4/5 PED-ST FEATURES Polarized aluminium electrolytic capacitors, non-solid Large types, cylindrical aluminium case, insulated with a blue sleeve Also available in bolt version (PED-STB) Pressure relief in the sealing Charge and discharge proof Extremely low ESR and ESL allowing very high ripple current load, achieved by a special construction with multiple internal anode and cathode connections Very long useful life: 0000 hours at 85 C High resistance to shock and vibration achieved by longitudinal rills and special internal construction. MBC4 - ST STB Fig. Component outlines. 086/087 PS-ST APPLICATIONS Computer, telecommunications and industrial systems Smoothing and filtering Standard and switched mode power supplies Energy storage in pulse systems. larger case sizes smaller handbook, 050/05 4 columns PEC-PW higher CV-values 4/5 PED-ST CV/volume 54/55 PEC-ST in DIN PW CCB08 larger case sizes high ripple 05 C 088/089 PHC-ST QUICK REFERENCE DATA VALUE DESCRIPTION 4 5 Case size ( D nom L nom in mm) 5 60 to 75 05 Rated capacitance range (E6 series), C R 50 to 0000 µf Tolerance on C R 0 to +0% Rated voltage range, U R 0 to 00 V 50 to 400 V Category temperature range 40 to +85 C Endurance test at 85 C 8000 hours (400 V: 000 hours) Useful life at 85 C 0000 hours (400 V: 5000 hours) Useful life at 40 C,.4 I R applied 50000 hours (400 V: 90000 hours) Shelf life at 0 V, 85 C 500 hours Based on sectional specification IEC 84-4/CECC 000 Climatic category IEC 68 40/085/56 998 Mar 6
4/5 PED-ST Selection chart for C R, U R and relevant nominal case sizes ( D L in mm) for 4 series Preferred types in bold. C R U R (V) (µf) 0 6 5 40 6 00 000 5 60 500 5 60 00 5 60 5 80 00 5 60 5 60 5 05 4700 5 60 5 60 5 80 50 80 6800 5 60 5 80 5 05 50 05 0000 5 60 5 80 5 05 50 80 65 05 5000 5 60 5 80 5 05 50 80 50 05 65 05 000 5 80 5 05 50 80 50 05 65 05 75 05 000 5 05 50 80 50 05 65 05 65 05 47000 50 80 50 05 65 05 65 05 75 05 68000 50 05 65 05 65 05 75 05 00000 65 05 65 05 75 05 50000 65 05 75 05 0000 75 05 Selection chart for C R, U R and relevant nominal case sizes ( D L in mm) for 5 series Preferred types in bold. C R U R (V) (µf) 50 50 85 400 50 5 60 5 60 0 5 60 5 80 5 80 0 5 60 5 80 5 05 5 05 470 5 80 5 05 50 80 50 80 680 5 05 50 80 50 05 50 05 000 50 80 50 05 65 05 65 05 500 50 05 65 05 65 05 65 05 00 65 05 65 05 75 05 75 05 00 65 05 75 05 4700 75 05 998 Mar 6
4/5 PED-ST MECHANICAL DATA AND PACKAGING QUANTITIES A handbook, full pagewidth L 5. 0.7 D 0. P d M5 9 0.5 d MGB0 - Dimensions in mm. For dimensions see Table. Maximum permissible torque which may be applied to the termination screws: Nm. For accessories refer to this handbook, Section Mounting Accessories. The capacitors are delivered with screws and washers. Fig. Screw terminal (ST); screw terminal bolt (STB). Table Physical dimensions, mass and packaging information; see Fig. NOMINAL CASE SIE D L D max L max P ±0. A d ±0. d l MASS (g) PACKAGING QUANTITIES (per box) CARDBOARD BOX DIMENSIONS l w h 5 60 6.5 6.0 8.4 8.0 M8 55 5 96 9 0 5 80 6.5 8.0 8.4 8.0 M8 80 5 96 9 5 5 05 6.5 08.0 8.4 8.0 M8 0 5 96 9 40 50 80 5.5 8.0 4. 8.0 M 6 60 5 9 7 5 50 05 5.5 08.0 4. 8.0 M 6 0 5 9 7 40 65 05 66.5 08 8.5 9.0 9.6 M 6 70 0 68 5 40 75 05 76.5 08.0.0 9.6 M 6 55 0 48 7 40 MARKING The capacitors are marked (where possible) with the following information: Rated capacitance (in µf) Tolerance code on rated capacitance (M for ±0%) Rated voltage (in V) Climatic category in accordance with IEC 68 Date code (year and week) in accordance with IEC 6 Code for factory of origin Name of manufacturer Code number (last 8 digits) Code for basic specification in accordance with IEC 84-4- and CECC 00. 998 Mar 6
998 Mar 6 4 ELECTRICAL DATA AND ORDERING INFORMATION Unless otherwise specified, all electrical values in Tables and apply at T amb =0 C, P = 86 to 06 kpa, RH = 45 to 75%. SYMBOL DESCRIPTION C R rated capacitance at 00 Hz, tolerance 0 to +0% I R rated RMS ripple current at 00 Hz, 85 C and 0 khz, 70 C I L max. leakage current after minute at U R I L5 max. leakage current after 5 minutes at U R ESR typical equivalent series resistance at 00 Hz impedance at 0 khz Tan δ max. dissipation factor at 00 Hz Table U R (V) Electrical data and ordering information for the 4 series; preferred types in bold C R 00 Hz (µf) NOMINAL CASE SIE D L I R 00 Hz 85 C (A) I R 0 khz 70 C (A) I L min (ma) I L5 5 min (ma) ESR TYP. 00 Hz Tan δ MAX. 00 Hz Ordering example Electrolytic capacitor 4 series 0000 µf/5 V; 0/+0% Nominal case size: 5 80 mm; ST version Catalogue number: 4 60. TYP. 0 khz MAX. 0 khz CATALOGUE NUMBER (see Table, note )...... 0 5000 5 60 6.4 0.90 0.0 0 0. 0 4 45 000 5 80 7.5 4.. 0.4 4 0. 9.5 4 4 4 000 5 05 0 9.98 0.66 0 0.5 7.5 0 4 4 47000 50 80 4 6.5.8 0.94 7.5 0.6 5.0 9.5 4 447 68000 50 05 8 4 4.08.6 5.5 0.8 4.0 8.0 4 468 00000 65 05 0 50 6.00.00.5 0.4.0 5.0 4 404 50000 65 05 0 50 9.00.00.0 0.45.0 5.0 4 454 0000 75 05 7 50.0 4.40.0 0.45.5 4.0 4 44 6 0000 5 60 6.4 0.96 0. 0. 0 4 50 5000 5 80 7.5 4..44 0.40 5 0. 9.5 4 4 55 000 5 05 0 9. 0.7 0.5 7.0 0 4 5 000 50 80 4.6.7.06 7.5 0.6 5.0 9.5 4 5 47000 50 05 8 4 4.5.5 5.5 0.7 4.0 8.0 4 547 68000 65 05 8 50 6.5.8.5 0.4.0 5.0 4 568 00000 65 05 8 50 9.60.0.0 0..0 5.0 4 504 50000 75 05 7 50 4.40 4.80.0 0..5 4.0 4 554 4/5 PED-ST Philips Components
998 Mar 6 5 U R (V) C R 00 Hz (µf) NOMINAL CASE SIE D L I R 00 Hz 85 C (A) I R 0 khz 70 C (A) I L min (ma) 5 4700 5 60 5. 0 0.7 0.4 0 0.4 5 4 647 6800 5 60 5. 0.0 0.4 5 0.8 4 4 668 0000 5 80 6.7.7.50 0.50 8 0.8 0 5 4 60 5000 5 05 9.7 8.4.5 0.75 0.9 7.5 4 65 000 50 80.5.7.0.0 8.5 0.9 5.5 9.5 4 6 000 50 05 8 4 4.95.65 6.0 0. 4.0 8.0 4 6 47000 65 05 7 50 7.05.5 4.0 0.8.0 5.0 4 647 68000 65 05 7 50 0.0.40.5 0..0 5.0 4 668 00000 75 05 7 50 5.00 5.0.5 0..5 4.0 4 604 40 00 5 60 4.5 8.5 0.80 0.7 7 0. 4 7 4700 5 60 4.5 8.5. 0.8 5 0.7 4 747 6800 5 80 6.4.64 0.55 5 0.7 5 4 768 0000 5 05 7.5 4..40 0.80 7 0.8 7 4 70 5000 50 80 0 9.60.0 0.7 7.5 4 75 000 50 05 5 8.5 5.8.76 8.0 0.8 5.5 0.5 4 7 000 65 05 40 7.9.64 5.0 0.6.5 6.0 4 7 47000 65 05 4.8.76 4.5 0..5 6.0 4 747 68000 75 05 0 50 6. 5.44.0 0..0 4.5 4 768 6 00 5 60.7 7 0.84 0.8 9 0.09 4 8 00 5 60.7 7.5 0.4 0. 0 0 4 8 4700 5 80 5. 0.78 0.66 0. 4 4 847 6800 5 05 7.5 4..57 0.86 7 0. 0 5 4 868 0000 50 80 9.5 8.78.6 0. 7.5 4 4 80 5000 50 05.5 5.6 5.67.89 8.5 0. 5.5 0.5 4 85 000 65 05 40 8..77 5.0 0..5 6.0 4 8 000 65 05 4.48 4.6 4.5 0.4.5 6.0 4 8 47000 75 05 0 50 7.77 5.9.0 0.4.0 4.5 4 847 I L5 5 min (ma) ESR TYP. 00 Hz Tan δ MAX. 00 Hz TYP. 0 khz MAX. 0 khz CATALOGUE NUMBER (see Table, note )...... 4/5 PED-ST Philips Components
998 Mar 6 6 U R (V) 00 000 5 60.0 5.7 0.60 0.0 85 0.09 45 67 4 90 500 5 60. 6. 0.90 0.0 65 0.0 40 60 4 95 00 5 80 4.6 8.7. 0.4 45 0.0 8 4 4 9 00 5 05 6.5..98 0.66 0 0.0 9 8 4 9 4700 50 80 7.4 4.0.8 0.94 7 0. 7 5 4 947 6800 50 05 9.9 8.8 4.08.6 9 0. 8 4 968 0000 65 05 5.0 8.5 6.00.00 0. 7 4 90 5000 65 05 5.8 0.0 9.00.00 0 0. 6 0 4 95 000 75 05 0.5 8.9.0 4.40 7 0. 5 8 4 9 Table U R (V) C R 00 Hz (µf) Electrical data and ordering information for the 5 series; preferred types in bold C R 00 Hz (µf) NOMINAL CASE SIE D L NOMINAL CASE SIE D L I R 00 Hz 85 C (A) I R 00 Hz 85 C (A) I R 0 khz 70 C (A) I R 0 khz 70 C (A) I L min (ma) I L min (ma) I L5 5 min (ma) ESR TYP. 00 Hz Tan δ MAX. 00 Hz TYP. 0 khz MAX. 0 khz CATALOGUE NUMBER (see note )...... 50 0 5 60.8.4 0.50 0.7 00 0.5 75 500 5 470 5 80.5 4.7 0.7 0.4 50 0.5 40 75 5 47 680 5 05.5 6.6.0 0.4 80 0.5 5 00 5 68 000 50 80 4. 8.50 0.50 0 0.5 60 0 5 0 500 50 05 6..5 0.75 60 0.5 40 00 5 5 00 65 05 8.8 6.7.0.0 45 0.5 0 60 5 00 65 05 0.5 0 4.95.65 0 0.5 5 50 5 4700 75 05 4 6.5 7.05.5 5 0.5 0 40 5 47 50 0 5 60.9.6 0.47 0.6 60 0.0 0 480 5 5 0 5 80.5 4.8 0.70 0. 45 0.0 50 0 5 5 470 5 05. 6. 0.99 0. 75 0.0 05 0 5 547 680 50 80.9 7.0.47 0.48 40 0.0 60 0 5 568 000 50 05 5.4 9.7.4 0.7 65 0.0 50 00 5 50 I L5 5 min (ma) ESR TYP. 00 Hz Tan δ MAX. 00 Hz TYP. 0 khz MAX. 0 khz CATALOGUE NUMBER (see Table, note )...... 4/5 PED-ST Philips Components
998 Mar 6 7 U R (V) C R 00 Hz (µf) NOMINAL CASE SIE D L I R 00 Hz 85 C (A) I R 0 khz 70 C (A) I L min (ma) 50 500 65 05 7.7 4.8.5.05 55 0.0 0 70 5 55 00 65 05 9. 7.5 4.6.54 5 0.0 50 5 5 00 75 05 0.8 9.4 6.9. 0 0. 0 45 5 5 85 50 5 60.0.8 0.4 0. 70 0. 450 95 5 85 0 5 80.4.6 0.50 0.7 50 0. 0 60 5 8 0 5 05.9.6 0.75 0.5 40 0. 0 45 5 8 470 50 80.7 5..06 0.6 00 0. 40 00 5 847 680 50 05.6 6.9.5 0.5 40 0. 00 05 5 868 000 65 05 5. 9.7.5 0.75 95 0. 65 5 5 80 500 65 05 5.7 0.6.8. 80 0. 45 95 5 85 00 75 05 7..8 4.95.65 55 0. 40 75 5 8 400 50 5 60.0.8 0.6 0. 70 0. 450 95 5 65 0 5 80.4.6 0.5 0.8 50 0. 0 60 5 6 0 5 05.9.6 0.79 0.6 40 0. 0 45 5 6 470 50 80.7 5.. 0.8 00 0. 40 00 5 647 680 50 05.6 6.9.6 0.54 40 0. 00 05 5 668 000 65 05 5. 9.7.40 0.80 95 0. 65 5 5 60 500 65 05 5.7 0.6.60.0 80 0. 45 95 5 65 00 75 05 7..8 5.8.76 55 0. 40 75 5 6 I L5 5 min (ma) ESR TYP. 00 Hz Tan δ MAX. 00 Hz TYP. 0 khz MAX. 0 khz Note. Catalogue number applies to the ST version; for STB version (not preferred) replace 8 th digit by 5 ( 4/5 5...). CATALOGUE NUMBER (see note )...... 4/5 PED-ST Philips Components
4/5 PED-ST Additional electrical data PARAMETER CONDITIONS VALUE Voltage Surge voltage for short periods 50 V versions U s =.5 U R 50 V versions U s =. U R Reverse voltage U rev V Current Leakage current after minute at U R I L 0.006C R U R +4µA after 5 minutes at U R I L5 0.00C R U R +4µA Inductance Equivalent series inductance (ESL) case D = 5 mm typ. nh case D = 50 mm typ. 6 nh case D = 65 mm typ. 9 nh case D = 75 mm typ. 0 nh 998 Mar 6 8
4/5 PED-ST Equivalent series resistance (ESR) 0 MGB04 ESR (m Ω) 0 Curve : case D L=5 60 mm. Curve : case D L=5 80 mm. Curve : case D L=5 05 mm. Curve 4: case D L=50 80 mm. Curve 5: case D L=50 05 mm. Curve 6: case D L=65 05 mm; 00000 µf. Curve 7: case D L=65 05 mm; 50000 µf. Curve 8: case D L=75 05 mm. ESR at 00 Hz and U R =0V. 0 50 4 5 6 7 8 0 50 00 Tamb ( o C) Fig. Typical ESR as a function of temperature. 0 MGB05 ESR (m Ω) 0 Curve : case D L=5 60 mm; 00 µf. Curve : case D L=5 60 mm; 00 µf. Curve : case D L=5 80 mm. Curve 4: case D L=5 05 mm. Curve 5: case D L=50 80 mm. Curve 6: case D L=50 05 mm. Curve 7: case D L=65 05 mm; 000 µf. Curve 8: case D L=65 05 mm; 000 µf. Curve 9: case D L=75 05 mm. ESR at 00 Hz and U R =6V. 0 50 4 5 6 7 8 9 0 50 00 o T amb ( C) Fig.4 Typical ESR as a function of temperature. 998 Mar 6 9
4/5 PED-ST 0 4 MGB06 ESR (m Ω) 0 0 Curve : case D L=50 80 mm. Curve : case D L=50 05 mm. ESR at 00 Hz and U R = 50 V. 0 50 0 50 00 Tamb ( o C) Fig.5 Typical ESR as a function of temperature. 0 5 MGB07 ESR (m Ω) 0 4 0 Curve : case D L=5 60 mm. Curve : case D L=5 80 mm. Curve : case D L=5 05 mm. Curve 4: case D L=50 80 mm. Curve 5: case D L=50 05 mm. Curve 6: case D L=65 05 mm; 000 µf. Curve 7: case D L=65 05 mm; 500 µf. Curve 8: case D L=75 05 mm. ESR at 00 Hz and U R = 85 V. 0 0 50 4 5 6 7 8 0 50 00 T amb ( o C) Fig.6 Typical ESR as a function of temperature. 998 Mar 6 0
4/5 PED-ST Impedance () 0 MGB08 (m Ω) 0 4 5 0 6 7 Curve : case D L=5 60 mm. Curve : case D L=5 80 mm. Curve : case D L=5 05 mm. Curve 4: case D L=50 80 mm. Curve 5: case D L=50 05 mm. Curve 6: case D L=65 05 mm. Curve 7: case D L=75 05 mm. at 0 khz and U R =0V. 50 0 50 00 Tamb ( o C) Fig.7 Typical impedance as a function of temperature. 0 MGB09 (m Ω) 0 4 5 6 7 8 0 Curve : case D L=5 60 mm; 00 µf. Curve : case D L=5 60 mm; 00 µf. Curve : case D L=5 80 mm. Curve 4: case D L=5 05 mm. Curve 5: case D L=50 80 mm. Curve 6: case D L=50 05 mm. Curve 7: case D L=65 05 mm. Curve 8: case D L=75 05 mm. at 0 khz and U R =6V. 50 0 50 00 o T amb ( C) Fig.8 Typical impedance as a function of temperature. 998 Mar 6
4/5 PED-ST 0 4 (m Ω) 0 4 5 6 7 8 MGB0 0 Curve : case D L=5 60 mm. Curve : case D L=5 80 mm. Curve : case D L=5 05 mm. Curve 4: case D L=50 80 mm. Curve 5: case D L=50 05 mm. Curve 6: case D L=65 05 mm; 00 µf. Curve 7: case D L=65 05 mm; 00 µf. Curve 8: case D L=75 05 mm. at 0 khz and U R = 50 V. 0 50 0 50 00 Tamb ( o C) Fig.9 Typical impedance as a function of temperature. 0 4 (m Ω) 0 4 5 6 7 8 MGB 0 Curve : case D L=5 60 mm. Curve : case D L=5 80 mm. Curve : case D L=5 05 mm. Curve 4: case D L=50 80 mm. Curve 5: case D L=50 05 mm. Curve 6: case D L=65 05 mm; 000 µf. Curve 7: case D L=65 05 mm; 500 µf. Curve 8: case D L=75 05 mm. at 0 khz and U R = 85 V. 0 50 0 50 00 o T amb ( C) Fig.0 Typical impedance as a function of temperature. 998 Mar 6
4/5 PED-ST 0 MGB 0 0 Curve : 00 µf, 6 V. Curve : 5000 µf, 0 V. Case D L=5 60 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig. Typical impedance as a function of frequency. 0 MGB 0 0 Curve : 4700 µf, 6 V. Curve : 000 µf, 0 V. Case D L=5 80 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig. Typical impedance as a function of frequency. 998 Mar 6
4/5 PED-ST 0 MGB4 0 0 Curve : 6800 µf, 6 V. Curve : 000 µf, 0 V. Case D L=5 05 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig. Typical impedance as a function of frequency. 0 MGB5 0 0 Curve : 0000 µf, 6 V. Curve : 47000 µf, 0 V. Case D L=50 80 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig.4 Typical impedance as a function of frequency. 998 Mar 6 4
4/5 PED-ST 0 MGB6 0 0 Curve : 5000 µf, 6 V. Curve : 68000 µf, 0 V. Case D L=50 05 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig.5 Typical impedance as a function of frequency. 0 MGB7 0 0 Curve : 000 µf, 6 V. Curve : 50000 µf, 0 V. Case D L=65 05 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig.6 Typical impedance as a function of frequency. 998 Mar 6 5
4/5 PED-ST 0 MGB8 0 0 Curve : 47000 µf, 6 V. Curve : 0000 µf, 0 V. Case D L=75 05 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig.7 Typical impedance as a function of frequency. 0 MGB9 0 0 Curve : 50 µf, 85 V. Curve : 0 µf, 50 V. Case D L=5 60 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig.8 Typical impedance as a function of frequency. 998 Mar 6 6
4/5 PED-ST 0 MGB0 0 0 Curve : 0 µf, 85 V. Curve : 470 µf, 50 V. Case D L=5 80 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig.9 Typical impedance as a function of frequency. 0 MGB 0 0 Curve : 0 µf, 85 V. Curve : 680 µf, 50 V. Case D L=5 05 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig.0 Typical impedance as a function of frequency. 998 Mar 6 7
4/5 PED-ST 0 MGB 0 0 Curve : 470 µf, 85 V. Curve : 000 µf, 50 V. Curve : 680 µf, 50 V. Case D L=50 80 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig. Typical impedance as a function of frequency. 0 MGB 0 0 Curve : 680 µf, 85 V. Curve : 000 µf, 50 V. Curve : 500 µf, 50 V. Case D L=50 05 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig. Typical impedance as a function of frequency. 998 Mar 6 8
4/5 PED-ST 0 4 MBC449 (m Ω) 0 4 0 0 Curve : 000 µf, 85 V. Curve : 500 µf, 85 V. Curve : 00 µf, 50 V. Curve 4: 00 µf, 50 V. Case D L=65 05 mm. T amb =0 C. 0 0 0 0 4 0 5 f (Hz) 0 6 Fig. Typical impedance as a function of frequency. 0 MGB4 0 0 Curve : 00 µf, 85 V. Curve : 4700 µf, 50 V Case D L=75 05 mm. T amb =0 C. 0 0 0 0 0 4 0 5 0 6 f (Hz) 0 7 Fig.4 Typical impedance as a function of frequency. 998 Mar 6 9
4/5 PED-ST RIPPLE CURRENT AND USEFUL LIFE Table 4 Multiplier of ripple current (I R ) as a function of frequency FREQUENCY (Hz) I R MULTIPLIER 50 0.8 00.00 00.0 400.5 000.9 000.0 handbook, full pagewidth.4 MGA45 I A I R....0.9.8.7.6. life multiplier.5.4. 4 5 8 0 5 0 0 60 80.5.. ().0 0.8 0.5 0.0 40 50 60 70 80 90 T amb ( oc).5 I A = actual ripple current at 00 Hz and 85 C. I R = rated ripple current at 00 Hz and 85 C. With an absolute maximum of 50 A at 85 C () Useful life at 85 C and I R applied: 0000 hours (5000 hours for 400 V types). Fig.5 Multiplier of useful life as a function of ambient temperature and ripple current load. 998 Mar 6 0
4/5 PED-ST SPECIFIC TESTS AND REQUIREMENTS General tests and requirements are specified in this handbook, Section Tests and Requirements. Table 5 Test procedures and requirements TEST NAME OF TEST REFERENCE Endurance IEC 84-4/ CECC 000 subclause 4. Useful life CECC 00 subclause.8. Shelf life (storage at high temperature) IEC 84-4/ CECC 000 subclause 4.7 PROCEDURE (quick reference) T amb =85 C; U R applied; 8000 hours (400 V types: 000 hours) T amb =85 C; U R and I R applied; 0000 hours (400 V types: 5000 hours) T amb =85 C; no voltage applied; 500 hours after test: U R to be applied for 0 minutes, 4 to 48 hours before measurement REQUIREMENTS U R 00 V; C/C: ±5% U R > 00 V; C/C: ±0% spec. limit I L5 spec. limit U R 00 V; C/C: ±45% U R > 00 V; C/C: ±0% spec. limit I L5 spec. limit no short or open circuit, no visible damage total failure percentage: U R 00 V: %; U R > 00 V: % C/C: ±0% I L5 spec. limit 998 Mar 6