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Power Factor Correction by Overtone Removal

Power Factor Correction by Overtone Removal. Robert S. Wrathall January 15, 2013. Essence of the Invention. Works in the frequency domain rather than time domain. Power Factor Correction by Closed Loop removal of harmonic frequency overtones

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Power Factor Correction by Overtone Removal

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  1. Power Factor Correction by Overtone Removal Robert S. Wrathall January 15, 2013

  2. Essence of the Invention • Works in the frequency domain rather than time domain. • Power Factor Correction by Closed Loop removal of harmonic frequency overtones • Sensing the harmonic content of the current wave form and removing it by closed loop feedback methods • Near perfect PFC over all conditions Robert S. Wrathall

  3. Advantages Works at constant frequency in PWM mode Works at same max current as CCM mode Higher switching frequency Inductor size reduced by approximately 20x in value. Inductor size limited by DCM requirement at switching frequency, voltages and load current. Robert S. Wrathall

  4. Advantages • The inductor is one of the more costly elements • Higher frequency operation minimizes inductance • This technique is particularly adapted to digital power control • Does not require high speed current sense • Can be adaptable to buck-boost configuration Robert S. Wrathall

  5. Basic Circuit • The basic circuit is a boost converter operating on the rectified AC voltage • The boost converter is operated in the discontinuous mode, • the current in the inductor goes to zero each cycle Robert S. Wrathall

  6. Simplified Typical Block diagram of basic AC to DC circuit Robert S. Wrathall

  7. Basic operation • The input diode bridge converts the AC supply to a rectified DC supply. • The amplifier operates to control the pulse width of the boost converter to control the output voltage with a constant pulse width • The “outer loop” with the amplifier is a generally slow loop Robert S. Wrathall

  8. Basic operation • The PWM circuit shown has some minimal power factor correction features • If a second loop, the PFC loop, is added, this allows the PWM circuit to do power factor correction • PFC is a lower order correction to the main “outer” loop as shown in the simplified PFC circuit Robert S. Wrathall

  9. Simplified Typical Block diagram of basic PFC circuit Correction Robert S. Wrathall

  10. Demonstration • A numerical simulation shows the operation of the power factor correction circuit. • A condition is chosen which accentuates the ability of this technique for power factor correction. • The condition is the input voltage is close to the output voltage and the inductor is as large as possiblewith no PFC • Duty factor is ratio Ton / Ttotal Robert S. Wrathall

  11. Vin 240v rms Vout 400v Iload 5 amp Power 2kw L1 20uH D 0.115 PwrFctr .662 No correction Discontinuous to continuous transition This plot shows the operation of the uncorrected basic circuit. Under these conditions there is a transition to continuous mode. Robert S. Wrathall

  12. Observations • These conditions were chosen to be extreme. • This condition forces the inductor into the continuous conduction mode (CCM) • The Power Factor is low, near 60%. Robert S. Wrathall

  13. Removal of 2nd Harmonic The correction circuit operates by the detection of discrete harmonics of the fundamental The amplitude of the harmonic is amplified and multiplied by its respective sine wave and subtracted from the PWM duty factor to make a new, corrected current wave form. Robert S. Wrathall

  14. Optimization by removal of only the 2nd Harmonic Vin 240v rms Vout 400v Iload 5 amp Power 2kw L1 20uH Dnom 0.202 PwrFctr .987 Robert S. Wrathall

  15. 2nd Harmonic Correction Correcting for just the lowest harmonic produces a power factor of 98% The harmonic content can be seen in the duty factor wave form The continuous current mode operation has been removed by shifting current to the lower voltage portions of the input wave. Robert S. Wrathall

  16. 7 Harmonic correction The simulation has capability of removing up to 7 harmonics. This would not normally be necessary in a real appliction. There is a small coupling between the several harmonics through the operation of the outer loop For full removal, the operation needs to be iterated several times This slide show the result of 3 iterations Robert S. Wrathall

  17. Vin 240v rms Vout 400v Iload 5 amp Power 2kw L1 20uH PwrFctr 0.999 Three times through the algorithm optimizing 7 harmonics each time Robert S. Wrathall

  18. Discussion • 1 harmonic removal seems good, 7 is excellent, maybe overkill • The number of harmonics removed determines the bandwidth of the current sense and the speed of the analog to digital conversion • Typically the BW will be less than 3 kHz and the current sense sample frequency 6 kHz Robert S. Wrathall

  19. Basic PFC Correction Circuit Robert S. Wrathall

  20. harmonic removal The algorithm is based on the idea that the uncorrected circuit does a modest job at power factor correction. It also depends on the idea that the removal of a harmonic using the uncorrected circuit is nearly independent of all other harmonics. Robert S. Wrathall

  21. Algorithm First block is a low pass filter to filter out the switching noise Second block is an ADC Third is a Fourier transform Fourth rejects the fundamental and selects either individual or all the harmonics of the fundamental Robert S. Wrathall

  22. Algorithm Fifth is a gain block with a soft start. This gain block can be located anywhere on the chain Sixth is the inverse transform Seventh is a resampling block. The original transform may only require a 6kHz sampling but the switching frequency might be 200kHz. The resampling matches these. Robert S. Wrathall

  23. Algorithm Finally there is an DAC to convert to an analog signal. If the outer loop is a digital loop this signal may remain in digital form to modify the outer loop response. The outer loop must be slow Robert S. Wrathall

  24. Software requirements Fourier transform occurs once each 8.333ms Transform only requires 30 data points for 7 odd overtones conversion every 8.33ms Resampling requires 833 points for a 100kHz switching frequency. 8 time points result from the inverse transform. These must be padded by 104 points each. Robert S. Wrathall

  25. Sample rate • Sample rate 0.277 ms • Fourier transform is simplified • Only real sine terms are needed • Only odd terms, N=3,5…, are needed • Of 32 points of sampled data only 8 points are required from the FFT in the frequency domain • Likewise in the inverse only 8 or less terms are used. Robert S. Wrathall

  26. Light Load Operation The duty factor must be kept above a minimum on-time of the PWM circuit for smooth operation. As the duty factor drops, cycle skipping may be implemented to keep the duty factor reasonable. As some point too many cycles will be skipped and the inner loop will no longer be adaptive. The last measured values may be used as shown in other patents Robert S. Wrathall

  27. Summation This technique eliminates fast current sense This technique does a nearly perfect power factor correction over all operating conditions Requires a minimal amount of computation overhead Fixed frequency operation for noise considerations Robert S. Wrathall

  28. Summation Not dependent on component or switching frequency considerations In particular, allows for a much smaller inductor Works as well as or better than critical conduction mode techniques Robert S. Wrathall

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