Parametri technici principales
| proiectum | proprius | |
| ambitus temperaturae operativae | -55~+105℃ | |
| Tensio operativa aestimata | 6.3-100V | |
| capacitatis spatium | 180~18000 microF 120Hz 20℃ | |
| Tolerantia capacitatis | ±20% (120Hz 20℃) | |
| tangens damni | 120Hz 20℃ infra valorem in indice productorum ordinariorum | |
| Fluxus electricus※ | Duo minuta ad tensionem nominalem infra valorem in indice productorum normalium ad 20°C imple. | |
| Resistentia Seriei Aequivalentis (ESR) | 100kHz 20°C infra valorem in indice productorum normalium | |
|
Durabilitas | Productum temperaturae 105°C satisfacere debet, tensione operativa aestimata per 2000 horas adhibenda est, et post 16 horas ad 20°C. | |
| Ratio mutationis capacitatis | ±20% valoris initialis | |
| Resistentia Seriei Aequivalentis (ESR) | ≤200% valoris specificationis initialis | |
| tangens damni | ≤200% valoris specificationis initialis | |
| fluxus electricus | ≤Valor specificationis initialis | |
|
Alta temperatura et humiditas | Productum temperaturae 60°C et humiditatis RH 90%~95% sine tensione applicata satisfacere debet; per horas 1000 collocare, et ad 20°C per horas 16 collocare. | |
| Ratio mutationis capacitatis | ±20% valoris initialis | |
| Resistentia Seriei Aequivalentis (ESR) | ≤200% valoris specificationis initialis | |
| tangens damni | ≤200% valoris specificationis initialis | |
| fluxus electricus | ≤Valor specificationis initialis | |
Delineatio Dimensionalis Producti
Dimensiones Producti (Unitas: mm)
| ΦD | B | C | A | H | E | K | a |
| 16 | 17 | 17 | 5.5 | 1.20±0.30 | 6.7 | 0.70±0.30 | ±1.0 |
| 18 | 19 | 19 | 6.7 | 1.20±0.30 | 6.7 | 0.70±0.30 |
Coefficiens Correctionis Frequentiae Currentis Undulati
factor correctionis frequentiae
| Frequentia (Hz) | 120Hz | 1kHz | 10kHz | 100kHz | 500kHz |
| factor correctionis | 0.05 | 0.3 | 0.7 | 1 | 1 |
Condensatores Electrolytici Aluminii Solidi Polymeri Conductivi: Partes Provectae pro Electronicis Modernis
Condensatores Electrolytici Aluminii Solidi Polymeri Conductivi progressum magnum in technologia condensatorum repraesentant, praestantiorem efficaciam, firmitatem, et diuturnitatem offerentes comparatione cum condensatoribus electrolyticis traditis. In hoc articulo, proprietates, utilitates, et applicationes horum elementorum innovativorum explorabimus.
Proprietates
Condensatores Electrolytici Aluminii Solidi Polymeri Conductivi utilitates condensatorum electrolyticorum aluminii traditionalium cum proprietatibus auctis materiarum polymericarum conductivarum coniungunt. Electrolytum in his condensatoribus est polymerum conductivum, quod electrolytum liquidum vel gelatinosum traditionalem, qui in condensatoribus electrolyticis aluminii conventionalibus invenitur, substituit.
Una ex praecipuis proprietatibus Condensatorum Electrolyticorum Aluminii Solidi Polymeri Conductivi est resistentia seriei aequivalentis (ESR) humilis et facultas tractandi currentem undulatam altam. Hoc efficientiam auctam, iacturas potentiae imminutas, et firmitatem auctam, praesertim in applicationibus altae frequentiae, efficit.
Praeterea, hi condensatores stabilitatem excellentem per latum ambitum temperaturarum offerunt et vitam operationalem longiorem habent comparati cum condensatoribus electrolyticis traditionalibus. Constructio eorum solida periculum effusionis vel exsiccationis electrolyti eliminat, efficientiam constantem etiam in condicionibus operationis asperis praebens.
Beneficia
Adoptio materiarum polymericarum conductivarum in capacitoribus electrolyticis aluminii solidi plura commoda systematibus electronicis affert. Primo, earum ESR humilis et aestimationes undulationis currentis altae eas ideales reddunt ad usum in unitatibus potentiae electricae, regulatoribus tensionis, et convertoribus DC-DC, ubi adiuvant ad tensiones productas stabiliendas et efficientiam augendam.
Deinde, Condensatores Electrolytici Aluminii Solidi Polymeri Conductivi auctam firmitatem et diuturnitatem offerunt, ita ut apti sint ad usus criticos in industriis sicut autocinetica, aerospatialis, telecommunicationis, et automationis industrialis. Eorum facultas tolerandi altas temperaturas, vibrationes, et tensiones electricas efficaciam diuturnam praestat et periculum defectus praematurae minuit.
Praeterea, hi condensatores impedantiae humilis proprietates exhibent, quae ad meliorem filtrationem strepitus et integritatem signorum in circuitibus electronicis conferunt. Hoc eos pretiosos componentes in amplificatoribus audio, apparatu audio, et systematibus audio altae fidelitatis facit.
Applicationes
Condensatores electrolytici aluminii solidi polymeri conductivi applicationes inveniunt in ampla varietate systematum et instrumentorum electronicorum. Vulgo adhibentur in unitatibus potentiae, regulatoribus tensionis, impulsoribus motorum, luminibus LED, apparatu telecommunicationis, et electronicis autocineticis.
In unitatibus fontis potentiae, hi condensatores adiuvant ad tensiones egressas stabiliendas, undulationem minuendam, et responsum transitorium emendandum, operationem fidam et efficientem praebentes. In electronicis autocineticis, ad efficaciam et diuturnitatem systematum in vehiculo conferunt, ut unitates moderationis machinae (ECU), systemata infotainment, et instrumenta salutis.
Conclusio
Condensatores electrolytici ex aluminio solido polymero conductivo progressum magnum in technologia capacitorum repraesentant, praestantes efficaciam, firmitatem, et diuturnitatem superiores systematibus electronicis modernis. Propter ESR humilem, facultates tractandi currentem undulatam altam, et diuturnitatem auctam, apti sunt ad amplam applicationum varietatem in variis industriis.
Dum instrumenta et systemata electronica pergunt evolvere, exspectatur crescere postulationem capacitorum magnae efficaciae, ut Condensatores Electrolyticos Aluminii Solidi Polymeri Conductivi. Eorum facultas occurrendi requisitis strictis electronicarum modernarum eos facit partes indispensabiles in hodiernis designis electronicis, conferentes ad efficientiam, firmitatem, et efficaciam augendam.
| Codex Productorum | Temperatura (℃) | Tensio Aestimata (V.DC) | Capacitas (µF) | Diameter (mm) | Altitudo (mm) | Fluxus fluxus (uA) | ESR/Impedentia [Ωmax] | Vita (Horae) | Certificatio producti |
| VPGJ1951H122MVTM | -55~105 | 50 | 1200 | 18 | 19.5 | 7500 | 0.03 | MM | - |
| VPGJ2151H152MVTM | -55~105 | 50 | 1500 | 18 | 21.5 | 7500 | 0.03 | MM | - |
| VPGI1751J561MVTM | -55~105 | 63 | 560 | 16 | 17.5 | 7056 | 0.03 | MM | - |
| VPGI1951J681MVTM | -55~105 | 63 | DCCLXXX | 16 | 19.5 | 7500 | 0.03 | MM | - |
| VPGI2151J821MVTM | -55~105 | 63 | DCCCXX | 16 | 21.5 | 7500 | 0.03 | MM | - |
| VPGJ1951J821MVTM | -55~105 | 63 | DCCCXX | 18 | 19.5 | 7500 | 0.03 | MM | - |
| VPGJ2151J102MVTM | -55~105 | 63 | mille | 18 | 21.5 | 7500 | 0.03 | MM | - |
| VPGI1751K331MVTM | -55~105 | 80 | 330 | 16 | 17.5 | 5280 | 0.03 | MM | - |
| VPGI1951K391MVTM | -55~105 | 80 | 390 | 16 | 19.5 | 6240 | 0.03 | MM | - |
| VPGI2151K471MVTM | -55~105 | 80 | 470 | 16 | 21.5 | 7500 | 0.03 | MM | - |
| VPGJ1951K561MVTM | -55~105 | 80 | 560 | 18 | 19.5 | 7500 | 0.03 | MM | - |
| VPGJ2151K681MVTM | -55~105 | 80 | DCCLXXX | 18 | 21.5 | 7500 | 0.03 | MM | - |
| VPGI1752A181MVTM | -55~105 | centum | CLXXX | 16 | 17.5 | 3600 | 0.04 | MM | - |
| VPGI1952A221MVTM | -55~105 | centum | 220 | 16 | 19.5 | 4400 | 0.04 | MM | - |
| VPGI2152A271MVTM | -55~105 | centum | 270 | 16 | 21.5 | 5400 | 0.04 | MM | - |
| VPGJ1952A271MVTM | -55~105 | centum | 270 | 18 | 19.5 | 5400 | 0.04 | MM | - |
| VPGJ2152A331MVTM | -55~105 | centum | 330 | 18 | 21.5 | 6600 | 0.04 | MM | - |
| VPGI1750J103MVTM | -55~105 | 6.3 | Decem milia | 16 | 17.5 | 7500 | 0.007 | MM | - |
| VPGI1950J123MVTM | -55~105 | 6.3 | Duodecim milia | 16 | 19.5 | 7500 | 0.007 | MM | - |
| VPGI2150J153MVTM | -55~105 | 6.3 | Quindecim milia | 16 | 21.5 | 7500 | 0.007 | MM | - |
| VPGJ1950J153MVTM | -55~105 | 6.3 | Quindecim milia | 18 | 19.5 | 7500 | 0.007 | MM | - |
| VPGJ2150J183MVTM | -55~105 | 6.3 | 18000 | 18 | 21.5 | 7500 | 0.007 | MM | - |
| VPGI1751A682MVTM | -55~105 | 10 | 6800 | 16 | 17.5 | 7500 | 0.008 | MM | - |
| VPGI1951A822MVTM | -55~105 | 10 | 8200 | 16 | 19.5 | 7500 | 0.008 | MM | - |
| VPGI2151A103MVTM | -55~105 | 10 | Decem milia | 16 | 21.5 | 7500 | 0.008 | MM | - |
| VPGJ1951A103MVTM | -55~105 | 10 | Decem milia | 18 | 19.5 | 7500 | 0.008 | MM | - |
| VPGJ2151A123MVTM | -55~105 | 10 | Duodecim milia | 18 | 21.5 | 7500 | 0.008 | MM | - |
| VPGI1751C392MVTM | -55~105 | 16 | 3900 | 16 | 17.5 | 7500 | 0.008 | MM | - |
| VPGI1951C472MVTM | -55~105 | 16 | 4700 | 16 | 19.5 | 7500 | 0.008 | MM | - |
| VPGI2151C562MVTM | -55~105 | 16 | 5600 | 16 | 21.5 | 7500 | 0.008 | MM | - |
| VPGJ1951C682MVTM | -55~105 | 16 | 6800 | 18 | 19.5 | 7500 | 0.008 | MM | - |
| VPGJ2151C822MVTM | -55~105 | 16 | 8200 | 18 | 21.5 | 7500 | 0.008 | MM | - |
| VPGI1751E222MVTM | -55~105 | 25 | MMCC | 16 | 17.5 | 7500 | 0.016 | MM | - |
| VPGI1951E272MVTM | -55~105 | 25 | 2700 | 16 | 19.5 | 7500 | 0.016 | MM | - |
| VPGI2151E332MVTM | -55~105 | 25 | 3300 | 16 | 21.5 | 7500 | 0.016 | MM | - |
| VPGJ1951E392MVTM | -55~105 | 25 | 3900 | 18 | 19.5 | 7500 | 0.016 | MM | - |
| VPGJ2151E472MVTM | -55~105 | 25 | 4700 | 18 | 21.5 | 7500 | 0.016 | MM | - |
| VPGI1751V182MVTM | -55~105 | 35 | MDCCC | 16 | 17.5 | 7500 | 0.02 | MM | - |
| VPGI1951V222MVTM | -55~105 | 35 | MMCC | 16 | 19.5 | 7500 | 0.02 | MM | - |
| VPGI2151V272MVTM | -55~105 | 35 | 2700 | 16 | 21.5 | 7500 | 0.02 | MM | - |
| VPGJ1951V272MVTM | -55~105 | 35 | 2700 | 18 | 19.5 | 7500 | 0.02 | MM | - |
| VPGJ2151V332MVTM | -55~105 | 35 | 3300 | 18 | 21.5 | 7500 | 0.02 | MM | - |
| VPGI1751H681MVTM | -55~105 | 50 | DCCLXXX | 16 | 17.5 | 6800 | 0.03 | MM | - |
| VPGI1951H821MVTM | -55~105 | 50 | DCCCXX | 16 | 19.5 | 7500 | 0.03 | MM | - |
| VPGI2151H102MVTM | -55~105 | 50 | mille | 16 | 21.5 | 7500 | 0.03 | MM | - |
