EPR-91 Datasheet, PDF(9/36 Page) Power Integrations, Inc. – Engineering Prototype Report for EP-91

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EPR-91 Datasheet, PDF (9/36 Pages) Power Integrations, Inc. – Engineering Prototype Report for EP-91 - 12 W Power Supply using

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7-Feb-2006

EP-91 12 V, 1 A, Universal Input Supply

4.3 Output Rectification and Filtering

Diode D7 rectifies the output of T1. Output voltage ripple was minimized by using a low

ESR capacitor for C10 (see Section 6 for component part numbers and values). A post

filter (ferrite bead L2 and C11) attenuates the high frequency switching noise.

4.4 Feedback and Output Voltage Regulation

The supplyâs output voltage regulation set point is set by the voltage that develops across

Zener diode VR3, R6 and the LED in opto-coupler U2. The value of R4 was calculated to

bias VR3 to about 0.5 mA when it goes into reverse avalanche conduction. This ensures

that it is operating close to its rated knee current. Resistor R6 limits the maximum current

during load transients. The values of R4 and R6 can both be varied slightly to fine-tune

the output regulation set point. When the output voltage rises above the set point, the

LED in U2 becomes forward biased. On the primary side, the photo-transistor of U2

turns on and draws current out of the EN/UV pin of U1. Just before the start of each

switching cycle, the controller checks the EN/UV pin current. If the current flowing out of

the EN/UV pin is greater than 115 ÂµA, that switching cycle will be disabled. As switching

cycles are enabled and disabled, the output voltage is kept very close to the regulation

set point. For greater output voltage regulation accuracy, a reference IC such as a

TL431 can be used in place of VR3.

4.5 Output Overvoltage Shutdown

The TinySwitch-III family of ICs can detect overvoltage on the output of the supply and

latch off. This protects the load in an open feedback loop fault condition, such as the

failure of the optocoupler. Overvoltage on the output is detected through the BP/M pin

and the bias winding on the transformer. The bias winding voltage is determined by the

reflection of the output voltage through the turns ratio of the transformer. Therefore, an

overvoltage on the output will be reflected onto the bias winding. The overvoltage

threshold is the sum of the breakdown voltage of Zener diode VR2 and the BP/M pin

voltage (28 V + 5.8 V). If the output voltage becomes abnormally high, the voltage on the

bias winding will exceed the threshold voltage and excess current will flow into the BP/M

pin. The latching shutdown circuit is activated when current into the BP/M pin exceeds

5 mA. Resetting a latched shutdown requires removing the AC input from the supply

long enough to allow the input capacitors (C1 and C2) to discharge, and the BP/M pin

voltage to drop below 2 V. Resistors R7 and R3 provide additional filtering of the bias

voltage, with R3 also limiting the maximum current into the BYPASS pin in an OV

condition

4.6 EMI Design Aspects

An input pi filter (C1, L1 and C2) attenuates conducted, differential mode EMI noise.

Shielding techniques (E-Shieldâ¢) were used in the construction of T1 to reduce common

mode EMI displacement currents. Resistor R2 and capacitor C4 dampen out some of the

high frequency ringing that occurs when the MOSFET turns off. When combined with the

ICâs frequency jitter function, these techniques produce excellent conducted and radiated

EMI performance (see Section 12 of this report).

Page 9 of 36

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