POWERINT DER-39

Design Example Report
Title
2.5W Adapter using LNK520P
Specification
Input: 90-265Vac
Output: 5.5V / 450mA
Application
Cell Phone Charger
Author
Power Integrations Applications Department
Document
Number
DER-39
Date
May 13, 2004
Revision
1.0
Summary and Features
•
•
•
•
•
•
•
•
No optocoupler
Provides sloping output VI characteristic, making it an ideal low standby power
replacement for a linear transformer
Uses an EF12.6 transformer
No Y1 safety capacitor required, giving very low earth leakage current
Meets CISPR-22B with large margin
Low component count
Less than 300mW standby consumption at 230 VAC
High efficiency
The products and applications illustrated herein (including circuits external to the products and transformer
construction) may be covered by one or more U.S. and foreign patents or potentially by pending U.S. and foreign
patent applications assigned to Power Integrations. A complete list of Power Integrations’ patents may be found
at www.powerint.com.
Power Integrations
5245 Hellyer Avenue, San Jose, CA 95138 USA.
Tel: +1 408 414 9200 Fax: +1 408 414 9201
www.powerint.com
DER-39
2.5W Adapter LNK520P
May 13, 2004
Table Of Contents
1
2
3
4
Introduction.................................................................................................................3
Power Supply Specification ........................................................................................4
Schematic...................................................................................................................5
Circuit Description ......................................................................................................6
4.1
Input EMI Filtering ...............................................................................................6
4.2
LinkSwitch Operation ..........................................................................................6
4.3
Clamp and Feedback Components .....................................................................7
4.4
Output Stage .......................................................................................................8
5 PCB Layout ................................................................................................................9
6 Bill Of Materials ........................................................................................................10
7 Transformer Specification.........................................................................................11
7.1
Transformer Winding .........................................................................................11
7.2
Electrical Specifications.....................................................................................11
7.3
Transformer Construction..................................................................................12
7.4
Winding Instructions ..........................................................................................12
7.5
Materials............................................................................................................13
7.6
Design Notes.....................................................................................................13
8 Performance Data ....................................................................................................14
8.1
Efficiency ...........................................................................................................14
8.2
No-load Input Power..........................................................................................15
8.3
Line and Load Regulation..................................................................................15
9 Thermal Performance...............................................................................................17
10
Waveforms............................................................................................................18
10.1 Drain Voltage and Current, Normal Operation...................................................18
10.2 Output Ripple Measurements............................................................................19
10.2.1 Ripple Measurement Technique ................................................................19
10.2.2 Measurement Results ................................................................................20
11
Conducted EMI .....................................................................................................21
12
Revision History ....................................................................................................23
Important Note:
Although this board is designed to satisfy safety isolation requirements, the engineering
prototype has not been agency approved. Therefore, all testing should be performed
using an isolation transformer to provide the AC input to the prototype board.
Design Reports contain a power supply design specification, schematic, bill of materials,
and transformer documentation. Performance data and typical operation characteristics
are included. Typically only a single prototype has been built.
Page 2 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
1 Introduction
This document is an engineering report giving performance characteristics of a prototype
2.5W charger/adapter optimized to replace a linear transformer. The supply uses
LinkSwitch (LNK520P) – an integrated IC combining a 700V high voltage MOSFET,
PWM controller, start-up, thermal shutdown, and fault protection circuitry.
Using LNK520P in the high side switching gives a sloping VI-characteristic with no
optocoupler. The design used no Y-cap, but has very low EMI emissions.
This document contains the power supply specification, schematic, bill of materials,
transformer documentation, and performance data.
Figure 1 – Populated Circuit Board Photograph
Page 3 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
2 Power Supply Specification
Description
Symbol
Min
Typ
Max
Units
VIN
fLINE
90
47
50/60
265
64
0.3
Vac
Hz
W
Comment
Input
Voltage
Frequency
No-load Input Power (230Vac)
Output
Output Voltage 1
VOUT
5.5
V
see Figure 1
Output Current 1
IOUT
0.45
A
see Figure 1
Continuous Output Power
POUT
2.5
W
Efficiency
Operating Temperature
Conducted EMI
η
TAMB
67
-5
50
2 Wire- No protective ground
%
C
At full load @ 230V
CISP22B/EN55022B with Artificial hand connected to output return
Table 1 – Typical Power Supply Specification
V-I CHARACTERISTIC
10
9
HLIMIT
8
LLIMIT
7
Vout
6
5
4
3
2
1
0
0
100
200
300
400
500
600
700
800
900
1000
Iload
Figure 2 - Output V-I Characteristic Envelope Specification
Page 4 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
3 Schematic
Figure 3 – Schematic
** optional parts are not installed on the board
Page 5 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
4 Circuit Description
The schematic shown in the Figure 3 provides a CV/CC (constant voltage and constant
current) output characteristic form the universal input voltage range of 90 VAC to 265
VAC. The nominal peak power point at the transition from CC to CV is 5.5 V at 450 mA.
The output envelope specification is shown is Figure 2.
4.1
Input EMI Filtering
The incoming AC is rectified and filtered by D1-4, C1 and C2. Resistor RF1 is a
flameproof fusible type to protect against fault conditions and is requirement to meet
safety agency fault testing. This component should be a wire wound type to withstand
input current surges while the input capacitors charge on application of power or during
withstand line-transient testing. Metal film type resistors are not recommended, they do
not have the transient dissipation capabilities required and may fail prematurely in the
field.
The input capacitance is split between C1 and C2 to allow an input pi filter to be formed
by L1. This filters noise associated with the supply to meet EN55022B/CSPR 22 B and
FCC B conducted EMC limits, even when no Y safety capacitor is used.
4.2
LinkSwitch Operation
When the power is applied to the supply, high voltage DC appears at the DRAIN pin of
the LINKSWITCH (U1). The CONTROL pin capacitor C3 is then charged through a
switched high voltage current source connected internally between the DRAIN and
CONTROL pins. When the CONTROL pin voltage reaches approximately 5.7 V relative
to the SOURCE pin, the internal current source is turned off. The internal control circuitry
is activated and the high voltage internal MOSFET starts to switch, using the energy in
C3 to power the IC,
As the current ramps in the primary of the flyback transformer T1, energy is stored. This
energy is delivered to the output when the mosfet turns off each cycle.
The secondary of the transformer is rectified and filtered by D6 and C5 to provide the DC
output to the load.
Control of the output characteristic is entirely sensed from the primary-side by monitoring
the primary-side VOR (voltage output reflected). While the output diode is conducting,
the voltage across the transformer primary is equal to the output voltage plus diode drop
multiplied by the turns ratio of the transformer. Since the LinkSwitch is connected on the
high side of the transformer, VOR can be sensed directly.
Page 6 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
Diode D5 and capacitor C4 form the primary clamp network. The voltage held across C4
is essentially the VOR with an error due to the parasitic leakage inductance.
The LinkSwitch has three operating modes determined by the current flowing into the
CONTROL pin.
During start-up, as the output voltage, and therefore the reflected voltage and voltage
across C4 increases, the feedback current increases from 0 to approximately 2mA
through R1 in the CONTROL pin. The internal current limit is increased during this period
until reaching 100%, providing an approximately constant output current.
Once the output voltage reaches the regulated CV value, the output voltage is regulated
through control of the duty cycle. As the current into the CONTROL pin exceeds
approximately 2 mA, the duty cycle begins to reduce, reaching 30% at a CONTROL pin
current of 2.3mA.
If the duty cycle reaches a 3% threshold, the switching frequency is reduced, which
reduces energy consumption under light or no load conditions.
As the output load increases beyond the peak power point (defined by 1/2LI2f) and the
output voltage and the VOR falls, the reduced CONTROL pin current will lower the
internal current providing an approximately constant current characteristic. If the output
load is further increased and the output voltage fall further to below a CONTROL pin
current of 1mA, the CONTROL pin capacitor C3 will discharge and the supply will enter
auto-restart.
The transformer is designed to always be discontinuous; that is all the energy is
transferred to the load during the mosfet off time.
4.3
Clamp and Feedback Components
Diode D5 should either be a fast or ultra-fast type to prevent the voltage across the
LinkSwitch from reversing and ringing below ground. A fast diode is preferred, being
lower cost. Leakage inductance in filtered by R2.
Capacitor C4 is typically fixed at 0.1uF and should be rated above the VOR and be stable
with both temperature and applied voltage. Low-cost, Metallized plastic film capacitors
are ideal; high value, low-cost ceramic capacitors are not recommended. Dielectrics
used for these capacitors such as Z5U and Y5U are not stable and can cause output
instability as their value changes with voltage and temperature.
Page 7 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
R1 was selected to program the peak power point to be 450mA when a transformer with
a nominal inductance value was used.
C3 sets the auto-restart period and also the time the output has to reach regulation
before entering auto-restart from start-up. If a battery load is used then a value of 0.22uF
is typical. However, if the supply is required to start into a resistive load then this should
be increased to 1uF to ensure enough time during start-up to bring the output into
regulation. The type of capacitor is not critical; either a small ceramic or electrolytic may
be used with a voltage rating of 10V or more.
4.4
Output Stage
Diode D6 should be rated for 80% of applied reverse voltage and thermally for average
current multiplied by forward voltage at maximum ambient.
A snubber series RC across D6 may be fitted to improved radiated EMI performance.
Capacitor C5 should be rated for output voltage and ripple current. Depending on the
application, the designer may choose not to derate for ripple current. If the application is
battery charging of equipment such as PDA’s or cell phones, the duty cycle of operation
at high ripple current is likely to be low, perhaps only 1 hour per day. In this case the
capacitor temperature can be allowed to rise significantly during charging without concern
for the overall lifetime.
Resistor R8 acted as preload to prevent the output from exceeding the maximum output
voltage limit as specified in Figure 3 at no-load and high line. Otherwise a preload is not
necessary.
Page 8 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
5 PCB Layout
Figure 4 - PCB Layout and Dimensions (0.001 inch)
Page 9 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
6 Bill Of Materials
Item
1
2
3
4
Quantity
2
1
1
1
Reference
C1, C2
C3
C4
C5
5
6
7
8
9
10
11
12
3
14
4
1
1
1
1
1
1
1
1
1
D1, D2, D3, D4
D5
D6
L1
RF1
R2
R1
R5
T1
U1
15
1
PCB
Page 10 of 23
Part Description
4.7uF, 400V
0.22uF, 25V, X7R ceramic
0.1uF, 100V, X7R ceramic
330uF, 10V Low ESR E-cap Panasonic FC
series
1N4005, 1A, 600V
1N4937, 1A, 600V 200nS, Fast Rectifier
UG1B, 1A, 100V, 15nS Ultra Fast Rectifier
1mH Inductor- Tokin part #SBCP-47HY102B
10 ohm, 1W, Fusible- Vitrohm 253-4 Series
130 ohms, 1% 0603 SMD resistor
23.7 Kohm 1%; 1/4W resistor
56 Kohm; 0603 SMD resistor
Custom EF12.6 – Core & Bobbin
LINK520P- High Voltage IC; Power
Integrations, Inc
FR1 – 1oz copper DIM: 1.7” x 1.1”; 1.0mm
thick
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DER-39
2.5W Adapter LNK520P
May 13, 2004
7 Transformer Specification
7.1
Transformer Winding
1
5
WDG1
18T 32AWG
T.I.W
6
WDG3
132T
#36AWG
4
4
WDG2
13T #34AWG X3
3
Figure 5 – Transformer Schematic EF12.6
7.2
Electrical Specifications
Electrical Strength
Primary Inductance
(Pin 1 -Pin 3 @ 42KHZ
Primary Leakage
Inductance @42KHZ
Page 11 of 23
60Hz 1minute, from Pins 1-4 to
Pins 5-6
3 kV for 1 minute
All windings open
2450 uH – 2700uH
LK with pins 5-6 shorted
< 60 uH
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DER-39
7.3
2.5W Adapter LNK520P
May 13, 2004
Transformer Construction
1
WDG3
4
4
3
5
6
WDG2
WDG1
Figure 6 – Transformer Cross-section EF12.6
7.4
Winding Instructions
Place the bobbin on the winding machine with pins 1-4 on the right side. Winding should
be in forward direction.
WDG1:
Secondary
Winding
Start at pin 4 temporarily. Wind 18 turns of item 5(#32AWG
T.I.W.) from right to left with tight tension. Wind uniformly in
a single layer across entire width of bobbin. Finish on pin 6.
Basic Insulation
Secure winding partially using item 6.
WDG1:
Secondary
Winding
Basic Insulation
Change the start pin connection of secondary winding from
pin 4 to pin 5.
WDG2:
Cancellation
Winding
Basic Insulation
Page 12 of 23
Continue winding the tape previously placed for one layer
with overlap to secure the end wire of WDG1.
Start at pin 3. Wind 13 turns with trifilar of item 3 (#34AWG
wire) from right to left with tight tension. Wind uniformly in a
single layer across entire width of bobbin. Finish on pin 4.
1 layer of tape (Item 6) for insulation.
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DER-39
2.5W Adapter LNK520P
May 13, 2004
WDG3: Primary
winding 3 layers.
Start at pin 4. Wind 132 turns of item 4 (#36AWG) from right
to left in three layers across entire width of bobbin. Wind
uniformly all layers with tight tension. Finish on pin 1.
Outer Insulation
7 Layer of tape using item 7.
Core Assembly
Assemble and secure core halves with glue.
Shield / Belly
Place outside 1 turn of item 8 with tight contact to winding
Band
surface. Connect item 8 to pin 3 by item 3.
Crop unused pins Remove pin 7 and 8
Varnish
NO
7.5
Materials
Item
[1]
[2]
[3]
[4]
[5]
[6]
[7]
[8]
7.6
Description
Core: EF12.6
Bobbin: BEF12.6- Horizontal 8-PINS
Magnet Wire: #34 AWG
Magnet Wire: #36 AWG
Triple Insulated wire: # 32 AWG
Tape: 3M 1298 Polyester Film (white) 0.311 x 2 mils
Tape: 3M 1298 Polyester Film (white) 0.275 x 2 mils
Copper Foil: 0.01mils x 6mm
Design Notes
Power Integrations Device
Frequency of Operation
Mode
Peak current
Reflected Voltage (Secondary to Primary)
AC Input Voltage Range
Page 13 of 23
LNK501P
42KHZ
Discontinuous
0.263 A
47 V
90-265VAC
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DER-39
2.5W Adapter LNK520P
May 13, 2004
8 Performance Data
All measurements performed at room temperature, 60 Hz input frequency.
8.1
Efficiency
The efficiency was measured at maximum output power at room temperature.
Efficiency
Percent Efficiency (%)
70.0
65.0
60.0
Efficiency
55.0
50.0
45.0
40.0
85
100 115 130 145 160 175 190 205 220 235 250 265
Input (Vac)
Figure 7 – Efficiency vs. Input voltage. At nominal inputs the efficiency is 67%
Page 14 of 23
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DER-39
8.2
2.5W Adapter LNK520P
May 13, 2004
No-load Input Power
Input Power (mW)
No-load
500
450
400
350
300
250
200
150
100
50
0
278mW at
230Vac
No-load
85
100 115 130 145 160 175 190 205 220 235 250 265
Line Input (Vac)
Figure 8 – Zero load input power vs. Input line voltage. The No-Load consumption at 230Vac is 278mW.
8.3
Line and Load Regulation
Output Voltage (Vdc)
V-I Characterisitc
10
9
8
7
6
5
4
3
2
1
0
230Vac
115Vac
H-Limit
L-Limit
0
100
200
300
400
500
600
700
800
900 1000
Load Current (mA)
Figure 9 – Output VI Characteristic at selected input voltages (115V & 230V)
Page 15 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
Output Voltage (Vdc)
V-I Characterisitc
10
9
8
7
6
5
4
3
2
1
0
90Vac
265Vac
H-Limit
L-Limit
0
100
200
300
400
500
600
700
800
900 1000
Load Current (mA)
Figure 10 – Output VI Characteristic at selected input voltages (90V & 265V)
Page 16 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
9 Thermal Performance
Measurement was taken at maximum output power inside a plastic enclosure at 90Vac;
TAMBIENT =25oC with no airflow.
Reference
Description
Temperature
U1
LNK520P
67ºC
T1
EF12.6 Transformer
54ºC
D6
UG1B
69ºC
Page 17 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
10 Waveforms
10.1 Drain Voltage and Current, Normal Operation
Figure 11 - 90 VAC, Full Load.
Upper: VDRAIN, 200 V, 5 µs / div
Lower: IDRAIN, 0.2 A / div
Page 18 of 23
Figure 12 - 265 VAC, Full Load
Upper: VDRAIN, 200 V, 5 µs / div
Lower: IDRAIN, 0.2 A / div
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DER-39
2.5W Adapter LNK520P
May 13, 2004
10.2 Output Ripple Measurements
10.2.1 Ripple Measurement Technique
For DC output ripple measurements, a modified oscilloscope test probe must be utilized
in order to reduce spurious signals due to pickup. Details of the probe modification are
provided in Figure 13 and Figure 14.
The 5125BA probe adapter is affixed with two capacitors tied in parallel across the probe
tip. The capacitors include one (1) 0.1 µF/50 V ceramic type and one (1) 1.0 µF/50 V
aluminum electrolytic. The aluminum electrolytic type capacitor is polarized, so
proper polarity across DC outputs must be maintained (see below).
Probe Ground
Probe Tip
Figure 13 - Oscilloscope Probe Prepared for Ripple Measurement. (End Cap and Ground Lead Removed)
Figure 14 - Oscilloscope Probe with Probe Master 5125BA BNC Adapter. (Modified with wires for probe
ground for ripple measurement, and two parallel decoupling capacitors added)
Page 19 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
10.2.2 Measurement Results
Figure 15 – V Ripple, 90 VAC, Full Load.
5 ms, 100 mV / div
Figure 16 - V Ripple, 115 VAC, Full Load.
2 ms, 50 mV / div
Figure 17 - Ripple, 230 VAC, Full Load.
5 ms, 100 mV /div
Figure 18 - Ripple, 265 VAC, Full Load.
5 ms, 100 mV /div
Page 20 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
11 Conducted EMI
Figure 19 - Conducted EMI, Maximum Steady State Load, LINE 115 VAC, 60 Hz, and EN55022 B Limits.
With Artificial hand connected to Sec GND.
Figure 20 - Conducted EMI, Maximum Steady State Load, LINE 115 VAC, 60 Hz, and EN55022 B Limits.
Without Artificial hand connected to Sec GND.
Page 21 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
Figure 21 - Conducted EMI, Maximum Steady State Load, LINE 230 VAC, 60 Hz, and EN55022 B Limits.
With Artificial hand connected to Sec GND.
Figure 22 - Conducted EMI, Maximum Steady State Load, LINE 230 VAC, 60 Hz, and EN55022 B Limits.
Without Artificial hand connected to Sec GND.
Page 22 of 23
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DER-39
2.5W Adapter LNK520P
May 13, 2004
12 Revision History
Date
May 13, 2004
Author
ME
Revision
1.0
Description & changes
First Release
Reviewed
VC / AM
For the latest updates, visit our Web site: www.powerint.com
PATENT INFORMATION
Power Integrations reserves the right to make changes to its products at any time to improve reliability or
manufacturability. Power Integrations does not assume any liability arising from the use of any device or circuit
described herein, nor does it convey any license under its patent rights or the rights of others.
The products and applications illustrated herein (including circuits external to the products and transformer
construction) may be covered by one or more U.S. and foreign patents or potentially by pending U.S. and foreign
patent applications assigned to Power Integrations. A complete list of Power Integrations’ patents may be found at
www.powerint.com.
The PI Logo, TOPSwitch, TinySwitch, LinkSwitch, and EcoSmart are registered trademarks of Power
Integrations, Inc. PI Expert and DPA-Switch are trademarks of Power Integrations, Inc.
© Copyright 2003, Power Integrations, Inc.
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