Infineon-ANICE2QR1080G-AN-v01_00-EN

28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
About this document
Scope and purpose
This document is an engineering report that describes universal input 28 W 12 V off-line flyback converter using
Infineon Quasi-Resonant CoolSET™ ICE2QR1080G which offers high efficiency, very low standby power, wider
VVCC operating range and various mode of protections for a high reliable system. This demonstrator board is
designed for users who wish to evaluate the performance of ICE2QR1080G in ease of use.
Intended audience
This document is intended for power supply design/application engineer, students, etc.) who wish to design
low cost and high reliable systems of off-line Switched Mode Power Supply (SMPS) for enclosed adapter, bluray/DVD player, set-top box, game console, smart meter, auxiliary power supply of white goods, PC, server, etc.
Table of Contents
About this document ....................................................................................................................... 1
Table of Contents ........................................................................................................................... 1
1
Abstract ........................................................................................................................ 3
2
Demonstrator board ...................................................................................................... 4
3
Specifications of Demonstrator Board.............................................................................. 5
4
4.1
4.2
4.3
4.4
4.5
4.6
4.7
4.8
4.9
Circuit description ......................................................................................................... 6
Line input ....................................................................................................................................................... 6
Start up ........................................................................................................................................................... 6
Integrated MOSFET and PWM control ......................................................................................................... 6
RCD clamper circuit ....................................................................................................................................... 6
Output stage .................................................................................................................................................. 6
Feedback loop ............................................................................................................................................... 6
Primary side peak current control ............................................................................................................... 7
Digital frequency reduction.......................................................................................................................... 7
Active burst mode ......................................................................................................................................... 7
5
5.1
5.2
5.3
5.4
5.5
Protection features ........................................................................................................ 8
VVCC over voltage and under voltage protection ......................................................................................... 8
Over load/Open loop protection ................................................................................................................. 8
Over temperature protection....................................................................................................................... 8
Adjustable output overvoltage protection ................................................................................................. 8
Short winding protection ............................................................................................................................. 8
6
Circuit diagram.............................................................................................................. 9
7
7.1
7.2
PCB layout ...................................................................................................................11
Top side ........................................................................................................................................................ 11
Bottom side .................................................................................................................................................. 11
8
Bill of material..............................................................................................................12
9
Transformer construction ..............................................................................................13
Application Note
www.infineon.com
Please read the Important Notice and Warnings at the end of this document
Revision 1.0
2016-04-15
28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Abstract
10
10.1
10.2
10.3
10.4
10.5
10.6
10.7
10.8
10.9
Test results ..................................................................................................................14
Efficiency, regulation and output ripple ................................................................................................... 14
Standby power............................................................................................................................................. 16
Line regulation ............................................................................................................................................. 16
Load regulation ........................................................................................................................................... 17
Maximum input power ................................................................................................................................ 17
ESD immunity (EN61000-4-2) ..................................................................................................................... 17
Surge immunity (EN61000-4-5) .................................................................................................................. 17
Conducted emissions (EN55022 class B) .................................................................................................. 18
Thermal measurement ............................................................................................................................... 20
11
11.1
11.2
11.3
11.4
11.5
11.6
11.7
11.8
11.9
11.10
11.11
Waveforms and scope plots ...........................................................................................21
Startup at low/high AC line input voltage with maximum load ............................................................. 21
Soft start ....................................................................................................................................................... 21
Drain and current sense voltage at maximum load................................................................................. 22
Zero crossing point during normal operation .......................................................................................... 22
Load transient response (Dynamic load from 10% to 100%) ................................................................. 23
Output ripple voltage at maximum load .................................................................................................. 23
Output ripple voltage at burst mode 1 W load ......................................................................................... 24
Active burst mode ....................................................................................................................................... 24
Over load protection (Auto Restart) .......................................................................................................... 25
VCC under voltage/Short optocoupler protection (Auto Restart).......................................................... 25
Output overvoltage protection (Latch mode) .......................................................................................... 26
12
References ...................................................................................................................27
Revision History ............................................................................................................................27
Application Note
2
Revision 1.0
2016-04-15
28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Abstract
1
Abstract
This application note is an engineering report of 28 W 12V demo board designed in a quasi resonant flyback
converter topology using ICE2QR1080G Quasi-resonant CoolSET™ .The target applications of ICE2QR1080G are
set-top box, portable game controller, Blue-Ray/DVD player, netbook adapter and auxiliary power supply of PC,
printer, TV, home theater/audio system, etc. With the CoolMOS™ integrated in this IC, it greatly simplifies the
design and layout of the PCB. Due to valley switching, the turn on voltage is reduced and this offers higher
conversion efficiency comparing to hard-switching flyback converter. With the DCM mode control, the reverse
recovery problem of secondary rectify diode is relieved. And for its natural frequency jittering with line voltage,
the EMI performance is better. Infineon’s digital frequency reduction technology enables a quasi-resonant
operation till very low load. As a result, the system efficiency, over the entire load range, is significantly
improved compared to conventional free running quasi resonant converter implemented with only maximum
switching frequency limitation at light load. In addition, numerous adjustable protection functions have been
implemented in ICE2QR1080G to protect the system and customize the IC for the chosen application. In case of
failure modes, like open control-loop/over load, output overvoltage, and transformer short winding, the device
switches into Auto Restart Mode or Latch-off Mode. By means of the cycle-by-cycle peak current limitation plus
foldback point correction, the dimension of the transformer and current rating of the secondary diode can both
be optimized.Thus, a cost effective solution can be easily achieved
Application Note
3
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Demonstrator board
2
Demonstrator board
This document contains the list of features, the power supply specification, schematic, bill of material and the
transformer construction documentation. Typical operating characteristics such as performance curve and
scope waveforms are showed at the rear of the report.
Figure 1
DEMO-2QR1080G (Top View)
ICE2QR1080G
Figure 2
DEMO-2QR1080G (Bottom view)
Application Note
4
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Specifications of Demonstrator Board
3
Table 1
Specifications of Demonstrator Board
Specifications of DEMO-2QR1080G
Input voltage and frequency
85 VAC (60 Hz) ~ 265 VAC (50Hz)
Output voltage, current and power
12 V, 2.33 A, 28 W
Dynamic load response
(10% to 100% load, slew rate at 1.5 A/µs, 100 Hz)
±3% of nominal output voltage
(Vripple_p_p < 280 mV)
Output ripple voltage
(full load, 85 VAC ~ 265 VAC)
±1% of nominal output voltage
(Vripple_p_p< 60 mV)
Active mode four point average efficiency (25%, 50%, 75%,
100% load) (EU CoC Version 5, Tier 1)
> 86% at 115 VAC and > 87% 230 VAC
10% load efficiency (EU CoC Version 5, Tier 1)
> 84% at 115 VAC and 230 VAC
No load power consumption (EU CoC Version 5, Tier 1)
< 50 mW at 265 VAC
Conducted emissions (EN55022 class B)
Pass with 10 dB margin for 115 VAC and 6 dB
margin for 230 VAC
ESD immunity (EN61000-4-2)
Special Level (±16 kV for both contact and air
discharge)
Surge immunity (EN61000-4-5)
Installation class 4 (±2 kV for line to line and ±4 kV
for line to earth)
Form factor case size (L x W x H)
(120 x 52 x 26) mm3
Application Note
5
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Circuit description
4
Circuit description
4.1
Line input
The AC line input side comprises the input fuse F1 as over-current protection. The choke L11, X-capacitor C11
and Y-capacitor C12 act as EMI suppressors. Optional spark gap devices SA1, SA2 and varistor VAR can absorb
high voltage stress during lightning surge test. A rectified DC voltage (120~374 VDC) is obtained through the
bridge rectifier BR1 together with bulk capacitor C13.
4.2
Start up
Since there is a built-in startup cell in the ICE2QR1080G, there is no need for external start up resistor, which
can improve standby performance significantly.
When VVCC reaches the turn on voltage threshold 18V, the IC begins with a soft start. The soft-start implemented
in ICE2QR1080G is a digital time-based function. The preset soft-start time is 12 ms with 4 steps. If not limited
by other functions, the peak voltage on CS pin will increase step by step from 0.32 V to 1 V finally. After IC turns
on, the VVCC voltage is supplied by auxiliary windings of the transformer.
4.3
Integrated MOSFET and PWM control
ICE2QR1080G is comprised of a power MOSFET and the Quasi-Resonant controller; this integrated solution
greatly simplifies the circuit layout and reduces the cost of PCB manufacturing. The PWM switch-on is
determined by the zero-crossing input signal and the value of the up/down counter. The PWM switch-off is
determined by the feedback signal VFB and the current sensing signal VCS. ICE2QR1080G also performs all
necessary protection functions in flyback converters. Details about the information mentioned above are
illustrated in the product datasheet.
4.4
RCD clamper circuit
A clamper network (R11, C15 and D11) dissipates the energy of the leakage inductance and suppress ringing on
the SMPS transformer.
4.5
Output stage
On the secondary side, 12 V output, the power is coupled out via a schottky diode D21. The capacitor C22 and
C23 provides energy buffering followed by the L-C filters L21 and C24 to reduce the output ripple and prevent
interference between SMPS switching frequency and line frequency considerably. Storage capacitor C22 and
C23 is designed to have an internal resistance (ESR) as small as possible. This is to minimize the output voltage
ripple caused by the triangular current.
4.6
Feedback loop
For feedback, the output is sensed by the voltage divider of R26 and R25 and compared to IC21 (TL431) internal
reference voltage. C25, C26 and R24 comprise the compensation network. The output voltage of IC21 (TL431) is
converted to the current signal via optocoupler IC12 and two resistors R22 and R23 for regulation control.
Application Note
6
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Circuit description
4.7
Primary side peak current control
The MOSFET drain source current is sensed via external resistor R14 and R14A. Since ICE2QR1080G is a current
mode controller, it would have a cycle-by-cycle primary current and feedback voltage control which can make
sure the maximum power of the converter is controlled in every switching cycle.
For a Quasi-Resonant flyback converter, the maximum possible output power is increased when a constant
current limit value is used for all the line input voltage range. This is usually not desired as this will increase
additional cost on transformer and output diode in case of output over power conditions.
The internal foldback point correction is implemented to adjust the VCS voltage limit according to the input line
voltage. Here, the input line voltage is sensed using the current flowing out of ZC pin, during the MOSFET ontime. As the result, the maximum current limit will be lower at high input voltage and the maximum output
power can be well limited versus the input voltage.
4.8
Digital frequency reduction
During normal operation, the switching frequency for ICE2QR1080G is digitally reduced with decreasing load. At
light load, the MOSFET will be turned on not at the first minimum drain-source voltage time, but on the nth. The
counter is in range of 1 to 7, which depends on feedback voltage in a time-base. The feedback voltage
decreases when the output power requirement decreases, and vice versa. Therefore, the counter is set by
monitoring voltage VFB. The counter will be increased with low VFB and decreased with high VFB. The thresholds
are preset inside the IC.
4.9
Active burst mode
At light load condition, the SMPS enters into Active Burst Mode. At this stage, the controller is always active but
the VVCC must be kept above the switch off threshold. During active burst mode, the efficiency increase
significantly and at the same time it supports low ripple on Vout and fast response on load jump.
For determination of entering Active Burst Mode operation, three conditions apply:
1. The feedback voltage is lower than the threshold of V FBEB(1.25 V). Accordingly, the peak current sense
voltage across the shunt resistor is 0.17;
2. The up/down counter is 7;
3. And a certain blanking time (tBEB=24 ms).
Once all of these conditions are fulfilled, the Active Burst Mode flip-flop is set and the controller enters Active
Burst Mode operation. This multi-condition determination for entering Active Burst Mode operation prevents
mis-triggering of entering Active Burst Mode operation, so that the controller enters Active Burst Mode
operation only when the output power is really low during the preset blanking time.
During active burst mode, the maximum current sense voltage is reduced from 1 V to 0.34 V so as to reduce the
conduction loss and the audible noise. At the burst mode, the FB voltage is changing like a sawtooth between
3.0 V and 3.6 V.
The feedback voltage immediately increases if there is a high load jump. This is observed by one comparator.
As the current limit is 34% during Active Burst Mode a certain load is needed so that feedback voltage can
exceed VFBLB (4.5 V). After leaving active burst mode, maximum current can now be provided to stabilize Vout. In
addition, the up/down counter will be set to 1 immediately after leaving Active Burst Mode. This is helpful to
decrease the output voltage undershoot.
Application Note
7
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Protection features
5
Protection features
5.1
VVCC over voltage and under voltage protection
During normal operation, the VCC voltage is continuously monitored. When the VCC voltage increases up to
VCC,OVP or VCC voltage falls below the under voltage lock out level V CC,off, the IC will enter into autorestart mode.
5.2
Over load/Open loop protection
In case of open control loop, feedback voltage is pulled up with internally block. After a fixed blanking time, the
IC enters into auto restart mode. In case of secondary short-circuit or overload, regulation voltage VFB will also
be pulled up, same protection is applied and IC will auto restart.
5.3
Over temperature protection
The IC has a built-in over temperature protection function. When the controller’s temperature reaches 140°C,
the IC will shut down switch and enters into auto restart. This can protect power MOSFET from overheated.
5.4
Adjustable output overvoltage protection
During off-time of the power switch, the voltage at the zero-crossing pin ZC is monitored for output overvoltage
detection. If the voltage is higher than the preset threshold 3.7 V for a preset period 100 μs, the IC is latched off.
5.5
Short winding protection
The source current of the MOSFET is sensed via external resistor R14 and R14A. If the voltage at the current
sensing pin is higher than the preset threshold V CSSW of 1.68 V during the on-time of the power switch, the IC is
latched off. This constitutes a short winding protection. To avoid an accidental latch off, a spike blanking time
of 190 ns is integrated in the output of internal comparator.
Table 2
Protection function of ICE2QR1080G
Protection Function
Failure Condition
Protection Mode
VCC Overvoltage
VVCC > 25 V & last for 10 μs (normal
mode only)
Auto Restart
VCC Undervoltage/ Short
Optocoupler
VVCC < 10.5 V
Auto Restart
Overload/Open Loop
VFB > 4.5 V & last for 30 ms
Auto Restart
Over Temperature (Controller
Junction)
TJ > 140 °C
Auto Restart
Output Overvoltage
VZCOVP > 3.7 V & last for 100 μs
Latch
Short Winding
VCSSW > 1.68 V & last for 190 ns
Latch
Application Note
8
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Circuit diagram
6
Figure 3
Circuit diagram
Schematic of DEMO-2QR1080G
Application Note
9
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Circuit diagram
Note:
1.
2.
3.
4.
5.
General guideline for layout design of Printed Cirduit Board (PCB):
Star ground at bulk capacitor C13: all primary grounds should be connected to the ground of bulk capacitor
C13 seperately in one point. It can reduce the switching noise going into the sensitive pins of CoolSET™ device
effectively. The primary star ground can be split into five groups as follows,
i. Signal ground includes all small signal grounds connecting to the CoolSET™ GND pin such as filter
capacitor ground C17, C18, C19 and opto-coupler ground.
ii. VCC ground includes the VCC capacitor ground C16 and the auxiliary winding ground, pin 5 of the
power transformer.
iii. Current Sense resistor ground includes current sense resistor R14 and R14A.
iv. EMI return ground includes Y capacitor C12.
v. DC ground from bridge rectifier, BR1
Filter capacitor close to the controller ground: Filter capacitors, C17, C18 and C19 should be placed as close to
the controller ground and the controller pin as possible so as to reduce the switching noise coupled into the
controller.
High voltage traces clearance: High voltage traces should keep enough spacing to the nearby traces.
Otherwise, arcing would incur.
i. 400 V traces (positive rail of bulk capacitor C13) to nearby trace: > 2.0 mm
ii. 600V traces (drain voltage of CoolSET™ IC11) to nearby trace: > 2.5 mm
Recommended minimum 232mm2 copper area at drain pin to add on PCB for better thermal performance.
Power loop area (bulk capacitor C13, primary winding of the transformer TR1 (Pin 1 and 3), IC11 Drain pin,
IC11 CS pin and current sense resistor R14/R14A) should be as small as possible to minimize the switching
emission.
Application Note
10
Revision 1.0
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
PCB layout
7
PCB layout
7.1
Top side
Figure 4
Top side component legend
7.2
Figure 5
Bottom side
Bottom side copper and component legend
Application Note
11
Revision 1.0
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Bill of material
8
Bill of material
Table 3
Bill of material (V0.2)
No.
Designator
Description
Part Number
Manufacturer
1
BR1
600V/2A
DS2B60A
Shindengen
1
2
C11
0.22µF/305V
B32922C3224
Epcos
1
3
C12
2.2nF/250V
DE1E3KX222MA4BN01F
Murata
1
4
C13
82µF/450V
450BXW82MEFC16X35
Rubycon
1
5
C15
1nF/600V
GRM31A7U2J102JW31D9
Murata
1
6
C16
22µF/50V
50PX22MEFC5X11
Rubycon
1
7
C17
100nF/50V
GRM188R71H104KA93D
Murata
1
8
C18, C26
1nF/50V
GRM1885C1H102GA01D
Murata
2
9
C19
39pF/50V
GRM1885C1H390GA01D
Murata
1
10
C22, C23
1200uF/16V
16ZLK1200M10X20
Rubycon
2
11
C24
680uF/16V
16ZLH680MEFC8X16
Rubycon
1
12
C25
220nF/50V
GRM188R71H224KAC4D
Murata
1
13
D11
0.8A/600V
D1NK60
Shindengen
1
14
D12
0.25A/200V
BAS21-03W
Infineon
1
15
D21
30A/100V
STPS30M100SFP
1
16
F1
1.6A/300V
36911600000
1
17
HS1
Heat Sink(D21)
574502B03300G
1
18
IC11
ICE2QR1080G(DSO-16/12)
ICE2QR1080G
19
IC12
SFH617A-3((DIP-4)
SFH617A-3
1
20
IC21
TL431ABVLPG(TO-92)
TL431ABVLPG
1
21
L11
47mH/0.65A
750342434
Wurth Electronics
1
22
L21
2.2uH/4.3A
744 746 202 2
Wurth Electronics
1
23
R11
68k/2W/500V
RSF200JB-73-68K
1
24
R12, R13
10Ω(0603)
10Ω(0603)
2
25
R14, R14A
1.1Ω/0.75W
ERJB2BF1R1V
2
26
R15
36kΩ/0603
0603
1
27
R16
8.3kΩ/0603
0603
1
28
R22
820Ω/0603
0603
1
29
R23
1.2kΩ/0603
0603
1
30
R24
68kΩ/0603
0603
1
31
R25
38kΩ/0603(1%)
0603(1%)
1
32
R26
10kΩ/0603(1%)
0603(1%)
1
33
TR1
639µH(72:11:14)
750343051
34
Test point
BA,FB,CS,Drain,Vcc,Gnd
5003
35
VAR
300V/0.25W
B72207S2301K101
36
ZD11
22V Zener
UDZS22B
37
(L N),
(+12V Com)
Connector
691102710002
Application Note
12
Infineon
Wurth Electronics
Quantity
1
1
1
Epcos
1
1
Wurth Electronics
2
Revision 1.0
2016-04-15
28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Transformer construction
9
Transformer construction
Core and material: EE25/13/7(EF25), TP4A (TDG)
Bobbin: 14-Pins, THT, horizontal version (070-5644)
Primary Inductance: LP = 639 µH (±10%), measured between pin 1 and pin 3
Manufacturer and part number: Wurth Electronics Midcom (750343051)
Figure 6
Start
Stop
No. of turns
Wire size
3
14
2
12
36
11
1xAWG#27
1xLitz TIW(7xAWG#29)
1
Layer
2
1
36
1xAWG#27
1
7
6
14
1xAWG#30
/2 Primary
Secondary
/2 Primary
Auxiliary
Transformer structure
Application Note
13
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Test results
10
Test results
10.1
Efficiency, regulation and output ripple
Table 4
Efficiency, regulation & output ripple
Input
(VAC/Hz)
85 VAC/60 Hz
115 VAC/60 Hz
230 VAC/50 Hz
265VAC/50 Hz
Application Note
Pout
(W)
Efficiency
(η) (%)
50.31
2.83
85.79
0.58
9.02
7.08
86.31
12.15
1.17
15.82
14.15
85.22
25.03
12.15
1.75
18.53
21.23
84.83
34.16
12.15
2.33
32.36
28.31
82.87
0.03064
12.15
0.00
42.44
3.28
12.15
0.23
51.69
2.83
86.31
8.14
12.15
0.58
8.27
7.08
86.95
16.31
12.15
1.17
13.29
14.15
86.79
24.45
12.15
1.75
13.73
21.23
86.84
32.87
12.15
2.33
19.33
28.31
86.13
0.03217
12.15
0.00
46.80
3.31
12.15
0.23
55.07
2.83
85.53
8.27
12.15
0.58
8.49
7.08
85.58
16.15
12.15
1.17
10.58
14.15
87.65
24.03
12.15
1.75
11.51
21.23
88.36
31.96
12.15
2.33
17.47
28.31
88.58
0.03342
12.15
0.00
45.78
3.33
12.15
0.23
57.38
2.83
85.01
8.35
12.15
0.58
8.62
7.08
84.76
16.20
12.15
1.17
10.31
14.15
87.38
24.05
12.15
1.75
11.82
21.23
88.28
31.98
12.15
2.33
12.40
28.31
88.52
Pin
(W)
Vout
(VDC)
Iout
(A)
VOutRPP
(mV)
0.03115
12.15
0.00
42.80
3.30
12.15
0.23
8.20
12.15
16.61
14
Average
η (%)
OLP Pin
(W)
OLP Iout
(A)
44.73
2.99
43.62
3.06
44.51
3.26
44.8
3.29
84.81
86.67
87.54
87.23
Revision 1.0
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Test results
Figure 7
Efficiency vs AC line input voltage
Figure 8
Efficiency vs output power at 115 VAC and 230 VAC line
Application Note
15
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Test results
10.2
Figure 9
Standby power
Standby power at no load vs AC line input voltage (measured by Yokogawa WT210 power
meter - integration mode)
10.3
Figure 10
Line regulation
Line regulation Vout at full load vs AC line input voltage
Application Note
16
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Test results
10.4
Figure 11
Load regulation
Load regulation Vout vs output power
10.5
Figure 12
Maximum input power
Maximum input power (before over-load protection) vs AC line input voltage
10.6
ESD immunity (EN61000-4-2)
Pass EN61000-4-2 Special Level (±16 kV for both contact and air discharge).
10.7
Surge immunity (EN61000-4-5)
Pass EN61000-4-5 Installation class 4 (±2 kV for line to line and ±4 kV for line to earth)1.
1
HS1 change to ATS-PCBT1093
Application Note
17
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Test results
10.8
Conducted emissions (EN55022 class B)
The conducted EMI was measured by Schaffner (SMR4503) and followed the test standard of EN55022 (CISPR
22) class B. The demo board was set up at maximum load (28 W) with input voltage of 115 VAC and 230 VAC.
Figure 13
Conducted emissions(Line) at 115 VAC and maximum Load
Figure 14
Conducted emissions(Neutral) at 115 V AC and maximum Load
Pass conducted emissions EN55022 (CISPR 22) class B with 10 dB margin for quasi peak limit at low line (115
VAC).
Application Note
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Test results
Figure 15
Conducted emissions(line) at 230 VAC and maximum Load
Figure 16
Conducted emissions(Neutral) at 230 V AC and maximum Load
Pass conducted emissions EN55022 (CISPR 22) class B with 6 dB margin for quasi peak limit at high line (230
VAC).
Application Note
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Test results
10.9
Thermal measurement
The thermal test of open frame demo board was done using an infrared thermography camera (TVS-500EX) at
ambient temperature 25°C. The measurements were taken after two hours running at full load.
Table 5
Hottest temperature of demo board
No.
Major component
85 VAC (°C)
265 VAC (°C)
1
IC11 (2QR1080G)
62.5
55.4
2
R14 (current sense resistor)
52.2
40.4
3
TR1 (transformer)
57.5
58.8
4
BR1 (bridge diode)
53.8
33.4
5
R11(clamper resistor)
37.2
34.3
6
L11 (EMI choke)
97.9
36.9
7
D21 (secondary diode)
61.5
61.6
8
Ambient
25
25
.
Figure 17
85 VAC full load and 25⁰C ambient
265 VAC full load and 25⁰C ambient
PCB top side
PCB top side
PCB bottom side
Infrared thermal image of DEMO-2QR1080G
PCB bottom side
Figure 18
Application Note
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Waveforms and scope plots
11
Waveforms and scope plots
All waveforms and scope plots were recorded with a TELEDYNELECROY 606Zi oscilloscope.
11.1
C1 (Yellow)
C2 (Purple)
C2 (Blue)
C2 (Green)
Startup at low/high AC line input voltage with maximum load
: Drain voltage (VD)
: Supply voltage (VVCC)
: Feedback voltage (VFB)
: Zero crossing voltage (VZC)
C1 (Yellow)
C2 (Purple)
C2 (Blue)
C2 (Green)
Startup time at 85 VAC and maximum load ≈ 500 ms
Figure 19 Startup
11.2
C1 (Yellow)
C2 (Purple)
C2 (Blue)
C2 (Green)
: Drain voltage (VD)
: Supply voltage (VVCC)
: Feedback voltage (VFB)
: Zero crossing voltage (VZC)
Startup time at 265 VAC and maximum load ≈ 500 ms
Soft start
: Current sense voltage (VCS)
: Supply voltage (VVCC)
: Feedback voltage (VFB)
: Zero crossing voltage (VZC)
Soft start time at 85 VAC and maximum load ≈ 13 ms
Figure 20 Soft start
Application Note
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Waveforms and scope plots
11.3
C1 (Yellow)
C2 (Purple)
Drain and current sense voltage at maximum load
: Drain voltage (VDrain)
: Current sense voltage (VCS)
C1 (Yellow)
C2 (Purple)
: Drain voltage (VDrain)
: Current sense voltage (VCS)
VDrain_peak at 85 VAC ≈ 321 V
VDrain_peak at 265 VAC ≈ 587 V
Figure 21 Drain and current sense voltage at maximum load
11.4
C1 (Yellow)
C2 (Purple)
Zero crossing point during normal operation
: Drain voltage (VDrain)
: Current sense voltage (VCS)
2nd zero crossing at 85 VAC
Figure 22 Zero corssing
Application Note
C1 (Yellow)
C2 (Purple)
: Drain voltage (VDrain)
: Current sense voltage (VCS)
7th zero crossing at 85 VAC
22
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Waveforms and scope plots
11.5
Load transient response (Dynamic load from 10% to 100%)
C1 (Yellow)
: Output ripple voltage (Vout)
C2 (Purple)
: Output current (Iout)
Vripple_pk_pk at 85 VAC ≈ 206 mV
(Load change from 10% to 100% at 85 VAC,100 Hz,0.4
A/μs slew rate)
Probe terminal end with decoupling capacitor of 0.1
μF(ceramic) and 1 μF(Electrolytic), 20 MHz filter
Figure 23 Load transient response
11.6
C1 (Yellow)
C2 (Purple)
C1 (Yellow)
: Output ripple voltage (Vout)
C2 (Purple)
: Output current (Iout)
Vripple_pk_pk at 265 VAC ≈ 279 mV
(Load change from10% to 100% at 2100 VAC,100 Hz,0.4
A/μs slew rate)
Probe terminal end with decoupling capacitor of 0.1
μF(ceramic) and 1 μF(Electrolytic), 20 MHz filter
Output ripple voltage at maximum load
: Output ripple voltage (Vout)
: Output current (Iout)
C1 (Yellow)
C2 (Purple)
: Output ripple voltage (Vout)
: Output current (Iout)
Vripple_pk_pk at 85 VAC ≈ 23 mV
Vripple_pk_pk at 265 VAC ≈ 13 mV
Probe terminal end with decoupling capacitor of 0.1 Probe terminal end with decoupling capacitor of 0.1
μF(ceramic) and 1 μF(Electrolytic), 20 MHz filter
μF(ceramic) and 1 μF(Electrolytic), 20 MHz filter
Figure 24 Output ripple voltage at maximum load
Application Note
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Waveforms and scope plots
11.7
C1 (Yellow)
C2 (Purple)
Output ripple voltage at burst mode 1 W load
: Output ripple voltage (Vout)
: Output current (Iout)
C1 (Yellow)
C2 (Purple)
: Output ripple voltage (Vout)
: Output current (Iout)
Vripple_pk_pk at 85 VAC ≈ 51 mV
Vripple_pk_pk at 265 VAC ≈ 59 mV
Probe terminal end with decoupling capacitor of 0.1
Probe terminal end with decoupling capacitor of 0.1
μF(ceramic) and 1 μF(Electrolytic), 20 MHz filter
μF(ceramic) and 1 μF(Electrolytic), 20 MHz filter
Figure 25 Output ripple voltage at burst mode 1 W load
11.8
Active burst mode
C1 (Yellow)
: Current sense voltage (VCS)
C2 (Purple)
: Supply voltage (VVCC)
C2 (Blue)
: Feedback voltage (VFB)
C2 (Green)
: Zero crossing voltage (VZC)
Condition to enter burst: VFB<1.2 V, NZC=7 and
tblanking =24 ms
(load change form full load to 1 W load at 85 VAC)
Figure 26 Active burst mode
Application Note
C1 (Yellow)
: Current sense voltage (VCS)
C2 (Purple)
: Supply voltage (VVCC)
C2 (Blue)
: Feedback voltage (VFB)
C2 (Green)
: Zero crossing voltage (VZC)
Condition to leave burst: VFB>4.5 V
(load change form full load to 1 W to full load at 85 VAC)
24
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Waveforms and scope plots
11.9
Over load protection (Auto Restart)
C1 (Yellow)
: Drain voltage (VD)
C2 (Purple)
: Supply voltage (VVCC)
C2 (Blue)
: Feedback voltage (VFB)
C2 (Green)
: Zero crossing voltage (VZC)
Condition to enter over load protection: VFB>4.5 V & last for 40ms blanking time
(output load change from 2.33 A to 3.5 A at 85 VAC)
Figure 27 Over load protection
11.10
VCC under voltage/Short optocoupler protection (Auto Restart)
C1 (Yellow)
: Drain voltage (VD)
C2 (Purple)
: Supply voltage (VVCC)
C2 (Blue)
: Feedback voltage (VFB)
C2 (Green)
: Zero crossing voltage (VZC)
Condition to enter VCC under voltage protection: VCC < 10.5 V
(short the transistor of optocoupler(Pin 3 and 4 of IC12) during system operating at full load and release at 85
VAC)
Figure 28 VCC under voltage/short optocoupler protection
Application Note
25
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
Waveforms and scope plots
11.11
Output overvoltage protection (Latch mode)
C1 (Yellow)
: Output voltage (Vout)
C2 (Purple)
: Supply voltage (VVCC)
C2 (Blue)
: Feedback voltage (VFB)
C2 (Green)
: Zero crossing voltage (VZC)
Condition to enter external protection enable: Vout >14 V (VZC>3.7 V)
(85 VAC, short R26 during while system operation at no load)
Figure 29 External auto restart enableOutput overvoltage protection
Application Note
26
Revision 1.0
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28W 12V SMPS Demo Board with ICE2QR1080G
AN-DEMO-2QR1080G
References
12
References
[1]
ICE2QR1080G datasheet, Infineon Technologies AG
[2]
AN-PS0025-CoolSET F3R DIP-8, DIP-7, DSO-16/12 new jitter version design guide-V2.2
Revision History
Major changes since the last revision
Page or Reference
--
Application Note
Description of change
First release.
27
Revision 1.0
2016-04-15
Trademarks of Infineon Technologies AG
AURIX™, C166™, CanPAK™, CIPOS™, CoolGaN™, CoolMOS™, CoolSET™, CoolSiC™, CORECONTROL™, CROSSAVE™, DAVE™, DI-POL™, DrBlade™, EasyPIM™,
EconoBRIDGE™, EconoDUAL™, EconoPACK™, EconoPIM™, EiceDRIVER™, eupec™, FCOS™, HITFET™, HybridPACK™, Infineon™, ISOFACE™, IsoPACK™,
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Trademarks updated August 2015
Other Trademarks
All referenced product or service names and trademarks are the property of their respective owners.
Edition 2016-04-15
Published by
Infineon Technologies AG
81726 Munich, Germany
©ANDEMO_201510_PL21_004owners.
2016 Infineon Technologies AG.
All Rights Reserved.
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document?
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Document reference
ANDEMO_201510_PL21_006
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