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L6562AT Datasheet(PDF) 12 Page - STMicroelectronics |
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L6562AT Datasheet(HTML) 12 Page - STMicroelectronics |
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12 / 25 page  Application information L6562AT 12/25 7 Application information 7.1 Overvoltage protection Under steady-state conditions, the voltage control loop keeps the output voltage Vo of a PFC pre-regulator close to its nominal value, set by the resistors R1 and R2 of the output divider. Neglecting ripple components, the current through R1, IR1, equals that through R2, IR2. Considering that the non-inverting input of the error amplifier is internally referenced at 2.5 V, also the voltage at pin INV will be 2.5 V, then: Equation 1 If the output voltage experiences an abrupt change ΔVo > 0 due to a load drop, the voltage at pin INV will be kept at 2.5 V by the local feedback of the error amplifier, a network connected between pins INV and COMP that introduces a long time constant to achieve high PF (this is why ΔVo can be large). As a result, the current through R2 will remain equal to 2.5/R2 but that through R1 will become: Equation 2 The difference current ΔI R1=I'R1-IR2=I'R1-IR1= ΔVo/R1 will flow through the compensation network and enter the error amplifier output (pin COMP). This current is monitored inside the device and if it reaches about 24 µA the output voltage of the multiplier is forced to decrease, thus smoothly reducing the energy delivered to the output. As the current exceeds 27 µA, the OVP is triggered (Dynamic OVP): the gate-drive is forced low to switch off the external power transistor and the IC put in an idle state. This condition is maintained until the current falls below approximately 7 µA, which re-enables the internal starter and allows switching to restart. The output ΔVo that is able to trigger the Dynamic OVP function is then: Equation 3 ΔV O = R1 · 20 · 10 - 6 An important advantage of this technique is that the OV level can be set independently of the regulated output voltage: the latter depends on the ratio of R1 to R2, the former on the individual value of R1. Another advantage is the precision: the tolerance of the detection current is 13%, i.e. 13% tolerance on ΔVo. Since ΔVo << Vo, the tolerance on the absolute value will be proportionally reduced. Example: Vo = 400 V, ΔVo = 40 V. Then: R1 = 40 V/27 µA ≈ 1.5 MΩ; R2 = 1.5 M Ω ·2.5/(400-2.5) = 9.43 kΩ. The tolerance on the OVP level due to the L6562AT will be 40·0.13 = 5.3 V, that is ± 1.2 %. I R2 I R1 2.5 R2 -------- V O 2.5 – R1 ---------------------- == = I' R1 V O 2.5 – V O Δ + R1 ---------------------------------------- = |
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