A thermal parametric study of non-evaporative spray cooling process

Otmani, Abdessalam; Mzad, Hocine; Bey, K.

doi:10.1051/matecconf/201824001030

Cited by 2 publications

(2 citation statements)

References 10 publications

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“…Case studies of single-phase cooling process were also considered in the experimental investigation of single-phase microjet cooling of microelectronics [10] and the thermal parametric study of non evaporative spray cooling process [11].…”

Section: Introductionmentioning

confidence: 99%

Archives of Thermodynamics

Mzad,

Otmani

2020

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As in many thermal processing technologies, there is a delicate balance between productivity and quality during ingot cooling process. Higher cooling velocities increase productivity but also create higher temperature gradients inside the ingot. Such a fast cooling does not leave sufficient time to establish the equilibrium within the solid, thus the final metal structure is strongly affected by the set up cooling mode throughout the liquid metal solidification. The first intention in this paper is to compare between three cooling modes in order to identify the required mode for a continuous casting process. Then, we study the influence of heat transfer coefficient on metal liquid-to-solid transition through the spray-cooled zone temperature and the metal latent heat of solidification. A gray iron continuous casting process subjected to water-sprays cooling was simulated using the commercial software for modeling and simulating multiphysics and engineering problems. The primary conclusions, from the obtained results, show the forcefulness of water spray cooling regarding standard cooling. Afterward, we highlight the great influence of heat transfer coefficient on the location of transition region as well as the relationship between heat transfer coefficient, wall outer temperature, latent heat dissipation, and the solidification time.

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Section: Introductionmentioning

confidence: 99%

Archives of Thermodynamics

Mzad,

Otmani

2020

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“…A specific experimental setup was elaborated in detail allowing the great potential on the performance of the PV cell by significant increasing of the total output power in circumstances of peak solar irradiation. A parametric analysis during spray cooling process [15,16] was conducted taking into account the thermodynamic behaviour of the fluid-flow on an aluminium plate at the temperature of 92 • C. Effects of total internal energy, convective heat flux, Reynolds number, spray distribution and velocity were carefully examined in order to better understand and control the temperature variation.…”

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confidence: 99%

Archives of Thermodynamics

Mzad,

Otmani

2021

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Solar cell performance decreases with increasing temperature, heat can reduce output efficiency by 10-25%. The operating temperature plays a key role in the photovoltaic conversion process. Increase in electrical efficiency depends on cooling techniques, in particular photovoltaic modules installed in the high temperature regions. A cooling process using a single nozzle of photovoltaic panel operating under different configurations was simulated. The simulation contains two parts: the first is a thermodynamic investigation of fluid impingement upon the sensor front face. The second is a performance comparison between two types of glass cover. The major result that emerges from this simulation is the effect of a single nozzle arrangement to enhance the cooling process, under a low cadence of impinging droplets in the range 0.1-1.7 m/s.

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A thermal parametric study of non-evaporative spray cooling process

Cited by 2 publications

References 10 publications

Archives of Thermodynamics

Archives of Thermodynamics

Archives of Thermodynamics

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