using generator tripping based on tracking rotor-angle. In: IEEE power engineering society winter meeting, pp 1113–1118
35.
O’Brien M, Ledwich G (1987) Static reactive-power compensator controls for improved system stability. IEE Proc C Gener Transm Distrib 134(1):38–42CrossRef
36.
Zhou X, Liang J (1999) Overview of control schemes for TCSC to enhance the stability of power systems. IEE Proc Gener Transm Distrib 146(2):125–130MathSciNetCrossRef
37.
Wagh S, Kamath AK, Singh NM (2009) Non-linear model predictive control for improving transient stability of power system using TCSC controller. In: 7th Asian control conference (ASCC), Hong Kong, pp 1627–1632
38.
Wagh SR, Kamath AK (2009) Singh NM (2009) A Nonlinear TCSC Controller based on control Lyapunov function and receding horizon strategy for power system transient stability improvement. IEEE international conference on control and automation 1–3:813–818
39.
Anh NT, Van Hertem D, Driesen J (2011) Effectiveness of TCSC controllers using remote input signals for transient stability enhancement. In: IEEE PowerTech, Trondheim, pp 1–8
40.
Zhang L, Zhang A, Jing J (2014) I&I stabilization based novel nonlinear adaptive TCSC control algorithm for improving transient stability. In: The 26th Chinese control and decision conference (2014 CCDC), Changsha, pp 1610–1615
41.
Dai X-Z, He D, Fan LL, Li N-H, Chen H (1999) Improved ANN \(\alpha \)th-order inverse TCSC controller for enhancing power system transient stability. IEE Proc Gener Transm Distrib 146(6):550–556CrossRef
42.
Sankara Prasad S (2012) Transient stability enhancement of multi-machine power system using fuzzy controlled TCSC. J Electr Electron Eng 1(6):1–7
43.
Kumkratug P (2011) Improving power system transient stability with static synchronous series compensator. Am J Appl Sci 8(1):77–81CrossRef
44.
Poshtan M, Singh BN, Rastgoufard P (2006) A nonlinear control method for SSSC to improve power system stability. In: International conference on power electronic, drives and energy systems (PEDES), pp 1–7
45.
Chandrakar VK, Kothari AG (2007) MFFN based static synchronous series compensator (SSSC) for transient stability improvement. In: International conference on intelligent systems applications to power systems (ISAP), Niigata, pp 5–8
46.
Panda S, Padhy NP (2007) A PSO-based SSSC controller for improvement of transient stability performance. Int J Electr Comput Energ Electron Commun Eng 1(9):1295–1302
47.
Chandrakar VK, Kothari AG (2004) Fuzzy logic based static synchronous series compensator (SSSC) for transient stability improvement. In: IEEE international conference on electric utility deregulation, restructuring and power technologies (DRPT), Hong Kong, pp 240–245
48.
Haque MH (2007) Application of UPFC to enhance transient stability limit. In: IEEE power engineering society general meeting, Tampa, pp 1–6
49.
Gholipour E, Saadate S (2005) Improving of transient stability of power systems using UPFC. IEEE Trans Power Deliv 20(2):1677–1682CrossRef
50.
Chu CC, Tsai HC (2008) Application of Lyapunov-based adaptive neural network UPFC damping controllers for transient stability enhancement. In: IEEE power and energy society general meeting—conversion and delivery of electrical energy in the 21st century, Pittsburgh, pp 1–6
51.
Mishra S (2006) Neural-network-based adaptive UPFC for improving transient stability performance of power system. IEEE Trans Neural Netw 17(2):461–470CrossRef
52.
Gupta A, Sharma PR (2013) Static and transient stability enhancement of power system by optimally placing UPFC (unified power flow controller). In: Third international conference on advanced computing and communication technologies, pp 121–125
53.
Ohura Y, Suzuki M, Yanagihashi K, Yamaura M, Omata K, Nakamura T, Watanabe H (1990) A predictive out-of-step protection system based on observation of the phase difference between substations. IEEE Trans Power Deliv 5(4):1695–1704CrossRef
54.
Wang C, Gao P, Zhu T, Shao W (2008) New method of searching for the out-of-step separation interface based on reactive power. In: IEEE PES transmission and distribution conference and exposition, Chicago, pp 1–5
55.
Adibi MM, Kafka RJ, Maram S, Mili LM (2006) On power system controlled separation. IEEE Trans Power Syst 21(4):1894–1902CrossRef
56.
McNabb P, Bialek J (2012) A priori transient stability indicator of islanded power systems using Extended Equal Area Criterion. In: IEEE power and energy society general meeting, San Diego, p 7
57.
Lin Z, Noms S, Shao H, Bialek J (2014) Transient stability assessment of controlled islanding based on power flow tracing. In: Power systems computation conference (PSCC), Wroclaw, p 7
58.
Quirós-Tortós J, Sánchez-García R, Brodzki J, Bialek J, Terzija V (2015) Constrained spectral clustering-based methodology for intentional controlled islanding of large-scale power systems. IET Gener Transm Distrib 9(1):31–42CrossRef
59.
Berglund RO, Mittelstadt WA, Shelton ML, Barkan P, Dewey CG, Skreiner KM (1974) One-cycle fault interruption at 500 kV: system benefits and breaker design. IEEE Trans Power Appar Syst 93(5):1240–1251CrossRef
60.
Schneider Electric (2001) Circuit breaker characteristic trip curves and coordination. Technical report, Schneider Electric, Cedar Rapids
61.
Siemens (2012) High-voltage circuit breakers. Technical report, Siemens
62.
ABB (2009) Power circuit breaker 245 kV, up to 63 kA. Technical report, ABB
63.
Khorashadi-Zadeh H, Li Z (2007) Transmission line single phase auto re-closing scheme based on wavelet transform and adaptive fuzzy neuro inference system. In: 39th North American power symposium (NAPS), Las Cruces, pp 43–48
64.
Takani H, Sonobe Y, Kagami T, Kawano F, Beaumont P, Baber GP, Main GT (2010) The application and advantages of multi-phase autoreclosing. In: 10th IET international conference on developments in power system protection (DPSP), Manchester, pp 1–5
65.
Li P, Zhang BH, Hao ZG, Rao YF, Wang YT, Bo ZQ, Klimek A (2008) Optimizing the re-closing time to improve the transmission capacity of power system. In: 43rd international universities power engineering conference (UPEC), Padova, pp 1–5
66.
Li P, Zhang BH, Hao ZG, Bo ZQ, Klimek A, Rao YF, Wang YT (2009) The study on optimizing re-closing time to improve the transmission capacity. In: IEEE/PES power systems conference and exposition (PSCE), Seattle, pp 1–6
67.
Goto Y, Yukita K, Yamada H, Ichiyanagi K, Matsumura T (2000) A study on power system transient stability due to introduction of superconducting fault current limiters. In: International conference on power system technology, Perth, pp 275–280
68.
Yokomizu GY, Yukita K, Mizuno K, Ichiyanagi K, Yokomizu Y, Matsumura T (2000) Experimental studies on power system transient stability due to introduction of superconducting fault current limiters. In: IEEE power engineering society winter meeting, Singapore, pp 1129–1134
69.
Tsuda M, Mitani Y, Tsuji K, Kakihana K (2001) Application of resistor based superconducting fault current limiter to enhancement of power system transient stability. IEEE Trans Appl Supercond 11(1):2122–2125CrossRef
70.
Yagami M, Shibata S, Murata T, Tamura J (2002) Improvement of power system transient stability by superconducting fault current limiter. In: IEEE/PES transmission and distribution conference and exhibition, Yokohama, pp 359–364
71.
Shirai Y, Furushiba K, Shouno Y, Shiotsu M, Nitta T (2008) Improvement of power system stability by use of superconducting fault current limiter with ZnO device and resistor in parallel. IEEE Transactions on Applied Superconductivity 18(2):680–683CrossRef
72.
Emhemed A, Tumilty RM, Singh N, Burt GM, McDonald JR (2010) Analysis of transient stability enhancement of LV-connected induction microgenerators by using resistive-type fault current limiters. IEEE Trans Power Syst 25(2):885–893CrossRef
73.
Hagh MT, Naderi SB, Jafari M (2010) Application of non-superconducting fault current limiter to improve transient stability. In: International conference on power and energy (PECon), Kuala Lumpur, pp 646–650
74.
Hagh MT, Jafari M, Naderi SB (2010) Transient stability improvement using non-superconducting fault current limiter. In: 1st power electronic and drive systems and technologies conference (PEDSTC), Tehran, pp 367–370
75.
Ashraf M, Sadi H, Ali MH (2015) transient stability enhancement of multi-machine power system by parallel resonance type fault current limiter. In: North American power symposium (NAPS), Charlotte, pp 1–6
76.
Hossain MK, Ali MH (2015) Transient stability augmentation of PV/DFIG/SG-based hybrid power system by nonlinear control-based variable resistive FCL. IEEE Trans Sustain Energy 6(4):1638–1649CrossRef
77.
Watch Technology (2009) Superconducting fault current limiters. Technical report, EPRI, Palo Alto
78.
Jovcic D, Ahmed K (2015) High-voltage direct-current transmission. Wiley, AberdeenCrossRef
79.
Phulpin Y, Hazra J, Ernst D (2011) Model predictive control of HVDC power flow to improve transient stability in power systems. In: IEEE international conference on smart grid communications (SmartGridComm), Brussels, pp 593–598
80.
Hazra J, Phulpin Y, Ernst D (2009) HVDC control strategies to improve transient stability in interconnected power systems. In: IEEE PowerTech, Bucharest, pp 1–6
81.
Eriksson R, Knazkins V, Söder L (2007) On the assessment of the impact of a conventional HVDC on a test power system. In: iREP symposium—bulk power system dynamics and control - VII, revitalizing operational reliability, Charleston, pp 1–5
82.
Renedo J, Garcia-Cerrada A, Rouco L (2016) Active power control strategies for transient stability enhancement of AC/DC Grids with VSC-HVDC multi-terminal systems. IEEE Trans Power Syst PP(99):1–10
83.
Eriksson R (2014) Coordinated control of multiterminal DC grid power injections for improved rotor-angle stability based on Lyapunov theory. IEEE Trans Power Deliv 29(4):1789–1797CrossRef
84.
Pertl M, Rezkalla M, Marinelli M (2016) A novel grid-wide transient stability assessment and visualization method for increasing situation awareness of control room operators. In: IEEE PES innovative smart grid technologies conference Asia (ISGT), Melbourne, pp 1–6
85.
Energinet (2010) Technical regulation 3.2.5 for wind power plants with a power output greater than 11 kW. Technical report, Energinet (TSO Denmark)
86.
Energinet (2015) Technical regulation 3.2.2 for PV power plants with a power output above 11 kW. Technical report, Energinet (TSO Denmark)
87.
ENTSO-E (2012) ENTSO-E network code for requirements for grid connection applicable to all generators. Technical report June, ENTSO-E
88.
ENTSO-E (2015) Draft-network code on requirements for grid connection applicable to all generators. Technical report, ENTSO-E, Brussels
89.
Energinet (2011) Technical regulation 3.2.1. for electricity generation facilities with a rated current of 16 A per phase or lower. Technical report, Energinet (TSO Denmark)
90.
der Netzbetreiber—VDN Verband (2007) TransmissionCode 2007—network and system rules of the German transmission system operators. Technical report August, Verband der Netzbetreiber—VDN e.V. beim VDEW
91.
Fichtner (2010) Grid codes for wind power integration in Spain and Germany: use of incentive payments to encourage grid-friendly wind power plants. Technical report, FICHTNER
92.
Meegahapola L, Flynn D (2010) Impact on transient and frequency stability for a power system at very high wind penetration. In: IEEE power and energy society general meeting, Minneapolis, pp 1–8
93.
Meegahapola LG, Littler T, Flynn D (2010) Decoupled-DFIG fault ride-through strategy for enhanced stability performance during grid faults. IEEE Trans Sustain Energy 1(3):152–162CrossRef
94.
Dong S, Li H, Wang Y (2012) Low voltage ride through capability enhancement of PMSG-based wind turbine. In: International conference on sustainable power generation and supply (SUPERGEN), Hangzhou, pp 1–5
95.
Molinas M, Vazquez S, Takaku T, Carrasco JM, Shimada R, Undeland T (2005) Improvement of transient stability margin in power systems with integrated wind generation using a STATCOM: an experimental verification. In: International conference on future power systems, Amsterdam, pp 1–6
96.
Arulampalam A, Barnes M, Jenkins N, Ekanayake JB (2006) Power quality and stability improvement of a wind farm using STATCOM supported with hybrid battery energy storage. IEE Proc Gener Trans Distrib 153(6):701–710CrossRef
97.
Molinas M, Suul JA, Undeland T (2006) Wind farms with increased transient stability margin provided by a STATCOM. In: Power electronics and motion control conference (IPEMC), Shanghai, pp 1–7
98.
Tian G, Wang S, Liu G (2010) Power quality and transient stability improvement of wind farm with fixed-speed induction generators using a STATCOM. In: International conference on power system technology (POWERCON), Hangzhou, pp 1–6
99.
Zhou H, Wei H, Qiu X, Xu J, Wei X, Wang S (2011) Improvement of transient voltage stability of the wind farm using SVC and TCSC. In: Asia-Pacific power and energy engineering conference (APPEEC), Wuhan, pp 1–4
100.
Hosseini H, Kalantar M (2012) Transient stability enhancement of power system including wind farms using improved ECS. In: 3rd IEEE international symposium on power electronics for distributed generation systems (PEDG), pp 782–787
101.
Amiri M, Sheikholeslami M (2014) Transient stability improvement of grid connected wind generator using SVC and STATCOM. In: International conference on innovative engineering technologies (ICIET), Bangkok, pp 136–140
102.
Sravanthi P, Rani K Radha, Amarnath J, Kamakshaiah S (2014) Critical clearing time and transient stability analysis of SCIG based wind farm with STATCOM. In: International conference on smart electric grid (ISEG), Guntur, pp 1–8
103.
Hemeida MG, Rezk H, Hamada MM (2017) A comprehensive comparison of STATCOM versus SVC-based fuzzy controller for stability improvement of wind farm connected to multi-machine power system. Electr Eng. doi:10.​1007/​s00202-017-0559-6
104.
Marinelli M, Massucco S, Mansoldo A, Norton M (2011) Analysis of inertial response and primary power-frequency control provision by doubly fed induction generator wind turbines in a small power system. In: 17th Power systems computation conference (PSCC), Stockholm, pp 1–7
105.
Arani MFM, El-Saadany EF (2013) Implementing virtual inertia in DFIG-based wind power generation. IEEE Trans Power Syst 28(2):1373–1384CrossRef
106.
Rakhshani E, Remon D, Cantarellas AM, Rodriguez P (2016) Analysis of derivative control based virtual inertia in multi-area high-voltage direct current interconnected power systems. IET Gener Transm Distrib 10(6):1458–1469CrossRef
107.
Wang Y, Meng J, Zhang X, Lie X (2015) Control of PMSG-based wind turbines for system inertial response and power oscillation damping. IEEE Trans Sustain Energy 6(2):565–574CrossRef
108.
Xu L, Wang G, Fu L, Wu Y, Shi Q (2015) General average model of D-PMSG and its application with virtual inertia control. In: IEEE International conference on mechatronics and automation (ICMA), Beijing, pp 802–807
109.
Wang X, Du W (2016) Virtual inertia control of grid-connected wind farms. In: International conference on renewable power generation (RPG), Beijing, pp 1–6
110.
Im W-S, Wang C, Liu W, Liu L, Kim J-M (2016) Distributed virtual inertia based control of multiple photovoltaic systems in autonomous microgrid. IEEE/CAA J Autom Sinica 1–9
111.
Waffenschmidt E (2016) Virtual inertia grid control with LED lamp driver. In: International energy and sustainability conference (IESC), Cologne, pp 1–6
112.
Waffenschmidt E, Hui RSY (2016) Virtual inertia with PV inverters using DC-link capacitors. In: 18th European conference on power electronics and applications (EPE’16 ECCE Europe), Karlsruhe, pp 1–10
113.
Wang X, Yue M, Muljadi E (2014) PV generation enhancement with a virtual inertia emulator to provide inertial response to the grid. In: IEEE energy conversion congress and exposition (ECCE), Pittsburgh, pp 17–23
114.
Rezkalla M, Zecchino A, Pertl M, Marinelli M (2016) Grid frequency support by single-phase electric vehicles employing an innovative virtual inertia controller. In: International universities power engineering conference (UPEC), Coimbra, pp 1–6
115.
Rezkalla M, Zecchino A, Martinenas S, Prostejovsky AM, Marinelli M (2017) Comparison between synthetic inertia and fast frequency containment control based on single phase EVs in a microgrid. Appl Energy. doi:10.​1016/​j.​apenergy.​2017.​06.​051
Metadaten
Titel
Transient stability improvement: a review and comparison of conventional and renewable-based techniques for preventive and emergency control
verfasst von
Michael Pertl
Tilman Weckesser
Michel Rezkalla
Mattia Marinelli
Publikationsdatum
06.10.2017
Verlag
Springer Berlin Heidelberg
Erschienen in
Electrical Engineering / Ausgabe 3/2018
Print ISSN: 0948-7921
Elektronische ISSN: 1432-0487
DOI
https://doi.org/10.1007/s00202-017-0648-6

Weitere Artikel der Ausgabe 3/2018

Electrical Engineering 3/2018 Zur Ausgabe

Original Paper

Analysis of faults in active distribution network with and without synchronous generator using instantaneous symmetrical components in time domain

Original Paper

Phase fault attenuation in SRM based on generalized predictive control and filter design

Original Paper

Optimization of the temperature profile of a high-powered strontium bromide laser

Original Paper

Improved teaching–learning-based optimization algorithm-based maximum power point trackers for photovoltaic system

Original Paper

Solving power transmission line routing problem using improved genetic and artificial bee colony algorithms

Original Paper

Behavior of nine levels NPC three-phase inverter topology interfacing photovoltaic system to the medium electric grid under variable irradiance

Neuer Inhalt

    Bildnachweise