G'ovak muhitlar tenglamasi

G'ovak muhitlar tenglamasi yoki nochiziqli issiqlik tenglamasi deb quyidagi nochiziqli xususiy hosilali differensial tenglamaga aytiladi^[1]

${{\cfrac {\partial u}{\partial t}}=\Delta \left(u^{m}\right),\;m>1}$ bu yerda $\Delta$ Laplas operatori. Shuningdek, yuqoridagi tenglamani quyidagicha, divergent ko'rinishda ham yozish mumkin ${\partial u \over {\partial t}}=\nabla \cdot \left[D(u)\nabla u\right]$ bu yerda $Du=mu^{m-1}$ diffuziya koeffitsienti va $\nabla \cdot (\cdot )$ divergensiya operatori.

Yechimlar[tahrir | manbasini tahrirlash]

Tenglama nochiziqli bo'lishiga qaramay o'zgaruvchilarni ajratish yoki avtomodel yechimlar metodlaridan foydalanib, analitik yechimlarni ham topish mumkin. Shuningdek, o'zgaruvchilari ajraladigan yechimlar chekli vaqtda chekizlik yoki "blow up" nomi bilan ma'lum^[2].

Barenblat-Kompanets-Zeldovich avtomodel yechimi[tahrir | manbasini tahrirlash]

G'ovak muhitlar tenglamasi uchun avtomodel yechimlar metodi Barenblat^[3], Kompanets, Zeldovich^[4] va Pattle tomonlaridan yaratilgan. $x\in R^{N},\;u(x,t)$ quyidagicha ko'rinishda qidiriladi $u(t,x)={1 \over {t^{\alpha }}}v\left({x \over {t^{\beta }}}\right),\quad t>0$ $\alpha$ va $\beta$ larni topib, yechimni quyidagicha ko'rinishda yozish mumkin $u(t,x)={1 \over {t^{\alpha }}}\left(b-{m-1 \over {2m}}\beta {\|x\|^{2} \over {t^{2\beta }}}\right)_{+}^{1 \over {m-1}}$ bu yerda $||\cdot ||^{2}$ - $\ell ^{2}$ norma, $(\cdot )=max(\cdot ,0)$ nomanfiy had va $\alpha$ , $\beta$ koeffitsientlar $\alpha ={n \over {n(m-1)+2}},\quad \beta ={1 \over {n(m-1)+2}}$

Qo'llanilishi[tahrir | manbasini tahrirlash]

G'ovak muhitlar tenglamasi gas oqimi, issiqlik tarqalishi, yer osti, sizot suvlari va boshqa ko'plab jarayonlarni tavsiflaydi.^[5]

Gaz oqimi[tahrir | manbasini tahrirlash]

G'ovak muhitlar tenglamasi nomi bir jinsli muhitlarda ideal gas oqimini tavsiflashda qo'llanilishidan kelib chiqqan.^[6] Muhit zichligi $\rho$ , muhit harakatlanish tezligi $v$ , bosim $p$ : massa saqlanishi uchun uzlukliksiz tenglamasi; g'ovak muhitlar tenglamasi Darsi qonuni va ideal gaz tenglamasi. Ushbu tenglamalar quyidagicha: ${\begin{aligned}\varepsilon {\partial \rho \over {\partial t}}&=-\nabla \cdot (\rho {\bf {v}})&({\text{Massaning saqlanish qonuni}})\\{\bf {v}}&=-{k \over {\mu }}\nabla p&({\text{Darsi qonuni}})\\p&=p_{0}\rho ^{\gamma }&({\text{Ideal gaz tenglamasi}})\end{aligned}}$ bu yerda $\varepsilon$ g'ovaklilik, $k$ muhitning o'tkazuvchanligi, $\mu$ dinamik yopishqoqlik va $\gamma$ Opolitropik konstanta. 'zgarmas g'ovaklik, o'tkazuvchanlik va dinamik yopishqoqlikni hisobga olsak, zichlik differensial tenglamasi quyidagicha yozish mumikin: ${\partial \rho \over {\partial t}}=c\Delta \left(\rho ^{m}\right)$ bu yerda $m=\gamma +1$ va $c=\gamma kp_{0}/(\gamma +1)\varepsilon \mu$ .

Issiqlik tarqalishi[tahrir | manbasini tahrirlash]

Fourierning issiqlik tarqalish qonuniga ko'rsa, issiqlik tarqalishi tenglamasi quyidagicha ko'rinishda bo'ladi: $\rho c_{p}{\partial T \over {\partial t}}=\nabla \cdot (\kappa \nabla T)$ bu yerda $\rho$ muhit zichligi, $c_{p}$ domiy bosim ostidagi issiqlik sig'imi va $\kappa$ issiqlik o'tkazuvchanlik koeffitsientlari. Agar issiqlik tarqalishi energiya qonuniga bog'liq bo'lsa: $\kappa =\alpha T^{n}$ U holda issiqlik tarqalishini g'ovak muhitlar tenglamasi ko'rinishida yozish mumkin: ${\partial T \over {\partial t}}=\lambda \Delta \left(T^{m}\right)$ bu yerda $m=n+1$ va $c=\gamma kp_{0}/(\gamma +1)\varepsilon \mu$ .

Shuningdek[tahrir | manbasini tahrirlash]

Diffyuziya tenglamasi
G'ovak muhit

↑ „Porous medium equation“, Wikipedia (inglizcha), 2023-11-16, qaraldi: 2024-06-08
↑ „Porous medium equation“, Wikipedia (inglizcha), 2023-11-16, qaraldi: 2024-06-08
↑ „Porous medium equation“, Wikipedia (inglizcha), 2023-11-16, qaraldi: 2024-06-08
↑ „Yakov Zeldovich“, Wikipedia (inglizcha), 2024-05-22, qaraldi: 2024-06-08
↑ „Porous medium equation“, Wikipedia (inglizcha), 2023-11-16, qaraldi: 2024-06-08
↑ Muskat, M.. The Flow of Homogeneous Fluids Through Porous Media. New York: McGraw-Hill, 1937. ISBN 9780934634168.

[1] „Porous medium equation“, Wikipedia (inglizcha), 2023-11-16, qaraldi: 2024-06-08

[2] „Porous medium equation“, Wikipedia (inglizcha), 2023-11-16, qaraldi: 2024-06-08

[3] „Porous medium equation“, Wikipedia (inglizcha), 2023-11-16, qaraldi: 2024-06-08

[4] „Yakov Zeldovich“, Wikipedia (inglizcha), 2024-05-22, qaraldi: 2024-06-08

[5] „Porous medium equation“, Wikipedia (inglizcha), 2023-11-16, qaraldi: 2024-06-08

[6] Muskat, M.. The Flow of Homogeneous Fluids Through Porous Media. New York: McGraw-Hill, 1937. ISBN 9780934634168.

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