IEEE Organizations related to Static Var Compensators (svc)

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Conferences related to Static Var Compensators (svc)

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2020 22nd European Conference on Power Electronics and Applications (EPE'20 ECCE Europe)

Energy conversion and conditioning technologies, power electronics, adjustable speed drives and their applications, power electronics for smarter grid, energy efficiency,technologies for sustainable energy systems, converters and power supplies


2020 IEEE International Conference on Industrial Technology (ICIT)

ICIT focuses on industrial and manufacturing applications of electronics, controls, communications, instrumentation, and computational intelligence.


2020 IEEE Power & Energy Society General Meeting (PESGM)

The Annual IEEE PES General Meeting will bring together over 2900 attendees for technical sessions, administrative sessions, super sessions, poster sessions, student programs, awards ceremonies, committee meetings, tutorials and more


2020 IEEE/PES Transmission and Distribution Conference and Exposition (T&D)

Bi-Annual IEEE PES T&D conference. Largest T&D conference in North America.


SoutheastCon 2020

SoutheastCon is the annual Region 3 conference that brings together engineering professionals, students, and volunteers for a weekend of technical presentations, meetings, student competitions, and volunteer education.

  • SoutheastCon 2021

    IEEE SoutheastCon is the annual IEEE Region 3 Student, Professional, and awards conference.

  • SoutheastCon 2019

    The annual IEEE SoutheastCon conferences promote all aspects of theories and applications of engineering disciplines. Sponsored by the IEEE Region-3 and IEEE Huntsville Section, this event will attract researchers, professionals, and students from the Southeastern region of the U.S. SoutheastCon 2019 will feature tutorial sessions, workshops, Technical Programs, and student Hardware, Software, Ethics, Paper, Web competitions.

  • SoutheastCon 2018

    SoutheastCon is a annual conference held in Region 3 and covers a Professional Track, Student Track and Regional Track.

  • SoutheastCon 2017

    Broad scope professional paper conference, region 3 annual meeting, region 3 annual student conference

  • SoutheastCon 2016

    Annual Region 3 Trifecta of Student competitions, Technical papers and volunteer training and administration.

  • SoutheastCon 2015

    Horizontal Technical Conference with all topics; students compete in multiple competions; Region 3 training meetings.

  • SOUTHEASTCON 2014

    Horizontal Technical Conference with all topics; students compete in multiple competions; Region 3 training meetings.

  • IEEE SOUTHEASTCON 2013

    Region 3 Meeting, Technical papers, student competitions.

  • SOUTHEASTCON 2012

    The annual IEEE SoutheastCon conferences promote all aspects of the theories and applications of the engineering disciplines. Sponsored by the IEEE Region 03, this event attracts researchers, professionals, and students from the Southeast region of the U.S and beyond. SoutheastCon 2012 will be held in Orlando, Florida.

  • SOUTHEASTCON 2011

    IEEE SoutheastCon2011 is the annual IEEE Region 3 technical, professional, and student conference, invites conference refereed and non-refereed technical paper presentations and tutorials that advance the work and careers of conference attendees in the areas of interest for the conference.

  • SOUTHEASTCON 2010

    SoutheastCon 2010 is the Region 3 event which includes a student conference, a technical conference, and the Region 3 business meeting.

  • SOUTHEASTCON 2009

    It is the annual IEEE Region 3 Technical, Professional, and Student Conference. As the premier conference for the IEEE Region 3, it brings together electrical, computer and other engineering and science professionals, faculty and students to share the latest information through technical sessions, tutorials and exhibits. The conference schedule includes: a technical program with seminars, tutorials, and workshops; exhibits; a student program with student competitions; and IEEE regional meetings.

  • SOUTHEASTCON 2008

    SoutheastCon is the Southeastern USA Region of the IEEE's premier conference. It contains three main sections: a technical program, student competitions and regional meetings. SouthEastCon features technical papers, tutorials and exhibits.

  • SOUTHEASTCON 2007

  • SOUTHEASTCON 2006

  • SOUTHEASTCON 2005

  • SOUTHEASTCON 2004

  • SOUTHEASTCON 2003

  • SOUTHEASTCON 2002

  • SOUTHEASTCON 2001

  • SOUTHEASTCON 2000

  • SOUTHEASTCON '99

  • SOUTHEASTCON '98

  • SOUTHEASTCON '97

  • SOUTHEASTCON '96


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Periodicals related to Static Var Compensators (svc)

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Most published Xplore authors for Static Var Compensators (svc)

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Xplore Articles related to Static Var Compensators (svc)

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IEEE Guide for Static Var Compensator Field Tests - Redline

IEEE Std 1303-2011 (Revision of IEEE Std 1303-1994) - Redline, 2011

General guidelines and criteria for the field testing of static var compensators (SVCs), before they are placed in-service, for the purpose of verifying their specified performance are described. The major elements of a commissioning program are identified so that the user can formulate a specific plan that is most suited for his or her own SVC.


Delta-connected static var compensator (SVC) based hybrid active power filter (SVC-HAPF) and its control method

IECON 2017 - 43rd Annual Conference of the IEEE Industrial Electronics Society, 2017

In this paper, a new structure and the coordinated control method of a delta connected static var compensator (SVC) based hybrid active power filter (SVC- HAPF) for reactive current, harmonic current and unbalanced current compensation are proposed. The proposed delta-connected SVC-HAPF has the desirable characteristics of wide compensation range with low voltage/current rating requirement in the active inverter part. Simulation ...


Optimal placement of static VAR compensator (SVC) in power system along with wind power generation

2017 IEEE International Conference on Electrical, Instrumentation and Communication Engineering (ICEICE), 2017

Power system is nothing but a power Generation, power Transmission and power Distribution. Most of the conventional energy sources generate the power at the hill areas or at the longer distances from electrical consumers, so that an electrical transmission and distribution system plays a vital role in power system. Since most of the electrical loads are inductive loads and transmission ...


Optimal allocation of Distributed Generation (DGs) and static VAR compensator (SVC) in a power system using Revamp Voltage Stability Indicator

2016 National Power Systems Conference (NPSC), 2016

The power system round the globe functions at highly loaded conditions resulting in poor voltage profile, voltage instability and high system losses. Electrical power increment and difficulties in providing required capacity provide a spur to appoint a Distributed Generation (DGs) and Static VAR Compensator (SVC) option. DGs and SVC integration ameliorate voltage profiles, system efficiency, Voltage stability and power quality ...


A combined operation of Superconducting Fault Current Limiter and Static Var Compensator for power system transient stability improvement

2014 International Electrical Engineering Congress (iEECON), 2014

This paper proposes a combined operation of Superconducting Fault Current Limiter (SFCL) and Static Var Compensator (SVC) for improving the transient stability performance of the interconnected power system. Presently, the SVC has been successfully applied to power system to suppress the voltage fluctuation and to increase the transient stability. Normally, when the fault occurs in the power system network, high ...


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Educational Resources on Static Var Compensators (svc)

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IEEE-USA E-Books

  • IEEE Guide for Static Var Compensator Field Tests - Redline

    General guidelines and criteria for the field testing of static var compensators (SVCs), before they are placed in-service, for the purpose of verifying their specified performance are described. The major elements of a commissioning program are identified so that the user can formulate a specific plan that is most suited for his or her own SVC.

  • Delta-connected static var compensator (SVC) based hybrid active power filter (SVC-HAPF) and its control method

    In this paper, a new structure and the coordinated control method of a delta connected static var compensator (SVC) based hybrid active power filter (SVC- HAPF) for reactive current, harmonic current and unbalanced current compensation are proposed. The proposed delta-connected SVC-HAPF has the desirable characteristics of wide compensation range with low voltage/current rating requirement in the active inverter part. Simulation results are provided to verify the effectiveness of the proposed structure and control method.

  • Optimal placement of static VAR compensator (SVC) in power system along with wind power generation

    Power system is nothing but a power Generation, power Transmission and power Distribution. Most of the conventional energy sources generate the power at the hill areas or at the longer distances from electrical consumers, so that an electrical transmission and distribution system plays a vital role in power system. Since most of the electrical loads are inductive loads and transmission and distribution lines itself not pure resistive lines, there is a reactive power requirement in the transmission and distribution systems. If transmission and distribution lines are not maintaining the required reactive power limits, then power losses increase and it also effect on the stability. There are different types of sources available for reactive power management in the power system are shunt capacitors, synchronous condensers and Static Var compensator (SVC). In this paper, optimal placement of SVC in transmission and distribution lines along with Distributed Generation sources (DGS) is analyzed based on better reactive support and stability limits in the lines.

  • Optimal allocation of Distributed Generation (DGs) and static VAR compensator (SVC) in a power system using Revamp Voltage Stability Indicator

    The power system round the globe functions at highly loaded conditions resulting in poor voltage profile, voltage instability and high system losses. Electrical power increment and difficulties in providing required capacity provide a spur to appoint a Distributed Generation (DGs) and Static VAR Compensator (SVC) option. DGs and SVC integration ameliorate voltage profiles, system efficiency, Voltage stability and power quality and to lower system losses, while neglecting consequential venture in transmission and distribution systems. The device does not work satisfactorily if it is placed in any random location in the system therefore It is necessary to determine the optimal location of the devices (DG and SVC), as the computational time requirement can be reduced by performance analysis of the device at weaker bus location. In the present work on an IEEE 14 bus system, the weak bus identification is determined by pioneering and ingenious approach called Revamp Voltage Stability Indicator (RVSI). The optimal allocation of the device has been done based on its performance assessment at different identified weak bus locations using 3 different indices Voltage Profile Improvement Index (VPII), Line Loss Reduction Index (LLRI) and Revamp Voltage Stability Indicator (RVSI). The Electrical Transient Analyzer Program (ETAP) software is being used for the load flow analysis of the IEEE 14 bus system.

  • A combined operation of Superconducting Fault Current Limiter and Static Var Compensator for power system transient stability improvement

    This paper proposes a combined operation of Superconducting Fault Current Limiter (SFCL) and Static Var Compensator (SVC) for improving the transient stability performance of the interconnected power system. Presently, the SVC has been successfully applied to power system to suppress the voltage fluctuation and to increase the transient stability. Normally, when the fault occurs in the power system network, high short-circuit currents might affect the transient stability performance of the power system. It might be insufficient for improving the effectiveness of transient stability by applying only the SVC. To overcome this issue, this paper applies the SFCL together with the SVC as a combined operation. The simulation results reveal that the combined SFCL and SVC can help limit the severity of short-circuit currents. Moreover, it can help improve the transient stability performance considerably, compared to the one with SVC only. In addition, it is found that a combined operation can reduce the size of SVC significantly, resulting to a lower investment cost.

  • Voltage Stability Enhancement of Bac Lieu Wind Power by ANFIS Controlled Static Var Compensator

    In this paper, a 99.2-MW grid-connected Bac Lieu wind farm using Doubly Fed Induction Generator (DFIG) is studied. For improving the voltage stability of the wind connected bus, a Static VAR Compensator (SVC) is proposed and an Adaptive Neuro Fuzzy Inference System (ANFIS) controller for SVC is also designed. Simulation results of the voltage response in time-domain are performed using MATLAB software to evaluate the effectiveness of the designed controller for SVC. From these results, it can be concluded that the proposed ANFIS controller can be applied to enhance the voltage stability of Bac Lieu power system.

  • Enhancing Voltage Stability of Thu Duc Transmission System Using Static Var Compensator

    This paper presents the comparative simulation results of using Static VAR Compensator (SVC) for enhancing the quality of voltage in normal operating conditions and fault conditions such as reducing oscillation and transience stability after three-phase short circuit fault happened. To improve the voltage stability of this studied Thu Duc transmission network in normal and fault operating conditions, an SVC device is proposed and installed at Intel bus for researching its effectiveness and the stability of the system. The presenting results are implemented by using Matlab software which is a powerful tool for simulating power transmission network. It can be concluded from simulation results of a case study based on the Thu Duc power system that SVC can gain the voltage profile, reduce amplitude and also improve transience time after the three-phase fault occurred. These parameters meet the grid code and qualifications of the studied system after severe hard operating conditions.

  • New static var compensator control strategy and coordination with under-load tap changer

    The static var compensator (SVC) has fast dynamic characteristics that can support effective system voltage following disturbances. Keeping reactive power reserve in an SVC during steady-state operation is always needed to provide reactive power requirements during system dynamics. This paper presents a new SVC control strategy with two stages of regulation slopes and two voltage regulation controls, which are fixed-voltage reference control and variable (floating) voltage reference control. The aim of this control is to limit the reactive power output from the SVC to the desired value during the steady-state voltage range and compensate the reactive power requirement from the upstream networks via the coordination with the under-load tap changer (ULTC). However, when the voltage deviates the steady-state voltage range, the SVC will react to support the system voltage using the SVC reactive power reserve. When a disturbance results in a new operating point, with a steady- state reactive-power output, the variable voltage reference control effectively changes the SVC output slowly and returns it within the steady- state margin.

  • Modeling and simulation of static var compensator to enhance the power system security

    Today's Power system is more complex and consequently it would lead to less security. To meet the demand and better security levels with existing transmission lines, the Flexible AC Transmission System (FACTS) devices are one of the alternates. In this paper a Newton Raphson(NR) algorithm was developed to find out the best operating point of a Static Var Compensator(SVC) for the enhancement of system security. The proposed algorithm minimizes the security index iteratively. Security index indicates the overload level of transmission lines. The proposed algorithm is verified by IEEE 5 bus system. Line power flows and bus voltages and bus angles are obtained by the Newton Raphson algorithm and the security index is calculated for both the cases with and without SVC. The results show that the voltage profile can be enhanced and the security margin increased by applying the proposed algorithm.

  • Design and implementation of laboratory scale static var compensator to demonstrate dynamic load balancing and power factor correction

    This paper presents the design and implementation of a lab scale FACTS device SVC (Static Var Compensation) for dynamical load balancing. The algorithm presented here is based on the Steinmetz method to balance a single phase load at the end of a 3-phase transmission line. The developed board connects to LabVolt bench equipment to complete the SVC system. The digital implementation of this compensator is done using a Texas Instruments microcontroller. The SVC is intended for demonstrating SVC operation and dynamic load balancing fundamentals to students.




Jobs related to Static Var Compensators (svc)

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