POWERINT DER-114

Title
21 W Standby Power Supply using
TNY280P
Specification
Input: 85 – 295 VAC (110 – 420 VDC)
Outputs: 5 V / 4 A; 15 V / 67 mA
Application
General PC-Standby Supply
Author
Power Integrations Applications Department
Document
Number
DER-114
Date
June 28, 2006
Revision
1.0
Summary and Features
•
•
•
•
•
High standby efficiency: PIN < 0.70 W @ POUT = 0.5 W, at 230 VAC input
Under-voltage lockout (UVLO) function: glitch-free startup and shutdown
Two means of implementing output overvoltage protection (OVP)
EEL22 transformer core meets clearance and creepage requirements
Output overload, short circuit and open feedback loop protection
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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DER-114
PC Standby Power Supply – TNY280P
June 28, 2006
Table Of Contents
1
2
3
4
Introduction .................................................................................................................3
Power Supply Specification ........................................................................................4
Schematic ...................................................................................................................5
Circuit Description.......................................................................................................6
4.1
Input Rectifier & filter ...........................................................................................6
4.2
TNY280 Primary ..................................................................................................6
4.3
Output Rectification .............................................................................................7
4.4
Output Feedback .................................................................................................7
4.5
UV Lockout ..........................................................................................................7
4.6
OV Protection ......................................................................................................7
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 Spreadsheets .......................................................................................13
9 Performance Data.....................................................................................................16
9.1
Efficiency ...........................................................................................................16
9.2
No-load Input Power ..........................................................................................16
9.3
0.5 W (5 V, 0.1 A) Load Input Power .................................................................17
9.4
Available Standby Output Power .......................................................................17
9.5
Regulation .........................................................................................................18
9.5.1
Load ...........................................................................................................18
9.5.2
Line.............................................................................................................18
10
Thermal Performance............................................................................................19
11
Waveforms ............................................................................................................20
11.1 Drain Voltage and Current, Normal Operation...................................................20
11.2 Drain Voltage & Current Startup Profile .............................................................21
11.3 Output Voltage Startup Profile ...........................................................................21
11.4 OV Shutdown ....................................................................................................22
11.5 Load Transient Response (3 A to 4 A Load Step) .............................................23
11.6 Output Ripple Measurements ............................................................................24
11.6.1 Ripple Measurement Technique.................................................................24
11.6.2 Measurement Results.................................................................................25
12
Design Notes:........................................................................................................26
13
Revision History ....................................................................................................27
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 2 of 28
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DER-114
PC Standby Power Supply – TNY280P
June 28, 2006
1 Introduction
This engineering report describes a universal input 5 V, 4 A power supply designed
around a TNY280P device from the TinySwitch-III family of ICs. Although designed as an
auxiliary or bias supply for a personal computer (PC) power supply, this design can also
be used as a general-purpose evaluation platform for TinySwitch-III devices.
Typically, PC power supplies have a power factor corrected (PFC) input stage. However,
since the bias supply must operate before the PFC stage is active, this supply has been
designed for universal input operation.
Input rectification and input storage capacitance have been included, for evaluation
purposes. This stage and the EMI filter components would normally be part of the main
PC supply, in an actual application.
This report contains the power supply specification, the circuit diagram, a complete bill of
materials (BOM), the PI Xls transformer spreadsheet design results, complete
transformer documentation, the printed circuit board (PCB) layout and relevant
performance data.
Figure 1– Populated Circuit Board Photograph.
Page 3 of 28
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DER-114
PC Standby Power Supply – TNY280P
June 28, 2006
2 Power Supply Specification
Description
Input
Voltage
Frequency
No-load Input Power (230 VAC)
Output
Output Voltage 1
Output Ripple Voltage 1
Output Current 1
Output Voltage 2
Output Current 2
Total Output Power
Continuous Output Power
Efficiency
Full Load
Ambient Temperature
Page 4 of 28
Symbol
Min
Typ
Max
Units
Comment
VIN
fLINE
85
47
VAC
Hz
W
Equivalent to 100 – 420 VDC
50/60
295
64
0.3
VOUT1
VRIPPLE1
IOUT1
VOUT2
4.75
5
5.25
50
4
18
67
V
mV
A
V
mA
21
W
50
o
12
15
POUT
η
TAMB
76
0
%
C
± 5%
20 MHz bandwidth
100 mA minimum load on VOUT1
& 40 mA load on auxiliary output
o
Measured at POUT 25 C
Free convection, sea level
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DER-114
PC Standby Power Supply – TNY280P
June 28, 2006
3 Schematic
Figure 2 – Circuit Diagram.
Page 5 of 28
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DER-114
PC Standby Power Supply – TNY280P
June 28, 2006
4 Circuit Description
This dual output converter is configured as a Flyback. The main output provides 4 A at 5
V, while the bias winding on transformer T1 is used to generate a 15 V output that can
supply up to 67 mA. The converter will operate over an input voltage range of 85 – 295
VAC or 100 – 420 VDC. The 5 V output is referenced to a TL431 located on the
secondary side, and feedback is passed back to the primary through optocoupler (U2).
4.1 Input Rectifier & filter
This circuit is designed for standby applications and components F1, RT1, D1-D4 & C1
are only provided for standalone testing. Fuse F1 will effectively isolate the converter
from the supply source in the event of short circuit failure. Thermistor RT1 limits the
inrush current at startup. Diodes D1, D2, D3 & D4 form a bridge rectifier, which charges
the bulk storage capacitor C1.
4.2 TNY280 Primary
The TNY280P device (U1) is an integrated circuit, which includes a power MOSFET, an
oscillator, control, start-up and protection functions.
A clamp circuit (D5, VR1, C3, R1 & R3) limits the voltage that appears on the drain of U1
each time its MOSFET turns off. During normal operation VR1 does not conduct and
clamping is performed by D5, C3, R1 & R3. Typically, VR1 will only conduct during fault
conditions such as overload. This approach allows the RCD clamp (R1, R3, C3 & D5) to
be sized for normal operation, which maximizes efficiency at light load.
The output of the bias/auxiliary supply winding is rectified by diode D6 and filtered by
capacitor C4. The rectified and filtered output of the bias winding (terminals J5 & J6) can
be used to power external circuitry on the primary side, such as the PFC and main
converter control circuits. The bias winding is also used to supply current to the TNY280
BYPASS/MULTIFUNCTION (BP/M) pin during steady state operation. The value of R4 is
selected to deliver the IC supply current to the BP/M pin, thereby inhibiting the internal
high-voltage current source that normally charges the BP/M pin capacitor (C2). This
results in reduced input power consumption under light load and no load conditions.
Capacitor C2 provides high frequency decoupling of the internally generated 5.85 V IC
supply voltage. Three different capacitor values could be used for C2, which would
select one of three internal current limit sets. A 0.1 uF capacitor was used in this design,
which selects the standard current limit set for a TNY280P.
The transistor of optocoupler U2 pulls current out of the ENABLE/UNDER-VOLTAGE
(EN/UV) pin of U1. The IC keeps switching as long as the current drawn from its EN/UV
pin is less than 90 µA. It stops switching whenever the current drawn from the EN/UV pin
exceeds that threshold, which ranges from 90 µA to 150 µA (with the typical value being
115 µA). By enabling and disabling switching pulses, the feedback loop regulates the
output voltage of the power supply.
Page 6 of 28
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DER-114
PC Standby Power Supply – TNY280P
June 28, 2006
An internal state machine sets the MOSFET current limit to one of four levels, depending
on the main output load current. This ensures that the effective switching frequency
remains above the audible frequency range. The lowest current limit (used at no-load)
makes the transformer flux density so low that dip-varnished transformers produce no
perceptible audible noise.
4.3 Output Rectification
Diode D7 rectifies the main output. Low ESR capacitors C7, C8 & C9 attenuate the
switching ripple. A post filter (L1 & C10) further reduces switching ripple and noise on the
main output.
4.4 Output Feedback
Resistors R6 and R7 form a voltage divider network. A portion of the output voltage is
fed into the input terminal of the TL431 (U3). The TL431 varies its cathode voltage in an
attempt to keep its input voltage constant (equal to 2.5 V, ±2%). As the cathode voltage
changes, the current through the LED and transistor within U2 change. Whenever the
EN/UV pin current exceeds its threshold, the next switching cycle is disabled. Whenever
the EN/UV pin current falls below the threshold, the next switching cycle is enabled. As
the load is reduced, the number of enabled switching cycles decreases, which lowers the
effective switching frequency and the switching losses. This results in almost constant
efficiency down to very light loads, which is ideal for meeting energy efficiency
requirements. Capacitor C12 rolls off the gain of U3 with frequency, to ensure stable
operation. Capacitor C11 prevents the output voltage from overshooting at startup.
4.5 UV Lockout
Optional resistors R11 and R12–connected between the DC bus and the EN/UV pin of
U1–enable the under-voltage lockout function. When these resistors are used, start-up is
inhibited until the current into the EN/UV pin exceeds 25 µA. The values of R11 and R12
sets a startup voltage threshold that prevents output voltage glitches when the input
voltage is abnormally low, such as when the AC input capacitor is discharging during
shutdown. Additionally, the UVLO status is checked whenever a loss of regulation
occurs–such as during an output overload or short-circuit. This effectively latches U1 off
until the input voltage is removed and reapplied. With the values of R11 and R12 shown
in figure 2, the UVLO threshold is approximately 100 VDC (71 VAC).
4.6 OVP
This supply has two different overvoltage protection circuits. The first OVP function is
provided by VR2 and the latching shutdown function built into U1. If the feedback loop
became an open circuit–due to the failure of U2, for example–the main output voltage
and the bias winding voltage would both rise. Once the bias voltage exceeded the sum
of the voltage across VR2 and the BP/M pin voltage, current would flow into the BP/M
pin. When that current exceeds the OV shutdown threshold (≈5.5 mA), the latching
shutdown function is triggered and MOSFET switching is disabled. MOSFET switching
remains disabled until the BP/M pin capacitor (C2) is discharged below 4.8 V.
Page 7 of 28
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DER-114
PC Standby Power Supply – TNY280P
June 28, 2006
The second OVP function is provided by VR3, U4 and R10, and is enabled when jumpers
JP1 and JP2 are installed (forms a second feedback loop). If the primary feedback loop
became an open circuit, the output voltage would rise. The EN/UV pin would be pulled
low once the output voltage exceeded the voltage across VR3 and the LED within U4.
The output voltage would then be regulated at a slightly higher voltage than that of the
primary feedback loop.
Page 8 of 28
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DER-114
PC Standby Power Supply – TNY280P
June 28, 2006
5 PCB Layout
Figure 3 – Printed Circuit Layout.
Page 9 of 28
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DER-114
PC Standby Power Supply – TNY280P
June 28, 2006
6 Bill Of Materials
Item
Qty
Part Ref
Value
1
1
C1
100 µF
2
3
2
1
C2 C12
C3
100 nF
1 nF
4
5
6
1
1
1
C4
C5
C6
100 µF
1 nF
470 pF
7
3
C7 C8 C9
1500 µF
8
1
C10
470 µF
9
10
11
1
1
4
C11
C13
D1 D2 D3 D4
2.2 µF
22 nF
1N4007
12
2
D5 D6
1N4937
13
14
1
1
D7
F1
15TQ060
3.15 A
15
16
1
2
HS1
J1 J4
6032B-TT
CON1
17
18
3
1
J2 J5 J6
J3
CON1
CON1
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
2
1
1
1
1
1
1
2
1
1
1
2
1
1
1
JP1 JP2
L1
R1
R2
R3
R4
R5
R6 R7
R8
R9
R10
R11 R12
R13
RT1
T1
J
3.3 µH
200 kΩ
3 kΩ
30 Ω
16 kΩ
33 Ω
10 kΩ
47 Ω
1 kΩ
100 Ω
2.0 MΩ
4.7 Ω
16 Ω
EEL22
34
1
U1
TNY280P
35
2
U2 U4
PC817A
36
1
U3
37
38
39
1
1
1
VR1
VR2
VR3
TL431
P6KE150
A
1N5247B
1N5231C
Page 10 of 28
Description
100 µF, 450 V, Electrolytic, Low ESR,
(18 x 30)
100 nF, 50 V, Ceramic, X7R
1 nF, 1 kV, Disc Ceramic
100 µF, 35 V, Electrolytic, Gen.
Purpose, (8 x 11.5)
1 nF, Ceramic, Y1
470 pF, 100 V, Ceramic, X7R
1500 µF, 10 V, Electrolytic, Very Low
ESR, 22 mΩ, (10 x 25)
470 µF, 10 V, Electrolytic, Low ESR,
120 mΩ, (8 x 12)
2.2 µF, 50 V, Electrolytic, Gen.
Purpose, (5 x 11)
22 nF, 630 V, Film
1000 V, 1 A, Rectifier, DO-41
600 V, 1 A, Fast Recovery Diode, 200
ns, DO-41
60 V, 15 A, Schottky, TO-220AC
3.15 A, 250 V, Fast, TR5
HEATSINK, Straight Fin, 8.3 °C/W,
TO-220
Test Point, BLK,THRU-HOLE MOUNT
Test Point, WHT,THRU-HOLE
MOUNT
Test Point, RED,THRU-HOLE MOUNT
Wire Jumper, Non insulated, 22 AWG,
0.2 in
3.3 µH, 5.5 A, 8.5 x 11 mm
200 kΩ, 5%, 1/2 W, Carbon Film
3 kΩ, 5%, 1/2 W, Carbon Film
30 Ω, 5%, 1/2 W, Carbon Film
16 kΩ, 5%, 1/4 W, Carbon Film
33 Ω, 5%, 1/4 W, Carbon Film
10 kΩ, 1%, 1/4 W, Metal Film
47 Ω, 5%, 1/4 W, Carbon Film
1 kΩ, 5%, 1/4 W, Carbon Film
100 Ω, 5%, 1/4 W, Carbon Film
2.0 MΩ, 5%, 1/4 W, Carbon Film
4.7 Ω, 5%, 1/4 W, Carbon Film
NTC Thermistor, 16 Ω, 2.7 A
Bobbin, EEL22, Vertical, 10 pins
TinySwitch-III, TNY280P, DIP-8C
Opto coupler, 35 V, CTR 80-160%, 4DIP
2.495 V Shunt Regulator IC, 2%, 0 to
70C, TO-92
150 V, 5 W, 5%, TVS, DO204AC (DO15)
17 V, 5%, 500 mW, DO-35
5.1 V, 2%, 500 mW, DO-35
Mfg Part Number
EPAG451ELL101M
M35S
B37987F5104K000 /
ECU-S1H104KBB
ECK-D3A102KBP
KME35VB101M6X1
1LL
440LD10
ECU-S2A471KBA
EKZE100ELL152MJ
25S
ELXZ100ELL471MH
12D
EKME500ELL2R2M
E11D
ECQ-E6223KF
1N4007
1N4937
Mfg
Nippon ChemiCon
Epcos/Panasonic
Panasonic
Nippon ChemiCon
Vishay
Panasonic
Nippon ChemiCon
Nippon ChemiCon
Nippon ChemiCon
Panasonic
Vishay
15TQ060
370 1315 041
Vishay
International
Rectifier
Wickmann
6032B-TT
5011
AAVID/Thermalloy
Keystone
5012
5010
Keystone
Keystone
298
R622LY-3R3M
CFR-50JB-200K
CFR-50JB-3K0
CFR-50JB-30R
CFR-25JB-16K
CFR-25JB-33R
MFR-25FBF-10K0
CFR-25JB-47R
CFR-25JB-1K0
CFR-25JB-100R
CFR-25JB-2M0
CFR-25JB-4R7
CL170
YC-2207
TNY280P
Alpha
Toko
Yageo
Yageo
Yageo
Yageo
Yageo
Yageo
Yageo
Yageo
Yageo
Yageo
Yageo
Thermometrics
Ying Chin
Power
Integrations
PC817X1
Sharp
TL431CLP
Texas Instruments
P6KE150A
1N5247B
1N5231C
Vishay
Microsemi
Microsemi
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DER-114
PC Standby Power Supply – TNY280P
June 28, 2006
7 Transformer Specification
7.1
Electrical Diagram
Figure 4 – Transformer Electrical Diagram.
7.2
Electrical Specifications
Electrical Strength
Primary Inductance
Resonant Frequency
Primary Leakage Inductance
7.3
1 second, 60 Hz, from Pins 1-5 to Pins 7-10
Pins 1-3, all other windings open, measured at
100 kHz, 0.4 VRMS
Pins 1-3, all other windings open
Pins 1-3, with Pins 7-10 shorted, measured at
100 kHz, 0.4 VRMS
3000 VAC
1084 µH, -/+10%
1200 kHz (Min.)
28 µH (Max.)
Materials
Item
[1]
[2]
[3]
[4]
[5]
[6]
[7]
[8]
[9]
Description
Core: PC40 - EEL22 with air gap GAPPED ALG VALUE- 131nH/T2
Bobbin: EEL-22, 10 Pin Bobbin (Ying Chin YC-2207/ Pin Shine P-2204 or equivalent)
Magnet Wire: #28 AWG Heavy Nyleze
Copper Foil 12 mm X 0.1 mm
Tape: 3M #44 Polyester Web Margin Tape 3 mm wide
Tape, 3M 1298 Polyester Film 18.5 mm, 0.002” Thick
Tape, 3M 1298 Polyester Film 12.5 mm, 0.002” Thick
Tape, 3M 1298 Polyester Film 4 mm, 0.002” Thick
Varnish
Page 11 of 28
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DER-114
7.4
PC Standby Power Supply – TNY280P
June 28, 2006
Transformer Build Diagram
Figure 5a – Transformer Build Diagram.
Figure 5b – Secondary Tape Preparation.
7.5
Figure 5c – Secondary Tape Cross-Section
Transformer Construction
Bobbin Preparation
Primary Margin
Primary WD#1
Basic Insulation
Secondary Margin
Secondary WD # 2
Basic Insulation
Bias Margin
Bias Winding
WD # 3
Basic Insulation
Primary Margin
Primary WD#4
Outer Wrap
Core Assembly
Varnish
Page 12 of 28
Set up Bobbin with pins oriented to the left hand side
Apply 3.0 mm wide margin to both sides of bobbin using item [5]. Match
height of primary windings.
Start at Pin 3. Wind 30 turns of item [3] in approximately 1 layer. Add 1
Layer of Tape [7] for insulation. Wind remaining 30 primary turns, finish
on Pin 2.
Use two layers of item [6] for basic insulation.
Apply 3.0 mm wide margin to both sides of bobbin using item [5]. Match
height of secondary winding.
Prepare Copper Foil as shown in figure 5b & 5c above. Starting at Pin 10,
wind 5 turns of item [4]. Finish at Pin 7.
Use two layers of item [6] for basic insulation.
Apply 3.0 mm wide margin to both sides of bobbin using item [5]. Match
height of bias winding
Start at Pins 4. Wind 14 turns of item [3]. Spread turns evenly across
bobbin. Finish on Pins 5.
Use two layers of item [6] for insulation
Apply 3.0 mm wide margin to both sides of bobbin using item [5]. Match
height of 1 layer of primary winding.
Start at Pin 2. Wind 31 turns of item [3] and end at pin 1.
Wrap windings with 2 layers of tape item [6].
Assemble cores item [1] on bobbin and secure using item [8].
Dip Varnish using item [9]
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DER-114
PC Standby Power Supply – TNY280P
June 28, 2006
8 Transformer Spreadsheets
(Note – Output current is made 4.20 A in the spreadsheet to account for load on the auxiliary output)
ACDC_TinySwitchIII_020706; Rev.1.6;
ACDC_TinySwitch-III_020706_Rev1-6.xls;
Copyright Power
TinySwitch-III Continuous/Discontinuous
Integrations 2006
INPUT
INFO
OUTPUT
UNIT
Flyback Transformer Design Spreadsheet
ENTER APPLICATION VARIABLES
VACMIN
85
Volts
Minimum AC Input Voltage
VACMAX
295
Volts
Maximum AC Input Voltage
fL
50
Hertz
AC Mains Frequency
VO
5.00
Volts
Output Voltage (at continuous power)
Power Supply Output Current (corresponding
to peak power)
IO
4.20
Amps
Power
21
Watts
Continuous Output Power
Efficiency Estimate at output terminals. Enter
0.7 if no better data available
n
0.75
Z Factor. Ratio of secondary side losses to
the total losses in the power supply. Use 0.5 if
Z
0.50
no better data available
tC
3.00
mSeconds Bridge Rectifier Conduction Time Estimate
CIN
100.00
100
uFarads
Input Capacitance
ENTER TinySwitch-III VARIABLES
TinySwitch-III
TNY280
Chosen Device
User defined TinySwitch-III
TNY280
TNY280
Standard
Current Limit
0.698
0.750
0.802
124000
Amps
Amps
Amps
Hertz
66.825
A^2kHz
100
Volts
VDS
VD
KP
10
0.5
0.49
Volts
Volts
KP_TRANSIENT
0.27
ENTER BIAS WINDING VARIABLES
VB
15
VDB
NB
VZOV
15.00
0.70
13.64
21.00
Volts
Volts
V_UV_TARGET
112.88
Volts
V_UV_ACTUAL
RUV_IDEAL
109.70
4.43
Volts
Mohms
RUV_ACTUAL
4.30
Mohms
Chose Configuration
ILIMITMIN
ILIMITTYP
ILIMITMAX
fSmin
STD
I^2fmin
VOR
100.00
Volts
Enter "RED" for reduced current limit (sealed
adapters), "STD" for standard current limit or
"INC" for increased current limit (peak or
higher power applications)
Minimum Current Limit
Typical Current Limit
Maximum Current Limit
Minimum Device Switching Frequency
I^2f (product of current limit squared and
frequency is trimmed for tighter tolerance)
Reflected Output Voltage (VOR < 135 V
Recommended)
TinySwitch-III on-state Drain to Source
Voltage
Output Winding Diode Forward Voltage Drop
Ripple to Peak Current Ratio (KP < 6)
Transient Ripple to Peak Current Ratio.
Ensure KP_TRANSIENT > 0.25
Bias Winding Voltage
Bias Winding Diode Forward Voltage Drop
Bias Winding Number of Turns
Over Voltage Protection zener diode.
UVLO VARIABLES
ENTER TRANSFORMER CORE/CONSTRUCTION VARIABLES
Core Type
EEL22
EEL22
Core
EEL22
EEL22_BOBB
Bobbin
IN
Page 13 of 28
Target under-voltage threshold, above which
the power supply with start
Typical start-up voltage based on standard
value of RUV_ACTUAL
Calculated value for UV Lockout resistor
Closest standard value of resistor to
RUV_IDEAL
P/N:
User-Selected transformer core
PC40EE22/29/6-Z
P/N:
EEL22_BOBBIN
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DER-114
PC Standby Power Supply – TNY280P
AE
LE
AL
BW
M
L
NS
3.20
3.00
5
DC INPUT VOLTAGE PARAMETERS
VMIN
VMAX
June 28, 2006
0.358
6.32
1400
18
cm^2
cm
nH/T^2
mm
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
3.2
3
5
mm
103
417
Volts
Volts
Minimum DC Input Voltage
Maximum DC Input Voltage
Amps
Amps
Amps
Amps
Duty Ratio at full load, minimum primary
inductance and minimum input voltage
Average Primary Current
Minimum Peak Primary Current
Primary Ripple Current
Primary RMS Current
CURRENT WAVEFORM SHAPE PARAMETERS
DMAX
IAVG
IP
IR
IRMS
0.52
0.30
0.6980
0.3448
0.44
TRANSFORMER PRIMARY DESIGN PARAMETERS
LP
LP_TOLERANCE
NP
ALG
1084
10
91
131
uHenries
%
BM
2671
Gauss
BAC
ur
LG
BWE
660
1967
0.31
34.8
Gauss
OD
0.383
mm
INS
DIA
0.06
0.324
mm
mm
AWG
CM
28
161
AWG
Cmils
CMA
364
Cmils/Amp
10.00
nH/T^2
mm
mm
TRANSFORMER SECONDARY DESIGN PARAMETERS
Lumped parameters
ISP
12.69
ISRMS
7.75
IRIPPLE
6.51
Amps
Amps
Amps
CMS
1550
Cmils
18
AWG
AWGS
Typical Primary Inductance. +/- 10% to
ensure a minimum primary inductance of 985
uH
Primary inductance tolerance
Primary Winding Number of Turns
Gapped Core Effective Inductance
Maximum Operating Flux Density, BM<3000
is recommended
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)
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)
VOLTAGE STRESS PARAMETERS
VDRAIN
647
Volts
PIVS
28
Volts
TRANSFORMER SECONDARY DESIGN PARAMETERS (MULTIPLE OUTPUTS)
1st output
VO1
5
Volts
Page 14 of 28
Maximum Drain Voltage Estimate (Assumes
20% zener clamp tolerance and an additional
10% temperature tolerance)
Output Rectifier Maximum Peak Inverse
Voltage
Main Output Voltage (if unused, defaults to
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IO1
PO1
VD1
NS1
ISRMS1
IRIPPLE1
PIVS1
Recommended
Diodes
PC Standby Power Supply – TNY280P
4.200
21.00
0.500
5.00
7.749
6.51
Amps
Watts
Volts
Amps
Amps
28
Volts
MBR1060
CMS1
1550
Cmils
AWGS1
DIAS1
18
1.03
AWG
mm
ODS1
2.32
mm
Page 15 of 28
June 28, 2006
single output design)
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
Recommended Diodes for this output
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
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9 Performance Data
All measurements performed at room temperature, 60 Hz input frequency.
9.1 Efficiency
(4 A Load on 5 V Output)
Figure 6 – Efficiency vs. Input Voltage, Room Temperature, 60 Hz.
9.2
No-load Input Power
Figure 7 – Zero Load Input Power vs. Input Line Voltage, Room Temperature, 60 Hz.
Page 16 of 28
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9.3
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0.5 W (5 V, 0.1 A) Load Input Power
Figure 8 – 0.5 W Load – Input Power with & without bias winding.
9.4 Available Standby Output Power
The chart below shows the available output power vs. line voltage for an input power
consumption of 1, 2 & 3 watts respectively. ON/OFF control is valuable in maintaining
high efficiency under light load conditions, and helps meet many standby requirements.
Figure 9 – Available Standby Output Power.
Page 17 of 28
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9.5
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June 28, 2006
Regulation
9.5.1 Load
Figure 10 – Load Regulation, Room Temperature.
9.5.2 Line
Figure 11 – Line Regulation, Room Temperature, Full Load.
Page 18 of 28
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10 Thermal Performance
Temperature measurement of key components were taken using T-type Thermocouples.
The thermocouples were attached directly to the SOURCE pin of the TNY280P device
and the case of the output rectifier. The thermocouples were glued to the output
capacitor & to the external core and winding surfaces of the transformer T1.
The cooling of the TNY280P is achieved through the copper plane on the PCB. It is
necessary to provide adequately large copper area on the PCB attached to the SOURCE
pins (5, 6, 7 and 8) of the DIP-8 package, to achieve the required cooling (se figure 3).
These results indicate an acceptable temperature rise of key components when ambient
is increased to 50 ºC.
Temperature (°C)
Item
85 VAC
Page 19 of 28
115 VAC 230 VAC
Ambient
25
25
25
Transformer (T1) core
49.9
45
44
Transformer (T1) coil
52.4
50.6
49.6
Tiny-Switch (U1)
62.3
56.3
49
Rectifier (D7) case
75
75
74
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11 Waveforms
11.1 Drain Voltage and Current, Normal Operation
Figure 12 – 90 VAC, Full Load.
Upper: VDRAIN, 50 V / div
Lower: IDRAIN, 0.4 A, 1 µs / div
Figure 14 – 90 VAC, Full Load
VDRAIN, 50 V, 10 µs / div.
Page 20 of 28
Figure 13 – 283 VAC, Full Load
Upper: VDRAIN, 100 V / div
Lower: IDRAIN, 0.4 A, 0.5 µs / div
Figure 15 – 283 VAC, Full Load
VDRAIN, 100 V, 20 µs / div.
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11.2 Drain Voltage & Current Startup Profile
Figure 16 – Start-up Profile, 90 VAC
Upper: VDRAIN, 200 V / div
Lower: IDRAIN, 0.4 A, 50 ms / div
Figure 17 – Start-up Profile, 283 VAC
Upper: VDRAIN, 200 V / div
Lower: IDRAIN, 0.4 A, 50 ms / div
11.3 Output Voltage Startup Profile
Figure 18 – Start-up Profile, 90 VAC (No Load)
VOUT, 1 V, 5 ms / div.
Page 21 of 28
Figure 19 – Start-up Profile, 90 VAC (Full Load)
VOUT, 1 V, 5 ms / div.
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Figure 20 – Start-up Profile, 283 VAC (No Load)
VOUT, 1 V, 5 ms / div
June 28, 2006
Figure 21 – Start-up Profile, 283 VAC (Full Load)
VOUT, 1 V, 5 ms / div.
11.4 OV Shutdown
Two different OV Protection circuits can be designed with TinySwitch-III. Figure 22
shows operation of primary side OV protection circuit (JP1 and JP2 not installed) and
feedback disconnected to cause OV condition at the output.
Figure 23 shows OV protection offered by VR3, U4 & R10 circuit (Feedback
disconnected during operation to cause OV condition at output).
Figure 22 – 5 V Output Voltage.
VOUT, 2 V, 200 ms / div
Page 22 of 28
Figure 23 – 5 V Output Voltage.
VOUT, 2 V, 20 ms / div.
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11.5 Load Transient Response (3 A to 4 A Load Step)
In the figures shown below, signal averaging was used to enable better viewing of the
load transient response. The oscilloscope was triggered using the load current step as a
trigger source. Since the output switching and line frequency occur essentially at random
with respect to the load transient, contributions to the output ripple from these sources
will average out, leaving only the contribution from the load step response.
The waveforms (Figures 24 and 25) show an instantaneous voltage change of 70 mV for
a 75% - 100% step load change. Increasing the size of the output filter capacitor
minimizes the 70 mV change.
Figure 24 – Transient Response, 90 VAC
Upper: VOUT, 100 mV, 2 ms / div
Lower: IOUT, 3 A to 4 A Load Step
Page 23 of 28
Figure 25 – Transient Response, 283 VAC
Upper: VOUT, 100 mV, 2 ms / div
Lower: IOUT, 3 A to 4 A Load Step
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11.6 Output Ripple Measurements
11.6.1 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 26 and Figure 27.
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 26 – Oscilloscope Probe Prepared for Ripple Measurement. (End Cap and Ground Lead Removed)
Figure 27 – Oscilloscope Probe with Probe Master 5125BA BNC Adapter. (Modified with wires for probe
ground for ripple measurement, and two parallel decoupling capacitors added)
Page 24 of 28
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11.6.2 Measurement Results
Figure 28 – 5 V Ripple, 90 VAC, Full Load.
VOUT, 20 mV, 10 ms / div
Page 25 of 28
Figure 29 – 5 V Ripple, 283 VAC, Full Load.
VOUT, 20 mV, 10 ms / div
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PC Standby Power Supply – TNY280P
June 28, 2006
12 Design Notes:
1. Use of sufficient copper area directly under the TNY280P device, connected to the
SOURCE pins of the IC is recommended for effective cooling. Generally, 1 square
inch of symmetrical copper (2 oz) should be sufficient. However, actual
temperature measurements should be used to determine adequacy. This is
especially important when using the TinySwitch-III devices at or near the power
levels specified on the datasheet output power table.
2. A dummy load (R2 in figure 2) was used in this design to ensure appropriate line &
load regulation of the auxiliary output. Since this output is not directly regulated, it
has a slightly higher output voltage when unloaded. The value of R13 should be
selected, based on the current drawn by the external circuit that loads the auxiliary
output. The filtering of the auxiliary output, and the need for an additional filter
stage should be carefully evaluated, based on the load circuit’s requirements.
3. R13 & C4 form a RC filter to reduce the ripple voltage on the auxiliary output
4. In many applications, the snubber circuit (R3, C3 & R1) can be eliminated,
depending on the EMC compliance requirements of the system.
5. The size and specification of the output diode (D7) heat sink depends on load and
operating conditions. In some designs, where augmented airflow is available, a
small surface-area heat sink may be sufficient.
Page 26 of 28
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PC Standby Power Supply – TNY280P
June 28, 2006
13 Revision History
Date
Author
28-June-06 RJ
Page 27 of 28
Revision
1.0
Description & changes
Initial Release
Reviewed
PV / JJ / KM
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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 2005 Power Integrations.
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