Power System Solutions | 250 Hogan Lane | Conway, AR 72034

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Merus Static VAR Compensators (SVC)

Merus Static VAR Compensator (SVC), another part of the Merus FACTS family, is built on proven thyristor technology. The state-of-the-art Merus thyristor valve is extremely compact in design and delivers superior performance compared with other solutions available in the market.

Fast, reactive power compensation with Merus SVC ensures effective flicker mitigation and voltage variation control in steel plants with electric arc furnaces (EAFs), in mining plants with mine winders, excavators, crushers and grinders or to enhance transmission capacity and achieve unity power factor in utilities. Merus SVC provides tailored solutions to meet customer requirements from 3.3KV up to 38.5kV 250MVAr. Power System Solutions can deliver a complete turnkey SVC solution.

Functions and customer benefits

Key functions

  • Voltage variation control

  • Flicker mitigation

  • Dynamic reactive power control

  • Power factor improvement

  • Harmonic current mitigation

  • Load balancing

Customer benefits

  • Increased productivity of steel plants by reducing melt-time

  • Increased torque and payload of large inductive loads with stabilized voltage

  • Transmission and distribution network capacity enhancement

  • Longer plant lifetime

  • Reduced maintenance costs

  • Improved plant reliability

Applications

Merus Static VAR Compensator (SVC) can be flexibly used in reactive power compensation and passive harmonic filtering applications. Merus SVC can be connected to voltage levels from 3.3 kV all the way up to 38.5 kV. The reactive power compensation range varies from 4 MVAr to 250 MVAr. Application areas include:

  • Steel industry (electric arc furnaces, rolling mills)

  • Mining (mine winders, excavators, conveyors)

  • Shredders, crushers and cranes

  • Voltage control in utilities

 

 

Product features

Innovative design and reliability

At the heart of SVC is Merus thyristor valve, used in TCRs and TSCs for dynamic control of reactive power. Merus thyristor valve was developed to meet the highest requirements for compactness, performance and reliability in harsh industrial environments. Thanks to the state-of-the-art composite construction, the valve is compact enough to be installed even into a standard sea freight container, enabling relocatable SVC designs.

Redundant and modular design

The SVC system can be built for all medium voltage levels starting from 3.3 kV all the way up to 38.5 kV. Power output ranges from 4 MVAr to 250 MVAr. The devices can be connected in parallel for a higher total output and added redundancy. Each SVC system is tailor-made to fit the network fault level and load parameters.

Efficiency with proven control algorithms

Open- and closed-loop control strategies permit effective flicker mitigation, reactive power control, power factor control and harmonic mitigation. The thyristor valves in the SVC are equipped with Merus Control & Protection System that utilizes proven control algorithms.

 
Control and monitoring

SVC can be monitored and controlled remotely or at on-site workstations with the advanced and easy user interface with a 19” touch screen. Fiber optic communications enable long-distance signal transfer.

 
How Merus SVC works

Voltage can be controlled by controlling the reactive power flowing in the system. The reactive power can be consumed with inductive reactance (reactors) and produced with capacitive reactance (capacitors). SVC can be understood as adjustable impedance that provides reactive power proportionally to the system supply voltage. SVC impedance can be modified by combining adequate amounts of inductive and capacitive reactance. Inductance is provided by thyristor controlled reactors (TCR) using Merus thyristor valves, while the capacitive part consists of fixed capacitor banks.

When the inductive part is operating at maximum current, the SVC’s output reactive power is zero or inductive, drawing the voltage of the connection point down. When inductive part current is zero, the SVC system, with its maximum capacitive power, pulls the voltage of the connection point up.  The capacitor banks also work as passive harmonic filters, fine-tuned to reduce harmonics generated by the thyristors of TCR and by the loads. With the line-commutated thyristors the reaction time of SVC is typically half a network cycle.