EVL170W-FTV STMicroelectronics, EVL170W-FTV Datasheet - Page 18

EVL170W-FTV

Manufacturer Part Number

EVL170W-FTV

Description

DEMO BOARD VIPER27 L6599A L6564

Manufacturer

STMicroelectronics

Series

VIPER™r

Datasheet

1.EVL170W-FTV.pdf (47 pages)

Specifications of EVL170W-FTV

Main Purpose

Power Supply with PFC

Outputs And Type

2, Isolated

Power - Output

170W

Voltage - Output

24V, 12V, 5V

Current - Output

6A, 2A, 2A

Voltage - Input

90 ~ 264VAC

Regulator Topology

Flyback

Frequency - Switching

130kHz

Board Type

Fully Populated

Utilized Ic / Part

Viper27LN, L6564, L6599A

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

497-11254

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Figure 29. PFC Vds and inductor current at

CH1: Q1 drain voltage

CH3: CS (pin #4)

Power factor corrector stage

Figure 29

CS (#4) and MULT (#3) pins along a line half-period at 115Vac. Low current distortion and

high power factor are achieved as the peak inductor current waveform follows the MULT pin.

THD (total harmonic distortion) is considerably reduced by the L6564 THD optimizer.

mode control makes the inductor work on the boundary between continuous and

discontinuous conduction mode. When the PFC MOSFET turns on, the inductor current

ramps up, until the voltage on the current sense input reaches the reference level

programmed by the internal multiplier block. At that point, the PWM comparator changes

state, turning off the power switch. During the MOSFET off-time, the current ramps down

until it reaches zero, so the inductor is demagnetized. The zero current detection (ZCD)

circuit detects that point by monitoring the voltage across the inductor auxiliary winding,

which falls to zero when the current reaches zero, due to the resonance between the

inductor and the drain capacitance. Once the demagnetization point is detected by the

L6564 internal logic, the signal on ZCD drives the MOSFET on again and another switching

cycle begins. A significant advantage of TM operation is the possibility to work in ZVS: if the

instantaneous input voltage of the converter is lower than the inductor voltage, the ZVS

(zero voltage switching) condition is achieved, decreasing MOSFET commutation losses.

However, if the instantaneous input voltage is higher than the inductor voltage the MOSFET

is turned on at the minimum voltage, on the valley point of the resonance, still minimizing the

transition losses, as seen in

Figure 31

higher than the inductor voltage, it is possible to observe the boost inductor resonating with

the total drain capacitance with an amplitude of twice the inductor voltage on the offset of

the input voltage. In order to maximize efficiency the RC network connected to the ZCD (#7)

pin is tuned to make the turn-on of the MOSFET occur just on the valley of the drain voltage.

115 Vac - 60 Hz, full load

Figure 30

shows the PFC MOSFET's drain voltage, inductor current, and voltages on the

and

the same signals are captured at the top of the input sine wave. Transition

CH2: MULT (pin #3)

CH4: L1 inductor current

Figure 32

show the same waveforms at 230 Vac. As the input voltage is

Figure

Doc ID 18376 Rev 1

32.

Figure 30. PFC Vds and inductor current at

CH1: Q1 drain voltage

CH3: CS (pin #4)

115 Vac - 60 Hz, full load - detail

CH4: L1 inductor current

CH2: MULT (pin #3)

AN3329

EVL170W-FTV STMicroelectronics, EVL170W-FTV Datasheet - Page 18

EVL170W-FTV

Specifications of EVL170W-FTV

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