POWERINT EPR-73

Engineering Prototype Report for EP-73 2.3 W CV/CC Charger/Adapter Using
LinkSwitch®-HF (LNK354P)
Title
Specification 85-265 VAC Input, 5.7 V, 400 mA Output
Application
Low Cost Charger or Adapter
Author
Power Integrations Applications Department
Document
Number
EPR-73
Date
25-Oct-04
Revision
1.0
Summary and Features
•
•
•
•
•
•
Low cost, low component count battery charger or adapter solution
No-load power consumption <300 mW at 265 VAC input meets worldwide
energy conservation guidelines
Output voltage (CV) tolerance: ±10% across operating range
Output current (CC) tolerance: ±12% across operating range
Meets EN550022 and CISPR-22 Class B EMI with low value Y1 safety
capacitor
Ultra-low leakage current: <10 µA at 265 VAC input
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.
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EP-73 5.7 V, 400 mA Charger / Adapter
25-Oct-2004
Table Of Contents
1
2
3
4
Introduction.................................................................................................................3
Power Supply Specification ........................................................................................4
Schematic...................................................................................................................6
Circuit Description ......................................................................................................7
4.1
Input EMI Filtering ...............................................................................................7
4.2
LinkSwitch-HF Primary ........................................................................................7
4.3
Output Rectification .............................................................................................7
4.4
Output Feedback.................................................................................................7
4.5
Design Aspects for EMI .......................................................................................8
5 PCB Layout ................................................................................................................9
6 Bill Of Materials ........................................................................................................10
7 Transformer Specification.........................................................................................11
7.1
Electrical Diagram .............................................................................................11
7.2
Electrical Specifications.....................................................................................11
7.3
Materials............................................................................................................11
7.4
Transformer Build Diagram ...............................................................................12
7.5
Transformer Construction..................................................................................12
8 Transformer Design Spreadsheet.............................................................................13
9 Performance Data ....................................................................................................16
9.1
Efficiency ...........................................................................................................16
9.2
No-load Input Power..........................................................................................17
9.3
Regulation .........................................................................................................17
9.3.1
CV and CC Output Characteristics.............................................................17
9.3.2
Load Regulation in CV ...............................................................................18
10
Thermal Performance ...........................................................................................19
11
Line Surge.............................................................................................................20
12
Waveforms............................................................................................................21
12.1 Drain Voltage and Current, Normal Operation...................................................21
12.2 Output Voltage Start-up Profile..........................................................................22
12.3 Drain Voltage and Current Start-up Profile ........................................................22
12.4 Load Transient Response (75% to 100% Load Step) .......................................23
12.5 Output Ripple Measurements............................................................................24
12.5.1 Ripple Measurement Technique ................................................................24
12.5.2 Measurement Results ................................................................................25
13
Conducted EMI .....................................................................................................26
13.1 115 VAC Input, Full Load ..................................................................................26
13.2 230 VAC Input, Full Load ..................................................................................27
14
Appendix A............................................................................................................28
15
Revision History ....................................................................................................33
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.
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Page 2 of 36
25-Oct-2004
EP-73 5.7 V, 400 mA Charger / Adapter
1 Introduction
This document is an engineering report describing a 5.7 V, 400 mA power supply utilizing
a LNK354P device. This power supply is intended as a general purpose evaluation
platform for LinkSwitch-HF devices in a battery charger application with secondary side
CV/CC control.
The document contains the power supply specification, schematic, bill of materials,
transformer documentation, printed circuit layout, and performance data.
Figure 1 – EP73 Populated Circuit Board Photograph.
Page 3 of 36
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EP-73 5.7 V, 400 mA Charger / Adapter
25-Oct-2004
2 Power Supply Specification
Description
Symbol
Min
Typ
Max
Units
Comment
VIN
fLINE
85
47
265
64
0.3
VAC
Hz
W
2 Wire – no P.E.
50/60
VOUT1
VRIPPLE1
5.2
5.7
6.3
100
V
mV
Output Current 1
IOUT1
350
400
450
mA
Total Output Power
Continuous Output Power
POUT
1.82
2.3
2.8*
W
η
55
Input
Voltage
Frequency
No-load Input Power (230 VAC)
Output
Output Voltage 1
Output Ripple Voltage 1
Efficiency
%
± 5%
20 MHz bandwidth
With battery model attached to
end of output cable, measured
at 25 °C
Measured at POUT (1.8 W),
o
230 VAC, 25 C
Environmental
Conducted EMI
Meets CISPR22B / EN55022B
> 6 dB Margin
Designed to meet IEC950, UL1950
Class II
Safety
Surge
2
kV
Surge
2
kV
Ambient Temperature
TAMB
0
50
o
C
1.2/50 µs surge, IEC 1000-4-5,
Series Impedance:
Differential Mode: 2 Ω
Common Mode: 12 Ω
100 kHz ring wave, 500 A short
circuit current, differential and
common mode
Free convection, sea level
*
Maximum output power of the LNK354 is restricted by enclosure size – higher powers
are possible with larger enclosures and PCB heatsink area.
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Page 4 of 36
25-Oct-2004
EP-73 5.7 V, 400 mA Charger / Adapter
7
6
Output Voltage (V)
5
4
3
2
1
0
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
0.45
0.5
Output Current (A)
Figure 2 – Output CV/CC Envelope Specification.
Page 5 of 36
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EP-73 5.7 V, 400 mA Charger / Adapter
25-Oct-2004
3 Schematic
Figure 3 – EP73 Schematic.
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Page 6 of 36
25-Oct-2004
EP-73 5.7 V, 400 mA Charger / Adapter
4 Circuit Description
This circuit is configured as a flyback topology power supply utilizing the LNK354P.
Secondary side constant voltage (CV) and constant current (CC) feedback circuitry
provides characteristics required for battery charging applications.
4.1 Input EMI Filtering
The AC input voltage is rectified by input bridge D1 – D4. The rectified DC is then filtered
by the bulk storage capacitors C1 and C2. Inductor L1, C1 and C2 form an input pi filter,
which attenuates differential mode conducted EMI.
It is recommended that RF1 be of wire-wound construction to withstand input current
surges while the input capacitor charges (metal film type are not recommended), and be
compliant with safety flammability hazard requirements. Please consult your safety
agency representative for requirements specific to your application.
4.2 LinkSwitch-HF Primary
The LNK354P device U1 integrates the power switching device, oscillator, control,
startup, and protection functions. The integrated 700 V MOSFET has excellent switching
characteristics allowing operation at the 200 kHz operating frequency.
The rectified and filtered input voltage is applied to the primary winding of T1. The other
side of the transformer primary is driven by the integrated MOSFET in U1. Diode D5, C3,
R1, R2, and R3 form the primary clamp network. This limits the peak drain voltage due
to leakage inductance. Resistor R3 allows the use of a slow, low cost rectifier diode by
limiting the reverse current through D5 when U1 turns on. The selection of a slow diode
also improves conducted EMI.
To regulate the output, ON/OFF control is used. During normal operation, switching of
the power MOSFET is disabled when a current greater than 49 µA is delivered into the
FEEDBACK pin. Current lower than this threshold allows a switching cycle to occur
terminating when the peak primary current reaches the internal current limit.
Current into the FEEDBACK pin is fed, via optocoupler U2, from the BYPASS pin
removing the need for an auxiliary bias winding on the transformer.
4.3 Output Rectification
Output rectification is provided by Schottky diode D6. The low forward voltage provides
high efficiency across the operating range. Low ESR capacitor C6 achieves minimum
output voltage ripple and noise in a small can size for the rated ripple current
specification.
4.4 Output Feedback
Output voltage, in constant voltage (CV) mode, is set by the Zener diode VR1 plus
emitter-base voltage of PNP transistor Q1. The VBE of Q1 divided by the value of R7 sets
Page 7 of 36
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EP-73 5.7 V, 400 mA Charger / Adapter
25-Oct-2004
the bias current through VR1 (~2.7 mA). When the output voltage exceeds the threshold
voltage determined by Q1 and VR1, Q1 is turned on and current flows through the LED of
U2. As the LED current increases, the current fed into the FEEDBACK pin increases
disabling further switching cycles of U1. At very light loads almost all switching cycles will
be disabled, giving a low effective switching frequency and providing low no-load
consumption.
Resistors R6 and R8 ensure that the ratings of Q1 are not exceeded during load
transients.
Resistors R9 and R10 form the constant current (CC) sense circuit. Above approximately
400 mA, the voltage across the sense resistor exceeds the optocoupler diode forward
conduction voltage of approximately 1 V. The current through the LED is therefore
determined by the output current and CC control dominates the CV feedback loop.
4.5 Design Aspects for EMI
In addition to the simple input pi filter for differential mode EMI, this design makes use of
shielding techniques in the transformer to reduce common mode EMI displacement
currents. Resistor R5 and C5 are added to act as a damping network to reduce high
frequency transformer ringing.
To return high frequency common mode displacement currents, a small value (100 pF)
Y1 safety capacitor is placed across the isolation barrier. This is a small enough value to
still meet the design requirement of low leakage current.
These techniques combined with the frequency jitter of LinkSwitch-HF give excellent
conducted and radiated EMI performance.
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Page 8 of 36
25-Oct-2004
EP-73 5.7 V, 400 mA Charger / Adapter
5 PCB Layout
Figure 4 – Printed Circuit Layout (Approximately 1.2 x 1.8 inches).
Page 9 of 36
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EP-73 5.7 V, 400 mA Charger / Adapter
25-Oct-2004
6 Bill Of Materials
Item Qnty Ref. Des. Value
Description
Mfg Part Number
Manufacturer
1
2
C1, C2
4.7 µF
4.7 µF, 400 V, Electrolytic, (8 x 11.5)
4.7 µF, 380 V, Electrolytic, (8 x 11.5)
SHD400WV 4.7uF
Sam Young
XX380VB4R7M8X11LL United Chemi-Con
2
1
C3
2.2nF
2.2 nF, 400 V, Film
222237065222
3
1
C4
100 nF
100 nF, 50 V, Ceramic, X7R, 0805
ECU-V1H221KBN
Vishay (BC
Components)
Panasonic
4
1
C5
2.2 nF
2.2 nF, 50 V, Ceramic, X7R, 0805
ECJ-2VB1H222K
Panasonic
KZE16VB331MH11LL
Nippon Chemi-Con
440LT10
Vishay
1N4005
Vishay
DL4007
Diodes Inc
SS14
Vishay
N/A
N/A
3PH243
Anam Instruments
(Korea)
298
Alpha
5
1
C6
330 µF
6
1
100 pF
7
4
CY1
D1, D2,
D3, D4
330 µF, 16 V, Electrolytic, Very Low ESR,
72 mΩ, (8 x 11.5)
100 pF, Ceramic, Y1
1N4005
600 V, 1 A, Rectifier, DO-41
8
1
D5
DL4007
9
1
D6
10
2
J1,J2
11
1
J3
SS14
PCB Terminal 22
PCB Terminal Hole, 22 AWG
AWG
Output Cable
6 ft, 0.25 Ω, 2.1 mm connector (custom)
Assembly
12
3
13
1
JP1, JP2,
J
JP3
L1
1 mH
1 mH, 0.15 A, Ferrite Core
SBCP-47HY102B
Tokin
14
1
Q1
MMST3906
PNP, Small Signal BJT, 40 V, 0.2 A, SOT-323
MMST3906-7
Diodes Inc
15
2
R1, R2
47 kΩ
47 kΩ, 5%, 1/8 W, Metal Film, 0805
ERJ-6GEYJ473V
Panasonic
1000 V, 1 A, Rectifier, Glass Passivated,
DO-213AA (MELF)
40 V, 1 A, Schottky, DO-214AC
Wire Jumper, Non insulated, 22 AWG, 0.4 in
16
2
R3, R9
200 Ω
200 Ω, 5%, 1/8 W, Metal Film, 0805
ERJ-6GEYJ201V
Panasonic
17
1
R4
5.1 kΩ
5.1 kΩ, 5%, 1/8 W, Metal Film, 0805
ERJ-6GEYJ512V
Panasonic
18
1
R5
68 Ω
68 Ω, 5%, 1/8 W, Metal Film, 0805
ERJ-6GEYJ680V
Panasonic
19
1
R6
6.8 Ω
6.8 Ω, 5%, 1/8 W, Metal Film, 0805
ERJ-6GEYJ6R8V
Panasonic
20
1
R7
220 Ω
220 Ω, 5%, 1/8 W, Metal Film, 0805
ERJ-6GEYJ221V
Panasonic
21
1
R8
390 Ω
390 Ω, 5%, 1/8 W, Metal Film, 0805
ERJ-6GEYJ391V
Panasonic
RSF100JB-2R4
Yageo
22
1
R10
2.4 Ω
2.4 Ω, 5%, 1 W, Metal Oxide
23
1
RF1
8.2 Ω
24
1
T1
EE16
25
1
U1
LNK354P
8.2 Ω, 2.5 W, Fusible/Flame-Proof Wire-Wound CRF253-4 5T 8R2
Sil6032
Custom
LSLA40331B
IM 040 416 11
LinkSwitch-HF, LNK354P, DIP-8B
LNK354P
Vitrohm
Hical
Li Shin
Vogt
Power Integrations
26
1
U2
PC817D
Optocoupler, 80 V, CTR 300-600%, 4-DIP
PC817X4, IPC817D
Sharp, ISP
27
1
VR1
BZX79-B5V1
5.1 V, 500 mW, 2%, DO-35
BZX79-B5V1
Vishay
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Page 10 of 36
25-Oct-2004
EP-73 5.7 V, 400 mA Charger / Adapter
7 Transformer Specification
7.1
Electrical Diagram
5
28 T
2 x 37 AWG
Winding #1
N/C
Floating
Winding #3
N/C
6T
4 x 28 AWG
4
9
9T
25 AWG Winding #4
T.I.W.
8
3
114 T
34 AWG
Winding #2
5
Figure 5 – Transformer Electrical Diagram.
7.2
Electrical Specifications
Electrical Strength
Primary Inductance
Resonant Frequency
Primary Leakage Inductance
7.3
60 Hz 1 minute, from Pins 3-5 to Pins 6-10
Pins 3-5, all other windings open, measured at
200 kHz, 0.4 VRMS
Pins 3-5, all other windings open
Pins 3-5, with Pins 8-9 shorted, measured at
200 kHz, 0.4 VRMS
3000 VAC
916 µH, -/+12%
900 kHz (Min.)
75 µH (Max.)
Materials
Item
[1]
[2]
[3]
[4]
[5]
[6]
[7]
[8]
Description
Core: PC40EE16-Z, TDK or equivalent Gapped for AL of 70 nH/T2
Bobbin: EE16 Horizontal 10 pin
Magnet Wire: #37 AWG
Magnet Wire: #34 AWG
Magnet Wire: #28 AWG
Triple Insulated Wire: #25 AWG.
Tape: 3M 1298 Polyester Film, 2.0 mils thick, 8.4 mm wide
Varnish
Page 11 of 36
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EP-73 5.7 V, 400 mA Charger / Adapter
7.4
25-Oct-2004
Transformer Build Diagram
8
9
Floating
4
Secondary
Winding
Shield
5
Primary
Winding
3
4 layers of
tape
5
Cancellation
Winding
Floating
Figure 6 – Transformer Build Diagram.
7.5
Transformer Construction
First Winding Cancellation
Insulation
Second Winding Primary
Insulation
Third Winding Shield
Insulation
Fourth Winding
Outer insulation
Core Assembly
Varnish
Primary pin side of the bobbin oriented to left-hand side. Start at Pin 8
temporarily. Wind 28 bifilar turns of item [3] from right to left. Wind with
tight tension across entire bobbin evenly and leave the finish end free.
Bend the free end 90° and draw the wire across the bobbin window
cutting in the center of the bobbin. Move start end of winding from Pin 8
to Pin 5.
4 Layers of tape [6] for insulation.
Start at Pin 3 wind 38 turns of item [4] from left to right. Add one layer of
tape. Wind another 38 turns from right to left. Add one layer of tape.
Wind 38 turns in third layer from left to right. Wind with tight tension
across entire bobbin evenly. Finish at Pin 5.
2 Layers of tape [6] for insulation.
Start at Pin 8 temporarily, wind 6 quadfilar turns of item [5]. Wind from
right to left with tight tension in a single uniform layer across entire width
of bobbin. Finish on Pin 4. Cut start end at Pin 8 ensuring uniformity of
winding and tape down in place.
2 Layers of tape [7] for insulation.
Start at Pin 9, wind 9 turns of item [6] from right to left. Wind uniformly, in
a single layer across entire bobbin width. Finish on Pin 8.
3 Layers of tape [7] for insulation.
Assemble and secure core halves.
Dip Varnish [8] – DO NOT VACUUM IMPREGNATE
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Page 12 of 36
25-Oct-2004
EP-73 5.7 V, 400 mA Charger / Adapter
8 Transformer Design Spreadsheet
ACDC_LinkSwitchHF_060904; Rev1-1;
INPUT INFO
Copyright Power
Integrations Inc. 2004
ENTER APPLICATION VARIABLES
VACMIN
85
VACMAX
265
fL
50
VO
5.7
IO
0.4
CC Threshold Voltage
OUTPUT UNIT
Volts
Volts
Hertz
Volts
Amps
1.04
PO
2.696
n
0.57
Z
tC
CIN
3
9.4
0.75
ENTER LinkSwitch-HF VARIABLES
LinkSwitch-HF
LNK354
Chosen Device
LNK354
ILIMITMIN
ILIMITMAX
fS
Power
Out
0.233
0.268
186000
Minimum AC Input Voltage
Maximum AC Input Voltage
AC Mains Frequency
Output Voltage
Power Supply Output Current
Voltage drop across sense resistor. For CV only circuits enter
Volts
"0"
Watts
Output Power
Efficiency Estimate. For CV only designs enter 0.7 if no better
data available
Loss Allocation Factor
mSeconds Bridge Rectifier Conduction Time Estimate
uFarads
Input Capacitance
Universal
115 Doubled/230V
4.5 W
5W
Amps
Amps
Hertz
Minimum Current Limit
Maximum Current Limit
Minimum Device Switching Frequency
Maximum switching frequency at full load and LP min. For
maximum power capability enter 186 kHz (fs_min), reducing
this value will reduce EMI but lower power capability
Reflected Output Voltage
LinkSwitch-HF on-state Drain to Source Voltage
Output Winding Diode Forward Voltage Drop
Ripple to Peak Current Ratio (0.6<KRP<1.0 : 1.0<KDP<6.0)
fS Full Load
178750
178750
Hertz
VOR
VDS
VD
KP
91
91
10
0.45
1.15
Volts
Volts
Volts
0.45
ENTER TRANSFORMER CORE/CONSTRUCTION VARIABLES
Core Type
EE16
EE16
Core
EE16
P/N:
Bobbin
EE16_BOBBIN
P/N:
AE
0.192
cm^2
LE
3.5
cm
AL
1140
nH/T^2
BW
8.6
mm
M
0
L
NS
3
9
9
DC INPUT VOLTAGE PARAMETERS
VMIN
VMAX
90
375
CURRENT WAVEFORM SHAPE PARAMETERS
DMAX
0.54
IAVG
0.05
IP
0.23
IR
0.23
IRMS
0.09
Page 13 of 36
ACDC_LinkSwitch-HF_060904_Rev1-1.xls; LinkSwitchTN_HF Continuous/Discontinuous Flyback Transformer
Design Spreadsheet
mm
User-Selected transformer core
PC40EE16-Z
EE16_BOBBIN
Core Effective Cross Sectional Area
Core Effective Path Length
Ungapped Core Effective Inductance
Bobbin Physical Winding Width
Safety Margin Width (Half the Primary to Secondary Creepage
Distance)
Number of Primary Layers
Number of Secondary Turns
Volts
Volts
Minimum DC Input Voltage
Maximum DC Input Voltage
Amps
Amps
Amps
Amps
Maximum Duty Cycle
Average Primary Current
Minimum Peak Primary Current
Primary Ripple Current
Primary RMS Current
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EP-73 5.7 V, 400 mA Charger / Adapter
TRANSFORMER PRIMARY DESIGN PARAMETERS
LP
916
LP_TOLERANCE
12
NP
114
ALG
71
mm
mm
mm
mm
mm
AWG
Cmils
Cmils/Amp
Typical Primary Inductance. +/- 12%
Primary inductance tolerance
Primary Winding Number of Turns
Gapped Core Effective Inductance
!!! Caution. Flux densities above ~ 1250 Gauss may produce audible
noise. Verify with dip varnished sample transformers. Increase NS to
greater than or equal to 10 turns or increase VOR
AC Flux Density for Core Loss Curves (0.5 X Peak to Peak)
Relative Permeability of Ungapped Core
Gap Length (Lg > 0.1 mm)
Effective Bobbin Width
Maximum Primary Wire Diameter including insulation
Estimated Total Insulation Thickness (= 2 * film thickness)
Bare conductor diameter
Primary Wire Gauge (Rounded to next smaller standard AWG value)
Bare conductor effective area in circular mils
Primary Winding Current Capacity (200 < CMA < 500)
TRANSFORMER SECONDARY DESIGN PARAMETERS
Lumped parameters
ISP
2.95
ISRMS
1.02
IRIPPLE
0.94
CMS
205
AWGS
26
DIAS
0.41
ODS
0.96
INSS
0.27
Amps
Amps
Amps
Cmils
AWG
mm
mm
mm
Peak Secondary Current
Secondary RMS Current
Output Capacitor RMS Ripple Current
Secondary Bare Conductor minimum circular mils
Secondary Wire Gauge (Rounded up to next larger standard AWG value)
Secondary Minimum Bare Conductor Diameter
Secondary Maximum Outside Diameter for Triple Insulated Wire
Maximum Secondary Insulation Wall Thickness
VOLTAGE STRESS PARAMETERS
VDRAIN
PIVS
Volts
Volts
Maximum Drain Voltage Estimate (Includes Effect of Leakage Inductance)
Output Rectifier Maximum Peak Inverse Voltage
BM
Caution
BAC
ur
LG
BWE
OD
INS
DIA
AWG
CM
CMA
uHenries
%
25-Oct-2004
nH/T^2
1298
Gauss
649
1654
0.32
25.8
0.23
0.05
0.18
34
40
466
Gauss
586
35
TRANSFORMER SECONDARY DESIGN PARAMETERS (MULTIPLE OUTPUTS)
1st output
VO1
5.7
Volts
Output Voltage (if unused, defaults to single output design)
IO1
0.473
Amps
Output DC Current
PO1
2.70
Watts
Output Power
VD1
0.45
Volts
Output Diode Forward Voltage Drop
NS1
8.34
Output Winding Number of Turns
ISRMS1
1.210
Amps
Output Winding RMS Current
IRIPPLE1
1.11
Amps
Output Capacitor RMS Ripple Current
PIVS1
33
Volts
Output Rectifier Maximum Peak Inverse Voltage
CMS1
AWGS1
DIAS1
ODS1
242
26
0.41
1.03
Cmils
AWG
mm
mm
Output Winding Bare Conductor minimum circular mils
Wire Gauge (Rounded up to next larger standard AWG value)
Minimum Bare Conductor Diameter
Maximum Outside Diameter for Triple Insulated Wire
Volts
Amps
Watts
Volts
2nd output
VO2
IO2
PO2
VD2
NS2
ISRMS2
IRIPPLE2
PIVS2
0.00
0.000
0.00
0
Amps
Amps
Volts
Output Voltage
Output DC Current
Output Power
Output Diode Forward Voltage Drop
Output Winding Number of Turns
Output Winding RMS Current
Output Capacitor RMS Ripple Current
Output Rectifier Maximum Peak Inverse Voltage
CMS2
AWGS2
DIAS2
ODS2
0
N/A
N/A
N/A
Cmils
AWG
mm
mm
Output Winding Bare Conductor minimum circular mils
Wire Gauge (Rounded up to next larger standard AWG value)
Minimum Bare Conductor Diameter
Maximum Outside Diameter for Triple Insulated Wire
0.00
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Page 14 of 36
25-Oct-2004
3rd output
VO3
IO3
PO3
VD3
NS3
ISRMS3
IRIPPLE3
PIVS3
EP-73 5.7 V, 400 mA Charger / Adapter
0.00
0.00
0.000
0.00
0
Volts
Amps
Watts
Volts
Amps
Amps
Volts
Output Voltage
Output DC Current
Output Power
Output Diode Forward Voltage Drop
Output Winding Number of Turns
Output Winding RMS Current
Output Capacitor RMS Ripple Current
Output Rectifier Maximum Peak Inverse Voltage
CMS3
0
Cmils
AWGS3
N/A
AWG
DIAS3
ODS3
N/A
N/A
mm
mm
Output Winding Bare Conductor minimum circular mils
Wire Gauge (Rounded up to next larger standard AWG
value)
Minimum Bare Conductor Diameter
Maximum Outside Diameter for Triple Insulated Wire
Total power
2.696
Watts
Total Output Power
Page 15 of 36
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9 Performance Data
All measurements performed at room temperature, 60 Hz input frequency. A DC output
cable was not included.
Efficiency
65%
60%
Efficiency
9.1
55%
90 VAC
50%
115 VAC
230 VAC
265 VAC
45%
40%
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
0.45
Output Load (A)
Figure 7 – Efficiency vs. Output Current (CV), Room Temperature, 60 Hz.
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9.2
EP-73 5.7 V, 400 mA Charger / Adapter
No-load Input Power
0.3
Input Power (W)
0.25
0.2
0.15
0.1
0.05
0
50
100
150
200
250
300
Input Voltage (VAC)
Figure 8 – Zero Load Input Power vs. Input Line Voltage, Room Temperature, 60 Hz.
9.3
Regulation
9.3.1 CV and CC Output Characteristics
No measurable difference was seen over line voltage variation.
7
6
Output Voltage (V)
5
4
3
2
1
0
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
0.45
0.5
Output Current (A)
Figure 9 – CV/CC Output Characteristic with Specification Limits Added, Room Temperature.
Page 17 of 36
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25-Oct-2004
9.3.2 Load Regulation in CV
7
Output Voltage (V)
6.5
6
5.5
5
4.5
4
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
Output Load (A)
Figure 10 – Load Regulation in CV Operation, Room Temperature, Full Load.
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EP-73 5.7 V, 400 mA Charger / Adapter
10 Thermal Performance
Temperature of key components was recorded using a T-type thermocouple.
Thermocouples were soldered directly to LNK354P SOURCE pin and cathode of output
rectifier. Thermocouples were glued to the output capacitor and transformer external
core/winding surfaces.
The unit was operated at full load in free convection in a thermal chamber inside an
additional enclosure to eliminate airflow. The ambient was measured in the additional
enclosure and maintained at 40 °C.
Temperature (°C)
Item
85 VAC
265 VAC
Ambient
40
40
LNK354P (U1)
94
96
Transformer (T1)
80
82
Output Rectifier (D6)
67
64
Output Capacitor (C6)
60
58
For reference an infrared thermograph was taken with the unit operating at room ambient
showing the relative temperature rise of the key supply components.
Figure 11 – Infrared Thermograph of PCB (85 VAC, Room Ambient).
Page 19 of 36
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EP-73 5.7 V, 400 mA Charger / Adapter
25-Oct-2004
11 Line Surge
Surge
Voltage
Phase Angle
Generator
Impedance
Number of Strikes
Test Result
2 kV
90°
2Ω
10
PASS
2 kV
90°
12 Ω
10
PASS
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EP-73 5.7 V, 400 mA Charger / Adapter
12 Waveforms
12.1 Drain Voltage and Current, Normal Operation
Figure 12 – 115 VAC, Full Load.
Upper: IDRAIN, 0.1 A / div.
Lower: VDRAIN, 50 V, 200 ns / div.
Figure 13 – 230 VAC, Full Load.
Upper: IDRAIN, 0.1 A / div.
Lower: VDRAIN, 100 V, 100 ns / div.
Figure 14 – 115 VAC, Full Load.
VDRAIN, 50 V, 20 µs / div.
Figure 15 – 115 VAC, Full Load.
VDRAIN, 100 V, 20 µs / div.
Page 21 of 36
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25-Oct-2004
12.2 Output Voltage Start-up Profile
Startup into resistive full load and no-load was verified. Load resistor was sized at 13 Ω
to maintain 300 mA under steady-state conditions.
Figure 16 – Start-up Profile115 VAC.
Fast trace is no load rise time.
Slower trace is maximum load (13 Ω)
1 V, 2 ms / div.
Figure 17 – Start-up Profile 230 VAC.
Fast trace is no load rise
time.
Slower trace is maximum
load (13 Ω)
1 V, 2 ms / div.
12.3 Drain Voltage and Current Start-up Profile
Figure 18 – 90 VAC Input and Maximum Load
(Resistive Load).
Upper: 200 V & 500 µs/ div.
Lower: VDRAIN, IDRAIN, 0.1 A / div.
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Figure 19 – 265 VAC Input and Maximum Load
(Resistive Load).
Upper: 200 V & 500 µs/ div.
Lower: VDRAIN, IDRAIN, 0.1 A / div.
Page 22 of 36
25-Oct-2004
EP-73 5.7 V, 400 mA Charger / Adapter
12.4 Load Transient Response (75% to 100% Load Step)
Figure 20 – Transient Response, 115 VAC,
75-100-75% Load Step.
Upper:. VOUT 20 mV, 1 ms / div.
Lower: IOUT, 0.1 A / div.
Page 23 of 36
Figure 21 – Transient Response, 230 VAC,
75-100-75% Load Step.
Upper: VOUT, 20 mV, 1ms / div.
Lower: IOUT, 0.1 A / div.
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25-Oct-2004
12.5 Output Ripple Measurements
12.5.1 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. Attach probe with end cap and ground
clip removed to circuit shown below which is attached to end of output cable.
The 5125BA probe adapter is affixed
Probe Ground
Probe Tip
Figure 22 – Oscilloscope Probe Prepared for Ripple Measurement (End Cap and Ground Lead Removed).
RCABLE
(0.15 Ω)
DA
RBATTERY
(0.44 Ω)
DB
CA
RLOAD
10,000 µF
(13 Ω)
Figure 23 – Equivalent Battery Model Circuit.
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25-Oct-2004
EP-73 5.7 V, 400 mA Charger / Adapter
12.5.2 Measurement Results
Figure 24 – Output Ripple, 115 VAC, Full Load.
20 µs, 50 mV / div.
Page 25 of 36
Figure 25 – Output Ripple, 230 VAC, Full Load.
20 µs, 50 mV / div.
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EP-73 5.7 V, 400 mA Charger / Adapter
25-Oct-2004
13 Conducted EMI
Conducted emissions tests were completed at 115 VAC and 230 VAC at full load,
5.5 V / 400 mA. Measurements were completed with Artificial Hand connection and
floating DC output load resistor. An output DC cable was included.
Composite EN55022B / CISPR22B conducted limits are shown.
13.1 115 VAC Input, Full Load
Line
Neutral
Artificial Hand Connected to Output Return
Artificial Hand Connected to Output Return
Output Floating
Output Floating
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25-Oct-2004
EP-73 5.7 V, 400 mA Charger / Adapter
13.2 230 VAC Input, Full Load
Line
Neutral
Artificial Hand Connected to Output Return
Artificial Hand Connected to Output Return
Output Floating
Output Floating
Page 27 of 36
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EP-73 5.7 V, 400 mA Charger / Adapter
25-Oct-2004
14 Appendix A – Design Modification Required To Remove Y Capacitor
In some applications where extremely low leakage current is required, it may be
necessary to remove the Y capacitor (CY1) that bridges the primary-to-secondary
isolation barrier.
In order to achieve this while still meeting conducted and radiated EMI requires reoptimization of the transformer. As with all no Y capacitor transformer designs, the
mechanical arrangement and relative spacing of the windings has a large impact on the
EMI performance of the supply. Therefore ensure that transformers are wound
consistently to ensure repeatable EMI performance.
14.1 No Y capacitor Transformer Specification
14.1.1 Electrical Diagram
5
Winding #1
(Cancellation)
17 T
2 x 32 AWG
N/C
Floating
Winding #3
(Shield)
N/C
7T
3 x 28 AWG
4
3
114 T
36 AWG
Winding #2
(Primary)
5
9
9T
Winding #4
25 AWG
(Secondary)
T.I.W.
8
Denotes mechanical start of
reverse wound winding where
electrical phasing and mechanical
start are not the same
14.1.2 Electrical Specifications
Electrical Strength
Primary Inductance
Resonant Frequency
Primary Leakage Inductance
60Hz 1minute, from Pins 3-5 to Pins 6-10
Pins 3-5, all other windings open, measured at
200 kHz, 0.4 VRMS
Pins 3-5, all other windings open
Pins 3-5, with Pins 8-9 shorted, measured at
200 kHz, 0.4 VRMS
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3000 VAC
916 µH, -/+12%
900 kHz (Min.)
75 µH (Max.)
Page 28 of 36
25-Oct-2004
EP-73 5.7 V, 400 mA Charger / Adapter
14.1.3 Winding Instructions
WD1
Cancellation
Winding
Insulation
WD#2
Primary winding
Insulation
WD #3
Shield Winding
Insulation
WD #4
Secondary
Winding
Outer Insulation
Core Assembly
Core Grounding
Varnish
Primary pin side of the bobbin oriented to left-hand side. Add 1 layer of
item [7] to the secondary side. Start at Pin 5. Wind 17 bifilar turns of item
[3] from right to left. Wind with tight tension across entire bobbin evenly.
Cut the ends of the bifilar and leave floating.
4 Layers of tape [8] for insulation.
Apply 1 layer of item [7] to the secondary side. Start at Pin 3. Wind 40
turns of item [4] from left to right. Add 1 layer of item [8] and 1 layer of
item [7] to the secondary side. Wind another 40 turns from right to left.
Add 1 layer of item [8] and 1 layer of item [7] to the secondary side. Wind
34 turns in third layer from left to right. Wind with tight tension across
entire bobbin evenly. Finish at Pin 5.
2 Layers of tape [8] for insulation.
Start at Pin 8 temporarily, wind 7 trifilar turns of item [5]. Wind from right
to left with tight tension. Wind uniformly, in a single layer across entire
width of bobbin. Finish on Pin 4. Cut the lead of the starting end and
ensure that the void area around the starting end is entirely covered with
the cut end. Tape down in place.
2 Layers of tape [8] for insulation.
Reverse orientation of bobbin such that secondary pin side is to the lefthand side. Start at Pin 8, wind 9 turns of item [6] from right to left. Wind
uniformly, in a single layer across entire bobbin evenly. Finish on Pin 9.
3 Layers of tape [8] for insulation.
Assemble and secure core halves using item [9].
Solder 1 end of item [10] to Pin 5. Wrap 2 turns around entire transformer
making sure that wire is in contact with cores. Terminate end to Pin 5.
Dip Varnish, item [11]
14.1.4 Materials
Item
[1]
[2]
[3]
[4]
[5]
[6]
[7]
[8]
[9]
[10]
[11]
Page 29 of 36
Description
Core: PC40EE16-Z, TDK or equivalent Gapped for AL of 192 nH/T2
Bobbin: EE16 Horizontal 10 pin
Magnet Wire: #32 AWG
Magnet Wire: #36 AWG
Magnet Wire: #28 AWG
Triple Insulated Wire: #25 AWG.
Tape: 3M # 44 Polyester web. 1.5 mm wide
Tape: 3M 1298 Polyester Film, 2.0 mils thick, 8.0 mm wide
Tape: 3M 1298 Polyester Film, 2.0 mils thick, 3.0 mm wide
Solid Wire: #28 AWG
Varnish
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EP-73 5.7 V, 400 mA Charger / Adapter
25-Oct-2004
14.1.5 Transformer Build Diagram
3 layers of tape
8
9
Secondary
Shield
4
5
N.C. (Floating)
Primary
3
Cancellation
1.5 mm
5
1.5 mm
4 layers
of tape
Tape margin
N.C.
Denotes mechanical start of
winding where mechanical start
and electrical phase are different
Denotes mechanical start and
electrical phase of winding where
they are the same
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Page 30 of 36
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EP-73 5.7 V, 400 mA Charger / Adapter
14.2 EMI Results
Both conducted and radiated EMI results with the revised transformer and CY1 removed
showed excellent margin to respective standards. Tests were performed on both line and
neutral (conducted) with the output return connected to the artificial hand input of the
LISN (line impedance stabilization network). The red trace represents EMI measured
with a quasi peak detector and the blue an average detector. These results should be
below the respective limit line of the same color.
Radiated results gave a margin of > 6dB.
Figure 26 – No Y Capacitor Conducted EMI Results (115 VAC).
Page 31 of 36
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EP-73 5.7 V, 400 mA Charger / Adapter
25-Oct-2004
Figure 27 – No Y Capacitor Conducted EMI (230 VAC).
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Page 32 of 36
25-Oct-2004
EP-73 5.7 V, 400 mA Charger / Adapter
15 Revision History
Date
01-Mar-04
01-Apr-04
05-Apr-04
Author
AO
PV
Revision
0.1
0.2
0.3
08-Apr-04
28-Apr-04
PV
AO
0.4
0.5
02-May-04
PV
0.6
20-May-04 AO
27-May-04 PV
16-June-04 PV
0.7
0.8
0.81
24-June-04 PV
25-Oct-04
PV
0.9
1.0
Page 33 of 36
Description & changes
First Draft
Transformer and layout change
Applied correct template, updated circuit
description
Reinserted Figure 4 (didn’t printout)
Updated BOM, Spreadsheet, Schematic and
Transformer
4.3: Change R2 to R3, replace terminated
with disabled
4.4: Added 1 V opto threshold
6: Corrected description of D6
Fig 4: Added filar to diagram
Added output characteristic spec
Updated PCB layout, charts corrected
R10 part number corrected
Figure 2 updated (Q1 shown as NPN not
PNP)
Reinserted final spreadsheet
Appendix A added for no Y cap solution
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25-Oct-2004
Notes
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EP-73 5.7 V, 400 mA Charger / Adapter
Notes
Page 35 of 36
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EP-73 5.7 V, 400 mA Charger / Adapter
25-Oct-2004
For the latest updates, visit our website: www.powerint.com
Power Integrations may make changes to its products at any time. Power Integrations has no liability arising from your use of any
information, device or circuit described herein nor does it convey any license under its patent rights or the rights of others. POWER
INTEGRATIONS MAKES NO WARRANTIES HEREIN AND SPECIFICALLY DISCLAIMS ALL WARRANTIES
INCLUDING, WITHOUT LIMITATION, THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A
PARTICULAR PURPOSE, AND NON-INFRINGEMENT OF THIRD PARTY RIGHTS.
PATENT INFORMATION
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, DPA-Switch and EcoSmart are registered trademarks of
Power Integrations. PI Expert and PI FACTS are trademarks of Power Integrations. © Copyright 2004, Power Integrations.
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