Surveying the hybrid of radiation and magnetic parameters on Maxwell liquid with TiO2 nanotube influence of different blades

In this paper, the impacts of Maxwell nanoliquid
transmission, rectangular with titanium oxide nanoparticles
are explored over the triangular, chamfer
blades. The innovation of this paper is the use of the
number of chamfers, rectangular, and triangular blades
at the top and bottom of a stretched plate to study
physical nanofluid parameters such as temperature
and the effects of magnetism. Also, by determining the
appropriate height and length for the blades, we
achieve the best optimization of temperature and
velocity of nanofluid between the plate and the blades,
which improves heat transfer and with a more and
better effect of magnetic effects. The finite element
method is utilized for the calculated differential
equations. In this paper, by utilizing the reaction
surface strategy, we optimized the titanium oxide
nanofluid velocity and temperature, and magnetic
parameter passing from the extending sheet. On
average, the titanium oxide nanoparticle velocity
around the two rectangular blades at the beginning
of the sheet is 73.09% higher than triangular blades and
66.98% higher than chamfer blades. Based on the
outcomes got from the titanium oxide nanofluid speed charts and the warm exchange cantors and magnetic
impacts within the Design‐Expert computer program,
the most excellent optimization occurred for TiO2
nanofluid speed and TiO2 nanofluid temperature and
TiO2 magnetic parameter with u = 0.523, T = 3.25, and
H = 2.671.