STMicroelectronics AN1897 In the past few years, many consumer products have been provided Datasheet

AN1897
Application note
VIPower™: low-cost universal input DVD supply
with the VIPer22A-E
Introduction
In the past few years, many consumer products have been provided to the end user, such
as DVD or VCD players. Generally, their power supply requires multiple outputs to supply a
variety of control circuits: MCU, motor, amplifier, VFD.
Offline switch mode power supply regulators from ST’s VIPer® family combine high voltage,
avalanche rugged vertical power MOSFET with current mode control PWM circuitry. The
result is the innovative AC-DC converter, simpler, quicker, with reduced component count
and cheap.
The VIPer family complies with the “Blue Angel” and “Energy Star” norms, with very low total
power consumption in standby mode, thanks to the burst operation. This document presents
the application on DVD player power supply with the VIPer22A-E meeting the specifications
in Table 1.
Figure 1. VIPer22A-E evaluation board
Table 1. Output specifications
Input
Output 1
Output 2
Output 3
Output 4
Output 5
Output 6
Universal
line
5 V+/-5%
+12 V+/-5%
-12 V+/-5%
-26 V+/-5%
3.3 V+/-5%
(1)
(1)
(1)
(1)
(1)
5 Vstb+/-5%
Imin.
20 mA
Imax.1.5 A
Imax.
30 mA
Imax.
30 mA
Imax.50 mA
Imax.
150 mA
Min. 85 Vac
Max. 265 Vac
(1)
Imax.100 mA
1. The accuracy of +/-5% is reached for a range of load combination only. See Section 3.2 for crossregulation results.
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Contents
AN1897
Contents
1
Application description and design . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1
1.2
Schematics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1.1
Start-up phase . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1.2
Auxiliary supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1.3
Burst mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1.4
Feedback loop . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1.5
Primary driver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Transformer consideration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
2
Layout recommendation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
3
Experimental results . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
3.1
Efficiency . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
3.2
Regulation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
4
Transformer specification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
5
PCB layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
6
Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
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Application description and design
1
Application description and design
1.1
Schematics
The overall schematic is shown in Figure 3.
1.1.1
Start-up phase
The VIPer22A-E has an integrated high voltage current source linked to the drain pin. At the
start-up converter, it charges the VDD capacitor until it reaches the start-up level (14.5 V),
and the VIPer22A-E starts switching.
1.1.2
Auxiliary supply
The VIPer22A-E has a wide operating voltage range from 8 V to 42 V, respectively minimum
and maximum values for undervoltage and overvoltage protections.
This function is very useful to achieve low standby total power consumption. The feedback
loop is connected to 5 V output by D12 to regulate 5 V output. +5 Vstb output is blocked by
Q3, so +5 Vstb regulation is neglected. When the standby signal is present, the Q3 Vce
cannot provide enough voltage to maintain D12 conducted, so the 5 V output is blocked,
and the +5 Vstb output is connected to the feedback loop. In this condition the +5 Vstb is
regulated. Thanks to the transformer structure, all the other secondary outputs and the
auxiliary voltages are pulled down to a very low level, also pulling down the total power
consumption. These features are below-indicated.
1.1.3
–
In normal full load, the VDD voltage must be lower than the overvoltage protection.
–
In short-circuit, the VDD voltage must be lower than the shutdown voltage.
Actually, this condition leads to the well-known hiccup mode.
–
In no-load condition, the VDD voltage must be higher than the shutdown voltage.
Burst mode
The Viper22A-E integrates a current mode PWM with a power MOSFET and includes the
leading edge blanking function. The burst mode allows the VIPer22A-E to skip some
switching cycles when the energy drained by the output load goes below E = (Tb*Vin)2 *
fsw/2Lp (Tb = blanking time, Vin= DC input voltage, fsw = switching frequency, Lp = primary
Inductance). The consequence is the reduction of the switching losses in case of low load
condition by reducing the switching frequency.
1.1.4
Feedback loop
The 5 V output voltage is regulated by a TL-431 (U3) via an optocoupler (U2) to the
feedback pin. If the output voltage is high, the TL-431 draws more current through its
cathode to the anode and the current increases in the optocoupler diode. The current in
optocoupler NPN increases accordingly and the current into the VIPer22A-E FB pin
increases. When the FB current increases, the VIPer22A-E skips some cycles to decrease
turn-on time and lower the output voltage to the proper level (see Figure 1). The 5 V output
voltage is regulated thanks to the TL-431 reference voltage and the R8 and R9 resistive
dividers.
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Application description and design
AN1897
Figure 2. VIPer22A-E FB pin internal structure
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Primary driver
In a flyback power supply, the transformer is used as an energy tank during the on-time of
the MOSFET. When the MOSFET turns off, its drain voltage rises from a low value to the
input voltage while the secondary diode conducts, transferring to the secondary side the
magnetic energy stored in the transformer. Since primary and secondary windings are not
magnetically coupled, there is a serial leakage inductance that behaves like an open
inductor charged at Ipk, causing the voltage spikes on the MOSFET drain. These voltage
spikes must be clamped to keep the VIPer22A-E drain voltage below the BVdss (730 V)
rating. If the peak voltage is higher than this value, the device is destroyed. The RCD clamp
(see Figure 4) is a very simple and cheap solution, but it impacts on the efficiency and on
the power dissipation in standby condition. Besides, the clamping voltage varies according
to the load current. RCD clamp circuits may allow the drain voltage to exceed the
breakdown rating of the VIPer22A-E during the overload operation or during turn-on with
high line AC input voltage. A Zener clamp is recommended (see Figure 5). However this
solution gives higher power dissipation at full load, even if the clamp voltage is exactly
defined.
1.2
Transformer consideration
On the electrical specifications of a multiple output transformer (cross-regulation, leakage
inductance), the main efforts focused on the proper coupling between the windings. A lower
leakage inductance transformer allows a lower power clamp to reduce the input power. It l
leads to lower power dissipation on the primary side. Auxiliary and secondary windings are
swapped in order to decrease the coupling to the primary one. The secondary windings act
as a shielding layer to reduce the capacitive coupling. Fewer spikes are generated on the
auxiliary windings, the primary and secondary windings have better coupling.
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Application description and design
Designing transformers for low leakage inductance involves several considerations:
–
Minimizing the number of turns
–
Keeping ratio of winding height to width small
–
Increasing width of windings
–
Minimizing the insulation between windings
–
Increasing coupling between windings
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Application description and design
AN1897
Figure 3. Application schematic
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AN1897
Application description and design
Figure 4. RCD clamp topology
Figure 5. Zener clamp topology
For safety requirements, a leakage inductance value is 1 to 3% of the open circuit primary
inductance. A high efficiency transformer should have low inter-winding capacitance to
decrease the switching losses. Energy stored in the parasitic capacitance of the transformer
is absorbed by the VIPer22A-E cycle-by-cycle during the turn-on transition. Excess
capacitance also rings with stray inductance during switch transitions, causing noise
problems. Capacitance effects are usually the most important in the primary winding, where
the operating voltage (and consequent energy storage) is high. The primary winding should
be the first winding on the transformer. This allows the primary winding to have a short
length per turn, reducing the internal capacitance. The driven end of the primary winding
(the end connected to the drain pin) should be the beginning of the winding rather than the
end. This takes advantage of the shielding effect of the second half of the primary winding
and reduces capacitive coupling to adjacent windings. A layer of insulation between
adjacent primary windings can cut the internal capacitance of the primary winding by a four
factor, with consequent reduction of losses. A common technique for winding multiple
secondaries with the same polarity sharing a common return, is to stack the secondaries
(see Figure 6). This arrangement improves the load regulation, and reduces the total
number of secondary turns. Commonly a clamper based on an RCD network or a diode with
a Zener to clamp the rise of the drain voltage is used.
Figure 6. Multiple output winding
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Layout recommendation
2
AN1897
Layout recommendation
Since EMI issues are strongly related to layout, a basic rule has to be taken into account in
high current path routing, (the current loop area has to be minimized). If a heatsink is used it
has to be connected to ground to reduce common mode emissions, since it is close to the
floating drain tab. Besides, in order to avoid any noise interference on the VIPer22A-E logic
pin, the control ground has to be separated from power ground.
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Experimental results
3
Experimental results
3.1
Efficiency
Figure 7. Efficiency at 230 Vac (load on 5 V)
Figure 8. Efficiency at 260 Vac (load on 5 V)
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Figure 10. Load regulation (load on + 5 V)
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Experimental results
3.2
AN1897
Regulation
Table 2. Line regulation
Output
85 Vac
85 Vac
260 Vac
5 V/ 0.1 A
5.15 V
5.15 V
5.15 V
5 Vstb/ 0 A
5.15 V 5
15.15 V
5.15 V
12 V/ 0 A
12.08 V
12.11 V
12.12 V
-12 V/ 0 A
-11.98 V
-11.99 V
-12.00 V
-26 V/ 0 A
-25.82 V
-25.85 V
-25.86 V
3.3 V/ 0 A
3.87 V
3.87 V
3.88 V
Figure 11. Cross-regulation
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Table 3. Standby model
10/17
Output
85 Vac
230 Vac
260 Vac
5V
2.05 V
2.05 V
2.07 V
5 Vstb (100 mA)
5.08 V
5.11 V
5.14 V
12 V
4.00 V
3.99 V
3.98 V
-12 V
3.99 V
3.99 V
3.98 V
-26 V
9.12 V
9.10 V
9.08 V
3.3 V
1.70 V
1.50 V
1.51 V
PDIs
0.8 W
1W
1.1 W
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Experimental results
Table 4. Full load regulation
Output
85 Vac
230 Vac
260 Vac
5 V/ 1.5 A
5.02 V
5.09 V
5.08 V
5 Vstb/ 0 A
5.02 V
5.09 V
5.08 V
12 V/30 mA
12.03 V
12.06 V
12.05 V
-12 V/30 mA
-12.01 V
-12.05 V
-12.05 V
-26 V/50 mA
-26.06 V
-26.16 V
-26.15 V
3.3 V/0.15 A
3.77 V
3.80 V
3.78 V
VIPer22A-E temp
53 °C
47 °C
45 °C
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Transformer specification
4
AN1897
Transformer specification
Figure 12. Transformer structure
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Table 5. Winding parameters
Layer description
Wire size
Symbol
Start pin
End pin
Number of layers
Turns
Primary
Wp
Pin 2
Pin 1
2
65
0.3
Out 1 (5 V/1.5 A)
W5
Pin 7
Pin 12
1
4
2*0.6
Out 2 (12 V/0.0 3 A)
W12
Pin 11
Pin 7
1
5
0.3
Out 3 (-12 V/0.0 3 A)
W-12
Pin 12
Pin 10
1
9
0.45
Out 4 (-26 V/0.05 A)
W-26
Pin1 0
Pin 13
1
10
0.3
Out 5 (5 Vstb/0. 1 A)
Wstb
Pin 9
Pin 8
1
12
0.3
Out 6 (3. 3V/0.15 A)
W3v3
Pin 14
Pin 15
1
3
0.3
Auxiliary
Waux
Pin 6
Pin 5
1
24
0.3
(mm)
Figure 13. Winding construction diagram
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5
PCB layout
PCB layout
Figure 14. Bottom view of the evaluation board (not in scale)
Figure 15. PCB art work (not in scale)
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PCB layout
AN1897
Table 6. Bill of materials
Reference
Description
Note
U1
Optocoupler PC817
Sharp
U2
VIPer22A-E DIP
ST
U3
TL431 ACZ
ST
U4
L4931 ABV33
ST
Q1
SS9014
Q3
SS8550
D1, D2, D3, D4
1N4007
D5
FR157
D6, D7, D9, D10, D13 STTH102
D8
D11, D12
C1, C2
STPS5L60
ST
1N5818
ST
Y1 capacitor 2200 pF
C3
X2 capacitor 0.1 uF
C4
Electrolytic capacitor 100 uF/400 V
C5, C8
1 nF/1 kV
C6
Ceramic capacitor 47 nF/50 V
C7
Electrolytic capacitor 47 uF/50 V
C9
Electrolytic capacitor 220 uF/50 V
C10
Ceramic capacitor 47 pF/50V
C12
Electrolytic capacitor 1000 uF/16 V
C13
Electrolytic capacitor 470 uF/16 V
C15
Electrolytic capacitor 100 uF/10 V
C17
Electrolytic capacitor 470 uF/25 V
C19
Electrolytic capacitor 470 uF/25 V
C20
Electrolytic capacitor 220 uF/50 V
C25
Electrolytic capacitor 220 uF/16 V
RT1
Not fit
R2
9.1 K¼ W
R3
100 K 1 W
R4, R5, R6
14/17
ST
1 K¼ W
R8, R9
5.1 K¼ W
R11
680 ¼ W
CH1
2.2 mH common choke
TX1
EER28 transformer
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PCB layout
Table 6. Bill of materials (continued)
Reference
F1
Description
Note
Fuse 1 A
J1, J2
2-pin connector
J3
5-pin connector
J4
4-pin connector
J5
9-pin connector
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Revision history
6
AN1897
Revision history
Table 7. Document revision history
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Date
Revision
12-Nov-2014
2
Changes
Updated the title in cover page.
Content reworked to improve readability, no technical
changes.
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