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Analytical Study of Heat Transfer When Heating or Cooling a Limited Volume of Liquid

Authors: Aleksandrov A.A., Akatev V.A., Tyurin M.P., Borodina E.S., Sedlyarov O.I. Published: 05.12.2021
Published in issue: #6(99)/2021  
DOI: 10.18698/1812-3368-2021-6-17-34

 
Category: Physics | Chapter: Thermal Physics and Theoretical Heat Engineering  
Keywords: analytical studies, heat exchanger, heat transfer coefficient, limited fluid volume, heat transfer

The paper shows the results of analytical studies of heat transfer when heating or cooling a limited volume of liquid. The purpose of the research was to determine the size of the heat transfer surface, with the initial parameters of the coolants, the final temperature in the reactor and its thermal equivalent, as well as the flow rate of the second coolant through the heat exchanger corresponding to the water equivalent at a given cooling time τo. Moreover, if intensive mixing is carried out in the vessel, i.e., if the temperature of the second heat carrier practically does not change along the length of the heat transfer surface, then W2 → ∞. The solution was based on the Laplace --- Carson integral transform. The exact solution was converted for special cases of heat transfer. In particular, it should be noted that in many practical cases formulas give a fairly good approximation to the exact solution. Only at low values of the heat transfer coefficient, as well as when the volume occupied by the coolant inside the heat exchanger is commensurate with the volume of the liquid contained in the vessel, it is necessary to apply the given exact solution

The work was carried out at Bauman Moscow State Technical University with the support of the Ministry of Education and Science of Russian Federation (agreement no. 075-11-2019-087 of 12/18/2019)

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