Abstract:
When a main switching transistor of a zero voltage switching power supply is conductive, a voltage is developed in a current sensing resistor coupled in series with the transistor. The voltage in the current sensing resistor is coupled to a first input of a comparator of the control circuit. A second input of the comparator is coupled to a capacitor that develops a voltage that varies in accordance with an output voltage of the power supply. During a given conduction interval of the transistor, the comparator is triggered in accordance with the difference between the current sensing resistor voltage and the capacitor voltage. An output of the comparator is coupled to the base of the transistor for controlling the turn off instant of the transistor on a current pulse-by-current pulse basis. Under overload condition, when the transistor is turned off, a reverse collector current flows through the base-collector junction of the transistor. The reverse collector current produces a voltage in the current sensing resistor that is at opposite polarity with respect to the voltage there, during forward conduction of the transistor. The voltage produced by the sensed reverse current turns on a diode switch and charges the capacitor that is coupled to the comparator of the control circuit in a manner to reduce the peak forward collector current. Thereby, the peak forward current in the transistor decreases relative to a value that would have occurred without the protection.

Description:
The invention relates to a protection circuit of a power supply. 
     BACKGROUND 
     A power supply operating in the Zero Voltage Switching (ZVS) and forward modes described in U.S. Pat. No. 5,877,946 issued Mar. 2, 1999, entitled A FORWARD CONVERTER WITH AN INDUCTOR COUPLED TO A TRANSFORMER WINDING, in the name of W. V. Fitzgerald (the Fitzgerald patent), includes a main switching transistor coupled to a primary winding of a main power transformer. Output supply voltages are developed from voltages developed in secondary windings of the transformer. When the transistor is conductive, a current pulse is developed in the primary winding of the transformer and in the transistor. A voltage is also developed in a current sensing resistor coupled in series with the transistor. The voltage in the current sensing resistor is coupled to a first input of a comparator of a control circuit. A second input of the comparator is coupled to a capacitor that develops a voltage varying in accordance with an output voltage of the power supply for providing regulation. 
     During a given conduction interval of the transistor, the comparator is triggered when the current sensing resistor voltage exceeds a threshold voltage of the comparator established by the capacitor voltage. Ann output of the comparator is coupled to the base of the transistor for controlling the turn off instant of the transistor on a current pulse-by-current pulse basis. 
     In normal operation, a voltage, present across the primary of the main power transformer, reduces the voltage across the supply inductance. This voltage is proportional to the output voltage produce in a given secondary winding of the transformer. The output voltage produces from the secondary winding is stepped up by the turns ratio of the transformer. When the switching transistor turns off at the end of each cycle, a negative voltage pulse, reflected from the secondary side of the transformer reduces the collector voltage of the transistor. 
     Excessive collector voltage may be developed in the main switching transistor if an overload condition occurs in one of the secondary winding. The over-voltage is caused by excessive circulating current in a resonant supply inductance which resonates with a resonate capacitor that are coupled to the collector of the main switching transistor to form ZVS. 
     If a severe overload occurs on one of the secondary windings, which causes the power supply to fall out of regulation, the voltage across the primary winding of the transformer also drops since the voltage reflected by the turns ratio of the transformer is reduced. The result is that the collector voltage of the transistor may become excessive. 
     When the output voltage produced from the secondary winding falls out of regulation, a maximum current limit is established by the control circuit. Under an overload condition, the transistor will still allow the maximum current to flow through the supply inductance. However, energy stored in the supply inductance is not delivered to the load through the transistor. The stored energy produces resonant current in the resonant current in the resonant capacitor when the transistor is turned off at the end of the cycle and causes the collector voltage of the transistor to rise substantially above the normal operating voltage, possibly exceeding the breakdown voltage rating of the transistor. Since, under overload, the energy that is stored in the supply inductance during each cycle is not delivered to the load, the energy returns back to the unregulated supply that energizes the transistor via a reverse or negative current. It may be desirable to reduce the resulting excessive collector voltage. 
     SUMMARY 
     In carrying out an inventive aspect, the reverse negative current is routed through the base-collector junction of the transistor, when the transistor is turned off, in a direction opposite to the forward collector current. The forward collector current occurs when the transistors turned on. The reverse collector current produces a voltage in the aforementioned current sensing resistor, at opposite polarity with respect to its polarity, during forward conduction of the transistor. During an overload, the voltage produced by the sensed reverse current turns on a diode switch and changes a charge in the capacitor that is coupled to the second input of the comparator of the control circuit in a manner to reduce the peak forward collector current. Thereby, the peak forward current in the transistor decreases relative to a value that would have occurred without the protection. The result is that excessive collector voltage is, advantageously, prevented. 
    
    
     IN THE FIGURES 
     FIG. 1 illustrates a schematic diagram showing an exemplary embodiment of the circuit of the invention; and 
     FIGS. 2 a  and  2   b  illustrate waveforms useful for explaining the operation of the circuit of FIG.  1 . 
    
    
     DETAILED DESCRIPTION 
     FIG. 1 illustrates an zero voltage switching forward converter or power supply  300 . A protection circuit  400 , embodying an inventive feature, provides protection to zero voltage switching power supply  300 . Zero voltage switching power, supply  300  operates similarly in many respects to that described in the Fitzgerald patent. 
     Power, for example, 200 watts, is supplied toa load  303  and to a load  302  coupled to a secondary winding T 1 W 2  and a secondary winding T 1 W 3 , respectively, of a transformer T 1 , during conduction time of a switching transistor Q 1 . Transistor Q 1  that operates as a switch is coupled in series with a primary winding T 1 W 1  of transformer T 1  for conducting current from an input supply, direct current (DC) voltage RAW B+. A current transformer T 2 , considered a drive transformer, supplies a base current iB to switching transistor Q 1 . Voltage RAW B+ can be derived from a bridge rectifier (not shown) that rectifies a mains supply voltage, and is coupled toa filter capacitor (not shown). 
     Also coupled to the emitter of transistor Q 1  in series with transistor Q 1  is a current sensing resistor R 7 . A resonant capacitor C 8  is coupled to primary winding T 1 W 1  and to the collector of transistor Q 1 . A resonant circuit  301  includes capacitor C 8 , a reflected capacitance CSEC, a current limiting supply inductor Lres, primary winding T 1 W 1  and a primary winding T 2 W 1  of transformer T 2 . Primary winding T 1 W 1  is coupled in series with the primary winding T 2 W 1  of current transformer T 2 . 
     Resonant circuit  301  produces a half cycle resonant voltage VQ 1  each cycle when transistor switch Q 1  is turned off. A collector voltage VQ 1  across transistor Q 1  (and on capacitor C 8 ) rises to a peak and then fall to approximately zero in a substantially sinusoidal half wave. After resonant voltage VQ! becomes close to zero, a series arrangement of resistor R 7 , a diode D 2 , a zener diode D 20 , coupled in parallel with a capacitor C 2 , and the base-collector junction of transistor Q 1  form a low impedance that clamps voltage VQ 1  to a voltage close to ground potential. Transistor Q 1  is then switched on again at approximately zero volts to provide zero voltage switching. 
     A secondary winding T 1 W 3  of transformer T 1  is coupled to an anode of a rectifier diode DOUT 3 , the cathode of which is coupled to a filter capacitor CFILTER 3 . Winding T 1 W 3  is coupled via a low impedance current path, during forward conduction operation, to filter capacitor CFILTER 3  and to load  302 . Similarly, a secondary winding T 1 W 2  is coupled through rectifier diode DOUT 2  to filter capacitor CFILTER  2  to provide output voltage REG B+. 
     Capacitor CSEC may be included in one or both of the secondary winding circuits T 1 W 2  and T 1 W 3  in parallel with the winding. Capacitor CSEC is transformer coupled to winding T 1 W 1  forming a part of resonant circuit  301 . 
     Advantageously, each of winding T 1 W 2  and T 1 W 3  is tightly coupled to primary winding T 1 W 1  in transformer T 1  in a manner to reduce leakage inductance. Inductance L res  on the primary side of the transformer T 1  is transformer coupled to limit the rate of change of each of currents IDOUT 3  and IDOUT 2  in the current paths that includes diodes DOUT 3  and DOUT 2 , respectively, during forward conduction. Advantageously, inductance L res  is shared in common with each of windings T 1 W 2  and T 1 W 3 . 
     When transistor Q 1  is conductive, advantageously, a current produced in a secondary winding T 2 W 2  is proportional to the current in primary winding T 2 W 1  of transformer T 2 . Winding T 2 W 1  of transformer T 2  is coupled in series with winding T 1 W 1  of transformer T 1  and switching transistor Q 1 . Therefore, a base current iB varies approximately linearly with the collector current iQ 1 . Advantageously, over-driving of the base of transistor Q 1  is prevented by a proportional drive technique. 
     Control of the duty cycle of transistor switch Q 1  is based on, for example, sensing output voltage REG B+ directly, rather than output voltage U. An error amplifier A is responsive to the voltage REG B+, and can include, for example, a comparator having inputs coupled to output voltage REG B+ and to a voltage divider providing a predetermined threshold. Error amplifier A is optically coupled through an opto-coupler μ 1  to control a triggering level or threshold of a comparator transistor Q 3 . 
     The voltage at the emitter of transistor Q 3  is developed from the charge in a capacitor C 6 . The emitter voltage in capacitor C 6  is limited to a forward diode drop by a diode D 7 , coupled to ground. The charge in capacitor C 6  is replenished while transistor Q 3  is conducting and is drained by opto-coupler μ 1  when it conducts in response to an output signal of error amplifier A. 
     When transistor Q 1  is conductive, a voltage VR 7  across resistor R 7 , which is proportional to the current level in transistor Q 1 , is coupled to the base of a comparator transistor Q 3 . Current-representative voltage VR 7  is resistor R 7  is coupled to a filter capacitor C 7  through a resistor R 8 . A voltage developed in capacitor C 7  from voltage VR 7  is coupled to the base of transistor Q 3 . 
     In a given conduction cycle of transistor Q 1 , when the base voltage of transistor Q 3  exceeds a threshold voltage of transistor Q 3  that is determined by a control voltage VC 6 , developed in capacitor C 6  at the emitter of transistor Q 3 , by an amount sufficient to forward bias the base-emitter junction, transistor Q 3  begins conducting. Thus, transistor Q 3  begins conducting, when a current iQ 1  in transistor Q 1  develops voltage VR 7  in resistor R 7  that exceeds the threshold voltage of transistor Q 3 . When transistor Q 3  conducts, it forms a regenerative latch with a transistor Q 2 . The collector of NPN transistor Q 3  is coupled to the base of PNP transistor Q 2  and the collector of transistor Q 2  is coupled to the base of transistor Q 3 , forming a regenerative switch. The emitter of transistor Q 2  is coupled back to the base of switching transistor Q 1  via diode D 20  and a capacitor C 2 , coupled in parallel. 
     When the latch formed by transistors Q 2  and Q 3  is triggered, transistor Q 2  draws current away from the base of switching transistor Q 1 . A control voltage coupled to the base of switching transistor Q 1  is developed at the emitter of transistor Q 2 . The emitter voltage of transistor Q 2  forms an output of the regenerative switch arrangement and is coupled to the base of transistor Q 1  to turn off transistor Q 1  when the latch formed by transistors Q 2  and Q 3  is triggered. 
     Secondary winding T 2 W 2  of current transformer T 2  provides base current iB of switching transistor Q 1 . The voltage across winding T 2 W 2  is an alternating current (AC) voltage, produced when switching transistor Q 1  alternately conducts and is turned off. Advantageously, when transistor Q 1  is turned on, transformer T 2  provides proportional drive current iB to transistor Q 12  for maintaining transistor Q 1  in saturation without over-driving transistor Q 1 . On the other hand, immediately after transistor Q 1  is turned off by the operation of transistors Q 2  and Q 3 , resonant voltage VQ 1  at the collector of transistor Q 1  is coupled to the base of transistor Q 1  via winding T 2 W 2  in a manner to maintain transistor Q 1  nonconductive. 
     A collector of an on/off transistor Q 4  is coupled via a diode D 11  to the emitter of transistor Q 2 . When transistor Q 4  is conductive, in accordance with an on/off signal ON/OFF, a base current is produced in transistor Q 2  that causes transistor Q 1  to stay nonconductive. The emitter current of transistor Q 4  produces forward conduction in a zener diode D 13 . Diode D 13  is coupled in parallel with a slow start capacitor C 1  that are coupled to the emitter of transistor Q 4 . 
     Start-up of the oscillation cycles occurs when transistor Q 4  is turned off and causes transistor Q 2  to turn off. Thereafter, a current starts flowing through a resistor R 4  and through the parallel arrangement of zener diode D 20  and capacitor C 2  and produces a start-up base current iB in switching transistor Q 1 . Resistor R 4  is large, and provides only a small amount of start-up base current drive to transistor Q 1 . As transistor Q 1  begins conducting, current transformer T 2  causes a current to flow in secondary winding T 2 W 2 . The current in secondary winding T 2 W 2  is proportional to the current in primary winding T 2 W 1 , as a function of their turns ratio. Diode D 1  and a parallel capacitor C 10  are coupled in series with secondary winding T 2 W 2  and with the parallel arrangement of zener diode D 20  and capacitor C 2  to produce the base current iB of transistor Q 1 . The added base drive current attains saturation for the added collector current in a regenerative manner, causing base current iB to increase in proportion to the increase in collector current iQ 1 . When transistor Q 1  saturates, collector current iQ 1  continues to increase by a rate determined by the total supply inductance coupled in series with the collector of transistor Q 1 . 
     When the voltage across current sensing resistor R 7  is sufficient to cause transistor Q 3  to conduct, triggering current is provided at the base of transistor Q 2 . Transistor Q 2  conducts and causes an increase in the voltage at the base of transistor Q 3  by producing additional drive current in capacitor C 7  and also operating in a regenerative manner to latch on. The low impedance developed at the emitter of latched drive transistor Q 2  quickly removes the base charge from the base of switching transistor Q 1 . The result is that transistor Q 1  is quickly turned off. 
     During the time that transistor Q 1  is conducting, positive current flows into the base through the diode D 20  and capacitor C 2 , which causes capacitor C 2  to charge to several volts. The voltage in capacitor C 2  is more positive on the terminal of capacitor C 2  that is remote from the base of transistor Q 1  and less positive at the base of transistor Q 1 . Therefore, when transistors Q 2  and Q 3  latch, they provide a low impedance path to ground, causing the voltage on capacitor C 2  to apply a negative bias to the base of transistor Q 1 . 
     A diode D 6  and a resistor R 6 , coupled in series between the collector of transistor Q 2  and current sensing resistor R 7 , shunt some of the reverse base current to resistor R 7 , which is low in impedance, for example a fraction of an ohm. This shunting reduces the tendency to overdrive the base of transistor Q 3 , which would otherwise cause excessive storage time and poor switching performance. 
     After transistor Q 1  is turned off, transformer T 2  winding T 2 W 2  produces a negative voltage across a diode D 2 , having an anode that is coupled to the emitter of transistor Q 1 . Drive control transistors Q 2  and Q 3  remain latched until the current flowing through them drops below a threshold needed to keep them regeneratively latched. Thereafter, the negative voltage across diode D 2  keeps transistor Q 1  from conducting. In addition, a diode D 3  and a capacitor C 3  are coupled to rectify and filter the negative voltage produced by transformer T 2  to produce a negative supply voltage VMINUS. 
     The resonant action of resonant circuit  301  causes the base-emitter voltage to reverse polarity via winding T 2 W 2 . When the voltage at the base of switching transistor Q 12  increases to a sufficient magnitude, current begins flowing in the base of transistor Q 1 , producing collector current that grows regeneratively, as explained before, forming the beginning of the next cycle. Collector current iQ 1  in transistor Q 1  begins flowing when collector voltage VQ 1  is at zero volts. Thereby, zero voltage switching is obtained. 
     Advantageously, current transformer T 2  provides for self-oscillations. In the circuit coupled to secondary winding T 2 W 2  of transformer T 2 , diode D 2  limits the negative voltage developed during the time off of transistor Q 1 . Because diode D 1  and capacitor C 10  form a low impedance, transformer T 2  operates as a current transformer during the turn off interval. Diode D 1  provides a current path for the forward drive current and also limits the voltage in capacitor C 10 , in parallel with diode D 1 , to the forward voltage developed across diode D 1  when conducting. Diode D 1 , capacitor C 2  and the base-emitter junction of transistor Q 1  form a low impedance operates as a current transformer. Advantageously, by operating as a current transformer, transformer T 2  need not have to store large magnetic energy and can have a small core. 
     During the start-up interval, voltage VMINUS produces a charge current in a resistor R 11  that is coupled to capacitor C 11 , causing a start-up, ramp negative voltage in capacitor C 11 . The ramp voltage in capacitor C 11  is coupled via a resistor R 13  to resistor R 8 . Consequently, the threshold voltage of comparator transistor Q 3  varies in a ramping manner to provide slow start operation. Voltage VMINUS is also coupled to the emitter of the phototransistor in opto-coupler μ 1 . The charge on capacitor C 6  is adjusted by conduction of the phototransistor of opto-coupler μ 1 , responsive to signals from error amplifier A. In this manner the voltage is closely regulated on a current pulse basis. 
     In normal operation, a voltage is present across primary winding T 1 W 1  of main power transformer T 1  which reduces the voltage across current limiting inductance L res . This voltage is proportional to output voltage REG B+ approximately multiplied by the turns ratio of windings T 1 W 2  and T 1 W 1 . When transistor Q 1  turns off at the end of each cycle, a negative voltage pulse, reflected from the secondary side of transformer T 1 , counteracts the positive pulse that appears on a terminal of current limiting inductance L res , close to the collector of transistor Q 1 . Thus, advantageously, the collector voltage VQ 1  of transistor Q 1  is reduced. 
     A severe overload may occur in, for example, secondary winding T 1 W 2 . Consequently, the power supply may cease regulating in a negative feedback loop manner. Therefore, voltages REG B+ and U will decrease. Consequently, the voltage across primary winding T 1 W 1  of main power transformer T 1  that is reflected by the turns ratio of the transformer also drops. The result is that the aforementioned reflected negative pulse is greatly reduced, causing the collector voltage VQ 1  across primary winding T 1 W 1  of main power transformer T 1  to rise substantially more than under normal, non-overload conditions. 
     During severe overload, voltages REG B+ and U decrease because of loss of regulation. A maximum current limit is established on a current pulse-by-current pulse basis by the control circuit that includes transistors Q 2  and Q 3 . Under an overload condition, transistor Q 1  will still allow maximum current iQ 1  to flow through the supply inductance that includes current limiting inductance L res . However, energy stored in, for example, current limiting inductance L re  is not delivered to the load through transformer T 1 . The stored energy is developed in resonant circuit  301 , when transistor Q 1  is turned off at the end of the cycle. The increased stored energy causes the collector voltage VQ 1  of transistor Q 1  to rise substantially above the permissible normal operating voltage, possibly exceeding the breakdown voltage rating of transistor Q 1 . 
     Since the energy stored in, for example, current limiting inductance L res  during each cycle is not delivered to the load, the energy returns back to the supply of voltage RAW B+. This returning energy, produces a reverse or negative current flowing through series arrangement of resistor R 7 , diode D 2 , zener diode D 20 , coupled in parallel with capacitor C 2 , the base-collector junction of transistor Q 1  and windings T 1 W 1  and L res  and develops voltage VR 7  across resistor R 7  in a negative polarity. 
     FIG. 2 b  illustrates the waveform of a negative current iR 7  in resistor R 7  that produces negative voltage VR 7  of FIG.  1 . The positive portion of current iR 7  of FIG. 2 b  occurs during forward conduction of transistor Q 1  of FIG.  1 . FIGS. 2 a  and  2   b  illustrate the effect of negative current iR 7  of FIG. 2 b  on control voltage VC 6  of FIGS. 1 and 2 a.  Similar symbols and numerals in FIGS. 1,  2   a  and  2   b  indicate similar items or functions. 
     In carrying out an inventive feature, a switch diode D 10  of FIG. 1 is coupled in series with a current limiting resistor R 10  between capacitor C 6  and resistor R 7  for decreasing control voltage VC 6  of FIG. 2 a  developed in capacitor C 6  of FIG. 1, when the negative current iR 7  of FIG. 2 b  in resistor R 7  of FIG. 1 in the vicinity of time t 0  of FIGS. 2 a  and  2   b  is excessive. The reverse or negative current in FIG. 2 b  occurs when collector current iQ 1  of transistor Q 1  of FIG. 1 flows to the supply terminal, where voltage RAW B+ is developed. As explained before, reverse current iQ 1  flows in a path that includes diode D 2 , zener diode D 20 , coupled in parallel with capacitor C 2  and the base-collector junction of transistor Q 1 . 
     The level of control voltage VC 6  of FIG. 2 a  in capacitor C 6  of FIG. 1 determines the maximum forward current iQ 1 , when transistor Q 1  is conductive. During overload, negative current iR 7  of FIG. 2 b  and negative voltage VR 7  across resistor R 7  of FIG. 1 turn on diode D 10  and cause voltage VC 6  of FIG. 2 a  in capacitor C 6  of FIG. 1 to decrease. Consequently, the peak forward current in transistor Q 1  is, advantageously, reduced. Advantageously, by forcing the reduction in the peak of each forward current pulse iQ 1  in transistor Q 1 , during overload conditions, the possibility of exceeding the voltage rating of transistor Q 1  is diminished and the reliability increases. The addition of resistor R 10  in series with diode D 10  allows for a small time constant of capacitor C 6  and resistor R 10  and minimizes the peak current through diode D 10 .