POWERINT EPR-85

Engineering Prototype Report for EP-85 –
2 W Charger using LinkSwitch®-LP
(LNK564P)
Title
Specification 90 – 265 VAC Input, 6 V, 330 mA Output
Application
Low Cost, Line Frequency Transformer Based
Charger Replacement
Author
Power Integrations Strategic Marketing Department
Document
Number
EPR-85
Date
04-Oct-2005
Revision
1.0
Summary and Features
•
•
•
•
•
•
Low cost, low part count solution (only 14 components)
• Proprietary IC and Circuit technology enable Clampless™ design and very
simple Filterfuse™ input stage
Integrated LinkSwitch-LP safety/reliability features
• Over-temperature protection – tight tolerance (+/-5%) with hysteretic
recovery for safe pcb temperature under all conditions
• Auto-restart output short circuit and open-loop protection
• Extended pin creepage distance for reliable operation in humid
environments - >3.2 mm minimum at package
EcoSmart® – Easily meets all existing and proposed international energy
efficiency standards – China (CECP) / CEC / EPA / European Commission
• No-load consumption 140 mW at 265 VAC
• 64.9% average efficiency measured to CEC spec (versus target 55.2%)
Ultra-low leakage current: <5 µA at 265 VAC input – No Y cap
Meets EN550022 and CISPR-22 Class B EMI with >9 dBµV margin
Meets IEC61000-4-5 Class 3 AC line surge
Power Integrations
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
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.
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Page 2 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
Table of Contents
1
2
3
4
Introduction .................................................................................................................4
Power Supply Specification ........................................................................................6
Schematic ...................................................................................................................7
Circuit Description.......................................................................................................7
4.1
Input and EMI Filtering.........................................................................................7
4.2
LinkSwitch-LP Feedback .....................................................................................7
4.3
Primary Clamp and Transformer Construction ....................................................8
4.4
Output Rectification and Filtering.........................................................................8
4.5
Optional Components ..........................................................................................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 ............................................................................................................12
7.4
Transformer Build Diagram................................................................................12
7.5
Design Spreadsheet ..........................................................................................14
8 Performance Data.....................................................................................................16
8.1
Efficiency ...........................................................................................................16
8.1.1
Active Mode CEC Measurement Data........................................................16
8.2
No-Load Input Power.........................................................................................17
8.3
Regulation .........................................................................................................17
9 Thermal Performance ...............................................................................................18
10
Waveforms ............................................................................................................20
10.1 Drain Voltage and Current, Normal Operation...................................................20
10.2 Output Voltage Start-Up Profile, Battery Load ...................................................21
10.3 Drain Voltage and Current Start-Up Profile........................................................22
10.4 Output Ripple Measurements ............................................................................23
10.4.1 Ripple Measurement Technique.................................................................23
10.4.2 Measurement Results.................................................................................24
11
Conducted EMI .....................................................................................................25
12
AC Line Surge.......................................................................................................27
13
Revision History ....................................................................................................28
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.
Page 3 of 32
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
1 Introduction
This document describes a universal input charger power supply designed to replace
linear transformer based chargers/adapters in low power applications. The power supply
utilizes a LinkSwitch-LP IC, LNK564P. The document contains the power supply
specification, schematic, bill of materials, transformer documentation, printed circuit
layout, and performance data.
The LinkSwitch-LP IC has been developed to replace linear transformers in low power
charger applications. The integrated 700 V switching MOSFET and ON/OFF control
function achieve very high efficiency operation under all load conditions with simple bias
winding voltage feedback. No-load and operating efficiency performance exceeds all
international energy efficiency standards either present or proposed in the future.
Thermal shutdown is included as a minimum requirement to match the safety thermal cut
out (thermal fuse) in linear transformers. The IC’s intelligent thermal shutdown feature is
specified with a very tight tolerance (142 ˚C +/-5%) and includes a hysteretic autorecovery feature to automatically restart the power supply while maintaining the average
pcb temperature at safe levels under all conditions. This auto-recovery is designed to
eliminate the potential for field returns since the power supply automatically recovers
when ambient temperatures return to the normal operating range. However, with latching
thermal shutdown, often used in RCC discrete switching power supply designs, the input
AC typically needs to be removed to reset the thermal latching function. With RCCs,
there is therefore a potential that power supplies will be returned after a thermal latch off,
as customers are often unaware of the need to reset by unplugging the power supply.
The auto-recovery thermal shutdown also eliminates noise sensitivity associated with
discrete latch circuits, which can be sensitive to circuit design, environmental conditions
and component age.
The IC package provides extended creepage distance between high and low voltage pins
(both at the package and pcb), which is required in high humidity conditions to prevent
arcing. Other features include pulsed auto-restart operation under output short circuit and
open loop conditions.
Worst-case no-load power consumption is approximately 140 mW at 265 VAC, well
within the 300 mW European standards and even 150 mW at 230 VAC targets set in
some customer specifications. Heat generation is minimized with high operating
efficiency under all load and line conditions.
The EE16 transformer bobbin provides extended creepage to meet safety spacing
requirements.
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Page 4 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
Figure 1 – LNK564 Low Cost Cell Phone Charger Populated Circuit Board Photograph.
Page 5 of 32
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
2 Power Supply Specification
Description
Input
Voltage
Frequency
No-load Input Power
Output
Output Voltage
Symbol
Min
VIN
fLINE
90
47
5.5
VOUT1
VRIPPLE1
VRIPPLE2
VRIPPLE3
VRIPPLE4
Output Ripple Voltage
VRIPPLE_TOTAL
0.3
IOUT1
Output Current
Total Output Power
Continuous Output Power
POUT
η
Efficiency
Typ
Max
Units
Comment
265
63
0.15
VAC
Hz
W
2 Wire – no P.E.
6
200
200
200
400
800
0.33
V
mVpp
mVpp
mVpp
mVpp
mVpp
A
90VAC max. power point
2.0
W
57
%
o
230 VAC, 25 C
0 – 20 Hz
20 Hz – 20 kHz
20 kHz – 200 kHz
200 kHz – 400 kHz
Total combined
90 VAC, max. power point
Measured at 115/230 VAC
o
Ave. 25/50/75/100% load, 25 C
Environmental
Conducted EMI
Meets CISPR22B / EN55022B
Safety
Designed to meet IEC950, UL1950
Class II
Surge
Meets IEC61000-4-5 Class 3
External Ambient Temperature
-5
TAMB
45
>6 dB margin
C
o
Free convection, sea level
10
9
Ou tp u t Vo ltag e (V
8
7
6
5
4
3
2
1
0
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
1.1
1.2
Output Current (A)
Figure 2 – Low Cost Charger Output Envelope Specification.
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Page 6 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
3 Schematic
Figure 3 – LNK564 Low Cost Charger Schematic.
4 Circuit Description
4.1 Input and EMI Filtering
AC input differential filtering is accomplished with the very low cost input filter stage
formed by C1 and L1. The proprietary frequency jitter feature of the LNK564 eliminates
the need for an input pi filter, so only a single bulk capacitor is required. This allows the
input inductor L1 to be used as a fuse as well as a filter component. This very simple
Filterfuse input stage further reduces system cost. The L1 is sleeved to allow it to function
as a fuse. An optional fusible resistor, RF1, may be used to provide the fusing function.
Input diode D2 may be removed from the neutral phase in applications where decreased
EMI margins and/or decreased input surge withstand is allowed.
4.2 LinkSwitch-LP Feedback
The power supply utilizes simplified bias winding voltage feedback enabled by LNK564
ON/OFF control. The resistor divider formed by R1 and R2 determine the output voltage
across the transformer bias winding during the switch off time. In the V/I constant voltage
region, the LNK564 device enables/disables switching cycles to maintain 1.69 V on the
FB pin. Diode D3 and low cost ceramic capacitor C3 provide rectification and filtering of
the primary feedback winding waveform. At increased loads, beyond the constant power
threshold, the FB pin voltage begins to reduce as the power supply output voltage falls.
The internal oscillator frequency is linearly reduced in this region until it reaches typically
50% of the starting frequency when the FB pin voltage reaches the auto-restart threshold
voltage (typically 0.8 V on the FB pin, which is equivalent to 1 V to 1.5 V at the output of
the power supply). This function limits the output current in this region without fold back
until the output voltage is low.
Page 7 of 32
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
No-load consumption can be further reduced by increasing C3 to 0.47 µF or higher.
4.3 Primary Clamp and Transformer Construction
A Clampless primary circuit is achieved due to the very tight tolerance current limit
trimming techniques used in manufacturing the LNK564, plus the transformer
construction techniques used. Peak drain voltage is therefore limited to typically less than
550 V at 265 VAC – providing significant margin to the 700 V minimum drain voltage
specification (BVDSS).
4.4 Output Rectification and Filtering
Output rectification and filtering is achieved with output rectifier D4 and filter capacitor C5.
Due to the auto-restart feature, the average short circuit output current is significantly less
than 1 A, allowing low cost rectifier D4 to be used. Output circuitry is designed to handle
a continuous short circuit on the power supply output. Diode D4 is an ultra-fast type,
selected for optimum V/I output characteristics. Optional resistor R3 provides a pre-load,
limiting the output voltage level under no-load output conditions. Despite this pre-load,
no-load consumption is within targets at approximately 140 mW at 265 VAC. The
additional margin of no-load consumption requirement can be achieved by increasing the
value of R4 to 2.2 kΩ or higher while still maintaining output voltage well below the 9 V
maximum specification. Placement is left on the board for an optional Zener clamp (VR1)
to limit maximum output voltage under open loop conditions, if required.
4.5 Optional Components
Fusible resistor RF1, VR1 and C4 are all optional components. Resistor RF1, VR1 and
C4 are not fitted on the board as standard, RF1 being replaced with a wire link.
•
•
•
Resistor RF1 may be fitted to designs where a traditional fuse is preferred over the
Filterfuse configuration.
Zener diode VR1 is fitted where the output voltage must be limited to a lower value
during open loop conditions. The auto-restart feature of LinkSwitch-LP limits the
output power under this condition, requiring only a zener with a low, 0.5 W rating.
The use of E-ShieldTM techniques in the transformer removes the need for a Y1
safety capacitor across the safety isolation barrier to meet EMI. However, the use
of C4, a small value (100 pF) Y1 capacitor provides improved EMI consistency if
transformer construction variation is a concern.
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Page 8 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
5 PCB Layout
Figure 4 – LNK564 Low Cost Charger Printed Circuit Layout.
Page 9 of 32
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
6 Bill Of Materials
Item Qty Ref
Description
Manufacturer
1
1
C1 10 µF, 400 V, Electrolytic, Low ESR,
Ltec
79 mA, (10 x 12.5)
2
1
C2 100 nF, 50 V, Ceramic, Z5U
Kemet
3
1
C3 330 nF, 50 V, Ceramic, X7R
Panasonic
4*
1
C4 100 pF, Ceramic, Y1
Vishay
United
5
1
C5 220 µF, 25 V, Electrolytic, Very Low ESR,
Chemi-Con
72 mΩ, (8 x 11.5)
6
1
D1 600 V, 1 A, Fast Recovery Diode,
Vishay
200 ns, DO-41
7
2 D2 D3 600 V, 1 A, Rectifier, DO-41
Vishay
8
1
D4 100 V, 1 A, Ultrafast Recovery, 50 ns,
Vishay
DO-41
9
2 J1 J2 Test Point
Keystone
10 1
J3 6 ft, 22 AWG, 0.25 Ω, 2.1 mm
Generic
Epcos
11 1
L1 3300 µH, 62 mA, 59.5 Ω, Axial Ferrite
Inductor
12 1
- Heatshrink tubing, 3/16” diameter, 0.5” length Generic
13 1
R1 37.4 kΩ, 1%, 1/4 W, Metal Film
Yageo
14 1
R2 3 kΩ, 5%, 1/8 W, Carbon Film
Yageo
15 1
R3 2 kΩ, 5%, 1/8 W, Carbon Film
Yageo
16** 1 RF1 8.2 Ω, 2.5 W, Fusible/Flame Proof Wire
Vitrohm
Wound
17 1
T1 Bobbin, EE16, Horizontal, 10 pins
Ngai Cheong
Electronics
Assembled unit available from
Falco
Hical
CWS
Li Shin
Woo Jin
18 1
U1 LinkSwitch-LP, LNK564P, DIP-8B
Power
Integrations
19* 1
VR1 10 V, 5%, 500 mW, DO-35
Microsemi
Manufacturer Part #
TYD2GM100G13O
C317C104M5U5CA
ECU-S1H334KBB
440LT10
KZE25VB221MH11LL
1N4937
1N4005
UF4002
5011
B78108S1335J
Generic
MFR-25FBF-37K4
CFR-12JB-3K0
CFR-12JB-2K0
CRF253-4 5T 8R2
EE-16 10PINs
E09077
SIL6036
CWS-T1-DAK85
LSLA40342
SLP-2218P1
LNK564P
1N5240B
*Optional component
** Optional components - not fitted replaced with jumper on board
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Page 10 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
7 Transformer Specification
7.1
Electrical Diagram
5
WDG #1
Bias
2
Primary
6
Cut
WDG #3
Shield
0.25 mm × 3 8T
0.14 mm 108T
1
Secondary
WDG #4
0.5 mm T.I.W. 8T
0.2 mm 25T
4
WDG #2
7
2
: Winding Start, forward winding direction
: Winding Start, reversed winding direction
Figure 5 – Transformer Electrical Diagram.
7.2
Electrical Specifications
Electrical Strength
Primary Inductance
Primary Winding Capacitance
Primary Leakage Inductance
Page 11 of 32
60 Hz 1 min, from pins 1-5 to pins 6-7
From pins 1-2, all other windings open
All windings open
From pins 1-2 with pins 6-7 shorted
3000 VAC
2.7 mH, -/+5%
50 pF (Max.)
75 µH (Max.)
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EP-85 6 V, 330 mA Low Cost Charger
7.3
Materials
Item
[1]
[2]
[3]
[4]
[5]
[6]
[7]
[8]
[9]
7.4
04-Oct-2005
Description
Core : EE16, PC40EE13, TDK – ALG 230 nH/T2
Bobbin: Horizontal 10 pin – pins 3, 8, 9, and 10 removed
Magnet Wire: 0.20 mm Polyurethane coated class 2 wire
Magnet Wire: 0.14 mm Polyurethane coated class 2 wire
Magnet Wire: 0.25 mm Polyurethane coated class 2 wire
Triple Insulated Wire: 0.5 mm
Tape: 3M 1298 Polyester Film (white) 320 mils wide by 1 mil thick
Barrier Tape: 2 mm width
Varnish (dip)
Transformer Build Diagram
Iso. Tape
Secondary
0.5 mm T.I.W.
8T
7
6
Iso. Tape
2
* Shield
0.25 mm × 3
8T 2
Iso. Tape
Primary
0.14 mm
1
Bias
0.2 mm
Iso. Tape
4
5
Barrier tape 2 mm
* See Fig. 7 for detail of shield winding start technique.
Figure 6 – Transformer Build Diagram.
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Page 12 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
2 mm margin tape 1/4T to
set winding start position.
Start winding here from
edge of margin tape.
Plastic tape
Position three wires to
line up with outside edge
of margin tape and stick
wires down with plastic
tape.
No empty space among
the wires.
Figure 7 – Winding Method of Shield Winding.
Page 13 of 32
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EP-85 6 V, 330 mA Low Cost Charger
7.5
04-Oct-2005
Design Spreadsheet
ACDC_LinkSwitchINPUT
LP_091605; Rev.1.0;
Copyright Power
Integrations 2005
ENTER APPLICATION VARIABLES
VACMIN
90
VACMAX
265
fL
50
VO
6.00
INFO
OUTP UNIT
UT
Volts
Volts
Hertz
Volts
EP85 Design
Minimum AC Input Voltage
Maximum AC Input Voltage
AC Mains Frequency
Output Voltage (main) measured at the end of output cable (For
CV/CC designs enter typical CV tolerance limit)
Power Supply Output Current (For CV/CC designs enter typical
CC tolerance limit)
Enter "YES" for CV/CC output. Enter "NO" for CV only output
IO
0.33
Constant Voltage / Constant
Current Output
Output Cable Resistance
PO
Feedback Type
YES
CVCC Volts
0.05
BIAS
Add Bias Winding
YES
Clampless design
YES
n
0.70
Z
tC
0.50
2.80
0.05 Ohms
Enter the resistance of the output cable (if used)
1.99 Watts
Output Power (VO x IO + dissipation in output cable)
Bias Winding Enter 'BIAS' for Bias winding feedback and 'OPTO' for
Optocoupler feedback
Yes
Enter 'YES' to add a Bias winding. Enter 'NO' to continue
design without a Bias winding. Addition of Bias winding can
lower no load consumption
Clamp
Enter 'YES' for a clampless design. Enter 'NO' if an external
less
clamp circuit is used.
Efficiency Estimate at output terminals. For CV only designs
enter 0.7 if no better data available
0.5
Loss Allocation Factor (Secondary side losses / Total losses)
mSecond Bridge Rectifier Conduction Time Estimate
s
uFarads Input Capacitance
H
Choose H for Half Wave Rectifier and F for Full Wave
Rectification
CIN
Input Rectification Type
10.00
H
ENTER LinkSwitch-LP VARIABLES
LinkSwitch-LP
LNK564
Chosen Device
ILIMITMIN
ILIMITMAX
fSmin
I^2fMIN
I^2fTYP
VOR
VDS
VD
KP
Amps
ACDC_LinkSwitch-LP_091605_Rev1-0.xls; LinkSwitch-LP
Continuous/Discontinuous Flyback Transformer Design
Spreadsheet
LinkSwitch-LP device
LNK564
0.124
0.146
93000
1665
Amps
Amps
Hertz
A^2Hz
1850 A^2Hz
88.00
88 Volts
10 Volts
0.5 Volts
1.54
ENTER TRANSFORMER CORE/CONSTRUCTION VARIABLES
Core Type
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 mm
L
NS
NB
VB
R1
8
2
8
27
21.93 Volts
36.89 k-ohms
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Minimum Current Limit
Maximum Current Limit
Minimum Device Switching Frequency
I^2f Minimum value (product of current limit squared and
frequency is trimmed for tighter tolerance)
I^2f typical value (product of current limit squared and
frequency is trimmed for tighter tolerance)
Reflected Output Voltage
LinkSwitch-LP on-state Drain to Source Voltage
Output Winding Diode Forward Voltage Drop
Ripple to Peak Current Ratio (0.9<KRP<1.0 : 1.0<KDP<6.0)
Suggested smallest commonly available 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
Number of Bias winding turns
Bias Winding Voltage
Resistor divider component between bias wiinding and FB pin
of LinkSwitch-LP
Page 14 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
R2
Recommended Bias Diode
3.00 k-ohms
1N400
3
DC INPUT VOLTAGE PARAMETERS
VMIN
VMAX
80 Volts
375 Volts
Minimum DC Input Voltage
Maximum DC Input Voltage
CURRENT WAVEFORM SHAPE PARAMETERS
DMAX
IAVG
IP
IR
IRMS
0.48
0.04
0.12
0.12
0.05
Maximum Duty Cycle
Average Primary Current
Minimum Peak Primary Current
Primary Ripple Current
Primary RMS Current
TRANSFORMER PRIMARY DESIGN PARAMETERS
LP
2738
LP_TOLERANCE
5.00
5
NP
108
ALG
233
BM
Info
1922
BAC
ur
LG
Warning
801
1654
0.08
BWE
OD
INS
DIA
AWG
17.2
0.16
0.04
0.12
37
CM
CMA
20
374
Amps
Amps
Amps
Amps
uHenries
%
Typical Primary Inductance. +/- 5%
Primary inductance tolerance
Primary Winding Number of Turns
nH/T^2
Gapped Core Effective Inductance
Gauss
!!! Info. Flux densities above ~ 1500 Gauss may produce
audible noise. Verify with dip varnished sample transformers.
Increase NS to greater than or equal to 11 turns or increase
VOR
Gauss
AC Flux Density for Core Loss Curves (0.5 X Peak to Peak)
Relative Permeability of Ungapped Core
mm
!!! INCREASE GAP>>0.1 (increase NS, decrease VOR,bigger
Core
mm
Effective Bobbin Width
mm
Maximum Primary Wire Diameter including insulation
mm
Estimated Total Insulation Thickness (= 2 * film thickness)
mm
Bare conductor diameter
AWG
Primary Wire Gauge (Rounded to next smaller standard AWG
value)
Cmils
Bare conductor effective area in circular mils
Cmils/Am Primary Winding Current Capacity (150 < CMA < 500)
p
TRANSFORMER SECONDARY DESIGN PARAMETERS
Lumped parameters
ISP
1.68 Amps
ISRMS
0.65 Amps
IRIPPLE
0.56 Amps
CMS
130 Cmils
AWGS
28 AWG
DIAS
ODS
0.32 mm
1.08 mm
INSS
0.38 mm
VOLTAGE STRESS PARAMETERS
VDRAIN
PIVS
- Volts
34 Volts
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
Peak Drain Voltage is highly dependent on Transformer
capacitance and leakage inductance. Please verify this on the
bench and ensure that it is below 650 V to allow 50 V margin for
transformer variation.
Output Rectifier Maximum Peak Inverse Voltage
Note: Gap size was verified with transformer vendor as being acceptable. Higher flux
density resulted in peak audible noise of <35 dBA without enclosure, also acceptable as
a further 10 dB reduction is typical once inside sealed enclosure.
Page 15 of 32
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
8 Performance Data
All measurements performed at room temperature, 47 Hz input frequency.
8.1
Efficiency
80%
70%
Efficiency
60%
50%
at 90 VAC
40%
at 115 VAC
at 230 VAC
30%
at 265 VAC
20%
10%
0%
0.00
0.50
1.00
1.50
2.00
2.50
Output Power (W)
Figure 8 – Efficiency vs. Output Power.
8.1.1 Active Mode CEC Measurement Data
The table below lists the operating efficiencies at specific load points measured at the
nominal input voltages. For the purposes of the CEC & EPA calculations, 2 W output was
taken as the 100% load point. The CEC & EPA spec shown in the table below was
calculated based on 2 W as the nominal 100% load.
Input Voltage
25%
Relative
POUT
50%
Relative
POUT
75%
Relative
POUT
100%
Relative
POUT
Average
Efficiency
(%)
CEC / EPA
Spec.
(%)
115 VAC
65.0
68.1
67.7
66.6
66.8
55.2
230 VAC
60.5
65.3
66.6
67.3
64.9
55.2
Power Integrations
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Page 16 of 32
04-Oct-2005
8.2
EP-85 6 V, 330 mA Low Cost Charger
No-Load Input Power
160
140
Input Power (mW)
120
100
80
60
40
20
0
50
100
150
200
250
300
AC Input Voltage (VAC)
Figure 9 – No-Load Input Power vs. Input Line Voltage.
8.3
Regulation
10
at 90 VAC
at 115 VAC
at 230 VAC
at 265 VAC
MIN
MAX
9
Output Voltage (V)
8
7
6
5
4
3
2
1
0
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
1.1
1.2
Output Current (A)
Figure 10 – Load and Line Regulation.
The LNK564 device enters auto-restart for output voltages below typically 1.5 V, thus
preventing excessive short circuit current.
Page 17 of 32
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
9 Thermal Performance
High temperature testing was completed in a sealed adapter enclosure at elevated
ambient of 45 °C under conditions of natural convection. Input voltage was set to
90/265 VAC with 47 Hz line frequency. The output was adjusted to maintain full load
1.93 W and 2.1 W, respectively.
Thermocouple
Location
LNK564P, pins 1,2
Bulk Input Capacitor
Transformer
Output Rectifier
Reference
U1
C1
T1
D4
Measured Temperature Rise (°C)
90 VAC, 1.93 WOUT
265 VAC, 2.1 WOUT
37.1
16
14
40
55
12
17
43
All temperatures are regarded as well within normally acceptable operating temperature
ranges.
An infrared thermograph was taken of the unit operating open frame at room ambient.
This confirms that the correct components were selected for temperature measurement
in the table above and that high line is worst case for U1.
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Page 18 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
265 VAC, 2 W load, 22°C Ambient
90 VAC, 2 W load, 22°C Ambient
Figure 11 – Infra-Red Thermograph of Unit Operating Open Frame, Room Ambient
Page 19 of 32
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
10 Waveforms
10.1 Drain Voltage and Current, Normal Operation
Figure 12 – 90 VAC, Full Load.
Upper: IDRAIN, 0.10 A / div.
Lower: VDRAIN, 200 V, 2 µs / div.
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Figure 13 – 265 VAC, Full Load.
Upper: IDRAIN, 0.10 A / div.
Lower: VDRAIN, 200 V / div, 2 µs / div.
Page 20 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
10.2 Output Voltage Start-Up Profile, Battery Load
A simulated battery load was used to verify the power supply start-up profile.
Figure 14 – Battery Output Load, RLOAD = 15 Ω.
Figure 15 – Battery Start-Up Profile, 90 VAC.
Upper: IDRAIN, 0.10 A / div.
Lower: VOUT, 2 V, 50 ms / div.
Figure 16 – Battery Start-Up Profile, 265 VAC.
Upper: IDRAIN, 0.10 A / div.
Lower: VOUT, 2 V, 50 ms / div.
With a simulated battery load, the output voltage reaches regulation within 200 ms. No
output overshoot is observed. Note that the peak of the IDRAIN waveform in Figure 15 is
the leading edge current spike, not IDRAIN at the end of the switching cycle.
Page 21 of 32
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
10.3 Drain Voltage and Current Start-Up Profile
Drain Voltage and Current waveforms are presented with the simulated battery load.
Figure 17 – 90 VAC Input and Maximum Load.
Upper: IDRAIN, 0.10 A / div.
Lower: VDRAIN, 100 V, 2 ms / div.
Figure 18 – 265 VAC Input and Maximum Load.
Upper: IDRAIN, 0.10 A / div.
Lower: VDRAIN, 200 V, 2 ms / div.
At start-up with a battery load, Drain current and Drain voltages are well controlled and
within acceptable operating limits. Note that the peak of the IDRAIN waveform in Figure 17
is the leading edge current spike not IDRAIN at the end of the switching cycle.
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Page 22 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
10.4 Output Ripple Measurements
10.4.1 Ripple Measurement Technique
A ripple probe, which included a 1.0 µF Aluminum electrolytic capacitor in parallel with
a 0.1 µF ceramic capacitor, was used for all ripple measurements. The probe was
located at the end of the DC output cable assembly.
Figure 19 – Oscilloscope Probe with Probe Master 5125BA BNC Adapter (modified with wires for probe
ground for ripple measurement, and two parallel decoupling capacitors added).
Page 23 of 32
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
10.4.2 Measurement Results
Output ripple measurements were carried out at room temperature. A programmable AC
source was used with line frequency set to 60 Hz. Output ripple measurement recorded
at end of DC harness. Carbon film resistive loads were utilized.
Figure 20 – VO Ripple, 90 VAC / 60 Hz,
VO = 2.5 V.
5 ms & 20 µs, 100 mV / div.
Figure 21 – VO Ripple, 90 VAC / 60 Hz, VO = 6 V.
5 ms & 20 µs, 100 mV / div.
Under worst-case 90 VAC and 265 VAC and maximum loading conditions, total switching
output ripple is below 150 mV pk-pk.
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Page 24 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
11 Conducted EMI
Power Integrations
27.Sep 05 14:40
Att 10 dB AUTO
dBµV
80
70
RBW
9 kHz
MT
500 ms
PREAMP OFF
1 MHz
10 MHz
LIMIT CHECK
PASS
SGL
1 QP
CLRWR
2 AV
CLRWR
EN55022Q
60
EN55022A
50
TDF
40
30
20
10
0
-10
-20
150 kHz
30 MHz
Figure 23 – Conducted Emissions, Neutral 115 VAC, 17 Ω Load, with Artificial Hand
at Output. QP-Dark Blue, AVG-Red.
Power Integrations
27.Sep 05 14:13
Att 10 dB AUTO
dBµV
80
RBW
9 kHz
MT
500 ms
PREAMP OFF
1 MHz
LIMIT CHECK
10 MHz
PASS
70
SGL
1 QP
EN55022Q
CLRWR
60
2 AV
EN55022A
CLRWR
50
TDF
40
30
20
10
0
-10
-20
150 kHz
30 MHz
Figure 24 – Conducted Emissions, Line 115 VAC, 17 Ω Load, with Artificial Hand
at Output. QP-Dark Blue, AVG-Red.
Page 25 of 32
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EP-85 6 V, 330 mA Low Cost Charger
Power Integrations
27.Sep 05 14:51
Att 10 dB AUTO
dBµV
80
04-Oct-2005
RBW
9 kHz
MT
500 ms
PREAMP OFF
1 MHz
LIMIT CHECK
10 MHz
PASS
70
SGL
1 QP
CLRWR
EN55022Q
2 AV
CLRWR
EN55022A
60
50
TDF
40
30
20
10
0
-10
-20
150 kHz
30 MHz
Figure 25 – Conducted Emissions, Neutral 230 VAC, 17 Ω Load, with Artificial Hand
at Output. QP-Dark Blue, AVG-Red.
Power Integrations
27.Sep 05 14:24
Att 10 dB AUTO
dBµV
80
RBW
9 kHz
MT
500 ms
PREAMP OFF
1 MHz
LIMIT CHECK
10 MHz
PASS
70
SGL
1 QP
CLRWR
EN55022Q
2 AV
CLRWR
EN55022A
60
50
TDF
40
30
20
10
0
-10
-20
150 kHz
30 MHz
Figure 26 – Conducted Emissions, Line 230 VAC, 17 Ω Load, with Artificial Hand
at Output. QP-Dark Blue, AVG-Red
The EMI results show >9 dB margin worst case to quasi-peak and average EN55022B
limits.
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Page 26 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
12 AC Line Surge
Input line 1.2/50 µs differential surge testing (2 Ω generator output impedance) was
completed on a single test unit to IEC61000-4-5. Input voltage was set at 230 VAC /
60 Hz. Output was loaded at full load with a 17 Ω resistor and operation was verified
during and following each surge event. Neither failures nor output glitches were seen.
Surge Testing Results
Surge
Input
Level (V)
Voltage
(VAC)
+250
230
-250
230
+500
230
-500
230
+750
230
-750
230
+1000
230
-1000
230
Injection
Location
Phase
Injection (°)
Test Result
(Pass/Fail)
LN
LN
LN
LN
LN
LN
LN
LN
90
90
90
90
90
90
90
90
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Unit passes under all test conditions.
Page 27 of 32
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
13 Revision History
Date
04-Oct-05
Author
SM/SR
Revision
1.0
Power Integrations
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Description & changes
Formatted for Final Release
Page 28 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
Notes
Page 29 of 32
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
Notes
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Page 30 of 32
04-Oct-2005
EP-85 6 V, 330 mA Low Cost Charger
Notes
Page 31 of 32
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EP-85 6 V, 330 mA Low Cost Charger
04-Oct-2005
For the latest updates, visit our website: www.powerint.com
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. POWER INTEGRATIONS
MAKES NO WARRANTY 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 transformer construction and circuits external to the products) 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 grants its
customers a license under certain patent rights as set forth at http://www.powerint.com/ip.htm.
The PI Logo, TOPSwitch, TinySwitch, LinkSwitch, DPA-Switch, EcoSmart, Clampless, E-Shield, Filterfuse,
PI Expert and PI FACTS are trademarks of Power Integrations, Inc. Other trademarks are property of their respective companies.
©Copyright 2005 Power Integrations, Inc.
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