| نویسندگان | Meysam Mahmoudi |
| همایش | پنجمین همایش ملی و اولین همایش بین الملی محاسبات نرم علوم مهندسی در صنعت و جامعه |
| تاریخ برگزاری همایش | 2026-02-15 |
| محل برگزاری همایش | ایرانشهر |
| شماره صفحات | 0-0 |
| نوع ارائه | سخنرانی |
| سطح همایش | داخلی |
| کلید واژه ها | Parabolic trough solar collector; Water, CuO nanofluid; Non‑uniform heat flux; Thermo‑hydrodynamic analysis; User‑Defined Function (UDF) |
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چکیده مقاله
higher outlet fluid temperatures in parabolic trough
solar collectors (PTSCs) are essential for
enhancing their thermal efficiency and applicability
in high‑temperature solar thermal systems. In this
study, a numerical investigation is conducted to
analyze the thermo‑hydrodynamic behavior of a
water–copper oxide (CuO) nanofluid flowing
through the absorber tube of a PTSC under
non‑uniform heat flux conditions representative of
the summer climate of Birjand. The spatially
varying solar heat flux on the absorber tube wall is
realistically
modeled using a User‑Defined
Function (UDF), accounting for the non‑uniform
distribution of concentrated solar radiation. The
nanofluid enters the absorber tube at a constant
mass flow rate of 0.0112 kg/s, with inlet conditions
selected based on local climatic data.The results
indicate that the non‑uniform heat flux leads to
localized enhancement of wall temperature and
heat transfer rates along the absorber tube.
Although the addition of CuO nanoparticles
increases the effective viscosity of the working
fluid and results in a higher pressure drop, it
simultaneously improves the convective heat
transfer
coefficient
and
overall
thermal
performance, particularly at higher flow velocities.
The findings demonstrate that an appropriate
balance between heat transfer enhancement and
hydraulic penalties can be achieved through the use
of water–CuO nanofluids. Overall, the study
confirms the strong potential of parabolic trough
solar collectors operating under favorable climatic
conditions such as Birjand for efficient solar
energy concentration and high‑temperature thermal
applications, including hot water and steam
generation.
لینک ثابت مقاله