FSQ0765RQUDTU Fairchild Semiconductor, FSQ0765RQUDTU Datasheet - Page 15
FSQ0765RQUDTU
Manufacturer Part Number
FSQ0765RQUDTU
Description
IC CONV QUASI-RES 650V TO-220F-6
Manufacturer
Fairchild Semiconductor
Series
FPS™r
Datasheet
1.FSQ0765RQWDTU.pdf
(19 pages)
Specifications of FSQ0765RQUDTU
Output Isolation
Isolated
Frequency Range
48kHz ~ 67kHz
Voltage - Input
9 V ~ 20 V
Voltage - Output
650V
Power (watts)
90W
Operating Temperature
-25°C ~ 85°C
Package / Case
TO-220-6 Formed Leads
On Resistance (max)
1.3 Ohms
Maximum Operating Temperature
+ 85 C
Minimum Operating Temperature
+ 25 C
Maximum Power Dissipation
45 W
Mounting Style
Through Hole
Off Time (max)
63 ns
On Time (max)
27 ns
Operating Frequency
66.7 KHz
Propagation Delay Time
200 ns
Supply Current
3 mA
Supply Voltage (max)
20 V
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Company:
Part Number:
FSQ0765RQUDTU
Manufacturer:
Fairchi/ON
Quantity:
30 000
FSQ0765RQ Rev. 1.0.1
© 2008 Fairchild Semiconductor Corporation
uses a sync signal instead of directly monitoring the
output voltage. If the sync signal exceeds 8V, an OVP is
triggered, shutting down the SMPS. To avoid undesired
triggering of OVP during normal operation, there are two
points to be considered, which are depicted in Figure 32.
One is at the peak voltage of the sync signal should be
designed below 6V and the other is that the spike of the
sync pin should be as low as possible; not to get longer
than t
at V
4.5 Thermal Shutdown with Hysteresis (TSD): The
SenseFET and the control IC are built in one package.
This allows the control IC to detect abnormally high
temperature of the SenseFET. If the temperature
exceeds approximately 140°C, the thermal shutdown
triggers IC shutdown. The IC recovers its operation when
the junction temperature decreases 60°C from TSD
temperature and V
5. Soft-Start: The FPS has an internal soft-start circuit
that increases PWM comparator inverting input voltage
with the SenseFET current slowly after it starts up. The
typical soft-start time is 17.5ms. The pulse width to the
power switching device is progressively increased to
establish the correct working conditions for transformers,
inductors, and capacitors. The voltage on the output
capacitors is progressively increased with the intention of
smoothly establishing the required output voltage. This
mode helps prevent transformer saturation and reduces
stress on the secondary diode during startup.
V
V
Vcc_coil
sync
CC
OVP
&V
winding coil.
CC
by decreasing the leakage inductance shown
Improper OVP triggering
V
t
OVP
Figure 32. OVP Triggering
CC
CC
Absolue max V
reaches startup voltage (V
V
V
V
OVP
SH2
V
Vcc_coil
CLAMP
(4.8V)
(8V)
CC
(20V)
FSQ0765R Rev.00
V
DC
t
OVP
N
N
start
pri
Vcc
).
15
6. Burst Operation: To minimize power dissipation in
standby mode, the FPS enters burst-mode operation. As
the load decreases, the feedback voltage decreases. As
shown in Figure 33, the device automatically enters
burst-mode when the feedback voltage drops below
V
output voltages start to drop at a rate dependent on
standby current load. This causes the feedback voltage
to rise. Once it passes V
resumes. The feedback voltage then falls and the
process repeats. Burst-mode operation alternately
enables and disables switching of the power SenseFET,
thereby reducing switching loss in standby mode.
7. Switching Frequency Limit: To minimize switching
loss and Electromagnetic Interference (EMI), the
MOSFET turns on when the drain voltage reaches its
minimum value in quasi-resonant operation. However,
this causes switching frequency to increases at light load
conditions. As the load decreases or input voltage
increases, the peak drain current diminishes and the
switching frequency increases. This results in severe
switching losses at light-load condition, as well as
intermittent switching and audible noise. These problems
create limitations for the quasi-resonant converter
topology in a wide range of applications.
To overcome these problems, FSQ-series employs a
frequency-limit function, as shown in Figures 34 and 35.
Once the SenseFET is turned on, the next turn-on is
prohibited during the blanking time (t
blanking time, the controller finds the valley within the
detection time window (t
shown in Figures 34 and Figure 35 (Cases A, B, and C).
BURL
FSQ0765R Rev.00
0.55V
0.35V
V
V
V
I
V
DS
FB
DS
O
set
O
Figure 33. Waveforms of Burst Operation
(350mV). At this point, switching stops and the
t1
Switching
disabled
W
) and turns on the MOSFET, as
t2 t3
BURH
Switching
disabled
(550mV), switching
B
www.fairchildsemi.com
). After the
t4
time
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