LT3798EMSE 查看數據表(PDF) - Linear Technology
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LT3798EMSE Datasheet PDF : 20 Pages
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LT3798
OPERATION
Switch Voltage Clamp Requirement
Leakage inductance of an offline transformer is high due
to the extra isolation requirement. The leakage inductance
energy is not coupled to the secondary but goes into
the drain node of the MOSFET. This is problematic since
400V and higher rated MOSFETs cannot always handle
this energy by avalanching. Therefore the MOSFET needs
protection. A transient voltage suppressor (TVS) and diode
are recommended for all offline application and connected,
as shown in Figure 3. The TVS device needs a reverse
breakdown voltage greater than (VOUT + VF) • NPS where
VOUT is the output voltage of the flyback converter, VF is
the secondary diode forward voltage, and NPS is the turns
ratio. An RCD clamp can be used in place of the TVS clamp.
VSUPPLY
VSUPPLY
GATE
GATE
3798 F03
Figure 3. TVS & RCD Switch Voltage Clamps
In addition to clamping the spike, in some designs where
short circuit protection is desired, it will be necessary to
decrease the amount of ringing by using an RC snubber.
Leakage inductance ringing is at its worst during a short
circuit condition, and can keep the converter from cycling
on and off by peak charging the bias capacitor. On/off
cycling is desired to keep power dissipation down in the
output diode. Alternatively, a heat sink can be used to
manage diode temperature.
The recommended approach for designing an RC snubber
is to measure the period of the ringing at the MOSFET
drain when the MOSFET turns off without the snubber
and then add capacitance—starting with something in
the range of 100pF—until the period of the ringing is 1.5
to 2 times longer. The change in period will determine
the value of the parasitic capacitance, from which the
parasitic inductance can be determined from the initial
period, as well. Similarly, initial values can be estimated
using stated switch capacitance and transformer leakage
inductance. Once the value of the drain node capacitance
and inductance is known, a series resistor can be added
to the snubber capacitance to dissipate power and criti-
cally dampen the ringing. The equation for deriving the
optimal series resistance using the observed periods
(tPERIOD, and tPERIOD(SNUBBED)) and snubber capacitance
(CSNUBBER) is below, and the resultant waveforms are
shown in Figure 4.
CPAR
=
CSNUBBER
tPERIOD(SNUBBED)
tPERIOD
2
–
1
LPAR
=
tPERIOD2
CPAR • 4π2
RSNUBBER =
LPAR
CPAR
90
80
70
60
50
40
30
20
10
0
0
NO SNUBBER
WITH SNUBBER
CAPACITOR
WITH RESISTOR
AND CAPACITOR
0.05 0.10 0.15 0.20 0.25 0.30
TIME (µs)
3798 F04
Figure 4. Observed Waveforms at MOSFET Drain when
Iteratively Implementing an RC Snubber
Note that energy absorbed by a snubber will be converted
to heat and will not be delivered to the load. In high volt-
age or high current applications, the snubber may need to
be sized for thermal dissipation. To determine the power
dissipated in the snubber resistor from capacitive losses,
measure the drain voltage immediately before the MOS-
FET turns on and use the following equation relating that
3798fa
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