DC_DC_Buck_PPT.ppt
- 1. 1 DC−DC Buck Converter: Operation & Designing Dr. Akbar Ahmad Director & Professor School of Mechatronics Engineering Symbiosis Skills & Professional University, Kiwale Pune
- 2. 2 Objective – to efficiently reduce DC voltage DC−DC Buck Converter + Vin − + Vout − Iout Iin Lossless objective: Pin = Pout, which means that VinIin = VoutIout and The DC equivalent of an AC transformer out in in out I I V V !
- 3. 3 Here is an example of an inefficient DC−DC converter 2 1 2 R R R V V in out + Vin − + Vout − R1 R2 in out V V R R R 2 1 2 If Vin = 39V, and Vout = 13V, efficiency η is only 0.33 The load Unacceptable except in very low power applications
- 4. 4 Another method – lossless conversion of 39Vdc to average 13Vdc If the duty cycle D of the switch is 0.33, then the average voltage to the expensive car stereo is 39 ● 0.33 = 13Vdc. This is lossless conversion, but is it acceptable? Rstereo + 39Vdc – Switch state, Stereo voltage Closed, 39Vdc Open, 0Vdc Switch open Stereo voltage 39 0 Switch closed DT T !
- 5. 5 Convert 39Vdc to 13Vdc, cont. Try adding a large C in parallel with the load to control ripple. But if the C has 13Vdc, then when the switch closes, the source current spikes to a huge value and burns out the switch. Rstereo + 39Vdc – C Try adding an L to prevent the huge current spike. But now, if the L has current when the switch attempts to open, the inductor’s current momentum and resulting Ldi/dt burns out the switch. By adding a “free wheeling” diode, the switch can open and the inductor current can continue to flow. With high- frequency switching, the load voltage ripple can be reduced to a small value. Rstereo + 39Vdc – C L Rstereo + 39Vdc – C L A DC-DC Buck Converter lossless Taken from “Course Overview” PPT
- 6. 6 C’s and L’s operating in periodic steady-state Examine the current passing through a capacitor that is operating in periodic steady state. The governing equation is dt t dv C t i ) ( ) ( which leads to t o t o t o dt t i C t v t v ) ( 1 ) ( ) ( Since the capacitor is in periodic steady state, then the voltage at time to is the same as the voltage one period T later, so ), ( ) ( o o t v T t v The conclusion is that T o t o t o o dt t i C t v T t v ) ( 1 0 ) ( ) ( or 0 ) ( T o t o t dt t i the average current through a capacitor operating in periodic steady state is zero which means that Taken from “Waveforms and Definitions” PPT !
- 7. 7 Now, an inductor Examine the voltage across an inductor that is operating in periodic steady state. The governing equation is dt t di L t v ) ( ) ( which leads to t o t o t o dt t v L t i t i ) ( 1 ) ( ) ( Since the inductor is in periodic steady state, then the voltage at time to is the same as the voltage one period T later, so ), ( ) ( o o t i T t i The conclusion is that T o t o t o o dt t v L t i T t i ) ( 1 0 ) ( ) ( or 0 ) ( T o t o t dt t v the average voltage across an inductor operating in periodic steady state is zero which means that Taken from “Waveforms and Definitions” PPT !
- 8. 8 KVL and KCL in periodic steady-state , 0 ) ( loop Around t v , 0 ) ( node of Out t i 0 ) ( ) ( ) ( ) ( 3 2 1 t v t v t v t v N Since KVL and KCL apply at any instance, then they must also be valid in averages. Consider KVL, 0 ) ( ) ( ) ( ) ( 3 2 1 t i t i t i t i N 0 ) 0 ( 1 ) ( 1 ) ( 1 ) ( 1 ) ( 1 3 2 1 dt T dt t v T dt t v T dt t v T dt t v T T o t o t T o t o t N T o t o t T o t o t T o t o t 0 3 2 1 Navg avg avg avg V V V V The same reasoning applies to KCL 0 3 2 1 Navg avg avg avg I I I I KVL applies in the average sense KCL applies in the average sense Taken from “Waveforms and Definitions” PPT !
- 9. 9 Capacitors and Inductors In capacitors: dt t dv C t i ) ( ) ( Capacitors tend to keep the voltage constant (voltage “inertia”). An ideal capacitor with infinite capacitance acts as a constant voltage source. Thus, a capacitor cannot be connected in parallel with a voltage source or a switch (otherwise KVL would be violated, i.e. there will be a short-circuit) The voltage cannot change instantaneously In inductors: Inductors tend to keep the current constant (current “inertia”). An ideal inductor with infinite inductance acts as a constant current source. Thus, an inductor cannot be connected in series with a current source or a switch (otherwise KCL would be violated) The current cannot change instantaneously dt t di L t v ) ( ) ( !
- 10. 10 Vin + Vout – iL L C iC Iout iin Buck converter + vL – Vin + Vout – L C Iout iin + 0 V – What do we learn from inductor voltage and capacitor current in the average sense? Iout 0 A • Assume large C so that Vout has very low ripple • Since Vout has very low ripple, then assume Iout has very low ripple !
- 11. 11 The input/output equation for DC-DC converters usually comes by examining inductor voltages Vin + Vout – L C Iout iin + (Vin – Vout) – iL (iL – Iout) Reverse biased, thus the diode is open , dt di L v L L L V V dt di out in L , dt di L V V L out in , out in L V V v for DT seconds Note – if the switch stays closed, then Vout = Vin Switch closed for DT seconds
- 12. 12 Vin + Vout – L C Iout – Vout + iL (iL – Iout) Switch open for (1 − D)T seconds iL continues to flow, thus the diode is closed. This is the assumption of “continuous conduction” in the inductor which is the normal operating condition. , dt di L v L L L V dt di out L , dt di L V L out , out L V v for (1−D)T seconds
- 13. 13 Since the average voltage across L is zero 0 1 out out in Lavg V D V V D V out out out in V D V V D DV in out DV V From power balance, out out in in I V I V D I I in out , so The input/output equation becomes Note – even though iin is not constant (i.e., iin has harmonics), the input power is still simply Vin • Iin because Vin has no harmonics !
- 14. 14 Examine the inductor current Switch closed, Switch open, L V V dt di V V v out in L out in L , L V dt di V v out L out L , sec / A L V V out in DT (1 − D)T T Imax Imin Iavg = Iout From geometry, Iavg = Iout is halfway between Imax and Imin sec / A L Vout ΔI iL Periodic – finishes a period where it started
- 15. 15 Effect of raising and lowering Iout while holding Vin, Vout, f, and L constant iL ΔI ΔI Raise Iout ΔI Lower Iout • ΔI is unchanged • Lowering Iout (and, therefore, Pout ) moves the circuit toward discontinuous operation
- 16. 16 Effect of raising and lowering f while holding Vin, Vout, Iout, and L constant iL Raise f Lower f • Slopes of iL are unchanged • Lowering f increases ΔI and moves the circuit toward discontinuous operation
- 17. 17 iL Effect of raising and lowering L while holding Vin, Vout, Iout and f constant Raise L Lower L • Lowering L increases ΔI and moves the circuit toward discontinuous operation
- 18. 18 RMS of common periodic waveforms, cont. T T T rms t T V dt t T V dt t T V T V 0 3 3 2 0 2 3 2 0 2 2 3 1 T V 0 3 V Vrms Sawtooth Taken from “Waveforms and Definitions” PPT !
- 19. 19 RMS of common periodic waveforms, cont. Using the power concept, it is easy to reason that the following waveforms would all produce the same average power to a resistor, and thus their rms values are identical and equal to the previous example V 0 V 0 V 0 0 -V V 0 3 V Vrms V 0 V 0 Taken from “Waveforms and Definitions” PPT !
- 20. 20 RMS of common periodic waveforms, cont. Now, consider a useful example, based upon a waveform that is often seen in DC-DC converter currents. Decompose the waveform into its ripple, plus its minimum value. min max I I 0 ) (t i the ripple + 0 min I the minimum value ) (t i max I min I = 2 min max I I Iavg avg I Taken from “Waveforms and Definitions” PPT !
- 21. 21 RMS of common periodic waveforms, cont. 2 min 2 ) ( I t i Avg Irms 2 min min 2 2 ) ( 2 ) ( I I t i t i Avg Irms 2 min min 2 2 ) ( 2 ) ( I t i Avg I t i Avg Irms 2 min min max min 2 min max 2 2 2 3 I I I I I I Irms 2 min min 2 2 3 I I I I I PP PP rms min max I I IPP Define Taken from “Waveforms and Definitions” PPT
- 22. 22 RMS of common periodic waveforms, cont. 2 min PP avg I I I 2 2 2 2 2 3 PP avg PP PP avg PP rms I I I I I I I 4 2 3 2 2 2 2 2 PP PP avg avg PP PP avg PP rms I I I I I I I I I 2 2 2 2 4 3 avg PP PP rms I I I I Recognize that 12 2 2 2 PP avg rms I I I avg I ) (t i min max I I IPP 2 min max I I Iavg Taken from “Waveforms and Definitions” PPT
- 23. 23 Inductor current rating 2 2 2 2 2 12 1 12 1 I I I I I out pp avg Lrms 2 2 2 2 3 4 2 12 1 out out out Lrms I I I I Max impact of ΔI on the rms current occurs at the boundary of continuous/discontinuous conduction, where ΔI =2Iout out Lrms I I 3 2 2Iout 0 Iavg = Iout ΔI iL Use max
- 24. 24 Capacitor current and current rating 2 2 2 2 2 3 1 0 2 12 1 out out avg Crms I I I I iL L C Iout (iL – Iout) Iout −Iout 0 ΔI Max rms current occurs at the boundary of continuous/discontinuous conduction, where ΔI =2Iout 3 out Crms I I Use max iC = (iL – Iout) Note – raising f or L, which lowers ΔI, reduces the capacitor current
- 25. 25 MOSFET and diode currents and current ratings iL L C Iout (iL – Iout) out rms I I 3 2 Use max 2Iout 0 Iout iin 2Iout 0 Iout Take worst case D for each
- 26. 26 Worst-case load ripple voltage Cf I C I T C I T C Q V out out out 4 4 2 2 1 Iout −Iout 0 T/2 C charging iC = (iL – Iout) During the charging period, the C voltage moves from the min to the max. The area of the triangle shown above gives the peak-to-peak ripple voltage. Raising f or L reduces the load voltage ripple !
- 27. 27 Vin + Vout – iL L C iC Iout Vin + Vout – iL L C iC Iout iin Voltage ratings Diode sees Vin MOSFET sees Vin C sees Vout • Diode and MOSFET, use 2Vin • Capacitor, use 1.5Vout Switch Closed Switch Open
- 28. 28 There is a 3rd state – discontinuous Vin + Vout – L C Iout • Occurs for light loads, or low operating frequencies, where the inductor current eventually hits zero during the switch- open state • The diode opens to prevent backward current flow • The small capacitances of the MOSFET and diode, acting in parallel with each other as a net parasitic capacitance, interact with L to produce an oscillation • The output C is in series with the net parasitic capacitance, but C is so large that it can be ignored in the oscillation phenomenon Iout MOSFET DIODE !
- 29. 29 Inductor voltage showing oscillation during discontinuous current operation 650kHz. With L = 100µH, this corresponds to net parasitic C = 0.6nF vL = (Vin – Vout) vL = –Vout Switch open Switch closed
- 30. 30 Onset of the discontinuous state sec / A L Vout f L D V T D L V I onset out onset out out 1 1 2 2Iout 0 Iavg = Iout iL (1 − D)T f I V L out out 2 guarantees continuous conduction use max use min f I D V L out out onset 2 1 Then, considering the worst case (i.e., D → 0), !
- 31. 31 Impedance matching out out load I V R equiv R DC−DC Buck Converter + Vin − + Vout = DVin − Iout = Iin / D Iin + Vin − Iin 2 2 D R D I V D I D V I V R load out out out out in in equiv Equivalent from source perspective Source So, the buck converter makes the load resistance look larger to the source !
- 32. 32 Example of drawing maximum power from solar panel PV Station 13, Bright Sun, Dec. 6, 2002 0 1 2 3 4 5 6 0 5 10 15 20 25 30 35 40 45 V(panel) - volts I - amps Isc Voc Pmax is approx. 130W (occurs at 29V, 4.5A) 44 . 6 5 . 4 29 A V Rload For max power from panels at this solar intensity level, attach I-V characteristic of 6.44Ω resistor But as the sun conditions change, the “max power resistance” must also change
- 33. 33 Connect a 2Ω resistor directly, extract only 55W PV Station 13, Bright Sun, Dec. 6, 2002 0 1 2 3 4 5 6 0 5 10 15 20 25 30 35 40 45 V(panel) - volts I - amps 130W 55W 56 . 0 44 . 6 2 , 2 equiv load load equiv R R D D R R To draw maximum power (130W), connect a buck converter between the panel and the load resistor, and use D to modify the equivalent load resistance seen by the source so that maximum power is transferred !
- 34. 34 Vpanel + Vout – iL L C iC Iout ipanel Buck converter for solar applications + vL – Put a capacitor here to provide the ripple current required by the opening and closing of the MOSFET The panel needs a ripple-free current to stay on the max power point. Wiring inductance reacts to the current switching with large voltage spikes. In that way, the panel current can be ripple free and the voltage spikes can be controlled We use a 10µF, 50V, 10A high-frequency bipolar (unpolarized) capacitor
- 35. 35 Worst-Case Component Ratings Comparisons for DC-DC Converters Converter Type Input Inductor Current (Arms) Output Capacitor Voltage Output Capacitor Current (Arms) Diode and MOSFET Voltage Diode and MOSFET Current (Arms) Buck out I 3 2 1.5 out V out I 3 1 2 in V out I 3 2 10A 10A 10A 40V 40V Likely worst-case buck situation 5.66A 200V, 250V 16A, 20A Our components 9A 250V Our M (MOSFET). 250V, 20A Our L. 100µH, 9A Our C. 1500µF, 250V, 5.66A p-p Our D (Diode). 200V, 16A BUCK DESIGN
- 36. 36 Comparisons of Output Capacitor Ripple Voltage Converter Type Volts (peak-to-peak) Buck Cf Iout 4 10A 1500µF 50kHz 0.033V BUCK DESIGN Our M (MOSFET). 250V, 20A Our L. 100µH, 9A Our C. 1500µF, 250V, 5.66A p-p Our D (Diode). 200V, 16A
- 37. 37 Minimum Inductance Values Needed to Guarantee Continuous Current Converter Type For Continuous Current in the Input Inductor For Continuous Current in L2 Buck f I V L out out 2 – 40V 2A 50kHz 200µH BUCK DESIGN Our M (MOSFET). 250V, 20A Our L. 100µH, 9A Our C. 1500µF, 250V, 5.66A p-p Our D (Diode). 200V, 16A