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Dynamic voltage restoration

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Dynamic voltage restoration (DVR) is a method of overcoming voltage sags and swells that occur in electrical power distribution.[1][2][3] These are a problem because spikes consume power and sags reduce efficiency of some devices. DVR saves energy through voltage injections that can affect the phase and wave-shape of the power being supplied.[3]

Devices used for DVR include static var devices, which are series compensation devices that use voltage source converters (VSC). The first such system in North America was installed in 1996 - a 12.47 kV system located in Anderson, South Carolina.

Operation

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The basic principle of dynamic voltage restoration is to inject a voltage of the magnitude and frequency necessary to restore the load side voltage to the desired amplitude and waveform, even when the source voltage is unbalanced or distorted. Generally, devices for dynamic voltage restoration employ gate turn off thyristors, (GTO) solid state power electronic switches in a pulse-width modulated (PWM) inverter structure. The DVR can generate or absorb independently controllable real and reactive power at the load side. In other words, the DVR is a solid state DC to AC switching power converter that injects a set of three-phase AC output voltages in series and synchronicity with the distribution and transmission line voltages.

The source of the injected voltage is the commutation process for reactive power demand and an energy source for the real power demand. The energy source may vary according to the design and manufacturer of the DVR, but DC capacitors and batteries drawn from the line through a rectifier are frequently used. The energy source is typically connected to the DVR through its DC input terminal.

The amplitude and phase angle of the injected voltages are variable, thereby allowing control of the real and reactive power exchange between the dynamic voltage restorer and the distribution system. As the reactive power exchange between the DVR and the distribution system is internally generated by the DVR without the AC passive reactive components.[4]

Similar devices

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DVRs use a technically similar approach as low voltage ride-through (LVRT) capability systems in wind turbine generators use. The dynamic response characteristics, particularly for line supplied DVRs, are similar to those in LVRT-mitigated turbines. Conduction losses in both kinds of devices are often minimized by using integrated gate-commutated thyristor (IGCT) technology in the inverters.[5][6]

Applications

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Practically, DVR systems can to inject up to 50% of nominal voltage, but only for a short time (up to 0.1 seconds). However, most voltage sags are much less than 50 percent, so this is not typically an issue.

DVRs can also mitigate the damaging effects of voltage swells, voltage unbalance and other waveform distortions.[7]

Drawbacks

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DVRs may provide good solutions for end-users subject to unwanted power quality disturbances. However, they are generally not used in systems that are subject to prolonged reactive power deficiencies (resulting in low voltage conditions) and in systems that are vulnerable to voltage collapse. Because DVRs will maintain appropriate supply voltage, in such systems where incipient voltage conditions are present they actually make collapses more difficult to prevent and can even lead to cascading interruptions.

Therefore, when applying DVRs, it is vital to consider the nature of the load whose voltage supply is being secured, as well as the transmission system which must tolerate the change in voltage-response of the load. It may be necessary to provide local fast reactive supply sources in order to protect the system, including the DVR, from voltage collapse and cascading interruptions.

SSSC and DVR

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The SSSC’s counterpart is the Dynamic Voltage Regulator (DVR). Although both are utilized for series voltage sag compensation, their operating principles differ from each other.[8] The static synchronous series compensator injects a balance voltage in series with the transmission line. On the other hand, the DVR compensates the unbalance in supply voltage of different phases. Also, DVRs are usually installed on a critical feeder supplying the active power through DC energy storage and the required reactive power is generated internally without any means of DC storage.

See also

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References

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  1. ^ Liasi, Sahand Ghaseminejad; Afshar, Zakaria; Harandi, Mahdi Jafari; Kojori, Shokrollah Shokri (2018-12-18). "An Improved Control Strategy for DVR in order to Achieve both LVRT and HVRT in DFIG Wind Turbine". 2018 International Conference and Exposition on Electrical and Power Engineering (EPE). pp. 0724–0730. doi:10.1109/ICEPE.2018.8559605. ISBN 978-1-5386-5062-2. S2CID 54449702.
  2. ^ Li, Peng; Liasi, Sahand Ghaseminejad (2017-12-15). "A New Voltage Compensation Philosophy for Dynamic Voltage Restorer to Mitigate Voltage Sags Using Three-Phase Voltage Ellipse Parameters (A review presentation) (PDF Download Available)". ResearchGate. doi:10.13140/RG.2.2.16427.13606. Retrieved 2018-01-07.
  3. ^ a b Choi SS, Li HH, Vilathgamuwa DM (2000). "Dynamic voltage restoration with minimum energy injection". IEEE Transactions on Power Systems. 15 (1): 51–57. Bibcode:2000ITPSy..15...51C. doi:10.1109/59.852100.
  4. ^ Ghosh, A. & Ledwich, G. (2002). Power quality enhancement using custom power devices (1st ed., pp. 7-8). Boston: Kluwer Academic Publishers.
  5. ^ Jowder, F.A.L. (2009-12-12). "Modeling and simulation of different system topologies for dynamic voltage restorer using Simulink". ResearchGate. pp. 1–6. Retrieved 2017-12-15.
  6. ^ Strzelecki, R.; Benysek, G. (2017-11-07). "Control strategies and comparison of the Dynamic Voltage Restorer". 2008 Power Quality and Supply Reliability Conference. pp. 79–82. doi:10.1109/PQ.2008.4653741. ISBN 978-1-4244-2500-6. S2CID 21079433.
  7. ^ Ital, Akanksha V.; Borakhade, Sumit A. (2017-11-07). "Compensation of voltage sags and swells by using Dynamic Voltage Restorer (DVR)". 2016 International Conference on Electrical, Electronics, and Optimization Techniques (ICEEOT). pp. 1515–1519. doi:10.1109/ICEEOT.2016.7754936. ISBN 978-1-4673-9939-5. S2CID 7937327.
  8. ^ Karthigeyan, P.; Raja, M. Senthil; Uma, P. S. (2017-11-07). "Comparison of dynamic voltage restorer and static synchronous series compensator for a wind turbine fed FSIG under asymmetric faults". Second International Conference on Current Trends in Engineering and Technology - ICCTET 2014. pp. 88–91. doi:10.1109/ICCTET.2014.6966268. ISBN 978-1-4799-7987-5. S2CID 32288193.
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