Transformātor electricus sine capsulā classe H 200kVA 250kVA 315kVA 400kVA

Describtiō:

Trānsfōrmātōrēs ālicuī secūndae H siccitātis, nōn cāpsulātī, quī in capacitātibus 200kVA, 250kVA, 315kVA et 400kVA disponuntur, sunt dispositiva efficiēntiae altae potestātis pro systematibus potestātis modernīs. Hi trānsfōrmātōrēs strūctūram apertam sine cāpsulā clausā adhibent, faciuntque componentes internos visū accessibiles et facile mānūtenendōs. Eōrum strūctūra corea ex materiīs insulātionis classis H cōnstruitur, quae operātiōnem stabilēm in ambīentibus altīs temperātūris permittunt et efficaciter perfōrmanciam fīdēlem trānsfōrmātōris sub conditiōnibus labōribus complexīs assecurant. In applīcātiōnibus practicīs, sive pro systematibus distributiōnis potestātis in aedificiīs commerciālibus sive pro suppeditātiōne potestātis in productiōne industriālī, hi trānsfōrmātōrēs variās capacitātibus possident ad adaptandum diversificātae necessitātīs potestātis, praebentes solidam supportum pro transmissiōne et distributiōne potestātis.

Characteristīca：

Perfōrmancia Insulātiōnis Eximia

• Adhibet materiam insulātionis classis H cum maximā temperātūrā operātiōnis 180°C

• Resistens altae temperātūrīs et senescendi, assecurans operātiōnem sānum et stabilem

• Vitam servitūs significanter prōlongat

Designus Dissipātiōnis Cāliditātis Efficiēns

• Strūctūra non cāpsulāta promovet convectionem aeris naturalis

• Dissipātiō cāliditātis rapidā prohibet accumulātiōnem thermālem

• Maintinet optimam efficiēntiam operātiōnis

Alta Fīdēlitās & Durabilitās

• Fīla electromagnetica et lamināta ferrī silicis praeferenda

• Processūs manufactūrae admodernī assecurant resistentiām circuitūs brevium

• Sustinet conditiōnes supercargae, redigens costūs mānūtenendi

Instalatiō Flexibilis & Mānūtenendi Facilis

• Designus apertus simplificat procedūras instalandi

• Diagnōsis velox defectūrum et accessibilitas componentum

• Minimat tempus interrupsiōnis et meliorat efficiēntiam retei

Amīca Ambiēntis & Efficiēns Energiae

• Designus sine oleo eliminat rīscum contaminātiōnis

• Designus electromagnetica optima redigit perdas sine onere et cum onere

• Economizat significanter costūs energiās longē temporālis

Parametri：

Quomodo operatur trānsfōrmātor secūndae H siccitātis non cāpsulātus？

Componentes Clāve：

• Core Ferrī: Saepe constat ex laminīs ferrī silicis qualitatis altae, habens perdas et sonum bassos. Functio core ferrī est ut concentret et ducat campum magneticum, ita perficiēntiam trānsfōrmātōris meliorans.

• Spīra Prima: Coniuncta ad latus altī voltūs, accipit tensiōnem intrāns. Spīra prima saepe volvitur cum filīs cupreis aut aluminī.

• Spīra Secunda: Coniuncta ad latus bassī voltūs, emittit tensiōnem requiritam. Spīra secunda similiter volvitur cum filīs cupreis aut aluminī.

• Materiae Insulātionis: Adhibentur materiae insulātionis classis H, sicut charta NOMEX et fibra vitrea, quae excellentiam resistentiae cāliditātis et proprietates electricās possident.

• Systema Refrigerātiōnis: Saepe adhibetur refrigerātiō aeris naturalis (AN) aut forcata (AF). Methodus refrigerātiōnis appropriāta selecta est secundum requisitus applicātiōnis specificī.

Processus Operātiōnis：

• Tensiō Intrāns: Tensiō alternae currentis applicatur ad trānsfōrmātōrem per spīram primam.

• Generātiō Campī Magneticī: Currentis in spīrā primā generat campum magneticum alternativum in core ferrī.

• Transmissiō Campī Magneticī: Campum magneticum alternativum transfertur ad spīram secundam per core ferrī.

• Inductiō Electromotricis: Campum magneticum alternativum inducit forcam electromotricam in spīrā secundā, generans tensiōnem extrāns.

• Tensiō Extrāns: Spīra secunda emittit tensiōnem requiritam ad usum oneris.