DI100/150 THRU DI1010/1510 DUAL-IN-LINE GLASS PASSIVATED SINGLE-PHASE BRIDGE RECTIFIER VOLTAGE - 50 to 1000 Volts CURRENT - 1.0~1.5 Amperes DIP FEATURES l Plastic material used carries Underwriters Laboratory recognition 94V-O l Low leakage l Surge overload rating— 30~50 amperes peak l Ideal for printed circuit board l Exceeds environmental standards of MIL-S-19500/228 MECHANICAL DATA Case: Reliable low cost construction utilizing molded plastic technique results in inexpensive product Terminals: Lead solderable per MIL-STD-202, Method 208 Polarity: Polarity symbols molded or marking on body Mounting Position: Any Weight: 0.02 ounce, 0.4 gram MAXIMUM RATINGS AND ELECTRICAL CHARACTERISTICS Ratings at 25 ambient temperature unless otherwise specified. Single phase, half wave, 60Hz, Resistive or inductive load. For capacitive load, derate current by 20%. Maximum Recurrent Peak Reverse Voltage Maximum RMS Bridge input Voltage Maximum DC Blocking Voltage Maximum Average Forward Current DI100 TA=40 DI150 Peak Forward Surge Current, 8.3ms single DI100 half sine-wave superimposed on rated load DI150 I2t Rating for fusing ( t < 8.35 ms) Maximum Forward Voltage Drop per Bridge Element at 1.0A Maximum Reverse Current at Rated TJ= 25 DC Blocking Voltage per element TJ=125 Typical Junction capacitance per leg (Note 1) CJ Typical Thermal resistance per leg (Note 2) R JA Typical Thermal resistance per leg (Note 2) R JL Operating Temperature Range TJ Storage Temperature Range TA DI100 DI101 DI150 DI151 50 100 35 70 50 100 DI102 DI104 DI152 DI154 200 400 140 280 200 400 1.0 1.5 30.0 50.0 10.0 1.1 DI106 DI156 600 420 600 5.0 0.5 25.0 40.0 15.0 -55 to +125 -55 to +150 DI108 DI1010 UNITS DI158 DI1510 V 800 1000 V 560 700 V 800 1000 A A A2t V A mA PF /W NOTES: 1. Measured at 1.0 MHz and applied reverse voltage of 4.0 Volts 2. Thermal resistance from junction to ambient and from junction to lead mounted on P.C.B. with 0.5×0.5”(13×13mm) copper pads RATING AND CHARACTERISTIC CURVES DI100/150 THRU DI1010/1510 Fig. 1-MAXIMUM NON-REPETITIVE SURGE CURRENT Fig. 2-DERATING CURVE FOR OUTPUT RECTIFIED CURRENT Fig. 3-TYPICAL FORWARD CHARACTERISTICS Fig. 4-TYPICAL REVERSE CHARACTERISTICS