Procedure for hydraulic oil heat exchanger performance improvement through integrated CFD analysis

Authors

  • R. Paoluzzi C.N.R. – IMAMOTER Institute for Agricultural and Earth Moving Machines, National Research Council of Italy, Via Canal Bianco 28, 44124, Ferrara, ITALY
  • A. Bonanno C.N.R. – IMAMOTER Institute for Agricultural and Earth Moving Machines, National Research Council of Italy, Via Canal Bianco 28, 44124, Ferrara, ITALY
  • C. Ferrari C.N.R. – IMAMOTER Institute for Agricultural and Earth Moving Machines, National Research Council of Italy, Via Canal Bianco 28, 44124, Ferrara, ITALY
  • M. Martelli C.N.R. – IMAMOTER Institute for Agricultural and Earth Moving Machines, National Research Council of Italy, Via Canal Bianco 28, 44124, Ferrara, ITALY

DOI:

https://doi.org/10.1080/14399776.2014.976097

Keywords:

heat exchanger, software, performance evaluation, sub-domain, η-NTU, CFD

Abstract

Present and future constraints on the layout of hydraulic circuits onboard mobile machinery will require more and more compact components with improved efficiency. The need to use IC engines complying with new standards on emissions will introduce new components into the engine hood, like Exhaust Gas Recirculation (EGR), Selective Catalytic Reduction (SCR), Dust Particulate Filter (DPF) and more, reducing the space available for components where traditionally the ratio between dimension and performance was not considered a ‘hard boundary’ to the design space. One of the components of the hydraulic circuit affected by the general tendency to an increase of the operating temperatures due to the new-generation engines introduction is the heat exchanger. The need to design properly tailored, efficient and compact heat exchangers is therefore one of the first priority targets in machine design. Accurate and reliable estimate of the performance at the design stage is a priority as well.

This paper shows how the concurrent use of Computational Fluid Dynamics (CFD) and numerical approximations allow the performance prediction with a good correlation with the experimental results. The approach is applied to a cross-flow heat exchanger and is aimed at developing a software tool able to predict the global performance, yet being easily applicable to a wider range of cases. The approach used and described in this paper can be easily extended to a product set, variable in both dimension and technical characteristics. The key feature is to split the exchanger into sub-domains having homogeneous boundary conditions on either side, hot and cold, in order to estimate their performance in terms of WHTC (Wall Heat Transfer Coefficient) and pressure drop. This step applies a detailed CFD analysis. Results obtained are used as building blocks in a dedicated software tool developed at IMAMOTER-C.N.R. which sums-up the results to full scale. This approach features a reliable, yet flexible, evaluation of the exchanger performance under different environmental conditions and dimensions. The results obtained by the numerical analysis have been compared with experimental tests, showing the good degree of approximation achieved.

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Author Biographies

R. Paoluzzi, C.N.R. – IMAMOTER Institute for Agricultural and Earth Moving Machines, National Research Council of Italy, Via Canal Bianco 28, 44124, Ferrara, ITALY

Dr. Roberto Paoluzzi Born in 1961 and MSc in Nuclear Engineering at the University of Bologna in 1986. Director of the Institute for Agricultural and Earth-Moving Machines (IMAMOTER) of the National Research Council of Italy (C.N.R.). Main research interests in fluid power systems and motion control technology, computational fluid dynamics and off-road machines design and safety. Chairman of ISO/TC 127/SC4, authored more than 300 technical papers and reports.

A. Bonanno, C.N.R. – IMAMOTER Institute for Agricultural and Earth Moving Machines, National Research Council of Italy, Via Canal Bianco 28, 44124, Ferrara, ITALY

Dr. Antonino Bonanno MSc in Material Engineer at University of Messina in 2004. He received a Master degree in Fluid Power at University of Modena and Reggio Emilia in 2005. Researcher of the Italian National Research Council since 2005. He is involved in many research activities: innovative materials for fluid power applications, multi‐body simulation, structural analysis, hydraulic circuits and heat exchanger study. He is also involved in International Standard activities under the Technical Committee ISO/TC 127. Author and coauthor of more than 30 scientific and technical papers.

C. Ferrari, C.N.R. – IMAMOTER Institute for Agricultural and Earth Moving Machines, National Research Council of Italy, Via Canal Bianco 28, 44124, Ferrara, ITALY

Dr. Massimo Martelli Received the MSc. in Electronics Engineering from the University of Ferrara, Italy, in 2000. He is currently a researcher at the IMAMOTER institute (National Research Council of Italy). His main research interests are modelling and simulation of multi-domain systems (electrical + hydraulic + mechanical + thermal), aimed at system/component optimization and electronic control design and implementation, and multi-platform design of applications for advanced Human-Machine interaction, mainly applied to agricultural and earth-moving machines. He is also active on functional safety analysis, as a member of Project Group 2 of AEF (Agricultural industry Electronics Foundation). He is a author of more than 50 technical papers and reports.

M. Martelli, C.N.R. – IMAMOTER Institute for Agricultural and Earth Moving Machines, National Research Council of Italy, Via Canal Bianco 28, 44124, Ferrara, ITALY

Dr. Cristian Ferrari, PhD Received M.Sc. in Mechanical Engineering in 2008 and Ph.D. in Turbomachinery Design at University of Ferrara in 2012. From 2013 fellow Researcher at IMAMOTER Institute of the National Research Council of Italy. Worked on the study of hydraulic power transmission and computational fluid dynamics analysis. He is author of several papers and advisor of several master degree thesis.

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Published

2018-12-29

How to Cite

Paoluzzi, R., Bonanno, A., Ferrari, C., & Martelli, M. (2018). Procedure for hydraulic oil heat exchanger performance improvement through integrated CFD analysis. International Journal of Fluid Power, 15(3), 169–180. https://doi.org/10.1080/14399776.2014.976097

Issue

2014: Vol 15 Iss 3

Section

Original Article

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