| No. | Partie # | Fabricant | Description | Fiche Technique |
|---|---|---|---|---|
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Power Innovations Limited |
SILICON TRIACS between the gate and Main Terminal 1. 2. This value applies for 50-Hz full-sine-wave operation with resistive load. Above 70°C derate linearly to 110°C case temperature at the rate of 500 mA/°C. 3. This value applies for one 50-Hz full-sine-wave whe |
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Power Innovations Limited |
SILICON TRIACS between the gate and Main Terminal 1. 2. This value applies for 50-Hz full-sine-wave operation with resistive load. Above 70°C derate linearly to 110°C case temperature at the rate of 500 mA/°C. 3. This value applies for one 50-Hz full-sine-wave whe |
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Power Innovations Limited |
SILICON TRIACS between the gate and Main Terminal 1. 2. This value applies for 50-Hz full-sine-wave operation with resistive load. Above 70°C derate linearly to 110°C case temperature at the rate of 500 mA/°C. 3. This value applies for one 50-Hz full-sine-wave whe |
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Power Innovations Limited |
SILICON TRIACS between the gate and Main Terminal 1. 2. This value applies for 50-Hz full-sine-wave operation with resistive load. Above 70°C derate linearly to 110°C case temperature at the rate of 500 mA/°C. 3. This value applies for one 50-Hz full-sine-wave whe |
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|
Power Innovations Limited |
SILICON TRIACS between the gate and Main Terminal 1. 2. This value applies for 50-Hz full-sine-wave operation with resistive load. Above 70°C derate linearly to 110°C case temperature at the rate of 500 mA/°C. 3. This value applies for one 50-Hz full-sine-wave whe |
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