Harmonic pollution is a growing problem in Europe and one that
designers of power continuity programmes and manufacturers of UPS
(uninterruptible power supplies) cannot ignore. Typical harmonic
problems include the distortion of mains power supply voltage,
overheating of wiring, neutral conductors, supply transformers and
switchgear and nuisance tripping of breakers. Harmonics can also cause
disruption to equipment on the same supply and lead to random failures.
Harmonics are caused by voltage or current waveforms with frequencies that are multiples of the fundamental frequency - in Europe, 50Hz (50 cycles per second). The multiples are always ordered in a specific sequence: for example, the 2nd harmonic is 100Hz (2x50Hz), the third 150Hz and the fourth 200Hz and so on.
The particular problem of Triplens (third order) harmonics. Harmonics are a particular issue for power continuity management due to the large number of switch mode power supply (SMPS) loads being connected to modern electrical distribution networks - and their associated UPS systems. These are the most common form of power supply unit (PSU) in use today. As a non-linear load, they draw their power in regular modulated pulses of current from a mains power supply rather than as a continuous linear supply. This can lead to SMPSs generating high levels of harmonics, especially when many are being supplied from a single three-phase mains power supply.
In particular, system designers must be aware of the potentially damaging Triple-Ns (or Triplens) whose harmonic order numbers are multiples of three and include the notorious third-harmonics as well as ninths and fifteenths. Thirds are probably the most challenging harmonic in terms of neutral conductor loading within a three-phase system. Whereas other harmonics cancel each other out, third-harmonics are in phase with each other and exhibit a summing effect which greatly increases the current - potentially overloading conductors and switchgear.
Harmonics and total power factor - implications for UPS sizing. Harmonics are also closely related to power factor management - and another key aspect of uninterruptible power supply system design and implementation. The displacement power factor is only applicable to the fundamental frequency (50Hz in Europe) and therefore does not take into account the power factor generated by any harmonics induced into the mains power supply by the load itself (referred to as the distortion power factor and produced by the harmonics produced by non-linear loads). The combination of the displacement power factor and the distortion power factor gives what is known to UPS systems experts as the true power factor. When correctly sizing a UPS, an understanding of this is critical.
Mitigation of total harmonics distortion. Harmonics issues need to be addressed at the design stage of any power continuity plan. Not least, because consumers are responsible for the harmonic levels introduced into their three-phase mains power supply.
A UPS can sometimes be fitted with a harmonic filter (post installation) but this can be a costly and inelegant solution as extensive internal wiring changes may be required. For a transformer-based UPS, using a 12-pulse rectifier in place of a 6-pulse set will reduce the levels of THDi (total harmonic distortion). Coupling this with a passive filter will provide further reduction to around 4%.
For a transformerless uninterruptible power supplies, THDi levels of less than 4% can be achieved by installing an active harmonic filter. However, levels as low as 3% can now be achieved by some designs whose rectifiers are IGBT (Insulated Gate Bipolar Transistor) based. This can remove the need for an additional active harmonic filter and simplify the UPS design process. Such designs are expected to become the norm: not only do they reduce initial costs, but they allow a smaller UPS system footprint whilst increasing input power factors.
Active harmonic filters reduce the impact of leading power factors. When designing a power continuity plan and UPS system, various methods can be applied to reduce the impact of leading power factors (where the current waveform leads the voltage waveform): ensuring that leading power factors represent a smaller percentage of the UPS load, installing power factor correction between the UPS and the load, increasing UPS size (and that of any standby generation capacity) and specifying a UPS with leading power factor capabilities.
Harmonics are caused by voltage or current waveforms with frequencies that are multiples of the fundamental frequency - in Europe, 50Hz (50 cycles per second). The multiples are always ordered in a specific sequence: for example, the 2nd harmonic is 100Hz (2x50Hz), the third 150Hz and the fourth 200Hz and so on.
The particular problem of Triplens (third order) harmonics. Harmonics are a particular issue for power continuity management due to the large number of switch mode power supply (SMPS) loads being connected to modern electrical distribution networks - and their associated UPS systems. These are the most common form of power supply unit (PSU) in use today. As a non-linear load, they draw their power in regular modulated pulses of current from a mains power supply rather than as a continuous linear supply. This can lead to SMPSs generating high levels of harmonics, especially when many are being supplied from a single three-phase mains power supply.
In particular, system designers must be aware of the potentially damaging Triple-Ns (or Triplens) whose harmonic order numbers are multiples of three and include the notorious third-harmonics as well as ninths and fifteenths. Thirds are probably the most challenging harmonic in terms of neutral conductor loading within a three-phase system. Whereas other harmonics cancel each other out, third-harmonics are in phase with each other and exhibit a summing effect which greatly increases the current - potentially overloading conductors and switchgear.
Harmonics and total power factor - implications for UPS sizing. Harmonics are also closely related to power factor management - and another key aspect of uninterruptible power supply system design and implementation. The displacement power factor is only applicable to the fundamental frequency (50Hz in Europe) and therefore does not take into account the power factor generated by any harmonics induced into the mains power supply by the load itself (referred to as the distortion power factor and produced by the harmonics produced by non-linear loads). The combination of the displacement power factor and the distortion power factor gives what is known to UPS systems experts as the true power factor. When correctly sizing a UPS, an understanding of this is critical.
Mitigation of total harmonics distortion. Harmonics issues need to be addressed at the design stage of any power continuity plan. Not least, because consumers are responsible for the harmonic levels introduced into their three-phase mains power supply.
A UPS can sometimes be fitted with a harmonic filter (post installation) but this can be a costly and inelegant solution as extensive internal wiring changes may be required. For a transformer-based UPS, using a 12-pulse rectifier in place of a 6-pulse set will reduce the levels of THDi (total harmonic distortion). Coupling this with a passive filter will provide further reduction to around 4%.
For a transformerless uninterruptible power supplies, THDi levels of less than 4% can be achieved by installing an active harmonic filter. However, levels as low as 3% can now be achieved by some designs whose rectifiers are IGBT (Insulated Gate Bipolar Transistor) based. This can remove the need for an additional active harmonic filter and simplify the UPS design process. Such designs are expected to become the norm: not only do they reduce initial costs, but they allow a smaller UPS system footprint whilst increasing input power factors.
Active harmonic filters reduce the impact of leading power factors. When designing a power continuity plan and UPS system, various methods can be applied to reduce the impact of leading power factors (where the current waveform leads the voltage waveform): ensuring that leading power factors represent a smaller percentage of the UPS load, installing power factor correction between the UPS and the load, increasing UPS size (and that of any standby generation capacity) and specifying a UPS with leading power factor capabilities.
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Regards,
Sonera Jhaveri
http://www.sonerajhaveri.com