Isolated flyback converter with efficient light load operation
First Claim
1. A method for operating a flyback converter with a low current load, the converter having a transformer with a primary winding and a secondary winding, the primary winding being coupled to a power source and a first transistor for conducting a current through the primary winding when the first transistor is on, the secondary winding being coupled to a second transistor for conducting a current through the secondary winding when the second transistor is on, the converter having a primary side regulated duty cycle for load currents above a threshold level and a primary side minimum duty cycle for load currents below the threshold level for periodically sensing an output voltage of the converter using primary side sensing, the converter having an output capacitor, the method comprising:
- turning on the first transistor for a first interval at the minimum duty cycle, due to the load current being below the threshold level, to draw a current through the primary winding;
turning on the second transistor after the first transistor has turned off to draw a current through the secondary winding to charge the output capacitor;
performing the primary side sensing of the output voltage;
determining whether the output voltage has exceeded a predetermined regulated voltage by a certain threshold to detect an over-voltage condition, resulting from the low current load;
if the over-voltage condition is detected, turning on the second transistor for a second interval to conduct a reverse current through the secondary winding to reduce the output voltage; and
after the second interval, turning off the second transistor to cease current flow in the secondary winding and to cause a current to flow in the primary winding and into the power source, such that excess power is transferred from a secondary side of the transformer to a primary side of the transformer to reduce the over-voltage during low load current conditions.
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0 Petitions
Accused Products
Abstract
A flyback converter uses primary side sensing to sense the output voltage for regulation feedback. Such sensing requires a predetermined minimum duty cycle even with very light load currents. Therefore, such a minimum duty cycle may create an over-voltage condition. In the flyback phase, after a minimum duty cycle of the power switch at light load currents, a synchronous rectifier turns off approximately when the current through the secondary winding falls to zero to create a discontinuous mode. If it is detected that there is an over-voltage, the synchronous rectifier is turned on for a brief interval to draw a reverse current through the secondary winding. When the synchronous rectifier shuts off, a current flows through the primary winding via a drain-body diode while the power switch is off. Therefore, excess power is transferred from the secondary side to the power source to reduce the over-voltage so is not wasted.
42 Citations
19 Claims
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1. A method for operating a flyback converter with a low current load, the converter having a transformer with a primary winding and a secondary winding, the primary winding being coupled to a power source and a first transistor for conducting a current through the primary winding when the first transistor is on, the secondary winding being coupled to a second transistor for conducting a current through the secondary winding when the second transistor is on, the converter having a primary side regulated duty cycle for load currents above a threshold level and a primary side minimum duty cycle for load currents below the threshold level for periodically sensing an output voltage of the converter using primary side sensing, the converter having an output capacitor, the method comprising:
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turning on the first transistor for a first interval at the minimum duty cycle, due to the load current being below the threshold level, to draw a current through the primary winding; turning on the second transistor after the first transistor has turned off to draw a current through the secondary winding to charge the output capacitor; performing the primary side sensing of the output voltage; determining whether the output voltage has exceeded a predetermined regulated voltage by a certain threshold to detect an over-voltage condition, resulting from the low current load; if the over-voltage condition is detected, turning on the second transistor for a second interval to conduct a reverse current through the secondary winding to reduce the output voltage; and after the second interval, turning off the second transistor to cease current flow in the secondary winding and to cause a current to flow in the primary winding and into the power source, such that excess power is transferred from a secondary side of the transformer to a primary side of the transformer to reduce the over-voltage during low load current conditions. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
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12. A flyback converter comprising:
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a transformer with a primary winding and a secondary winding, the primary winding being coupled to a power source; a first transistor coupled to the primary winding for conducting a current through the primary winding when the first transistor is on; a second transistor for conducting a current through the secondary winding when the second transistor is on; a regulator coupled to the first transistor for controlling a duty cycle of the first transistor to regulate the output voltage of the converter, the regulator being configured to control the first transistor to have a primary side regulated duty cycle for load currents above a threshold level and a primary side minimum duty cycle for load currents below the threshold level; an output voltage sensor circuit coupled to the transformer for sensing an output voltage of the converter using primary side sensing; an output capacitor coupled to an output terminal of the converter; a synchronous rectifier controller coupled to the second transistor for controlling the second transistor to be on or off; a comparator having one input coupled to receive a voltage corresponding to the output voltage of the converter and having another input connected to a reference voltage representing a threshold voltage exceeding a regulated voltage of the converter, wherein triggering of the comparator signifies an over-voltage condition; during operation of the regulator at the minimum duty cycle with the load currents below the threshold level, an output of the comparator being coupled so as to control the synchronous rectifier controller to turn the second transistor on for an interval to conduct a reverse current through the secondary winding, upon the over-voltage condition being detected, to reduce the output voltage of the converter to mitigate the over-voltage condition; and a diode coupled to the primary winding to conduct a current through the primary winding after the interval without turning on the first transistor, such that power is transferred from a secondary side of the transformer to the power source while mitigating the over-voltage condition. - View Dependent Claims (13, 14, 15, 16, 17, 18, 19)
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Specification
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- Resources
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Current AssigneeAnalog Devices International Unlimited Company (Analog Devices, Inc.)
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Original AssigneeLinear Technology Corporation (Analog Devices, Inc.)
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InventorsMorris, John D., Negrete, Michael G., Chen, Min
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Primary Examiner(s)Nguyen, Matthew
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Assistant Examiner(s)Moody, Kyle J.
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Application NumberUS13/359,447Publication NumberTime in Patent Office642 DaysField of Search363/21.14, 363/21.06, 363/52, 363/55, 363/84, 363/89, 363/21.17US Class Current363/21.14CPC Class CodesH02M 1/0032 Control circuits allowing l...H02M 1/32 Means for protecting conver...H02M 3/33584 Bidirectional convertersH02M 3/33592 having a synchronous rectif...Y02B 70/10 Technologies improving the ...
