Hoeffding's lemma: Difference between revisions

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In an [[Electrical grid|electric power transmission system]], a '''thyristor-controlled reactor''' (TCR) is a [[Magnetic reactance|reactance]] connected in series with a bidirectional [[thyristor]] valve. The thyristor valve is phase-controlled, which allows the value of delivered reactive power to be adjusted to meet varying system conditions. Thyristor-controlled reactors can be used for limiting voltage rises on lightly loaded transmission lines. Another device which used to be used for this purpose is a magnetically controlled reactor (MCR), a type of [[magnetic amplifier]] otherwise known as a [[transductor]].
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In parallel with series connected reactance and thyristor valve, there may also be a capacitor bank, which may be permanently connected or which may use mechanical or thyristor switching. The combination is called a [[static VAR compensator]].
 
==Circuit diagram==
 
 
A thyristor controlled reactor is usually a three-phase assembly, normally connnected in a delta arrangement to provide partial cancellation of [[Harmonic]]s. Often the main TCR reactor is split into two halves, with the thyristor valve connected between the two halves. This protects the vulnerable thyristor valve from damage due to flashovers, lightning strikes etc.
 
[[File:Thyristor Controlled Reactor circuit.png|400px|Typical three-phase, delta-connected TCR]]
 
==Operating principles==
 
 
The current in the TCR is varied from maximum (determined by the connection voltage and the inductance of the reactor) to almost zero by varying the "Firing Delay Angle", α. α is defined as the delay angle from the point at which the voltage becomes positive to the point at which the thyristor valve is turned on and current starts to flow.
 
[[File:Thyristor Controlled Reactor waveforms.png|thumb|Voltage and current waveforms in a TCR]]
 
Maximum current is obtained when α is 90°, at which point the TCR is said to be in "full conduction" and the rms current is given by:
 
<math>I_{tcr-max} = {V_{svc}\over{2 \pi f L_{tcr}}}</math>
 
Where:
 
V<sub>svc</sub> is the rms value of the line-to-line busbar voltage to which the SVC is connected
 
L<sub>tcr</sub> is the total TCR inductance per phase
 
The current lags 90° behind the voltage in accordance with classical AC circuit theory. As α increases above 90°, up to a maximum of 180°, the current decreases and becomes discontinuous and non-sinusoidal. The TCR current, as a function of time, is then given by:
 
<math>\omega t < {\pi -\alpha} : I(\omega t) = I_{tcr-max} \sqrt{2} [-cos(\alpha)-cos(\omega t)]</math>
 
<math>\alpha < \omega t < 2 \pi - \alpha : I(\omega t) = I_{tcr-max} \sqrt{2} [cos(\alpha)-cos(\omega t)]</math>
 
<math>{\omega t > {\pi + \alpha}} : I(\omega t) = I_{tcr-max} \sqrt{2} [-cos(\alpha)-cos(\omega t)]</math>
 
Otherwise, zero.
 
==Main equipment==
 
 
A TCR comprises two main items of equipment: the reactor itself, which is usually air-cored (although iron-cored reactors are possible) and the thyristor valve. Depending on the system voltage, an intermediate power [[transformer]] may be required to step up from the voltage handled by the thyristors to the transmission system voltage.
 
===Thyristor valve===
 
 
The thyristor valve typically consists of 5-20 inverse-parallel-connected pairs of [[Thyristor]]s connected in series. The inverse-parallel connection is needed because most connercially available thyristors can conduct current in only one direction. The series connection is needed because the maximum voltage rating of commercially available thyristors (up to approximately 8.5kV) is insufficient for the voltage at which the TCR is connected. For some low-voltage applications, it may be possible to avoid the series-connection of thyristors; in such cases the thyristor valve is simply an inverse-parallel connection of two thyristors.
 
[[File:Thyristor Controlled Reactor Valve.png|thumb|left|A TCR Thyristor Valve (one phase)]]
 
[[File:Thyristor Controlled Reactor valve waveforms.png|thumb|right|TCR Thyristor valve voltage and current waveforms]]
 
In addition to the thyristors themselves, each inverse-parallel pair of thyristors has a [[Resistor]] - [[Capacitor]] circuit connected across it, to force the voltage across the valve to divide uniformly amongst the thyristors and to damp the "commutation overshoot" which occurs when the valve turns off.
 
===Harmonics===
 
A TCR operating with α > 90° generates substantial amounts of harmonic currents, particularly at 3rd, 5th and 7th harmonics. By connecting the TCR in delta, the harmonic currents of order 3n ("Triplen harmonics") flow only around the delta and do not escape into the connected AC system. However, the 5th and 7th harmonics (and to a lesser extent 11th, 13th, 17th etc.) must be filtered in order to prevent excessive voltage distortion on the AC network. This is usually accomplished by connecting [[Harmonic Filters]] in parallel with the TCR. The filters provide capacitive reactive power which partly offsets the inductive reactive power provided by the TCR.
 
 
[[Category:Electric power]]
[[Category:Electric power systems components]]

Latest revision as of 12:01, 18 August 2014

My name: Reginald Bingaman
Age: 28
Country: Australia
Home town: Kamma
ZIP: 4865
Street: 64 Whitehaven Crescent

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