A novel approach to investigate the effect of hybrid nanofluids in a non-Newtonian Maxwell model on thermal management for medical engineering applications DOI

Shahryar Hajizadeh,

Payam Jalili,

Bahram jalili

и другие.

Modern Physics Letters B, Год журнала: 2025, Номер unknown

Опубликована: Март 20, 2025

This study explores the potential of hybrid nanofluids (HNFs) in enhancing efficiency thermal management systems, particularly medical engineering applications where precise temperature control is critical. Motivated by need for innovative and sustainable cooling solutions, this research examines infusion carbon nanostructures (CNS) into HNFs to improve exchange performance. The applies non-Newtonian Maxwellian model Cattaneo–Christov flow framework simulate their behavior specialized curved channels analogous heat exchangers devices such as imaging equipment or cryogenic systems. Hypothetical trials computerized simulations evaluate transfer rate dynamics nanotube-infused HNFs. Key factors, including radiation, fluid resistance, sliding velocity, permeable substances, are assessed determine improvements. By utilizing similarity transformation simplify governing partial differential equations (PDEs) employing finite element method (FEM) alongside Akbari–Ganji’s (AGM) highlights multi-layered nanotube–single-layered nanotube with engine oil mixed significantly enhance transfer. findings demonstrate a 1.65% improvement performance, suggesting promising implications advanced systems healthcare technologies.

Язык: Английский

A novel approach to investigate the effect of hybrid nanofluids in a non-Newtonian Maxwell model on thermal management for medical engineering applications DOI

Shahryar Hajizadeh,

Payam Jalili,

Bahram jalili

и другие.

Modern Physics Letters B, Год журнала: 2025, Номер unknown

Опубликована: Март 20, 2025

This study explores the potential of hybrid nanofluids (HNFs) in enhancing efficiency thermal management systems, particularly medical engineering applications where precise temperature control is critical. Motivated by need for innovative and sustainable cooling solutions, this research examines infusion carbon nanostructures (CNS) into HNFs to improve exchange performance. The applies non-Newtonian Maxwellian model Cattaneo–Christov flow framework simulate their behavior specialized curved channels analogous heat exchangers devices such as imaging equipment or cryogenic systems. Hypothetical trials computerized simulations evaluate transfer rate dynamics nanotube-infused HNFs. Key factors, including radiation, fluid resistance, sliding velocity, permeable substances, are assessed determine improvements. By utilizing similarity transformation simplify governing partial differential equations (PDEs) employing finite element method (FEM) alongside Akbari–Ganji’s (AGM) highlights multi-layered nanotube–single-layered nanotube with engine oil mixed significantly enhance transfer. findings demonstrate a 1.65% improvement performance, suggesting promising implications advanced systems healthcare technologies.

Язык: Английский

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