Main objective of the paper was to experimentally investigate the thermo-magnetic convection of diamagnetic fluids in the Rayleigh-Benard configuration. For better understanding of the magnetic field influence on the phenomena occurring in cubical enclosure the following parameters were studied: absence or presence of nanoparticles (single and twophase fluids), thermal conditions (temperature difference range of 5-25 K) and magnetic field strength (magnetic induction range of 0-10 T). A multi-stage approach was undertaken to achieve the aim. The multi-stage approach means that the forces system, flow structure and heat transfer were considered. Without understanding the reasons (forces) and the fluid behaviour it would be impossible to analyse the exchanged heat rates through the Nusselt number distribution. The forces were determined at the starting moment, so the inertia force was not considered. The flow structure was identified due to the FFT analysis and it proved that magnetic field application changed the diamagnetic fluid behaviour, either single or two-phase. Going further, the heat transfer analysis revealed dependence of the Nusselt number on the flow structure and at the same time on the magnetic field. It can be said that imposed magnetic field changed the energy transfer within the system. In the paper, it was shown that each of presented steps were linked together and that only a comprehensive approach could lead to better understanding of magnetic field interference in the convection phenomenon.
Abstract. The main aim of this paper was to analyze possible utilization of the low concentration nanofluids and the magnetic field to enhance heat transfer. The studied fluids were based on water with an addition of copper particles (40-60 nm diameter). They belonged to the diamagnetic group of materials. As a first attempt to stated target the analysis of enclosure placed in the maximal value of square magnetic induction gradient was carried out. The maximum was in the centre of investigated cavity and it caused the most complex system of gravitational and magnetic buoyancy forces. In the lower part of cavity both forces acted in the same direction, while in the upper part they counteracted. Therefore an enhancement and attenuation of heat transfer could be observed. Due to the particle concentration and magnetic field action the character of flow was changed. In the case of 50 ppm nanofluid the flow was steady end the strong magnetic field didn't change much in its structure except for the suppression of some vortices. In the case of 500 ppm nanofluid the flow was not steady even without magnetic field, but increasing magnetic induction caused change of its structure towards the inertial-convective regime of turbulent flow.
Abstract. The main purpose of this paper was to investigate an influence of various parameters on the heat transfer processes with strong magnetic field utilization. Two positions of experimental enclosure in magnetic environment, two methods of preparation and three different concentrations of nanoparticles (0.0112, 0.056 and 0.112 vol.%) were taken into account together with the magnetic field strength. Analysed nanofluids consisted of distilled water (diamagnetic) and Cu/CuO particles (paramagnetic) of 40-60 nm size. The nanofluids components had different magnetic properties what caused complex interaction of forces' system. The heat transfer data and fluid flow structure demonstrated the influence of magnetic field on the convective phenomena. The most visible consequence of magnetic field application was the heat transfer enhancement and flow reorganization under applied conditions.
The elements that possess the ability of changing the flow structure (neckings, nozzles, valves, elbows) can be found in numerous industrial and medical applications. This ability leads to the velocity and temperature fields modification and can be a reason of negative effects like pressure loss. These negative effects can be reduced by the usage of magnetic field. Magnetic control of weakly magnetic fluids' velocity and temperature distributions is well known. Presented paper considers the numerical analysis of velocity and temperature maldistribution due to the influence of strong magnetic field. The analysis was carried out for threedimensional circular duct with simplified stenosis (narrowing of the blood vessels), which took form of confusor-diffuser section of the pipe. The system included duct and the magnetic coil that was oriented perpendicularly to the flow axis and placed in between confusor and diffuser. The wall of the stenosis was divided into subzones partially heated in order to control the velocity and temperature fields. Biot-Savart's law was applied to calculate the distribution of the magnetic field, which was then used to obtain the magnetic force distribution and added to principle of conservation of momentum equations as the external body force. Commercially available software Ansys Fluent 13 was chosen to conduct the numerical analysis, however special user-defined modulus to calculate the distribution of magnetic force was prepared and implemented in it. The results pointed out that the usage of magnetic field might provide a significant change in both velocity and temperature distribution, especially for low Reynolds number flows.
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