Abstract:
A high efficiency non-dissipative snubber circuit suitable for most power supplies used in international markets is disclosed. Circuit uses diode-capacitor-inductor structure to capture input voltage equivalent and reverse polarity on snubber capacitor. No external voltage source is required.

Description:
BACKGROUND OF THE INVENTION 
     This invention deals generally with power supplies, and more specifically with non-dissipative switching transistor snubbers. 
     A switching transistor snubber is circuitry added to a switchmode power supply which reshapes the transistor load line to reduce stresses on the switch transistor, and can also reduce electromagnetic interference (EMI) caused by the switchmode power supply. The switch transistor in a switchmode power supply is turning off into an inductive load which causes a transistor load line as shown in FIG. 1 for no snubber. If the load line is not reshaped by a snubber, circuit peak collector voltages are coincident with peak collector currents as shown in FIG. 2, resulting in maximum power dissipated in the switch transistor. 
     A dissipative resistor-capacitor (RC) snubber circuit in a single-ended flyback converter is shown in FIG. 3. While transistor Q 1  is on, capacitor C 1  is charged to a value of E in  through resistor R 1 . When transistor Q 1  is turned off, the current from transformer T 1 , which would pass through transistor Q 1  without a snubber, is diverted to capacitor C 1  and resistor R 1 . Power typically dissipated by rsistor R 1  is: 
     
         P=(f) (C.sub.1) (2E.sub.in).sup.2. 
    
     An offline converter using: C 1  =2000 pF, f=20 kHz, and E in  (max)=360 V, would find P=20.7 watts. 
     A dissipative diode-resistor-capacitor (DRC) snubber circuit for a single-ended flyback converter is shown in FIG. 4. The function of the ciruit is similar to the RC snubber circuit. However, the power consumption, although still high, is approximately halved by shunting resistor R 1  with a diode CR 1 . 
     A nondissipative diode-inductor-capacitor (DLC) snubber circuit disclosed in a paper titled &#34;DESIGNING NON-DISSIPATIVE CURRENT SNUBBERS FOR SWITCHED MODE CONVERTERS&#34; by Eugene C. Whitcomb at the Proceedings of the Sixth National Solid-State Power Conversion Conference in May 1979 is shown in FIG. 5. This snubber would probably work in a non-dissipative manner for 115 V AC power, but has drawbacks when operating with 230 V AC power. The voltage at the node between resistors R 1  and R 2  tends to be pulled down by the current drawn through diode CR 2 . Consequently, capacitor C 1  would have to be a high voltage capacitor, rated at approximately 300 Volts or more. This part is physically larger than most standard capacitors, and is less common and therefore more expensive. Common objectives in designing power supplies for international markets include efficiency of power and physical space and adaptability to international power standards (115/230 V). 
     SUMMARY OF THE INVENTION 
     In accordance with the illustrated preferred embodiment of the present invention, a practical and efficient non-dissipative switching transistor snubber circuit is realized by adding a diode to a prior art non-dissipative switching transistor snubber and using residual energy in a snubber capacitor resulting from diverting current from the switching transistor during turn-off. The purpose of the snubber circuit is to charge the capacitor to the input voltage, thus shielding the switching transistor from sudden rise times and peak power draws. This circuit takes advantage of the fact that the capacitor is charged to the value it needs at one point in the cycle, but that the polarity is wrong. The added diode holds the correct charge on the capacitor. By using one-half cycle of a resonant LC cycle polarity on the capacitor is reversed. Another diode stops the resonant LC cycle. Since no resistive elements reside in the circuit, the circuit ideally dissipates no power. The circuit works equally well with 115 V or 230 V AC power. This design obviates the need for high voltage capacitors, provides for fewer oscillations, and uses standard, smaller, and more efficent parts. 
    
    
     BRIEF DESCRIPTION OF THE FIGURES 
     FIG. 1 shows transistor load lines for power supplies having no snubber circuit, an RC snubber circuit and a DRC or DLC circuit. 
     FIG. 2 shows a graph of the collector current I c  vs. the collector voltage V ce  for a non-snubbed power supply circuit. 
     FIG. 3 shows an RC dissipative snubber circuit for a single-ended flyback converter. 
     FIG. 4 shows an DRC dissipative snubber circuit for a single-ended flyback converter. 
     FIG. 5 shows a prior art nondissipative DLC snubber circuit. 
     FIG. 6 shows the preferred embodiment of the present invention. 
     FIG. 7 shows an alternate embodiment of the present invention. 
     FIGS. 8A and 8B show timing diagrams for collector current I c  and collector voltage V ce  for the embodiments of the present invention shown in FIGS. 6 and 7. 
     FIG. 9 shows phase relationships for current and voltage in a resonant LC circuit 
     FIG. 10 shows the idealized voltage waveform of the collector for the alternate embodiment. 
     FIG. 11 shows the actual voltage waveform of the collector for the alternate embodiment. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     FIG. 6 shows the illustrated preferred embodiment of the present invention. The object of inductor L 1  is to place a charge on capacitor C 1  equal to or close to E in  with a polarity of plus to minus from top to bottom while transistor Q 1  is on. Then C 1  will divert the transformer primary current from transistor Q 1  through capacitor C 1  and diode CR 3  while transistor Q 1  is turning off to relieve the stress in transistor Q 1 , as shown in the load lines in FIG. 1. 
     Capacitor C 1  becomes charged to a voltage polarity of minus to plus from top to bottom through diodes CR 3  and CR 4  when the collector voltage of transistor Q 1  reaches its maximum value. The voltage across capacitor C 1  equals the reset voltage of the transformer T 1  primary plus a leakage inductance spike of transformer T 1 . This voltage can be and usually is greater than E in . Diode CR 4  prevents capacitor C 1  from discharging until transistor Q 1  turns back on. The voltage across capacitor C 1  is of sufficient value but of opposite polarity of what is desired. Therefore a resonant LC circuit made up of inductor L 1  and capacitor C 1  reverses the voltage polarity on capacitor C 1  during the on time of transistor Q 1 . Blocking diode CR 2  stops oscillation at the end of one-half cycle leaving a voltage charge on capacitor C 1  of plus to minus from top to bottom approximately equal to E in . Any excess current stored in inductor L 1  is dumped back into the source E in  through diode CR 3 . 
     The amount of time allowed to charge capacitor C 1  needs to be less than the on time of transistor Q 1  and is determined by: 
     
         Charge time=t=period/2=[2(pi)(L.sub.1 *C.sub.1).sup.(1/2) ]/2 
    
     
         t=(pi)(L.sub.1 *C.sub.1).sup.(1/2) 
    
     where L 1  and C 1  determine the resonant frequency. 
     The charging path is from ground through diode CR 2 , inductor L 1 , capacitor C 1 , and transistor Q 1  back to ground. In a lossless series resonant circuit (that is allowed to sustain oscillation) the total energy U in the circuit is equal to the energy U b  stored in the air gap (magnetic flux) of an inductor, plus the energy U e  stored in the electric field of a capacitor, or: 
     
         U =U.sub.b +U.sub.e =(1/2)L*i.sup.2 =(1/2)(q.sup.2)/C) 
    
     where i is the current in the inductor and q is the charge in the capacitor. 
     FIG. 9 shows the phase relationship between current and voltage in an ideal resonant LC circuit. All the energy U will be in the inductor twice during a cyle of oscillation when the current i is at a maximum and flowing in one direction and at a maximum and flowing in the other direction, at 90 degrees and 270 degrees. All the energy will be in the capacitor twice during a cycle, when the capacity is charged to opposite polarities, at 0 or 360 degrees and 180 degrees. 
     In the snubber circuit shown in FIG. 6, the voltage polarity across inductor L 1  of plus to minus from left to right occurs from 0 to 90 degrees. That polarity reverses from 90 to 180 degrees. Current is blocked at 180 degrees by diode CR 2  leaving all of the energy in capacitor C 1 . Diode CR 3  serves as a clamp to dump any excess energy back into the E in  voltage supply. Due to reverse recovery time in diode CR 2 , some current is put back into inductor L 1  and diode CR 1  is required to limit the reverse voltage seen by diode CR 2  as inductor L 1  oscillates with reverse biased diode CR 2  and other stray capacitances. The required voltage has been established on capacitor C 1  and the snubber circuit is prepared for transistor Q 1  to turn off. 
     An alternate embodiment of the invention is shown in FIG. 7. Here an auxillary winding provides additional voltage to charge capacitor C 1  to E in . During the time transformer T 1  is transfering energy to the secondary, V ce  on Q 1  drops down and diode CR 2  becomes slightly forward biased by the potential on capacitor C 1 . 
     In an ideal single-ended flyback converter with equal charging and discharging times for transformer T 1 , capacitor C 1   would be left with a charge equal to E in  even without the auxillary primary. The idealized waveform at the collector of transistor Q 1  is shown in FIG. 10. Just prior to turn-on, the energy has dumped from transformer T 1  and V ce  returned to a voltage equal to E in . The voltage across capacitor C 1  would be E in  with a polarity of minus to plus from top to bottom because it charges through diode CR 3  when the voltage on the collector of transistor Q 1  is at its peak value. When transistor Q 1  turns on, the resonant circuit formed by diode CR 2 , inductor L 1 , capacitor C 1  and transistor Q 1  would oscillate for one-half cycle (because diode CR 2  allows current in only one direction). All of the energy stored in capacitor C 1  would transfer to inductor L 1  and then back to capacitor C 1  leaving capacitor C 1  charged to E in  again but with a polarity of plus to minus from top to bottom. 
     In practice though, the voltage left on capacitor C 1  at turn-on is generally considerably less than E in  because the collector waveform does not look like FIG. 10. Since the DLC snubber does not dissipate a significent amount of power many different resonant circuits exist during a complete cycle of transistor Q 1 . Oscillations of these various circuits do not decay much during the time transformer T 1  is dumped because of the lack of resistance in the ciruit. The resonant circuit of transformer T 1  (primary), capacitor C 1 , inductor L 1 , and diode CR 1  is likely to be oscillating at turn-on and depending on where energy is stored at turn-on will determine the voltage capacitor C 1  can be charged to. Voltage drops caused by diode CR 2  and transistor Q 1  also represent lost energy due to Joule heating. See FIG. 11. 
     If at turn-on capacitor C 1  happened to have a voltage across it of (0.7)E in , then at turn-off transistor Q 1  would have to carry all of I T1 , the current from the transformer until diode CR 3  becomes forward biased. Transistor Q 1  would have to carry all of I T1  until V ce  =(0.3)E in . So to be able to charge capacitor C 1  to E in , another winding was put on the transformer (Aux pri) to make up the lost charge on capacitor C 1 . The turns ratio of PR 1  :Aux pri equal to 6.33:1 is a good comprimise of sufficient charge on capacitor C 1  and excess current that gets dumped through diode CR 3 . This ratio is not critical and a primary winding may already exist for other functions that can be used. The amount of voltage that is put on capacitor C 1  by Aux pri is: 
     
         V.sub.chg =2 (E.sub.aux) 
    
     in an ideal circuit. 
     In one example of this embodiment of the invention, inductor L 1  =680 uH and capacitor C 1  =2200 pF. Capacitor C 1  must be a high quality capacitor (low dissipation factor) to handle the high peak currents. Wima FKPI capacitors are a good choice. Inductor L 1  must also be of high quality. The voltage across inductor L 1  is (E in  +E aux ) so the winding must be controlled to prevent winding shorts. Inductor L 1  should be a gapped toroid or pot core to contain the magnetic field generated by inductor L 1 . Efficiency measured on this power supply was 88% where V out  =120 V, I out  =0.45 A, P out  =54 W.