K0900E70 Datasheet, PDF(180/224 Page) Teccor Electronics – Thyristor Product Catalog

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K0900E70 Datasheet, PDF (180/224 Pages) Teccor Electronics – Thyristor Product Catalog

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AN1008

Application Notes

IT: Current Rating

SCR

For RMS and average currents, the restricting factor is usually

confined so that the power dissipated during the on state and as

a result of the junction-to-case thermal resistance will not pro-

duce a junction temperature in excess of the maximum junction

temperature rating. Power dissipation is changed to RMS and

average current ratings for a 60 Hz sine wave with a 180Â° con-

duction angle. The average current for conduction angles less

than 180Â° is derated because of the higher RMS current con-

nected with high peak currents. The DC current rating is higher

than the average value for 180Â° conduction since no RMS com-

ponent is present.

The dissipation for non-sinusoidal waveshapes can be deter-

mined in several ways. Graphically plotting instantaneous dissi-

pation as a function of time is one method. The total maximum

allowable power dissipation (PD) may be determined using the

following equation for temperature rise:

PD

=

T----J---(--M-----A---X----)---â-----T----C--

RÎ¸JC

where TJ(max) is the maximum rated junction temperature (at

zero rated current), TC is the actual operating case temperature,

and RÎ¸JC is the published junction-to-case thermal resistance.

Transient thermal resistance curves are required for short inter-

val pulses.

Triac

The limiting factor for RMS current is determined by multiplying

power dissipation by thermal resistance. The resulting current

value will ensure an operating junction temperature within maxi-

mum value. For convenience, dissipation is converted to RMS

current at a 360Â° conduction angle. The same RMS current can

be used at a conduction angle of less than 360Â°. For information

on non-sinusoidal waveshapes and a discussion of dissipation,

refer to the preceding description of SCR current rating.

ITSM: Peak Surge (Non-repetitive) On-state

Current â SCR and Triac

The peak surge current is the maximum peak current that may be

applied to the device for one full cycle of conduction without

device degradation. The maximum peak current is usually speci-

fied as sinusoidal at 50 Hz or 60 Hz. This rating applies when the

device is conducting rated current before the surge and, thus,

with the junction temperature at rated values before the surge.

The junction temperature will surpass the rated operating tem-

perature during the surge, and the blocking capacity may be

decreased until the device reverts to thermal equilibrium.

The surge-current curve in Figure AN1008.3 illustrates the peak

current that may be applied as a function of surge duration. This

surge curve is not intended to depict an exponential current

decay as a function of applied overload. Instead, the peak current

shown for a given number of cycles is the maximum peak surge

permitted for that time period. The current must be derated so

that the peak junction temperature during the surge overload

does not exceed maximum rated junction temperature if blocking

is to be retained after a surge.

1000

400

300

250

SUPPLY FREQUENCY: 60 Hz Sinusoidal

LOAD: Resistive

RMS ON-STATE CURRENT [IT(RMS)]:

Maximum Rated Value at Specified

Case Temperature

40 A TO-218

150

120

100

80

25 A T0-220

60

50

40

30

20

Notes:

1) Gate control may be lost

during and immediately

following surge current interval.

2) Overload may not be repeated

until junction temperature has

returned to steady-state

rated value.

15 A TO-220

10

1

10

100

1000

Surge Current Duration â Full Cycles

Figure AN1008.3 Peak Surge Current versus Surge Current Duration

ITM: Peak Repetitive On-state Current â SCR and Triac

The ITM rating specifies the maximum peak current that may be

applied to the device during brief pulses. When the device oper-

ates under these circumstances, blocking capability is main-

tained. The minimum pulse duration and shape are defined and

control the applied di/dt. The operating voltage, the duty factor,

the case temperature, and the gate waveform are also defined.

This rating must be followed when high repetitive peak currents

are employed, such as in pulse modulators, capacitive-discharge

circuits, and other applications where snubbers are required.

di/dt: Rate-of-change of On-state Current â SCR and Triac

The di/dt rating specifies the maximum rate-of-rise of current

through a thyristor device during turn-on. The value of principal

voltage prior to turn-on and the magnitude and rise time of the

gate trigger waveform during turn-on are among the conditions

under which the rating applies. If the rate-of-change of current

(di/dt) exceeds this maximum value, or if turn-on with high di/dt

during minimum gate drive occurs (such as dv/dt or overvoltage

events), then localized heating may cause device degradation.

During the first few microseconds of initial turn-on, the effect of

di/dt is more pronounced. The di/dt capability of the thyristor is

greatly increased as soon as the total area of the pellet is in full

conduction.

The di/dt effects that can occur as a result of voltage or transient

turn-on (non-gated) is not related to this rating. The di/dt rating is

specified for maximum junction temperature.

As shown in Figure AN1008.4, the di/dt of a surge current can be

calculated by means of the following equation.

-d---i = Ï----(---I--T---M-----)

dt

t

As an example, surge current of 400 A at 60 Hz has a di/dt of

Ï400/8.3 or 151.4 A/ms.

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AN1008 - 2

Â©2002 Teccor Electronics

Thyristor Product Catalog

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