Metallized Polypropylene Film Capacitor DC-Link capacitor APPLICATIONS Industrial and high-end power supplies High performance DC filtering Frequency converters Solar inverters Renewable energies inverters FEATURES Good self-healing properties Low losses with high current capability High performance DC filter Low High reliability MARKING Manufacturer logo Rated capacitance Capacitance tolerance Rated DC voltage Tracking number CONSTRUCTION Dielectric: PP film (MKP) Electrodes: Metallized dielectric film Plastic case (flame retardant) Epoxy resin sealing (UL-94 V-0) Terminals: Tinned copper wire TECHNICAL DATA AND SPECIFICATION Referenced standard GB/T17702,IEC61071 Rated Voltage 450VDC~1200VDC Rated capacitance range 1μF - 120 μf Maximum permissible peak to peak ripple voltage 0.2 x U NDC Capacitance tolerance ±5 %, ±10 %, ±20% Rated temperature 85 ºC Climatic Category 40/85/21 Maximum permissible case temperature 105 C, respecting voltage derating Self inductance (LS) < 1 nh per mm of lead spacing DC voltage test between terminals 1.5Un for 10s Insulation resistance (20 C, 100V, 1min) RC > 10 000 s 1.1 x Un, 30% on load duration. 1.15 x Un for 30min Temporarily Overvoltage (per day) 1.2 x Un for 5min 1.3 x Un for 1min 1.5 x Un for 100ms each time, 1,000 times during the life of the capacitor. Lifetime expectancy (Un, θ hs=70 ) 100 000h Revision: 15-Jun-17 Page 1 of 11 Document number: DS17002
SAFETY APPROVALS.. TUV R E215893 TUV UL EN61071: 2007, 0.68 μf to 200 μf, 400 VDC to 1400 VDC -40/85 C or -40/70 C, Certificate No.: R 50321877 UL810, Voltage Limits: Max. 1400VDC, 85 C Certificate No.: E215893 COMPOSITION OF ORDERING CODE 1GLBH 620 D 450 6 3 1 Type code Capacitance Code (pf) Voltage code Voltage value Dash Version Lead spacing (mm) Packaging DC-Link box type First digit specifies number of zeros. The last two digits represent significant figures of capacitance value. D=DC voltage 450=450V NA 6=Normal version 2=27.5 3=37.5 5=52.5 1 = Straight terminals, untapped (lead length 6 ± 1 mm) DIMENSIONS AND ORDERING CODE 2 PINS 4 PINS L(±0.5) W(±0.5) L(±0.5) W(±0.5) H(±0.5) H(±0.5) P Φd P P2 Φd TECHNICAL DATA AND ORDERING CODE U N, 70 :500Vdc, U N, 85 :450Vdc 1 32 7 16 27.5-0.8 65 10 100 52 2 1GLBH510D450-621 2 32 8.5 18 27.5-0.8 65 10 100 34 3 1GLBH520D450-621 3 32 11 20 27.5-0.8 65 10 100 22 4 1GLBH530D450-621 4 32 12 22 27.5-0.8 65 10 100 20 4 1GLBH540D450-621 5 32 13 23 27.5-0.8 65 10 100 16 5 1GLBH550D450-621 6 32 14 25 27.5-0.8 65 10 100 13 5 1GLBH560D450-621 7 32 16 25 27.5-0.8 65 10 100 11 6 1GLBH570D450-621 8 32 17 28 27.5-0.8 65 10 100 10 8 1GLBH580D450-621 9 32 17 28 27.5-0.8 65 10 100 9 8 1GLBH590D450-621 10 32 18 28 27.5-0.8 65 10 100 8 9 1GLBH610D450-621 Revision: 15-Jun-17 Page 2 of 11 Document number: DS17002
U N, 70 :500Vdc, U N, 85 :450Vdc 15 32 20 35 27.5-0.8 65 10 100 7 11 1GLBH615D450-621 18 32 22 37 27.5-0.8 65 12 120 6 11.5 1GLBH618D450-621 10 42 18 33 37.5 10.2 1.0 30 12 120 14 7 1GLBH610D450-631 12 42 18 33 37.5 10.2 1.0 30 12 120 11 8 1GLBH612D450-631 15 42 18 33 37.5 10.2 1.0 30 12 120 9 9 1GLBH615D450-631 20 42 20 40 37.5 10.2 1.0 30 15 150 7 11 1GLBH620D450-631 25 42 24 38 37.5 10.2 1.0 30 15 150 6.5 12 1GLBH625D450-631 30 42 28 43 37.5 10.2 1.0 30 15 150 5.5 13 1GLBH630D450-631 35 42 28 43 37.5 10.2 1.0 30 15 150 4 16 1GLBH635D450-631 40 42 30 45 37.5 10.2 1.0 30 15 150 4 17 1GLBH640D450-631 25 58 22 32 52.5 10.2 1.2 15 35 350 9 9 1GLBH625D450-651 30 58 30 45 52.5 10.2 1.2 15 35 350 8 10 1GLBH630D450-651 35 58 30 45 52.5 10.2 1.2 15 35 350 8 11 1GLBH635D450-651 40 58 30 45 52.5 10.2 1.2 15 35 350 7 12 1GLBH640D450-651 45 58 30 45 52.5 10.2 1.2 15 35 350 7 12.5 1GLBH645D450-651 50 58 30 45 52.5 10.2 1.2 15 35 350 6 14 1GLBH650D450-651 55 58 30 45 52.5 10.2 1.2 15 35 350 5.5 15 1GLBH655D450-651 60 58 30 45 52.5 10.2 1.2 15 35 350 5 15.5 1GLBH660D450-651 70 58 35 50 52.5 20.3 1.2 15 35 350 4.5 18 1GLBH670D450-651 75 58 35 50 52.5 20.3 1.2 15 35 350 4 19 1GLBH675D450-651 80 58 35 60 52.5 20.3 1.2 15 35 350 4 20 1GLBH680D450-651 90 58 35 60 52.5 20.3 1.2 15 35 350 3 22 1GLBH690D450-651 100 58 35 60 52.5 20.3 1.2 15 35 350 2.5 23 1GLBH710D450-651 120 58 45 65 52.5 20.3 1.2 15 35 350 2.5 24 1GLBH712D450-651 U N, 70 :800Vdc, U N, 85 :700Vdc 1 32 7 16 27.5-0.8 65 10 90 52 2 1GLBH510D700-621 2 32 11 20 27.5-0.8 65 10 90 34 3 1GLBH520D700-621 3 32 11 21 27.5-0.8 65 10 90 22 4 1GLBH530D700-621 4 32 13 23 27.5-0.8 65 10 90 16 5 1GLBH540D700-621 5 32 15 25 27.5-0.8 65 10 90 13 6 1GLBH550D700-621 6 32 17 28 27.5-0.8 65 10 90 11 7 1GLBH560D700-621 7 32 18 28 27.5-0.8 65 10 90 10 8 1GLBH570D700-621 8 32 18 28 27.5-0.8 65 10 90 8 8.5 1GLBH580D700-621 9 32 21 31 27.5-0.8 65 10 90 7.5 9 1GLBH590D700-621 10 32 21 31 27.5-0.8 65 10 90 7 10 1GLBH610D700-621 12 32 20 35 27.5-0.8 65 10 90 6 11 1GLBH612D700-621 10 42 18 33 37.5-1.0 30 20 150 13 7 1GLBH610D700-631 12 42 18 33 37.5-1.0 30 20 150 11 8 1GLBH612D700-631 Revision: 15-Jun-17 Page 3 of 11 Document number: DS17002
U N, 70 :800Vdc, U N, 85 :700Vdc 15 42 18.5 35.5 37.5-1.0 30 20 150 9 9 1GLBH615D700-631 20 42 21 40 37.5 10.2 1.0 30 20 150 7 11 1GLBH620D700-631 25 42 24 44 37.5 10.2 1.0 30 20 150 5.5 13 1GLBH625D700-631 30 42 30 45 37.5 10.2 1.0 30 20 150 4.5 16 1GLBH630D700-631 35 42 30 45 37.5 10.2 1.0 30 20 150 4 17 1GLBH635D700-631 30 58 25 45 52.5 10.2 1.2 15 35 330 9 11 1GLBH630D700-651 35 58 25 45 52.5 10.2 1.2 15 35 330 8 12 1GLBH635D700-651 40 58 25 45 52.5 10.2 1.2 15 35 330 6.5 13 1GLBH640D700-651 45 58 30 45 52.5 20.3 1.2 15 35 330 6 14 1GLBH645D700-651 50 58 30 45 52.5 20.3 1.2 15 35 330 5.5 15 1GLBH650D700-651 55 58 35 50 52.5 20.3 1.2 15 35 330 5 17 1GLBH655D700-651 60 58 35 50 52.5 20.3 1.2 15 35 330 4.5 18 1GLBH660D700-651 70 58 35 60 52.5 20.3 1.2 15 35 330 4 20 1GLBH670D700-651 75 58 35 60 52.5 20.3 1.2 15 35 330 3.5 21 1GLBH675D700-651 80 58 35 60 52.5 20.3 1.2 15 35 330 3 22 1GLBH680D700-651 90 58 45 65 52.5 20.3 1.2 15 35 330 3 23 1GLBH690D700-651 100 58 45 60 52.5 20.3 1.2 15 35 330 2.5 23.5 1GLBH710D700-651 U N, 70 :900Vdc, U N, 85 :800Vdc 1 32 8 17 27.5-0.8 70 9 90 62 2 1GLBH510D800-621 2 32 11 20 27.5-0.8 70 9 90 30 3.5 1GLBH520D800-621 3 32 13 25 27.5-0.8 70 9 90 20 4.5 1GLBH530D800-621 4 32 15 25 27.5-0.8 70 9 90 15 5 1GLBH540D800-621 5 32 18 28 27.5-0.8 70 9 90 12 7 1GLBH550D800-621 6 32 18 28 27.5-0.8 70 9 90 10 7.5 1GLBH560D800-621 7 32 20 30 27.5-0.8 70 9 90 9 9 1GLBH570D800-621 8 32 22 31 27.5-0.8 70 9 90 8 9.5 1GLBH580D800-621 9 32 20 35 27.5-0.8 70 9 90 8 10 1GLBH590D800-621 10 42 18 33 37.5-1.0 35 18 150 13 8 1GLBH610D800-631 12 42 18.5 35.5 37.5-1.0 35 18 150 11 9 1GLBH612D800-631 15 42 21.5 38.5 37.5 10.2 1.0 35 18 150 9 10 1GLBH615D800-631 20 42 24 44 37.5 10.2 1.0 35 18 150 6 13 1GLBH620D800-631 25 42 30 45 37.5 10.2 1.0 35 18 150 5 15 1GLBH625D800-631 30 58 25 45 52.5 10.2 1.2 15 32 300 8 12 1GLBH630D800-651 35 58 30 45 52.5 20.3 1.2 15 32 300 7 13 1GLBH635D800-651 40 58 35 50 52.5 20.3 1.2 15 32 300 6 15 1GLBH640D800-651 45 58 35 50 52.5 20.3 1.2 15 32 300 5.5 16 1GLBH645D800-651 50 58 35 50 52.5 20.3 1.2 15 32 300 5 17 1GLBH650D800-651 55 58 35 60 52.5 20.3 1.2 15 32 300 4 18 1GLBH655D800-651 60 58 35 60 52.5 20.3 1.2 15 32 300 3.5 20 1GLBH660D800-651 Revision: 15-Jun-17 Page 4 of 11 Document number: DS17002
U N, 70 :900Vdc, U N, 85 :800Vdc 70 58 45 65 52.5 20.3 1.2 15 32 300 3.5 21 1GLBH670D800-651 80 58 45 65 52.5 20.3 1.2 15 32 300 3.2 23 1GLBH680D800-651 U N, 70 :1100Vdc, U N, 85 :900Vdc 1 32 9 19 27.5-0.8 80 8 70 60 2 1GLBH510D900-621 2 32 13 23 27.5-0.8 80 8 70 30 3 1GLBH520D900-621 3 32 15 25 27.5-0.8 80 8 70 20 5 1GLBH530D900-621 4 32 18 28 27.5-0.8 80 8 70 15 6 1GLBH540D900-621 5 32 21 31 27.5-0.8 80 8 70 12 7 1GLBH550D900-621 6 32 21 31 27.5-0.8 80 8 70 10 8 1GLBH560D900-621 7 32 20 35 27.5-0.8 80 8 70 9 9 1GLBH570D900-621 5 42 18 33 37.5-1.0 40 15 130 20 5.5 1GLBH550D900-631 6 42 18 33 37.5-1.0 40 15 130 19 6 1GLBH560D900-631 7 42 18 33 37.5-1.0 40 15 130 18 6.5 1GLBH570D900-631 8 42 18 33 37.5-1.0 40 15 130 16 7 1GLBH580D900-631 9 42 18.5 35.5 37.5-1.0 40 15 130 14 7.5 1GLBH590D900-631 10 42 21.5 38.5 37.5 10.2 1.0 40 15 130 12 8 1GLBH610D900-631 12 42 21.5 38.5 37.5 10.2 1.0 40 15 130 10 9 1GLBH612D900-631 15 42 22 44 37.5 10.2 1.0 40 15 130 8 10 1GLBH615D900-631 20 42 30 45 37.5 10.2 1.0 40 15 130 6 13 1GLBH620D900-631 15 58 25 45 52.5 10.2 1.2 20 28 270 14 9 1GLBH615D900-651 20 58 25 45 52.5 10.2 1.2 20 28 270 12 10 1GLBH620D900-651 25 58 30 45 52.5 20.3 1.2 20 28 270 10 11 1GLBH625D900-651 30 58 30 45 52.5 20.3 1.2 20 28 270 8 13 1GLBH630D900-651 35 58 35 50 52.5 20.3 1.2 20 28 270 7 14 1GLBH635D900-651 40 58 35 50 52.5 20.3 1.2 20 28 270 6 15 1GLBH640D900-651 45 58 35 60 52.5 20.3 1.2 20 28 270 5 17 1GLBH645D900-651 50 58 35 60 52.5 20.3 1.2 20 28 270 4 18 1GLBH650D900-651 60 58 45 65 52.5 20.3 1.2 20 28 270 4 19 1GLBH660D900-651 70 58 45 65 52.5 20.3 1.2 20 28 270 3.5 20 1GLBH670D900-651 U N, 70 :1300Vdc, U N, 85 :1100Vdc 1 32 11 21 27.5-0.8 90 8 60 45 3 1GLBH510D1100-621 2 32 15 25 27.5-0.8 90 8 60 22 4 1GLBH520D1100-621 3 32 18 28 27.5-0.8 90 8 60 15 6 1GLBH530D1100-621 4 32 21 31 27.5-0.8 90 8 60 11 8 1GLBH540D1100-621 5 32 20 35 27.5-0.8 90 8 60 10 9 1GLBH550D1100-621 5 42 18 33 37.5-0.8 90 8 60 18 6 1GLBH550D1100-631 Revision: 15-Jun-17 Page 5 of 11 Document number: DS17002
U N, 70 :1300Vdc, U N, 85 :1100Vdc 6 42 18.5 35.5 37.5-0.8 90 8 60 15 7 1GLBH560D1100-631 7 42 21.5 38.5 37.5 10.2 1.0 45 15 100 13 8 1GLBH570D1100-631 8 42 21.5 38.5 37.5 10.2 1.0 45 15 100 11 9 1GLBH580D1100-631 9 42 22 44 37.5 10.2 1.0 45 15 100 10 10 1GLBH590D1100-631 10 42 22 44 37.5 10.2 1.0 45 15 100 9 11 1GLBH610D1100-631 12 42 30 45 37.5 10.2 1.0 45 15 100 8 12 1GLBH612D1100-631 10 58 25 45 52.5 10.2 1.0 45 15 100 18 8 1GLBH610D1100-651 12 58 25 45 52.5 10.2 1.0 45 15 100 15 9 1GLBH612D1100-651 15 58 25 45 52.5 10.2 1.0 45 15 100 12 10 1GLBH615D1100-651 20 58 30 45 52.5 20.3 1.2 22 25 200 9 11 1GLBH620D1100-651 25 58 35 50 52.5 20.3 1.2 22 25 200 7 14 1GLBH625D1100-651 30 58 35 60 52.5 20.3 1.2 22 25 200 5 16 1GLBH630D1100-651 35 58 45 65 52.5 20.3 1.2 22 25 200 5 17 1GLBH635D1100-651 40 58 45 65 52.5 20.3 1.2 22 25 200 4.5 18 1GLBH640D1100-651 45 58 45 65 52.5 20.3 1.2 22 25 200 4 20 1GLBH645D1100-651 U N, 70 :1400Vdc, U N, 85 :1200Vdc 1 32 11 21 27.5-0.8 90 8 60 42 3 1GLBH510D1200-621 2 32 15 25 27.5-0.8 90 8 60 21 5 1GLBH520D1200-621 3 32 18 28 27.5-0.8 90 8 60 14 6.5 1GLBH530D1200-621 4 32 21 31 27.5-0.8 90 8 60 11 8 1GLBH540D1200-621 5 42 18 33 37.5-0.8 90 15 100 17 15 1GLBH550D1200-631 6 42 18.5 35.5 37.5-0.8 90 15 100 14 12 1GLBH560D1200-631 7 42 21.5 38.5 37.5 10.2 1.0 45 15 100 12 11 1GLBH570D1200-631 8 42 21.5 38.5 37.5 10.2 1.0 45 15 100 10 9 1GLBH580D1200-631 9 42 22 44 37.5 10.2 1.0 45 15 100 9 8 1GLBH590D1200-631 10 42 22 44 37.5 10.2 1.0 45 15 100 8 7 1GLBH610D1200-631 12 42 30 45 37.5 10.2 1.0 45 25 200 7 6 1GLBH612D1200-631 10 58 25 45 52.5 10.2 1.2 22 25 200 17 8 1GLBH610D1200-651 12 58 25 45 52.5 10.2 1.2 22 25 200 14 9 1GLBH612D1200-651 15 58 25 45 52.5 10.2 1.2 22 25 200 11 10 1GLBH615D1200-651 20 58 30 45 52.5 20.3 1.2 22 25 200 8.5 14 1GLBH620D1200-651 25 58 35 50 52.5 20.3 1.2 22 25 200 7.5 15 1GLBH625D1200-651 30 58 35 60 52.5 20.3 1.2 22 25 200 6.5 16 1GLBH630D1200-651 35 58 45 65 52.5 20.3 1.2 22 25 200 6 17 1GLBH635D1200-651 40 58 45 65 52.5 20.3 1.2 22 25 200 5.5 18 1GLBH640D1200-651 45 58 45 65 52.5 20.3 1.2 22 25 200 5 19 1GLBH645D1200-651 Note: 1. Equivalent series resistance () typical values at f = 10 khz 2. Maximum RMS current at 10 khz, +85 C, t = +15 C, capacitance tolerance ± 5 % Revision: 15-Jun-17 Page 6 of 11 Document number: DS17002
CHARACTERISTICS CURE Working/Rated Voltage Ratio (Uw/UN) 1.3 1.2 1.1 1.0 50 70 85 0.9 0.8 0.7 105 0.6 0.5 10 3 10 4 10 5 10 6 Expected Lifetime(h) (typical) Expected Lifetime (h) C/C (%) 4 3 2 1 0-1 -2-3 -4-5 -6-60 -40-20 0 20 40 60 80 100 120 Tamb ( ) Capacitance (typical) 10 5 RC (s) 10 4 10 3 0 20 40 60 80 100 Tamb ( ) Insulation Resistance (typical) Ioperational/Imax 1.6 1.4 1.2 1.0 0.8 0.6 0.4 0.2 0 40 50 60 70 80 90 100 110 Tamb ( ) Maximum Irms current in function of the ambient temperature 10 2 10 1 Z(ohm) 10 1 10 0 10-1 10-2 18μF 1μF LS=27.5 Z(ohm) 10 0 10-1 10-2 40μF 5μF LS=37.5 10-3 10 1 10 4 10 5 10 6 10 7 f(hz) Impedance vs. frequency (typical) LS=52.5 10-3 10 4 10 5 10 6 10 7 f(hz) Impedance vs. frequency (typical) Z(ohm) 10 0 10-1 40μF 10-2 80μF 10-3 10 4 10 5 10 6 10 7 f(hz) Impedance vs. frequency (typical) Revision: 15-Jun-17 Page 7 of 11 Document number: DS17002
Maximum increase of the component temperature (ΔT), resulting from the component s power dissipation and heat conductivity. The maximum component temperature-increase ΔT is the difference between the temperature measured on the capacitor s housing and the ambient temperature (in proximity to the capacitor) when the capacitor is working during normal operation. During operation ΔT must not exceed 15 C at rated temperature. ΔT corresponds the rise of the component temperature caused by the Irms. In order not to exceed ΔT of 15 C at rated temperature, the Irms must be decreased with an increase of the ambient temperature. T = P/G T = T housing - T ambient P = Irms 2 x = power dissipation (mw) G = heat conductivity (mw/ C) RESISTANCE TO SOLDERING HEAT Soldering process Internal temperature of the capacitor must be kept as follows: Preheating: Soldering: T max. 100 C T max. 110 C Single wave soldering Soldering bath temperature: T 260 C Dwell time: t 5 sec Double wave soldering Soldering bath temperature: T 260 C Dwell time: Σt 5 sec Due to different soldering processes and heat requirements the graphs are to be regarded as a recommendation only. T/ 260 240 220 200 180 160 140 120 100 80 60 40 20 10s see detail enlargement 30 60 90 120 150 180 210 240 Typical temperature/time graph for double wave soldering 2s 3s t/sec Revision: 15-Jun-17 Page 8 of 11 Document number: DS17002
INSPECTION REQUIREMENTS SUB-CLAUSE NUMBER AND TEST CONDITIONS PERFORMANCE REQUIREMENTS ROUTINE TEST-FINAL INSPECTION 1 External inspection, Legible marking as specified visual examination 2 Dimensions See specification drawing 3 Capacitance 1 khz at room temperature See specific reference data 4 1 khz at room temperature 10 khz at room temperature See specific reference data 5 Voltage test between terminal 1.5 x U NDC at T amb No visible damage or puncture Duration 10 s No flashover 6 Insulation resistance U NDC > 100 V measuring voltage 100V See specific reference data TYPE TESTS at room temperature Duration 1 min 1 External inspection Check for finish, marking and overall Legible marking and finish as specified 2 Mechanical tests 2.1 Robustness of terminations dimensions 2.1.1 Initial measurements Capacitance at 1 khz Tan δ at 10 khz 2.1.2 Robustness of terminations Tensile Ua1 IEC 60068-2-21 Wire diameter section load 0.8 mm 0.5 mm 2 10 N 1.25 mm 1.2 mm 2 20 N Duration 10 s ± 1s Bending Ub method 1 Wire diameter section load 0.8 mm 0.05 mm 3 10 N 1.25 mm 0.019 mm 3 20 N 4 x 90, Duration 2 s to 3 s/bend 2.1.3 Resistance to soldering heat No predrying, Method 1A IEC 60068-2-20 Solder bath: 260 C Duration 10 s ± 1 s 2.1.4 Final measurements Capacitance ΔC/C 0.5% 3 Voltage test between terminals 3.1 Initial measurements Capacitance at 1 khz Dimensions: see specific drawing Tan δ Increase of 0.0050 at 10 khz R insulation 3.2 Voltage test between terminal 1.5 x U NDC at T amb Duration 60 s 3.3 Final measurements Capacitance ΔC/C 0.5 % Compared to values measured in 2.1.1 Increase of 1.2 initial + 0.0001 R insulation R insulation 50 % of specified values 4 Surge discharge test 4.1 Initial measurements Capacitance at 1 khz at 10 khz 4.2 Surge discharge test 1.1 x U NDC Number of discharges: 5 Time lapse: every 2 min (10 min total) Revision: 15-Jun-17 Page 9 of 11 Document number: DS17002
SUB-CLAUSE NUMBER AND TEST CONDITIONS PERFORMANCE REQUIREMENTS 4.3 Voltage test between terminal Within 5 min after the surge discharge test Duration 60 s 1.5 x U NDC at T amb 4.4 Final measurements Capacitance ΔC/C 1.0 % 5 Self healing test 5.1 Initial measurements at 10 khz 1.2 initial + 0.0001 Capacitance at 1 khz at 10 khz 5.2 Self healing test 1.5 x U NDC Duration 10 s Number of clearings 5 Clearing = voltage drop of 5 % increase the voltage at 100 V/s till 5 clearings occur with a max. of 2.5 x U NDC for a duration of 10 s Compared to values measured in 4.1 5.3 Final measurements Capacitance ΔC/C 0.5 % 1.2 initial + 0.0001 Compared to values measured in 5.1 6 Environmental testing 6.1 Initial measurements Capacitance at 1 khz Tan δ at 10 khz 6.2 Change of temperature Test Nb acc. to IEC 60068-2-14 T max. = 85 C T min. = -40 C Transition time: 1 h, equivalent to 1 C/min 6.3 Damp heat steady state Test Ca acc. to IEC 60068-2-78 T max. = 40 C ± 2 C RH = 93 % ± 3 % Duration 56 days 7 Thermal stability test 7.1 Initial measurements 7.2 Thermal stability test under overload conditions Capacitance at 1 khz at 1 khz Natural cooling T amb ± 5 C 1.21 P max. = (U 2/2) W 2 C = 121 (I 2 max./w 2 C) 2 with W 2 = 2 p f 2 for I max. (see specific reference data) f 2 = 1 khz Duration 48 h 7.3 Final measurements Measure the temperature every 1.5 h during Temperature rise < 1 C the last 6 h ΔC/C 2% Capacitance Increase of 1.2 initial + 0.0150 at 1 khz 8 Resonance frequency Impedance analyzer at T amb < 0.9 times the value as specified in typical measurement curve Resonant frequency of this specification Revision: 15-Jun-17 Page 10 of 11 Document number: DS17002
SUB-CLAUSE NUMBER AND TEST CONDITIONS PERFORMANCE REQUIREMENTS 9 Endurance test between terminals 9.1 Initial measurements Capacitance at 1 khz at 1 khz 9.2 Endurance test between terminals Sequence 1.3 x U NDC at T max. = 85 C Duration 500 h 1000 discharge at 1.4 Ipeak (maximum repetitive peak current in continuous Operation) 1.3 x U NDC at T max. = 85 C Duration 500 h 9.3 Final measurements Capacitance ΔC/C 3 % Increase of 0.0150 Compared to values measured in 9.1 10 THB test 10.1 Initial measurements Capacitance at 1 khz at 1 khz 10.2 THB test U NDC at T max = 85 C RH=85 % 1000H 10.3 Final measurements Capacitance ΔC/C 10% Increase of 0.0150 IMPORTANT NOTES Some parts of this publication contain statements about the suitability of our products for certain areas of application. These statements are based on our knowledge of typical requirements that are often placed on our products in the areas of application concerned. We nevertheless expressly point out that such statements cannot be regarded as binding statements about the suitability of our products for a particular customer application. As a rule, BM is either unfamiliar with individual customer applications or less familiar with them than the customers themselves. For these reasons, it is always ultimately incumbent on the customer to check and decide whether an BM product with the properties described in the product specification is suitable for use in a particular customer application. In individual cases, a malfunction of electronic components or failure before the end of their usual service life cannot be completely ruled out in the current state of the art, even if they are operated as specified. In customer applications requiring a very high level of operational safety and especially in customer applications in which the malfunction or failure of an electronic component could endanger human life or health (e.g. in accident prevention or lifesaving systems), it must therefore be ensured by means of suitable design of the customer application or other action taken by the customer (e.g. installation of protective circuitry or redundancy) that no injury or damage is sustained by third parties in the event of malfunction or failure of an electronic component. Revision: 15-Jun-17 Page 11 of 11 Document number: DS17002