Condensator membranae filtratoriae triphasicus AC cum involucro cylindrico aluminio ad apparatum potentiae
APPLICATIONES
Late in apparatu electronico potentiae adhibitum, quod ad filtrum AC adhibetur.In UPS magnae potentiae, fonte potentiae commutante, inversore et aliis apparatibus pro filtro AC,harmonicas et moderationem factoris potentiae emendare.
TECHNICUS DATA
| Ambitus temperaturae operativae | Temperatura maxima operandi: +85℃Temperatura categoriae superioris: +70℃Temperatura categoriae inferioris: -40℃ |
| Capacitas | 3*17~3*200μF |
| Tensio aestimata | 400V.AC ~ 850V.AC |
| Tolerantia capacitatis | ±5% (J); ±10% (K) |
| Tensio probationis inter terminales | 1.25UN(AC) / 10S vel 1.75UN(DC) / 10S |
| Terminalis tensionis probationis ad capsam | 3000V.AC / 2S, 50/60Hz |
| Supertensio | 1.1Urms(30% durationis in onere) |
| 1.15Urms(30 minuta / die) | |
| 1.2Urms(5 min / die) | |
| 1.3Urms(1 minutum / die) | |
| Factor dissipationis | Tgδ ≤ 0.002 f = 100Hz |
| Autoinductantia | <70 nH per mm spatii inter plumbum |
| Resistentia insulationis | RS×C ≥ 10000S (ad 20℃ 100V.DC) |
| Currentis percussionis sustinere | Vide schedam specificationis |
| Irms | Vide schedam specificationis |
| Expectatio vitae | Tempus vitae utilis: >100000h apud UNDCet 70℃APTITUDO: <10×10-9/h(10 per 109pars h) apud 0.5×UNDC,40℃ |
| Dielectricum | Polypropylenum metallicum |
| Constructio | Impletio gase inerti/oleo siliconico, non inductiva, superpressio |
| Casus | Capsa aluminii |
| Retardatio flammae | UL94V-0 |
| Norma referentialis | IEC61071, UL810 |
APPROBATIONES SECURITATIS
|
E496566 | UL | UL810, Limites Tensionis: Maximum 4000VDC, 85℃Numerus Certificati: E496566 |
TTABULA CONTORNIS
TABULA SPECIFICATIONUM
| CN (μF) | ΦD (mm) | H (mm) | Imax (A) | Ip (A) | Is (A) | ESR (mΩ) | Rth (K/W) |
| Urms = 400V.AC | |||||||
| 3*17 | 65 | CL | 20 | 450 | 1350 | 3*1.25 | 6.89 |
| 3*30 | 65 | CLXXV | 25 | DCCCXC | 2670 | 3*1.39 | 6.25 |
| 3*50 | 76 | 205 | 33 | 1167 | 3501 | 3*1.35 | 4.85 |
| 3*66 | 76 | 240 | 40 | 1336 | 4007 | 3*1.45 | 3.79 |
| 3*166.7 | 116 | 240 | 54 | 1458 | 4374 | 3*0.69 | 3.1 |
| 3*200 | 136 | 240 | 58 | 2657 | 7971 | 3*0.45 | 2.86 |
| Urms = 450V.AC | |||||||
| 3*50 | 86 | 205 | 30 | DCCCII | 2406 | 3*1.35 | 4.36 |
| 3*80 | 86 | 285 | 46 | 1467 | 4401 | 3*1.89 | 3.69 |
| 3*100 | 116 | 210 | 56 | MMXL | 6120 | 3*1.5 | 3.8 |
| 3*135 | 116 | 240 | 58 | 2680 | 8040 | 3*1.6 | 3.1 |
| 3*150 | 136 | 205 | 67 | 3060 | 9180 | 3*2.5 | 3.2 |
| 3*200 | 136 | 240 | 60 | 3730 | 11190 | 3*2 | 3.46 |
| Urms = 530V.AC | |||||||
| 3*50 | 86 | 240 | 32 | 916 | 2740 | 3*1.75 | 3.64 |
| 3*66 | 96 | 240 | 44 | MDXLVII | 4641 | 3*1.36 | 3.32 |
| 3*77 | 106 | 240 | 48 | 1685 | 5055 | 3*1.16 | 3.21 |
| 3*100 | 116 | 240 | 65 | MM | Sex milia | 3*1.87 | 4.2 |
| Urms = 690V.AC | |||||||
| 3*25 | 86 | 240 | 29 | DCXCVII | 2091 | 3*2.22 | 3.54 |
| 3*33.4 | 96 | 240 | 36 | DCCCXXXVII | 2511 | 3*1.81 | 3.21 |
| 3*55.7 | 116 | 240 | 44 | 1395 | 4185 | 3*1.24 | 3.04 |
| 3*75 | 136 | 240 | 53 | 2100 | 6300 | 3*1.31 | 2.87 |
| Urms = 850V.AC | |||||||
| 3*25 | 96 | 240 | 30 | DCCLXXIX | 2037 | 3*1.95 | 3.25 |
| 3*31 | 106 | 240 | 36 | 906 | 2718 | 3*1.57 | 2.98 |
| 3*55.7 | 136 | 240 | 49 | MDCCXXI | 5163 | 3*0.9 | 2.56 |
| Urms = 1200V.AC | |||||||
| 3*12 | 116 | 245 | 56 | 1300 | 3900 | 3*3.5 | 3.6 |
| 3*20 | 136 | 245 | 56 | 3300 | 9900 | Tres * quattuor | 2.29 |
Incrementum maximum temperaturae componentium (ΔT), ex componente resultans'potestasdissipatio et conductivitas caloris.
Incrementum temperaturae maximae componentium ΔT est differentia inter temperaturam in involucro condensatoris mensuratam et temperaturam ambientis (prope condensatorem) cum condensator operatur in operatione normali.
Dum operatur, ΔT non debet excedere 15°C ad temperaturam nominalem. ΔT respondet ascensui componenti.temperatura a IRM effecta. Ne ΔT 15°C ad temperaturam nominalem excedatur, IRM debet essecum incremento temperaturae ambientis imminuitur.
△T = P/G
△T = TC- T.ambus
P = Irms2x ESR = dissipatio potentiae (mW)
G = conductivitas caloris (mW/°C)
