Calculating electrical harmonics in a power system involves analyzing the waveforms of the electrical signals and determining the presence and characteristics of harmonics. Harmonics are integer multiples of the fundamental frequency of the power system (typically 50 or 60 Hz, depending on the region).
Here's a general outline of the process:
Signal Measurement: The first step is to measure the voltage and current waveforms at different points in the power system using appropriate instruments like oscilloscopes, power analyzers, or data loggers. These measurements are usually taken over a specific period of time.
Data Preprocessing: The acquired data may need some preprocessing to remove noise, DC offsets, or any other undesirable artifacts that could interfere with the harmonic analysis.
Frequency Domain Analysis: The next step is to perform a frequency domain analysis, typically by using a mathematical tool called the Fast Fourier Transform (FFT). The FFT converts the time-domain signals into their frequency-domain representation. It helps to identify the different frequency components present in the waveform.
Harmonic Identification: By analyzing the frequency spectrum obtained from the FFT, you can identify the different harmonic components. The first peak corresponds to the fundamental frequency (e.g., 50 Hz or 60 Hz), and the subsequent peaks at integer multiples of the fundamental frequency are the harmonics (2nd harmonic, 3rd harmonic, 4th harmonic, and so on).
Harmonic Magnitude and Phase: For each harmonic component, you can determine its magnitude (amplitude) and phase angle with respect to the fundamental frequency.
Total Harmonic Distortion (THD) Calculation: THD is a measure of the distortion caused by harmonics in the power system. It is calculated by dividing the root sum of the squares of the harmonic magnitudes by the magnitude of the fundamental frequency.
THD (%) = (Square root of (H2^2 + H3^2 + H4^2 + ... + Hn^2) / H1) * 100
Where H1 is the magnitude of the fundamental frequency, and H2, H3, H4, etc., are the magnitudes of the individual harmonics.
Power System Impact: Once the harmonics are identified, their impact on the power system can be assessed. Excessive harmonics can cause issues like overheating of equipment, increased power losses, interference with communication systems, and reduced power factor.
Harmonic Mitigation: If harmful harmonics are detected, various techniques can be employed to mitigate them. These may include using harmonic filters, employing power factor correction equipment, or implementing harmonic-tolerant equipment.
It's important to note that harmonic analysis can be complex, especially in large and complex power systems. Specialized software and expertise in power system analysis are often employed for accurate and detailed harmonic studies.