Solar energy is a harmless form of energy that is plentiful. Due to the extreme usefulness of solar energy, it is used in applications like solar collectors (SCs). The application leads to this research that focuses specifically on the inclined magnetically driven Maxwell nanofluid flow on an endless plate. The Maxwell nanofluid flows past over an exponentially uniform, horizontal porous stretchable plate inside the parabolic trough solar collector (PTSC). The essential exterior resources in PTSC like thermal radiative, viscous dissipative flow and Joule heating parameters are considered. Two common Maxwell nanofluids are always being used in the application are chosen in this research; Copper-methanol (Cu-Ch₃OH) and Titanium-methanol (TiO₂-Ch₃OH) in this research. The governing equation in PDEs involved is converted into higher-order ODEs by utilizing the similarity variables. The converted ODEs are solved numerically by adopting the Keller-box scheme. Based on the findings, Cu-Ch₃OH nanofluid has better heat transfer compared to TiO₂-Ch₃OH. It is also found that the Cu-Ch₃OH thermal efficiency can achieve a maximum of 29%.

太阳能是一种无害的能量形式，而且很丰富。由于太阳能的极端用途，它被用于太阳能收集器 (SC) 等应用中。该应用导致了这项研究，该研究特别关注环形板上倾斜的磁驱动麦克斯韦纳米流体流动。Maxwell 纳米流体流过抛物线槽式太阳能集热器 (PTSC) 内的指数均匀、水平多孔可拉伸板。考虑了 PTSC 中的基本外部资源，如热辐射、粘性耗散流和焦耳热参数。本研究选择了应用中一直使用的两种常见的麦克斯韦纳米流体；铜-甲醇 (Cu-Ch ₃ OH) 和钛-甲醇 (TiO ₂ -Ch ₃哦）在这项研究中。所涉及的偏微分方程中的控制方程通过利用相似性变量转换为高阶常微分方程。采用 Keller-box 方案对转换后的 ODE 进行数值求解。基于研究结果，与TiO ₂ -Ch ₃ OH相比，Cu-Ch ₃ OH纳米流体具有更好的传热。还发现Cu-Ch ₃ OH热效率最高可达到29%。