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High Frequency Distortion in Power Grids due to Electronic Equipment Anders Larsson Luleå University of Technology. Outline of the presentation. Background and motivation of the work Waveform distortion Low-frequency distortion (harmonics) High-frequency distortion
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High Frequency Distortion in Power Grids due to Electronic Equipment Anders Larsson Luleå University of Technology
Outline of the presentation • Background and motivation of the work • Waveform distortion • Low-frequency distortion (harmonics) • High-frequency distortion • Results and analysing methods of measurements • Measurement on fluorescent tube power by a high frequency ballast • Measurement on multiple fluorescent lamps • Long term measurement at different locations • Conclusions
New technology has changed our lifestyle, we use more electronic product in our life than ever • Electronic equipment is often served by a regulated power supply • New technology has made it possible to build more energy efficient power supplies • Often are this type of power supplies nonlinear • This new technology has brought new distortions phenomena to the power grid • New measurement technology has made it easier and cheaper to measure
Some questions brought up in the beginning of the project • What types of signals can be found in this frequency range? • How do we observe these types of signals? • What happens when a large number of equipments are connected together? • How does these signals propagate in the LV net work? • Can these signals lead to a barrier to the introduction of other equipments such as PLC, home care equipments, alarms, audio equipments etc? • Can high frequency distortion lead to deterioration of other equipments?
How do we analyze waveform distortion? • If the current is not sinusoidal it contains other frequencies than the fundamental at 50 or 60 Hz • One way to analyze the signal is to use the Discreet Fourier Transform (DFT) to transfers the signal from the time- to the frequency-domain • There are two reasons to transform the signal; to quantify the waveform distortion and to determent the propagation of the signal
Harmonic content of the current drawn by the incandescent lamp
Almost all new electronic equipments has SMPS that uses switching technology in the frequency range from about 20 to 80 kHz • The product standards covering harmonic set limits up to about 2 or 3 kHz • Radio disturbances standards mainly sets limits from 150 kHz and up • High frequency distortion is in this case defined from 2 kHz up to about 1 MHz
Sources • Switch Mode Power Supplies • HF-ballasts • Active Power Factor Correction • Power Line Communications • Other loads containing power electronics e.g. converters, dimmers etc.
Spectrogram of the filtered voltage in the range between 2 and 150 kHz with 0.5 ms time resolution, 50% overlap and 1kHz frequency separation.
Some conclusion • The lamp adds extra high frequency components • The high frequency components are often synchronized with the fundamental frequency • One lamp generate high frequency notches which repeats synchronized with the power system frequency • Published papers describing “zero-crossing distortion” generated by the APFC circuit reminds of “high frequency notches” • High frequency notches increases with the number of lamps but the increase seems not to be linear. The STFT shows that these signals is found in the lower frequency range
The DFT gives some information about the content of high frequency distortion but the time-domain information is “lost” • The STFT seems like a suitable analysing method but in this case when many of the high frequency components are synchronized with the fundamental it is impossible to get an good frequency resolution in the lower frequency range • There are large deviations between different locations and quite surprisingly the highest amplitudes were found at the resident • There is an change of in amplitude of the high frequency distortion over time. Some frequencies seems to be attenuated by loads coming on while other frequencies is generated by the loads