NCP1075: Non-isolated, 8 W Dual Output, Off-line Power Supply

DN05038/D
Design Note – DN05038/D Rev 1
Non-Isolated, 8 Watt Dual Output, Off-line Power Supply
Device
Application
NCP1075
NST45011
White Goods,
Industrial Equipment
Input Voltage
180 to 270 Vac
Output Power
Topology
I/O Isolation
8 Watts Nominal
Non-Isolated
Flyback
No isolation from
mains
Other Specification
Output Voltage
Ripple
Nominal Current
Max Current
Min Current
Output 1
Output 2
Output 3
Output 4
5.0 Vdc +/- 2%
200 mV p/p
1A
1.25 A
1%
8.5 Vdc +/- 5%
200 mV p/p
200 mA
300 mA
1%
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
No
76% at 8 watts output
Yes – limiting resistor and fuse
0 – 50 C
Convection
NA
68 mW @ 230 Vac
PFC (Yes/No)
Efficiency
Inrush Limiting / Fuse
Operating Temp. Range
Cooling Method /
Supply Orientation
No Load Standby Power
Others Optional high regulation sense circuit using NCP431
Circuit Description
This Design Note features an 8 watt, off-line, dual output,
flyback power supply intended for powering white goods or
industrial equipment circuitry which does not require output
isolation from the AC mains. The flyback converter is
designed around ON Semiconductor’s 100 kHz NCP1075
monolithic switching controller. A simple voltage sensing
and feedback scheme utilizing a current mirror transistor
pair (Q1), and zener diode (Z1) is utilized for low cost yet
effective output regulation for most typical applications.
This particular design example provides output voltages of
5V and 8.5V but these can be tailored to other voltages to
accommodate the specific requirements by appropriate
transformer turns ratio changes and alterations to voltage
setting zener Z1 and resistor R6.
The regulation loop is closed around the 5 volt main output
while the 8.5 volt output is configured using a “slave”
secondary winding on the transformer. The slave
secondary is tightly coupled to the main 5V winding via
bifilar winding techniques which assures reasonable load
and cross regulation without requiring dedicated regulation
circuitry. Other 2nd channel voltages are possible by
changing the turns of the slave secondary winding.
October 2012, Rev. 0
Logic power (Vcc) for the control chip is derived via diode
D9 directly from the slave output. Since the control IC
needs a minimum of about 8 volts to maintain efficient
operation, Schottky D6 is provided as an optional logic Vcc
source instead of D9 in the event it is required that the
second output is somewhat less than 8 volts. At Vcc
voltages less than about 8 volts, the controller will operate
in DSS mode and there will be some degradation in overall
circuit efficiency.
Although this design is for European mains voltage, a
transformer design for a universal AC input version is
available on request. A 5V/12V transformer design is also
included in the information below.
Key Features
 Schottky diodes (D6, D7) on both outputs for high
efficiency
 Dual sensing options depending on desired regulation
accuracy
 Input EMI filter for conducted emission compliance
 Input fuse and inrush limiting resistor (R1)
 Good load and cross regulation on 8.5Vout due to
secondary winding technique on transformer
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1
DN05038/D
Schematic1
D6
D9
BAT54
MMSD
4148A
D8
J1
F1
L
1 mH
1A
C1
AC Input
T1
L1A
0.1uF
"X"
R2A
C2
3.3M
R1
N
6.8 ohms
2W
(wire wound)
D1-D4
MRA4007
X4
C3
0.1uF
"X"
R2B L1B
68K
1/2W
1 mH
Primary
Ground
Plane
4
MBRS240
C11
C10
1000uF
16V
6
1
VS2
+8.5V
C9A C9B
1nF
1kV
0.1uF
50V
8
VS1
+5V
D5
10uF
400V
U1
3.3M
C4
R3
7
1N4937
3
2
4
5
D7
C8
Com
MBRS240
(100 kHz)
C5
22uF
25V
0.1uF
50V
R4
1
NCP1075
1500uF, 6.3V
Z1
2K
C6
10nF
C7
0.1uF
Q1
NST45011
R5
MMSZ
5229B
(4.3V)
R6
100
Vtrim
120
R9
10K
R10
10K
NOTES:
1. Crossed schematic lines are not connected.
2. R4 value dependent on VS2 nominal output voltage.
3. R1 is optional inrush limiting resistor.
4. U1 tab (pin 4) should have heatsinking clad pours and be
part of a ground plane area for best noise immunity.
5. Heavy lines indicate recommended ground plane areas.
6. L1A/L1B are Wurth 7447728102.
7. Z1 sets nominal 5Vout. R6 can trim Vout upward.
Non-Isolated, 8 Watt, Dual Output NCP1075 PSU
with Universal AC Input (Rev 8)
October 2012, Rev. 0
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2
DN05038/D
MAGNETICS DESIGN DATA SHEET
Project / Customer: ON Semiconductor - NCP1014/1075, 8W dual output PSU
Part Description: 8 watt flyback transformer, 100kHz, 5V/9V outputs (Rev 5 - Euro version)
Schematic ID: T1
Wurth Electronics Part # 750313309 Rev 02
Core Type: EF16 (E16/8/5); 3C90 material or similar
Core Gap: Gap for 5.5 mH +/- 5% inductance across primary (pins 1 - 4)
Inductance: 5 to 6 mH when measuring from pin 1 to pin 4
Bobbin Type: 8 pin horizontal mount for EF16
Windings (in order):
Winding # / type
Turns / Material / Gauge / Insulation Data
Primary A (4 - 2)
78 turns of #38 mag wire wound over 1 layer.
Insulate with Mylar tape for at least 1kV breakdown.
5V/8.5V Secondaries (8,5 - 7,6)
7 turns of two pieces of #26 magnet wire (different
colors) spiral wound bifilar over one layer. Remove two
turns so winding terminating to pins 7/6 has only
5 turns. Triple Insulated wire can also be used if
desired. Self-leads to pins.
Primary B (2 - 1)
Same as primary A.
Varnish assembly
Hipot: 1 kV from primary to secondary - no agency primary/secondary insulation requirements
Lead Breakout / Pinout
Schematic
(Bottom View - facing pins)
1
Pri B
2
8
7
5 turns
(8Vstack)
6
Pri A
4
October 2012, Rev. 0
4
7 turns
(5Vout)
3
2
1
5
6
7
8
5
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DN05038/D
MAGNETICS DESIGN DATA SHEET
Project / Customer: ON Semiconductor - NCP1014/1075, 8W dual output PSU
Part Description: 8 watt flyback transformer, 100kHz, 5V/12V outputs (Rev 1 - Euro version)
Schematic ID: T1
Core Type: EF16 (E16/8/5); 3C90 material or similar
Core Gap: Gap for 5.5 mH +/- 5% inductance across primary (pins 1 - 4)
Inductance: 5 to 6 mH when measuring from pin 1 to pin 4
Bobbin Type: 8 pin horizontal mount for EF16
Windings (in order):
Winding # / type
Turns / Material / Gauge / Insulation Data
Primary A (4 - 2)
78 turns of #38 mag wire wound over 1 layer.
Insulate with Mylar tape for at least 1kV breakdown.
5V/12V Secondaries (8,5 - 7,6)
7 turns of two pieces of #26 magnet wire (different
colors) spiral wound bifilar over one layer. Add two
more turns so the winding terminating to pins 7/6 has
9 turns total (12V stack). Triple Insulated wire can also
be used if desired. Self-leads to pins.
Primary B (2 - 1)
Same as primary A.
Varnish assembly
Hipot: 1 kV from primary to secondary - no agency primary/secondary insulation requirements
Lead Breakout / Pinout
Schematic
(Bottom View - facing pins)
1
Pri B
2
8
7
9 turns
(12Vstack)
6
Pri A
4
October 2012, Rev. 0
4
7 turns
(5Vout)
3
2
1
5
6
7
8
5
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4
DN05038/D
Efficiency versus Pout (5V:8.5V = 2:1 Loading Ratio Respectively)
8.5 Vout Load Regulation (5 Vout set to 1A Load)
October 2012, Rev. 0
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5
DN05038/D
Cross Regulation (8.5Vout loaded at 100mA)
Output Ripple – 5 Vout at 1 Amp
Output Ripple – 8.5 Vout at 350 mA
October 2012, Rev. 0
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6
DN05038/D
Mosfet Drain Voltage at 150 Vac Input and 8 Watt Load
Mosfet Drain Voltage at 265 Vac Input and 8 Watt Load
Mosfet Drain Voltage at 260 Vac Input and 1 Watt Load
October 2012, Rev. 0
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7
DN05038/D
Conducted EMI Scan with 8 Watt Load (EN55022, Level B; Average)
dBuV
1075 Dual
240Vac 60Hz Input
80
70
60
50
40
EN 55022; Class B Conducted, Average
Average
30
20
10
0
-10
-20
1
10
10/15/2012 11:24:00 AM
(Start = 0.15, Stop = 30.00) MHz
PC Board Layout/Photo
October 2012, Rev. 0
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DN05038/D
Designator
Qty Description
Value
Tolerance
Substitution Lead
Allowed
Free Comments
Footprint
Manufacturer
Manufacturer Part Number
SMB
SMA
axial lead
SOD-123
SOD-123
SOD-123
SOD-123
SOT-363
SOIC8 / SOT23
SOT223
ON Semi
ON Semi
ON Semi
ON Semi
ON Semi
ON Semi
ON Semi
ON Semi
ON Semi
ON Semi
MBRS240L (or MBRS2040L)
MRA4007
1N4937
BAT54
MMSD4148A
MMSZ5229B
MMSZ5223B
NST45011
NCP431A
NCP1075ST100
No
D7, D8
D1, 2, 3, 4
D5
D6
D9
Z1
Z2
Q1
U2
U1
2
4
1
1
1
1
1
1
1
1
Schottky diode
Diode - 60 Hz,
Diode - fast recov
Schottky diode
Signal diode
Zener diode
Zener diode
Dual NPN matched xstr
Programmable zener
Switcher IC - NCP1075
3A, 40V
1A, 800V
1A, 600V
200mA, 30V
100mA, 100V
4.3V, 500 mA
2.7V, 500 mA
45V, 100 mA
2.5V
100 kHz
C1, C2
C4
C6
C7, 8, 11
C12
C3
C10
C5
C9A, C9B
2
1
1
3
1
1
1
1
2
"X" cap, box type
Ceramic cap, disc
Ceramic cap, monolythic
Ceramic cap, monolythic
Ceramic cap, monolythic
Electrolytic cap
Electrolytic cap
Electrolytic cap
Electrolytic cap
100nF, X2
1 nF, 1kV
1 nF, 50V
100nF, 50V
100nF, 50V
10uF, 400/450V
1000uF, 16V
22uF, 25V
1,500uF, 6.3V
LS = 15 mm
LS = 7.5 mm
1206
1206
1206
LS=7.5mm, D=16mm
LS=5 mm, D=12.5mm
LS=2.5mm, D=6.3mm
LS=5mm, D=12.5mm
Rifa, Wima
Rifa, Wima
AVX, Murata
AVX, Murata
AVX, Murata
UCC, Panasonic
UCC, Panasonic
UCC, Panasonic
UCC, Panasonic
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
Yes
5%
10%
10%
10%
10%
10%
10%
10%
R1
R3
R2A,R2B
R5
R4
R9, R10
R7
R6
R8
R11
1
1
2
1
1
2
1
1
1
1
Resistor, 2W, Wire wound
Resistor, 0.5W, metal film
Resistor, 1/4W SMD
Resistor, 1/4W SMD
Resistor, 1/4W SMD
Resistor, 1/4W SMD
Resistor, 1/4W SMD
Resistor, 1/4W SMD
Resistor, 1/4W SMD
Resistor, 1/4W SMD
6.8 ohm, 2W
68K, 0.5W
3.3 Meg
120 ohms
2.0K
10K
10K
100 ohms
1 Meg
4.7K
10%
10%
5%
1%
1%
1%
1%
1%
1%
1%
LS=7.5mm, D=7mm
Axial lead; LS=12.5mm
SMD 1206
SMD 1206
SMD 1206
SMD 1206
SMD 1206
SMD 1206
SMD 1206
SMD 1206
Ohmite, Dale
Ohmite, Dale
AVX, Vishay, Dale
AVX, Vishay, Dale
AVX, Vishay, Dale
AVX, Vishay, Dale
AVX, Vishay, Dale
AVX, Vishay, Dale
AVX, Vishay, Dale
AVX, Vishay, Dale
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
Yes
F1
L1A/B
T1 (5/8.5Vout
J1
1
1
1
1
Fuse, TR-5 style
Inductor (EMI choke)
Transformer
Screw Terminal
TR-5, LS=5mm
See Wurth Drawing
See Mag Drawing
LS = 0.2"
Minifuse
LS=5mm, D=8mm
Wurth Magnetics
DigiKey
7447728102
750313309 Rev 02
# 281-1435-ND
1A
1 mH, 500 mA
E20/10/6 core
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No
No
No
For 12Vout and higher
No
No
No
No
No
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yellow indicates parts for standard Vout sense scheme
Green indicates parts for alternate Vout sense scheme.
October 2012, Rev. 0
No
9
12V version
DN05038/D
References:
NCP1075 data sheet: http://www.onsemi.com/pub_link/Collateral/NCP1072-D.PDF
NCP1075 Design Note: http://www.onsemi.com/pub_link/Collateral/DN05018-D.PDF
NCP1072 EVAL Board Documents:
http://www.onsemi.com/PowerSolutions/supportDoc.do?type=boards&rpn=NCP1072
1
© 2012 ON Semiconductor.
Disclaimer: ON Semiconductor is providing this design note “AS IS” and does not assume any liability arising from its use; nor
does ON Semiconductor convey any license to its or any third party’s intellectual property rights. This document is provided only to
assist customers in evaluation of the referenced circuit implementation and the recipient assumes all liability and risk associated
with its use, including, but not limited to, compliance with all regulatory standards. ON Semiconductor may change any of its
products at any time, without notice.
Design note created by Frank Cathell, e-mail: [email protected]
October 2012, Rev. 0
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