129NQ150

Bulletin PD-20719 rev. A 03/01 129NQ...(R) SERIES SCHOTTKY RECTIFIER 120 Amp D-67 Major Ratings and Characteristics Characteristics IF(AV) Rectangular waveform VRRM range IFSM VF TJ @ tp = 5 µs sine @120Apk, TJ=125°C range Description/Features The 129NQ... (R) high current Schottky rectifier module series has been optimized for low reverse leakage at high temperature. The proprietary barrier technology allows for reliable operation up to 175° C junction temperature. Typical applications are in switching power supplies, converters, freewheeling diodes, and reverse battery protection. 175° C TJ operation Unique high power, Half-Pak module Replaces two parallel DO-5's Easier to mount and lower profile than DO-5's High purity, high temperature epoxy encapsulation for enhanced mechanical strength and moisture resistance Low forward voltage drop High frequency operation Guard ring for enhanced ruggedness and long term reliability 129NQ...(R) Units 120 A 135 to 150 10000 0.74 - 55 to 175 V A V °C 129NQ150 Lug Terminal Anode Base Cathode 129NQ150R Lug Terminal Cathode Base Anode Outline D-67 HALF PAK Module Dimensions in millimeters and (inches) www.irf.com 1 129NQ...(R) Series Bulletin PD-20719 rev. A 03/01 Voltage Ratings Part number VR Max. DC Reverse Voltage (V) 135 150 VRWM Max. Working Peak Reverse Voltage (V) 129NQ135 129NQ150 Absolute Maximum Ratings Parameters I F(AV) Max. Average Forward Current * See Fig. 5 I FSM Max. Peak One Cycle Non-Repetitive Surge Current * See Fig. 7 EAS I AR Non-Repetitive Avalanche Energy Repetitive Avalanche Current 129NQ Units 120 10000 1200 15 1 A Conditions 50% duty cycle @ TC = 117° C, rectangular wave form 5µs Sine or 3µs Rect. pulse 10ms Sine or 6ms Rect. pulse Following any rated load condition and with rated VRRMapplied A mJ A TJ = 25 °C, IAS = 1 Amps, L = 30 mH Current decaying linearly to zero in 1 µsec Frequency limited by TJ max. VA = 1.5 x VR typical Electrical Specifications Parameters V FM Max. Forward Voltage Drop * See Fig. 1 (1) 129NQ Units 1.07 1.27 0.74 0.86 V V V V mA mA pF nH V/ µs @ 120A @ 240A @ 120A @ 240A TJ = 25 °C TJ = 125 °C Conditions TJ = 25 °C TJ = 125 °C VR = rated VR IRM CT LS Max. Reverse Leakage Current (1) * See Fig. 2 Max. Junction Capacitance Typical Series Inductance 3 45 3000 7.0 10,000 VR = 5VDC, (test signal range 100Khz to 1Mhz) 25 °C From top of terminal hole to mounting plane dv/dt Max. Voltage Rate of Change ( Rated VR ) Thermal-Mechanical Specifications Parameters TJ Tstg Max. Junction Temperature Range Max. Storage Temperature Range (1) Pulse Width < 300µs, Duty Cycle < 2% 129NQ Units -55 to 175 -55 to 175 0.40 0.15 °C °C °C/W °C/W DC operation Conditions RthJC Max. Thermal Resistance Junction to Case RthCS Typical Thermal Resistance, Case to Heatsink wt T Approximate Weight Mounting Torque Terminal Torque Case Style Min. Max. Min. Max. * See Fig. 4 Mounting surface , smooth and greased 25.6 (0.9) g (oz.) 40 (35) 58 (50) 58 (50) 86 (75) HALF PAK Module Kg-cm (Ibf-in) Non-lubricated threads 2 129NQ...(R) Series Bulletin PD-20719 rev. A 03/01 1000 1000 100 Reverse Current - I R (mA) TJ = 175˚C 150˚C 125˚C 10 1 0.1 0.01 25˚C 100˚C 75˚C 50˚C 100 Instantaneous Forward Current - I F (A) TJ = 175˚C TJ = 125˚C TJ = 25˚C 0.001 0 30 60 90 120 150 Reverse Voltage - V R (V) Fig. 2 - Typical Values Of Reverse Current Vs. Reverse Voltage 10000 Junction Capacitance - C T (pF) 10 T = 25˚C J 1000 1 0 0.5 1 1.5 2 Forward Voltage Drop - VFM (V) 2.5 100 0 40 80 120 160 Reverse Voltage - VR (V) Fig. 3 - Typical Junction Capacitance Vs. Reverse Voltage Fig. 1 - Max. Forward Voltage Drop Characteristics 1 Thermal Impedance Z thJC (°C/W) D = 0.75 D = 0.50 D = 0.33 D = 0.25 D = 0.20 0.1 PDM t1 0.01 Notes: t2 Single Pulse (Thermal Resistance) 1. Duty factor D = t1 / t 2 2. Peak T J = P DM x Z thJC + T C 0.001 0.00001 0.0001 0.001 0.01 0.1 1 10 100 t1, Rectangular Pulse Duration (Seconds) Fig. 4 - Max. Thermal Impedance ZthJC Characteristics 3 129NQ...(R) Series Bulletin PD-20719 rev. A 03/01 180 Allowable Case Temperature (°C) Average Power Loss (Watts) 140 120 100 80 RMS Limit DC D = 0.20 D = 0.25 D = 0.33 D = 0.50 D = 0.75 160 DC 140 120 Square wave (D = 0.50) 60 40 20 0 100 Rated VR applied 80 see note (2) 60 0 40 80 120 160 200 Average Forward Current - IF(AV)(A) 0 20 40 60 80 100 120 140 160 180 Average Forward Current - I F(AV) (A) Fig. 5 - Max. Allowable Case Temperature Vs. Average Forward Current Fig. 6 - Forward Power Loss Characteristics 10000 Non-Repetitive Surge Current - I FSM (A) 1000 At Any Rated Load Condition And With Rated VRRM Applied Following Surge 100 10 100 1000 10000 Square Wave Pulse Duration - t p (microsec) Fig. 7 - Max. Non-Repetitive Surge Current L H IG H -SPE ED S W ITC H FREE-W HE EL D IO D E 40H FL40S02 V d = 25 V olt D UT IRFP460 Rg = 25 ohm + C UR RE N T M O N ITO R Fig. 8 - Unclamped Inductive Test Circuit (2) Formula used: TC = TJ - (Pd + PdREV) x RthJC ; Pd = Forward Power Loss = IF(AV) x VFM @ (IF(AV) / D) (see Fig. 6); PdREV = Inverse Power Loss = VR1 x IR (1 - D); IR @ VR1 = rated VR 4