SSIQLIK AKKUMULYATORIDA FAZAVIY O‘ZGARUVCHI MATERIALNI HISOBLASH GIDRODINAMIKASI USULLARIDAN FOYDALANIB MODELLASHTIRISH ORQALI TADQIQ QILISH

SSIQLIK AKKUMULYATORIDA FAZAVIY O‘ZGARUVCHI MATERIALNI HISOBLASH GIDRODINAMIKASI USULLARIDAN FOYDALANIB MODELLASHTIRISH ORQALI TADQIQ QILISH

##article.authors##

  • Mirzayev Mirfayz Salimovich
  • Hikmatov Behzod Amonovich
  • Sharifova Madina Sherali qizi

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https://doi.org/10.5281/zenodo.19651564

##article.subject##:

issiqlik akkumulyatori, ikki o‘lchovli model, yashirin issiqlik, fazaviy o‘zgaruvchi material, parafin RT35HC, COMSOL 6.2.

##article.abstract##

Binolarda isitish va sovutish maqsadida sarflanadigan energiya iste’moli global energiya iste’molining 30–40
foizini tashkil etadi hamda energiya iste’moli natijasida atrof-muhitga chiqariladigan CO₂ gazlari ulushining 26 foiziga
to‘g‘ri keladi. Bino va sanoat obyektlarining issiqlik energiyasiga bo‘lgan ehtiyojini quyosh, shamol va geotermal energiya
kabi qayta tiklanuvchi energiya manbalari hisobidan qoplashda katta salohiyat mavjud. Biroq mazkur manbalarning
energiya ishlab chiqarish vaqti bilan energiyaga bo‘lgan talab o‘rtasidagi nomuvofiqliklar (tungi yoki bulutli paytlarda
quyosh energiyasining mavjud emasligi, shamol tezligining o‘zgaruvchanligi va boshqalar) issiqlik akkumulyatorlaridan
foydalanishni taqozo etadi. Ushbu tadqiqotda issiqlik akkumulyatorida issiqlik energiyasini saqlash uchun qo‘llanilgan
fazaviy o‘zgaruvchi materialning (FO‘M) erish vaqti hamda mis plastinkalar yordamida qatlamlarga ajratilgan issiqlik
akkumulyatorining har bir qatlamidagi issiqlik almashinuvi ikki o‘lchovli model asosida aniqlangan. Umumiy qobiq uzunligi
500 mm, balandligi 150 mm, qobiq qalinligi 2 mm bo‘lgan issiqlik akkumulyatori asos qismiga 5 kW issiqlik energiyasi
berilganda FO‘Mning erish jarayoni vaqtga bog‘liq ravishda t=60 min, t=120 min, t=180 min, t=240 min, t=300 min
va t=360 min holatlarida tahlil qilindi. Natijada FO‘Mning to‘liq erishi uchun 360 minut vaqt talab etilishi hamda suyuq
fazadagi material harorati 343 K gacha ko‘tarilishi aniqlandi

Биографии авторов

Mirzayev Mirfayz Salimovich

Buxoro davlat universiteti,
“Geliofizika, qayta tiklanuvchi energiya manbalari va elektronika” kafedrasi dotsenti (PhD)


Hikmatov Behzod Amonovich

Buxoro davlat universiteti,
“Geliofizika, qayta tiklanuvchi energiya manbalari va elektronika”
kafedrasi tayanch doktoranti


Sharifova Madina Sherali qizi

Buxoro davlat universiteti,
“Geliofizika, qayta tiklanuvchi energiya manbalari va elektronika”
kafedrasi tayanch doktoranti

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##submissions.published##

2026-04-01

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##issue.vol## 4 ##issue.no## 4 (2026): «Muhandislik va Iqtisodiyot» jurnali

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