Abstract
This paper addresses the problem of understanding the relationship between fluid flow and heat transfer in industrial quenching systems. It also presents an efficient analysis to design or optimize long standing quenching tanks to increase productivity. The study case is automotive leaf springs quenched in an oil-tank agitated with submerged jets. This analysis combined an efficient numerical prediction of the detailed isothermal flow field in the whole tank with the thermal characterization of steel probes in plant and laboratory during quenching. These measurements were used to determine the heat flow by solving the inverse heat conduction problem. Differences between laboratory and plant heat flux results were attributed to the difference in surface area size between samples. A proposed correlation between isothermal wall shear stress and heat flux at the surface of the steel component, based on the Reynolds-Colburn analogy, provided the connection between thermal characterization and computed isothermal fluid flow. The present approach allowed the identification of the potential benefits of changes in the tank design and the evaluation of operating conditions while using a much shorter computing time and storage memory than full-domain fluid flow calculations.
Highlights
The generation of a quantitative understanding of fluid dynamics and heat transfer during quench tank production is a research area that offers wide space for technical contributions
We read in that plot a heat flux that is half the value the expected one for an “infinite” surface. Considering that this full correction is applicable for the maximum heat flux, and that the Taylor instability does not exist during one-phase cooling, we propose the following empirical corrections for laboratory boiling curve
The analysis is based on a proposed empirical power-law equation to relate the isothermal wall shear stress, computed numerically on the surface of the leaf springs, with the heat flux removed during their quenching
Summary
The generation of a quantitative understanding of fluid dynamics and heat transfer during quench tank production is a research area that offers wide space for technical contributions. Many of commercially important steels and aluminum alloys are heat-treated to achieve the target hardness and tensile strength. This treatment consists of heating the metallic pieces to their dissolution temperature and quenching them by fast cooling. Agitation plays a key role in determining the rate of heat transfer from the workpieces to the quenching medium. A vapor film develops over the surface, and the rate of heat transfer is controlled by the isolating properties of this stable vapor film. Once the surface cools to reach the so-called Leidenfrost temperature, the vapor film collapses, Metals 2017, 7, 190; doi:10.3390/met7060190 www.mdpi.com/journal/metals
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