STMicroelectronics L6590D Fully integrated power supply fip Datasheet

L6590
FULLY INTEGRATED POWER SUPPLY
■
■
■
■
■
■
■
■
■
WIDE-RANGE MAINS OPERATION
"ON-CHIP" 700V V(BR)DSS POWER MOS
65 kHz INTERNAL OSCILLATOR
2.5V ± 2% INTERNAL REFERENCE
STANDBY MODE FOR HIGH EFFICIENCY AT
LIGHT LOAD
OVERCURRENT AND LATCHED
OVERVOLTAGE PROTECTION
NON DISSIPATIVE BUILT-IN START-UP CIRCUIT
THERMAL SHUTDOWN WITH HYSTERESIS
BROWNOUT PROTECTION (SMD PACKAGE
ONLY)
MAIN APPLICATIONS
■ WALL PLUG POWER SUPPLIES UP TO 15 W
■ AC-DC ADAPTERS
■ AUXILIARY POWER SUPPLIES FOR:
- CRT AND LCD MONITOR (BLUE ANGEL)
- DESKTOP PC/SERVER
- FAX, TV, LASER PRINTER
MINIDIP
SO16W
ORDERING NUMBERS:
L6590N
■
L6590D
- HOME APPLIANCES/LIGHTING
LINE CARD, DC-DC CONVERTERS
DESCRIPTION
The L6590 is a monolithic switching regulator designed in BCD OFF-LINE technology, able to operate
with wide range input voltage and to deliver up to
15W output power. The internal power switch is a lateral power MOSFET with a typical RDS(on) of 13Ω
and a V(BR)DSS of 700V minimum.
TYPICAL APPLICATION CIRCUIT
AC line
88 to 264 Vac
Pout
up to 15W
AC line
88 to 264 Vac
Pout
up to 15W
DRAIN
DRAIN
1
1
L6590
L6590
Vcc
Vcc
3
3
6, 7, 8
GND
4
Primary Feedback
October 2000
6, 7, 8
5
COMP
VFB
GND
VFB
5
4
COMP
Secondary Feedback
1/23
L6590
efficiency (Pin < 1W @ Pout = 0.5W with wide range
mains).
DESCRIPTION (continued)
The MOSFET is source-grounded, thus it is possible
to build flyback, boost and forward converters.
Internal protections like cycle-by-cycle current limiting,
latched output overvoltage protection, mains undervoltage protection (SMD version only) and thermal shutdown generate a 'robust' design solution.
The device can work with secondary feedback and a
2.5V±2% internal reference, in addition to a high gain
error amplifier, makes possible also the use in applications either with primary feedback or not isolated.
The IC uses a special leadframe with the ground pins
(6, 7 and 8 in minidip, 9 to16 in SO16W package) internally connected in order for heat to be easily removed from the silicon die. An heatsink can then be
realized by simply making provision of few cm2 of
copper on the PCB. Furthermore, the pin(s) close to
the high-voltage one are not connected to ease compliance with safety distances on the PCB.
The internal fixed oscillator frequency and the integrated
non dissipative start-up generator minimize the external
component count and power consumption.
The device is equipped with a standby function that
automatically reduces the oscillator frequency from
65 to 22 kHz under light load conditions to enhance
BLOCK DIAGRAM
DRAIN
(1) [1]
[x] : L6590D (SO16W)
START-UP
VREF
SUPPLY
& UVLO
THERMAL
SHUTDOWN
VCC
(3) [4]
+
-
OVP
VREF
SGND
[5]
BROWNOUT
+
+
-
GND
(6,7,8)
PGND
[9, ..., 16]
-
OCP
2.5V
BOK
[6]
PWM
STANDBY
VFB
(5) [8]
-
OSC
65/22 kHz
+
2.5V
COMP
(4) [7]
PIN CONNECTIONS (Top view)
DRAIN
GND
DRAIN
PGND
N.C.
PGND
N.C.
PGND
N.C.
GND
Vcc
PGND
Vcc
GND
SGND
PGND
COMP
VFB
BOK
PGND
COMP
PGND
VFB
PGND
MINIDIP
L6590
SO16W
L6590D
2/23
L6590
PIN FUNCTIONS
Pin#
Name
Description
L6590
L6590D
1
1
DRAIN
2
2, 3
N.C.
Not internally connected. Provision for clearance on the PCB.
3
4
VCC
Supply pin of the IC. An electrolytic capacitor is connected between this pin and ground.
The internal start-up generator charges the capacitor until the voltage reaches the startup threshold. The PWM is stopped if the voltage at the pin exceeds a certain value.
4
7
COMP
Output of the Error Amplifier. Used for control loop compensation or to directly control
PWM with an optocoupler.
5
8
VFB
Inverting input of the Error Amplifier. The non-inverting one is internally connected to a
2.5V± 2% reference. This pin can be grounded in some feedback schemes.
6 to 8
-
GND
Connection of both the source of the internal MOSFET and the return of the bias current
of the IC. Pins connected to the metal frame to facilitate heat dissipation.
-
6
BOK
Brownout Protection. If the voltage applied to this pin is lower than 2.5V the PWM is
disabled. This pin is typically used for sensing the input voltage of the converter through
a resistor divider. If not used, the pin can be either left floating or connected to Vcc
through a 15 kΩ resistor.
-
5
SGND
Current return for the bias current of the IC.
-
9 to 16
PGND
Connection of the source of the internal MOSFET. Pins connected to the metal frame to
facilitate heat dissipation.
Drain connection of the internal power MOSFET. The internal high voltage start-up
generator sinks current from this pin.
THERMAL DATA
Symbol
Parameter
Rthj-amb
Thermal Resistance Junction to ambient (*)
Rthj-pins
Thermal Resistance Junction to pins
Minidip
SO16W
Unit
35 to 60
40 to 65
°C/W
15
20
°C/W
(*) Value depending on PCB copper area and thickness.
ABSOLUTE MAXIMUM RATINGS
Symbol
Value
Unit
-0.3 to 700
V
Drain Current
0.7
A
Vcc
IC Supply Voltage
18
V
Iclamp
Vcc Zener Current
20
mA
Error Amplifier Ouput Sink Current
3
mA
Voltage on Feedback Input
5
V
BOK pin Sink Current
1
mA
1.5
W
Operating Junction Temperature
-40 to 150
°C
Storage Temperature
-40 to 150
°C
Vds
Id
Ptot
Parameter
Drain Source Voltage
Power Dissipation at Tamb < 50°C (Minidip and SO16W)
3 cm2, 2 oz copper dissipating area on PCB
Tj
Tstg
3/23
L6590
ELECTRICAL CHARACTERISTCS (Tj = -25 to 125°C, Vcc = 10V; unless otherwise specified)
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
POWER SECTION
V(BR)DSS Drain Source Voltage
Idss
RDS(on)
Id < 200 µA; Tj = 25 °C
Off state drain current
Vds = 560V; Tj = 125 °C
Drain-to-Source on resistance
RDS(on) vs. Tj: see fig. 20
Id = 120mA; Tj = 25 °C
Id = 120mA; Tj = 125 °C
700
V
200
µA
13
16
Ω
23
28
ERROR AMP SECTION
VFB
Ib
Avol
B
Input Voltage
Tj = 25 °C
2.45
2.5
2.55
Tj = 125°C
2.4
2.5
2.6
0.3
5
E/A Input Bias Current
VFB = 0 to 2.5 V
DC Gain
open loop
Unity Gain Bandwidth
V
µA
60
70
dB
0.7
1
MHz
SVR
Supply voltage Rejection
f = 120 Hz
70
dB
Isink
Output Sink Current
VCOMP = 1V
1
mA
Output Source Current
VCOMP = 3.5V; VFB = 2V
-0.5
-1
VCOMPH
Vout High
Isource = -0.5mA; VFB=2V
3.8
4.50
VCOMPL
Vout Low
Isink = 1mA ; VFB=3V
Isource
-2.5
mA
V
1
V
kHz
OSCILLATOR SECTION
Fosc
Oscillator Frequency
Tj = 25 °C
Dmin
Min. Duty Cycle
VCOMP = 1V
Dmax
Max. Duty Cycle
VCOMP = 4V
58
65
72
52
65
74
67
0
%
70
73
%
DEVICE OPERATION SECTION
Iop
Operating Supply Current
fsw = Fosc
4.5
7
mA
IQ
Quiescent Current
MOS disabled
3.5
6
mA
VCC charge Current
Vcc = 0V to Vccon - 0.5V;
Vds = 100 to 400V; Tj = 25°C
-3
-4.5
-7
mA
Vcc = 0V to Vccon - 0.5V;
Vds = 100 to 400V
-2.5
-4.5
-7.5
mA
Iclamp = 10mA (*)
16.5
17
17.5
V
Icharge
VCCclamp VCC clamp Voltage
Vccon
Start Threshold
voltage
(*)
14
14.5
15
V
Vccoff
Min operating voltage after Turn
on
(*)
6
6.5
7
V
Vdsmin
Drain start voltage
40
V
4/23
L6590
ELECTRICAL CHARACTERISTICS (continued)
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
CIRCUIT PROTECTIONS
Ipklim
Pulse-by-pulse Current Limit
di/dt = 120 mA/ µs
550
625
700
mA
OVP
Overvoltage Protection
Icc = 10 mA (*)
16
16.5
17
V
LEB
Masking Time
After MOSFET turn-on (**)
120
ns
STANDBY SECTION
FSB
Oscillator Frequency
Ipksb
Peak switch current for Standby
Operation
Transition from Fosc to FSB
80
mA
Ipkno
Peak switch current for Normal
Operation
Transition from FSB to Fosc
190
mA
19
22
25
kHz
BROWNOUT PROTECTION (L6590D only)
Vth
Threshold Voltage
Voltage either rising or falling
2.4
2.5
2.6
V
IHys
Current Hysteresis
Vpin = 3V
-30
-50
-70
µA
VCL
Clamp Voltage
Ipin = 0.5 mA
5.6
6.4
7.2
V
150
165
°C
40
°C
THERMAL SHUTDOWN (***)
Threshold
Hysteresis
(*) Parameters tracking one the other
(**) Parameter guaranteed by design, not tested in production
(***) Parameters guaranteed by design, functionality tested in production
Figure 1. Start-up & UVLO Thresholds
Figure 2. Start-up Current Generator
Vcc [V]
Icc [mA]
16
5.5
Vdrain = 40 V
14
5
Start-up
12
4.5
10
4
UVLO
8
Tj = -25 °C
Tj = 25 °C
3.5
Tj = 125 °C
6
-50
0
50
Tj [°C]
100
150
3
0
2
4
6
8
10
12
Vcc [V]
5/23
L6590
Figure 3. Start-up Current Generator
Figure 6. IC Operating Current
Icc [mA]
Icc [mA]
5.5
5
Vdrain = 60 V
VFB = 2.3 V
fsw = 65 kHz
Tj = -25 °C
5
Tj = 125 °C
4.5
Tj = 25 °C
Tj = 25 °C
4.5
4
Tj = -25 °C
4
Tj = 125 °C
3.5
3.5
3
0
2
4
6
8
10
12
3
7
8
9
10
11
12
Figure 4. IC Consumption Before Start-up
Figure 7. IC Operating Current
Icc [µA]
Icc [mA]
700
4.4
Tj = -25 °C
600
VFB = 2.3 V
fsw = 22 kHz
4.2
14
15
Tj = 125 °C
4
500
Tj = 25 °C
Tj = 25 °C
400
3.8
Tj = -25 °C
3.6
Tj = 125 °C
300
3.4
200
100
13
Vcc [V]
Vcc [V]
3.2
7
8
9
10
11
12
13
14
15
3
7
8
9
10
11
12
13
14
15
Vcc [V]
Vcc [V]
Figure 5. IC Quiescent Current
Figure 8. Switching Frequency vs.
Temperature
Icc [mA]
4
fsw [kHz]
Tj = 25 °C
VFB = 2.7 V
80
3.8
Normal operation
70
60
3.6
50
3.4 Tj = 125 °C
Tj = -25 °C
3.2
3
40
Standby
30
20
6
8
10
12
Vcc [V]
14
16
18
10
-50
0
50
Tj [°C]
6/23
100
150
L6590
Figure 9. Vcc clamp vs. Temperature
Figure 12. OCP threshold vs. Temperature
VCCclamp [V]
Ipklim / (Ipklim @ Tj = 25°C)
1.1
18
di/dt = 120 mA/µs
1.08
17.8
1.06
17.6
Iclamp = 20 mA
1.04
17.4
Iclamp = 10 mA
1.02
17.2
17
-50
1
0
50
100
150
0.98
-50
0
50
100
150
Tj [°C]
Tj [°C]
Figure 10. OVP Threshold vs. Temperature
Figure 13. Internal E/A Reference Voltage
Vth [V]
Vref [V]
16
2.6
15.8
2.55
15.6
2.5
15.4
2.45
15.2
15
-50
0
50
100
2.4
-50
150
0
50
100
Figure 11. OCP Threshold vs. Current Slope
Figure 14. Error Amplifier Slew Rate
Ipklim / (Ipklim @ di/dt = 120 mA/µs)
VCOMP [V]
1.06
5
Tj = 25 °C
1.04
4
RL = 10 kΩ
CL = 100 pF
open loop
VCOMP
3 V
FB
1.02
1
2
0.98
1
0.96
50
150
Tj [°C]
Tj [°C]
0
100
150
dI/dt [mA/µs]
200
250
0
2
4
6
8
10
12
14
16
t [µs]
7/23
L6590
Figure 15. COMP pin Characteristic
Figure 18. Breakdown Voltage vs. Temperature
VCOMP [V]
BVDSS / (BVDSS @ Tj = 25°C)
6
1.08
VFB = 0
Tj = 25 °C
5
1.06
Idrain = 200 µA
1.04
4
1.02
3
1
0.98
2
0.96
1
0
0.94
0
0.2
0.4
0.6
0.8
1
1.2
1.4
0.92
-50
0
50
ICOMP [mA]
100
150
Tj [°C]
Figure 16. COMP pin Dynamic Resistance vs.
Temperature
Figure 19. Drain Leakage vs. Drain Voltage
RCOMP [kOhm]
50
Idrain [µA]
Tj = 125 °C
10.5
VFB = 0
10
9.5
9
40
Tj = 25 °C
30
Tj = -25 °C
20
8.5
10
100
8
-50
0
50
100
200
300
400
500
600
700
Vdrain [V]
150
Tj [°C]
Figure 20. Rds(ON) vs. Temperature
Figure 17. Error Amplifier Gain and Phase
Rds(ON) / (Rds(ON) @ Tj=25°C)
1.8
dB
°
0
Phase
100
1.6
Idrain = 120 mA
1.4
Gain
90
1.2
50
mφ
0
1
180
0.8
1
10
100
1k
1M
f [Hz]
8/23
10k
100k
0.6
-50
0
50
Tj [°C]
100
150
L6590
Figure 21. Rds(ON) vs. Idrain
Figure 22. Coss vs. Drain Voltage
Rds(ON) / (Rds(ON) @ Idrain=120 mA)
Coss [pF]
1.3
250
Tj = 25 °C
Tj = 25 °C
200
1.2
150
1.1
100
1
0.9
50
0
100
200
300
400
500
600
Idrain [mA]
0
0
100
200
300
400
500
600
700
Vdrain [V]
Figure 23. Standby Function Thresholds
Drain Peak Current [mA]
220
22 kHz → 65 kHz
200
180
160
140
120
65 kHz → 22 kHz
100
80
60
-50
0
50
100
150
Tj [°C]
9/23
L6590
Figure 24. Test Board (1) with Primary Feedback: Electrical Schematic
F1
2A/250V
BD1
DF06M
Vin
88 to 264 Vac
T1
C1
22 µF
400 V
D4 BYW100-100
L1
4.7 µH
Vo =12 V ± 10%
Po= 1 to 10 W
D1
BZW06-154
C9
100 µF
16 V
C7, C8
330 µF
16 V
D2
STTA106
R1 68 Ω
IC1
1
3
C4
100 nF
C5
R3
680 nF 1.1 kΩ
L6590
6, 7, 8
D3
C2
22 µF 1N4148
25 V
R2
5.6 kΩ
C7
2.2 nF
Y
4
R5
110 Ω
C6
10 nF
5
T1 specification
Core E20/10/6, ferrite 3C85 or N67 or equivalent
≈0.5 mm gap for a primary inductance of 2.9 mH
Lleakage <90 µH
Primary : 180 T, 2 series windings 90T each, AWG33 (∅ 0.22 mm)
Sec : 19 T, AWG30 (∅ 0.3 mm)
Aux : 19 T, AWG33
R4
1.5 kΩ
Figure 25. Test Board (1) Evaluation Data
Load & Line regulation
Efficiency
Output Voltage [V]
Efficiency [%]
13.5
86
1W
12.5
Pout =
10 W
84
13
82
5W
80
2.5 W
78
12
11.5
50
5W
76
Pout =
10 W
74
100
150
200
Input Voltage [Vac]
10/23
250
300
72
50
2.5 W
1W
100
150
200
Input Voltage [Vac]
250
300
L6590
Figure 26. Test Board (1) Main Waveforms
Ch3: Idrain
Ch3: Idrain
Vin = 400 VDC
Pout = 10 W
Vin = 100 VDC
Pout = 10 W
Ch2: Vdrain
Ch2: Vdrain
Ch3: Idrain
Ch3: Idrain
Vin = 100 VDC
Pout = 1 W
Vin = 400 VDC
Pout = 1 W
Ch2: Vdrain
Ch2: Vdrain
Figure 27. Test Board (2) with Secondary Feedback: Electrical Schematic
F1
2A/250V
Vin
88 to 264
Vac
CxA
100 nF
L
22 mH
BD1
DF06M
T1
C1
22 µF
400 V
CxB
100 nF
L1
4.7 µH
D4 1N5822
D1
BZW06-154
C8
220 µF
10V
Rubycon
ZL
C5, C6, C7
470 µF
16V
Rubycon ZL
D2
STTA106
5 Vdc / 2 A
R1 10 Ω
1
C2
22 µF
25V
3
IC1
L6590
6, 7, 8
5
D3
1N4148
R2
560 Ω
4
C3
22 nF
OP1
PC817
1
4
3
R5
2 kΩ
2
R6
6.8 kΩ
C9
100 nF
1
2
R3
2.43 kΩ
3
C4
2.2 nF
Y1
class
IC2
TL431
R4
2.43 kΩ
T1 specification
Core E20/10/6, ferrite 3C85 or N67 or equivalent
≈0.6 mm gap for a primary inductance of 1.4 mH
Lleakage <30 µH
Primary : 128 T, 2 series windings 64T each, AWG32 (∅ 0.22 mm)
Sec : 6 T, 4xAWG32
Aux : 14 T, AWG32
11/23
L6590
Figure 28. Test Board (2) evaluation data
Load & Line regulation
Efficiency
Output Voltage [V]
Efficiency [%]
80
5
264 VAC
4.98
88 VAC
70
60
4.96
110 VAC
264 VAC
50
40
110 VAC
4.92
30
88 VAC
4.9
0.003
220 VAC
220 VAC
4.94
0.01
0.03
0.1
0.3
1
20
0.003
3
0.01
0.03
Load Current [A]
0.1
0.3
1
3
Load Current [A]
Device Power Dissipation
Light-load Consumption
Pdiss [W]
Input Power [mW]
5
1,000
Pout
0.5W
800
Rthj-amb= 58 °C/W @ 1.5W
2
88 V AC
264 VAC
1
600
0.25W
0.5
0.1W
0.05W
0W
0.2
220 VAC
400
200
0
50
100
150
200
250
300
350
400
450
DC Input Voltage [V]
Figure 29. Test Board (2) EMI Characterization
12/23
110 VAC
0.1
0.05
0.003
0.01
0.03
0.1
0.3
Load Current [A]
1
3
L6590
Figure 30. Test Board (2) Main Waveforms
Ch1: Vdrain
A1: Idrain
Vin = 400 VDC
Iout = 2 A
Vin = 100 VDC
Iout = 2 A
A1: Idrain
Ch1: Vdrain
A1: Idrain
A1: Idrain
Vin = 100 VDC
Iout = 50 mA
Ch1: Vdrain
Vin = 400 VDC
Iout = 50 mA
Ch1: Vdrain
Figure 31. Test Board (2) Load Transient Response
Vout
Vout
Vin = 200 VDC
Iout = 0.2 ↔ 0.4 A
transition
65 22 kHz
⇒
transition
22 65 kHz
⇒
Vin = 200 VDC
Iout = 0.1 ↔ 0.3 A
Iout
Iout
Standby Function
is not tripped
Standby Function
is tripped
13/23
L6590
APPLICATION INFORMATION
In the following sections the functional blocks as well as the most important internal functions of the device will
be described.
Start-up Circuit
When power is first applied to the circuit and the voltage on the bulk capacitor is sufficiently high, an internal
high-voltage current generator is sufficiently biased to start operating and drawing about 4.5 mA through the
primary winding of the transformer and the drain pin. Most of this current charges the bypass capacitor connected between pin Vcc (3) and ground and makes its voltage rise linearly.
As the Vcc voltage reaches the start-up threshold (14.5V typ.) the chip, after resetting all its internal logic, starts
operating, the internal power MOSFET is enabled to switch and the internal high-voltage generator is disconnected. The IC is powered by the energy stored in the Vcc capacitor until the self-supply circuit (typically an
auxiliary winding of the transformer) develops a voltage high enough to sustain the operation.
As the IC is running, the supply voltage, typically generated by a self-supply winding, can range between 16 V
(Overvoltage protection limit, see the relevant section) and 7 V, threshold of the Undervoltage Lockout. Below
this value the device is switched off (and the internal start-up generator is activated). The two thresholds are in
tracking.
The voltage on the Vcc pin is limited at safe values by a clamp circuit. Its 17V threshold tracks the Overvoltage
protection threshold.
Figure 32. Start-up circuit internal schematic
DRAIN
POWER
MOSFET
15 MΩ
UVLO
150 Ω
Vcc
17 V
GND
Power MOSFET and Gate Driver
The power switch is implemented with a lateral N-channel MOSFET having a V(BR)DSS of 700V min. and a typical RDS(on) of 13Ω. It has a SenseFET structure to allow a virtually lossless current sensing (used only for protection).
During operation in Discontinuous Conduction Mode at low mains the drain voltage is likely to go below ground.
Any risk of injecting the substrate of the IC is prevented by an internal structure surrounding the switch.
The gate driver of the power MOSFET is designed to supply a controlled gate current during both turn-on and
turn-off in order to minimize common mode EMI.
Under UVLO conditions an internal pull-down circuit holds the gate low in order to ensure that the power MOSFET cannot be turned on accidentally.
14/23
L6590
Figure 33. PWM Control internal schematic
Max. Duty cycle
S
OSCILLATOR
Clock
R
+
PWM
-
Q
to gate
driver
from OCP
comparator
+
E/A
-
COMP
VFB
Oscillator and PWM Control
PWM regulation is accomplished by implementing voltage mode control. As shown in fig. 33, this block includes
an oscillator, a PWM comparator, a PWM latch and an Error Amplifier.
The oscillator operates at a frequency internally fixed at 65 kHz with a precision of ± 10 %. The maximum duty
cycle is limited at 70% typ.
The PWM latch (reset dominant) is set by the clock pulses of the oscillator and is reset by either the PWM comparator or the Overcurrent comparator.
The Error Amplifier (E/A) is an op-amp with a MOS input stage and a class AB output stage. The amplifier is
compensated for closed loop stability at unity gain, has a small-signal DC gain of 70 dB (typ.) and a gain-bandwidth product over 1 MHz.
In case of overcurrent the error amplifier output saturates high and the conduction of the power MOSFET is
stopped by the OCP comparator instead of the PWM comparator.
Under zero load conditions the error amplifier is close to its low saturation and the gate drive delivers as short
pulses as it can, limited by internal delays. They are however too long to maintain the long-term energy balance,
thus from time to time some cycles need being skipped and the operation becomes asynchronous. This is automatically done by the control loop.
Standby Function
The standby function, optimized for flyback topology, automatically detects a light load condition for the converter and decreases the oscillator frequency. The normal oscillation frequency is automatically resumed when the
output load builds up and exceeds a defined threshold.
This function allows to minimize power losses related to switching frequency, which represent the majority of losses
in a lightly loaded flyback, without giving up the advantages of a higher switching frequency at heavy load.
The Standby function is realized by monitoring the peak current in the power switch. If the load is low that it does
not reach a threshold (80 mA typ.), the oscillator frequency will be set at 22 kHz typ.
When the load demands more power and the peak primary current exceeds a second threshold (190 mA typ.)
the oscillator frequency is reset at 65 kHz. This 110 mA hysteresis prevents undesired frequency change when
power is such that the peak current is close to either threshold.
The signal coming from the sense circuit is digitally filtered to avoid false triggering of this function as a result of
large load changes or noise.
15/23
L6590
Figure 34. Standby Function timing diagram
Pout
0000000000000000000000000000000000000000000000
80 mA
190 mA
Peak 0000000000000000000000000000000000000000000000
0000000000000000000000000000000000000000000000
Primary 0000000000000000000000000000000000000000000000
0000000000000000000000000000000000000000000000
0000000000000000000000000000000000000000000000
Current 0000000000000000000000000000000000000000000000
0000000000000000000000000000000000000000000000
0000000000000000000000000000000000000000000000
0000000000000000000000000000000000000000000000
0000000000000000000000000000000000000000000000
Load
regulation
Vout
small glitch
STANDBY
(before filter)
2 ms
1 ms
STANDBY
(filtered)
65 kHz
fsw
22 kHz
Brownout Protection (L6590D only)
Brownout Protection is basically a not-latched device shutdown functionality. It will typically be used to detect a
mains undervoltage (brownout). This condition may cause overheating of the primary power section due to an
excess of RMS current.
Figure 35. Brownout Protection Function internal schematic and timing diagram
HV Input bus
VON
VOFF
HV Input bus
Vcc
VinOK
50 µA
BOK
Vcc
+
6.4 V
VinOK
-
2.5 V
L6590D
PWM
Vout
16/23
000000000000000000000
000000000000000000000
000000000000000000000
000000000000000000000
000000000000000000000
000000000000000000000
000000000000000000000
000000000000000000000
L6590
Another problem is the spurious restarts that are likely to occur during converter power down if the input voltage
decays slowly (e.g. with a large input bulk capacitor) and that cause the output voltage not to decay to zero
monothonically.
Converter shutdown can be accomplished with the L6590D by means of an internal comparator that can be
used to sense the voltage across the input bulk capacitor. This comparator is internally referenced to 2.5V and
disables the PWM if the voltage applied at its non-inverting input, externally available, is below the reference.
PWM operation is re-enabled as the voltage at the pin is more than 2.5V.
The brownout comparator is provided with current hysteresis instead of a more usual voltage hysteresis: an internal 50 µA current generator is ON as long as the voltage applied at the non-inverting input exceeds 2.5V and
is OFF if the voltage is below 2.5V. This approach provides an additional degree of freedom: it is possible to set
the ON threshold and the OFF threshold separately by properly choosing the resistors of the external divider,
which is not possible with voltage hysteresis.
Overvoltage Protection
The IC incorporates an Overvoltage Protection (OVP) that can be particularly useful to protect the converter and
the load against voltage feedback loop failures. This kind of failure causes the output voltage to rise with no
control and easily leads to the destruction of the load and of the converter itself if not properly handled.
If such an event occurs, the voltage generated by the auxiliary winding that supplies the IC will fly up tracking
the output voltage. An internal comparator continuously monitors the Vcc voltage and stops the operation of the
IC if the voltage exceeds 16.5 V. This condition is latched and maintained until the Vcc voltage falls below the
UVLO threshold. The converter will then operate intermittently.
Figure 36. OVP internal schematic
Vcc
DRAIN
to
MOSFET
+
to OVP
latch
OVP
-
GND
Overcurrent Protection
The device uses pulse-by-pulse current limiting for Overcurrent Protection (OCP), in order to prevent overstress
of the internal MOSFET: its current during the ON-time is monitored and, if it exceeds a determined value, the
conduction is terminated immediately. The MOSFET will be turned on again in the subsequent switching cycle.
As previously mentioned, the internal powerMOSFET has a SenseFET structure: the source of a few cells are
connected together and kept separate from the other source connections so as to realize a 1:100 current divider.
The "sense" portion is connected to a ground referenced, sense resistor having a low thermal coefficient. The
OCP comparator senses the voltage drop across the sense resistor and resets the PWM latch if the drop exceeds a threshold, thus turning off the MOSFET. In this way the overcurrent threshold is set at about 0.65 A
(typical value).
17/23
L6590
At turn-on, there are large current spikes due to the discharge of parasitic capacitances and, in case of Continuos Conduction Mode operation, to secondary diode reverse recovery as well, which could falsely trigger the
OCP comparator. To increase noise immunity the output of the OCP comparator is blanked for a short time
(about 120 ns) just after the MOSFET is turned on, so that any disturbance within this time slot is rejected (Leading Edge Blanking).
Figure 37. OCP internal schematic
DRAIN
Max. Duty cycle
S
OSCILLATOR
Driver
Clock
R
Q
1
1/100
+
PWM
-
+
OCP
-
Clock
LEB
Rsense
0.5 V
GND
Thermal Shutdown
Overheating of the device due to an excessive power throughput or insufficient heatsinking is avoided by the
Thermal Shutdown function. A thermal sensor monitors the junction temperature close to the power MOSFET
and, when the temperature exceeds 150 °C (min.), sets an alarm signal that stops the operation of the device.
This is a not-latched function and the power MOSFET is re-enabled as the temperature falls about 40 °C.
18/23
L6590
APPLICATION IDEAS
Figure 38. 10W AC-DC adapter with no isolation
F1
2A/250V
Vin
88 to 264 Vac
CxA
100 nF
L
22 mH
BD1
DF06M
T1
C1
22 µF
400 V
CxB
100 nF
L1
4.7 µH
D4 STPS3L60S
D1
BZW06-154
C9
100 µF
16 V
C7, C8
330 µF
16 V
D2
STTA106
Vo =12 V ± 3%
Io= 0 to 0.8 A
R1 10 Ω
C2
22 µF
25 V
IC1
1
3 (4)
L6590
(L6590D)
6, 7, 8
(9 to 16)
D3
1N4148
R2
3.9 kΩ
C4
R3
100 nF 27 kΩ
4
(7)
C5
2.2 nF
5 (8)
R4
1 kΩ
T1 specification
Core E20/10/6, ferrite 3C85 or N67 or equivalent
≈0.5 mm gap for a primary inductance of 1.6 mH
Lleakage <30 µH
Primary : 130 T, 2 series windings 65T each, AWG33 (∅ 0.22 mm)
Sec : 14 T, AWG26 (∅ 0.4 mm)
Figure 39. 15W Auxiliary SMPS for PC
T1
Vin = 200 to 375 Vdc
L1
4.7 µH
D4 STPS10L25D
D1
BZW06-154
C8
100 µF
10V
C5, C6, C7
470 µF
10 V
D2
STTA106
5 Vdc / 3 A
R1 10 Ω
R2
1.8 MΩ
1
C2
22 µF
25 V
4
D3
1N4148
R4
560 Ω
IC1
6
8
C1
10 nF
L6590D
5
7
9, ..., 16
C3
47 nF
4
1
3
2
R5
2.43 kΩ
OP1
PC817
R7
240 Ω
R3
20 kΩ
1
C4
2.2 nF
Y
2
3
C9
470 nF
IC2
TL431
R6
2.43 kΩ
T1 specification
Core E20/10/6, ferrite 3C85 or N67 or equivalent
≈ 0.9 mm gap for a primary inductance of 2 mH
Lleakage <50 µH
Primary : 200 T, 2 series windings 100T each, AWG33 (∅ 0.22 mm)
Sec : 9 T, 2 x AWG23 (∅ 0.64 mm)
Aux : 21 T, AWG33
19/23
L6590
Figure 40. 7.2V/7W Battery Charger
F1
2A/250V
Vin
88 to 264 Vac
L
22 mH
CxA
100 nF
C1
22 µF
400 V
CxB
100 nF
D5
1N4148
T1
16:1
BD1
DF06M
3
1
3 (4)
L6590
(L6590D)
6, 7, 8
(9 to 16)
R1
39 Ω
C3
10 µF
25V
5
(8)
C5, C6
330 µF
16V
D4 1N5821
C2
220 nF
R7
620 Ω
C3 10 nF
C7
10 µF
25V
D8
BZX79C12
R6
0.1 Ω
R8
560 Ω
R9
22.6 kΩ
C8 680 nF
C4
2.2 nF
Y1 class
R10
6.8 kΩ
1
R11
2
11.8 kΩ
R4 10 kΩ
R3
1.5 kΩ
R12
1 kΩ
T1 specification
Core E20/10/6, ferrite 3C85 or N67 or equivalent
≈ 1 mm gap for a primary inductance of 2.6 mH
Lleakage <60 µH
Primary : 230 T, 2 series windings 115T each, AWG36 (∅ 0.16 mm)
Sec : 13 T, AWG23 (∅ 0.64 mm)
Aux : 60 T, AWG36
6
5
D6
1N4148
D7
1N4148
8
3
IC2
7 TSM103 2
1
4
R13
12 kΩ
C9 330 nF
REFERENCES
[1] “Getting Familiar with the L6590 Family, High-voltage Fully Integrated Power Supply” (AN1261)
[2] “Offline Flyback Converters Design Methodology with the L6590 Family” (AN1262)
20/23
7.2 Vdc / 1 A
D3 BAV21
4
OP1
PC817
4 (7)
Q1
BC337
D1
BZW06-154
D2
STTA106
R2
5.6 kΩ
R5
4.7 kΩ
L6590
21/23
L6590
22/23
L6590
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