Capacitor BankThe capacitor bank co

Capacitor Bank
The capacitor bank consists of capacitor units connected in series and parallel to obtain the required total Mvar ratings. The capacitor units consist of an all film design with a biodegradable impregnant. The capacitor units are equipped with internal discharge resistors to fulfill the discharge requirements according to applicable standards. Internally fused capacitor units are usually chosen in order to optimize the overall configuration.




Metal Oxide Varistor
The Metal Oxide Varistor (MOV) overvoltage protection is made from individual MOV blocks that are connected in series in order to achieve the desired protective level and in parallel in order to obtain the required energy absorption capability. The MOV blocks are assembled in stacks with high strength silicone rubber polymer housings or porcelain housings, according to specification.


Damping Circuit
The purpose of the current limiting damping circuit is to limit and damp the discharge current caused by spark gap operation or closing the bypass switch. The current limiting damping circuit normally consists of an air core reactor. In case high damping of the discharge current is required, a damping resistor is connected across the reactor.


By-Pass Switch
The ABB bypass switch is an Auto-Puffer type SF6 circuit breaker. With a closing time less than half of that of other bypass switches, it is the fastest bypass switch available on the market for EHV Series Capacitor applications. This enables a great saving on MOV in the protective scheme.

Each pole is equipped with an operating mechanism to obtain sufficient stored energy without recharging in order to meet the duty cycle (O)-C-O-C.


Choosing the optimum scheme
Optimization with regard to the environment in which the series capacitor is called upon to operate is key to the scheme selected.

In a fault situation of a severity which calls for temporary by-passing the series capacitor, the FPD enables by-pass of the varistor a hundred times faster than a by-pass switch. This means that typically, the FPD scheme requires less varistor capacity in a certain operating environment of the series capacitor. The plain ZnO scheme, which relies solely on the by-pass switch for bypassing the varistor in a fault situation, will typically require a larger varistor size to make up for the slower bypass. This, however, may still be attractive if the series capacitor operates in a network where fault currents are never severe, and the required varistor rating is correspondingly limited.

The scheme which represents the highest benefit for the customer at the lowest cost will be chosen for each individual situation. This deliberation is a basic ingredient in series capacitor design.

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CapThorTM
CapThor is a novel protective device for Series Capacitors, replacing conventional forced triggered spark gaps in varous combinations with MOVs.

CapThor is a switch consisting of two high voltage modules. The modules comprise one Arc Plasma Injector (API) and one Fast Contact (FC) respectively, enclosed in composite insulator housings. The two modules are connected in parallel and are very compact when compared with conventional spark gaps. The two high voltage modules are hermetically enclosed and filled with synthetic air at an over-pressure. The function of CapThor is independent of environmental conditions and designed for high series capacitor protection levels and fault currents.

CapThor does not need any electrode adjustments for project specific capacitor voltages or fault currents. It does not suffer from the conventional spark gap dilemma - electrodes having to be close enough for secure operation, but separated enough not to unintentionally spark over – as it does not require a high electrical field between the electrodes to operate.











Control and protection system: MACH 2

To meet the requirements for control and protection both today and into the future, ABB has developed a fully computerized modular control and protection system. The highly integrated concept, called MACH 2, is based on ABB’s extensive engineering expertise to further improve the performance and efficiency of power systems.

MACH 2 is specifically designed for FACTS applications and uses industry standard computers, microcontrollers and digital signal processors connected by high performance buses and fiber optic communication links.

Modular construction
The control and protection system supervises all functions of the series capacitor and provides protective action in the event of faults such as capacitor overload or unbalance, flashover to platform or ZnO varistor overload.

The system is duplicated to form a fully redundant protection concept.

The MACH 2 system has a modular building block concept, based on high performance standard computers, referred to as the Main Computer. A typical Main Computer is a motherboard of PC architecture with multi-processing features. Add-in boards are available for future expansion and connection to the distributed I/O. The boards are equipped with digital signal processors (DSPs), for signal processing and fast calculation.

Station control and monitoring
The Station Control and Monitoring system including Human Machine Interface for visualization of the station, supervsory control and data acquisition, is based on one or several standard Windows NT Operator Workstations (OWS). The main OWS software is the InTouch application, specifically designed for operator control.




MACH 2 features and benefits:
– High computing capacity
– Remote control
– Remote interrogation
– Minimum maintenance
– Shorter delivery times
– Easy upgrading

Main functions of the OWS:
The Operator Work Station handles the communication between the user and the control system of the series capactor. It provides: – Full graphic status displays of the series capacitor
– Display and control of protective settings
– Display of alarms and sequence of events lists
– Transient fault recordings (TFR)




Platform to ground communication
As the series capacitor operates in series with the line, it must have full system level insulation to ground. For transmission voltages in excess of 145 kV, this is usually solved by mounting the series capacitor on fully insulated steel platforms, one platform for each phase.

For communication between platforms and ground, fiber optic transmission links are utilized. The system employs optical current transducers for current measurements on the platforms. The measured signals are brought to the control room via optical fibers where all protection and control functions are performed.


Major benefits of system
– No control or protection equipment located on platform.
– No auxiliary power sources needed on the platforms.
– No multiplexing of measured quantities.


Optical current transformers
Current measurements are performed by means of Optical Current Transformers consisting of a Current Transducer in the high voltage busbar and an Optical Interface Board in the control room. Signal transmission between the transducer and interface is via an optical fiber system including high voltage links and fiber optic cables.

Each Optical Interface Board handles six separate current channels. It includes laser diodes to power the transducers and detector circuits to receive and decode light pulses from the transducers.

















Thyristor Controlled Series Compensation
Controllable series capacitors can optimize their degree of compensation over a wide range under various network conditions. This is done partly or fully by means of thyristor control. Thyristor controlled series capacitors (TCSC) can be employed in a range of circumstances to improve power transmission performance.


By adjusting the degree of compensation to the network operating conditions, the level of firm power delivered through a specific line can be controlled. Power flow can also be distributed through several parallel lines to secure transfer capability in the event of an outage in part of the system, or to achieve the lowest possible transmission losses.

In networks connected by weak links, TCSC can be used to damp active power oscillations caused by disturbances to the system.

Where Sub-Synchronous Resonance (SSR) is an issue, TCSC offers an effective means of mitigation.

As an example, a nuclear power station in central Sweden is connected to the north of the country via a number of 400 kV lines of varying length; all series compensated for increased power transmission capability.

One of the generator units is subject to the risk of SSR in conjunction with certain fault situations in the power grid. To counteract this, an existing series capacitor was rebuilt as a thyristor controlled series capacitor. This has eliminated the SSR risk for all possible system operating conditions and thereby increases the availability of active power over the system.