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DIPIPM+ Series Application note
(3) Calculation of shunt resistance
The value of current sensing shunt resistance for current sensing is calculated by the following formulation:
R
= V
/SC
Shunt
SC(ref)
The maximum SC trip level SC(max) should be set less than the IGBT minimum saturation current which is 1.7
times as large as the rated current. For example, the SC(max) of PSS25MC1FT should be set to 25x1.7=42.5A.
The parameters (V
SC(ref)
of DIPIPM+ series is +/-0.025V in the specification of V
Table 2-2-1 Specification for V
Symbol
V
SC(ref)
Therefore, the range of SC trip level can be calculated by the following descriptions with +/-5% dispersion of
shunt resistor :
R
=V
Shunt(min)
SC(ref) max
where SC(max) is 1.7 times of rated current, and so 0.95 is due to -5% dispersion of shunt resistor that
R
= R
Shunt(typ)
Shunt(min)
Therefore, SC(typ) = V
R
= R
Shunt(max)
Shunt(typ)
Therefore, SC(min)= V
In this case, SC trip level is 42.5A,
= 0.505V / 42.5A = 11.9 mΩ, R
R
Shunt(min)
When the both of SC trip level and shunt resistor will be maximum, typical and minimum, these will be described
as follows;
SC(max)= 42.5 A (setting), SC (typ) = 0.480 / 12.5 = 38.4 A, SC(min) = 0.455 / 13.1 = 34.7 A
From the above, the SC trip level range is described as Table 2-2-2.
Table 2-2-2 Operative SC Range
Condition
Tj=25°C, V
There is the possibility that the actual SC protection level becomes less than the calculated value. This is
considered due to the resonant signals caused mainly by parasitic inductance and parasitic capacitance. It is
recommended to make a confirmation of the resistance by prototype experiment.
(4) RC filter time constant
It is necessary to set an RC filter in the SC sensing circuit in order to prevent malfunction of SC protection due
to noise interference. The RC time constant is determined depending on the applying time of noise interference
and the SCSOA of the DIPIPM.
When the voltage drop on the external shunt resistor exceeds the SC trip level, The time (t1) that the CIN
terminal voltage rises to the referenced SC trip level can be calculated by the following expression:
=
⋅
V
R
I
SC
shunt
c
τ
=
−
⋅
−
t
1
ln(
1
R
Where Vsc is the CIN terminal input voltage, Ic is the peak current, τ is the RC time constant.
On the other hand, the typical time delay t2 (from Vsc voltage reaches Vsc(ref) to IGBT gate shutdown) of IC
is shown in Table 2-2-3.
Table 2-2-3 Internal time delay of IC
Item
IC transfer delay time
Therefore, the total delay time from an SC level current happened to the IGBT gate shutdown becomes:
t
=t1+t2
TOTAL
Publication Date: September 2016
where V
is the SC trip voltage.
SC(ref)
, R
) dispersion should be considered when designing the SC trip level. The dispersion
Shunt
SC(ref)
Condition
Tj=25°C, V
=15V
D
/SC(max)
/ 0.95
/ R
SC(ref) typ
Shunt(typ)
x 1.05*
/ R
SC(ref) min
Shunt(max)
min.
=15V
34.7
D
t
1
−
ε
⋅
−
τ
1 (
)
V
SC
)
⋅
I
shunt
c
Min
-
as shown in Table 2-2-1.
SC(ref)
Min
Typ
Max
0.455
0.480
0.505
.
*1.05 is due to +5% dispersion of shunt resistor
= 11.9mΩ / 0.95 = 12.5 mΩ, R
Shunt(typ)
typ.
max.
38.4
42.5
typ
max
-
1.0
15
Unit
V
= 12.5 x 1.05 = 13.1mΩ
Shunt(max)
Unit
A
Unit
μs
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