Experimental and Modelling Analysis of a Downstream Compensation System: Energy Optimization of the Directional Control Valves

Authors

  • Antonella Bonavolontà University of Naples “Federico II”, Napoli, Italy
  • Emma Frosina University of Sannio, Benevento, Italy
  • Pietro Marani CNR – STEMS, Ferrara, Italy
  • Davide Mesturini Walvoil SpA, Reggio Emilia, Italy
  • Cesare Dolcin Walvoil SpA, Reggio Emilia, Italy
  • Ulderico Busani Walvoil SpA, Reggio Emilia, Italy

DOI:

https://doi.org/10.13052/ijfp1439-9776.2415

Keywords:

Energy recovery, directional control valve, accumulator, efficiency, downstream compensation, flow sharing system

Abstract

Through a study on the Fluid Power innovations in the last years emerged that still few solutions have been successfully implemented for the optimization of the hydraulic circuits. The recent machine electrification offers a potential for investment in energy-saving hydraulic systems to ensure greater performance and higher battery autonomy. From different studies emerged that in the specific field of ICE Off-road Vehicles, only about 10–15% of the available power at fuel level is actually transformed into useful energy for the actuators. Particularly the losses in the Directional Control Valves represent about 35–40% of the hydraulic energy available at the pump level. The traditional Directional Control Valves design solutions, in fact, neglects important opportunities for reducing losses and improving internal regeneration. Especially, energy recovery is rarely applied and in any case by means of important superstructures which considerably increase the costs of the system. This paper presents a new hydraulic architecture: an original Directional Control Valve layout based on a Downstream Compensation approach. In particular, a Flow Sharing system is implemented in this new architecture with the goal to minimize the wasted energy. In fact, this system realizes an important energy recovery from both the inertial loads and the simultaneous use of multiple actuators at different pressure level. The circuit enables recovered energy to be stored in a high-pressure accumulator. The paper presents the simulation results and the energy saving estimation realized through a lumped parameter environment “Amesim Simcenter”. Additionally, the results of experimental activities show the innovative system performance, benefits and physical applicability. This idea is based on concrete objectives and pays particular attention to cost sustainability, industrial manufacturability and system scalability.

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Author Biographies

Antonella Bonavolontà, University of Naples “Federico II”, Napoli, Italy

Antonella Bonavolontà is an engineer working on the study and optimization on valves in the fluid power field. From 2017 to 2022, she was involved in Fluid Power Research, getting her Ph.D. at the University of Naples Federico II in 2020; working in both academic and industrial sectors, her research interest was in the design optimization of valves by means of numerical modeling and in prototype development and testing.

Emma Frosina, University of Sannio, Benevento, Italy

Emma Frosina is an Assistant Professor at the Department of Engineering of the University of Sannio Benevento. She received her M.S. Degree in Mechanical Engineering from the University of Naples Federico II in 2012 and her Ph.D. Degree in Mechanical Systems Engineering in 2016. She is the author of over 50 scientific papers published in peer-reviewed international journals and in international conference proceedings. Her research interests are in the fluid power field where she is mainly specialized in modeling and optimization of components (machines, valves, etc.) using numerical approaches (both lumped parameter and three-dimensional CFD) and testing.

Pietro Marani, CNR – STEMS, Ferrara, Italy

Pietro Marani is researcher at CNR-STEMS (Institute of Science and Technology for Energy and Mobile Sustainability of the National Research Council of Italy), formerly IMAMOTER.

Received his Ph.D. in Mechanical Engineering from Modena and Reggio Emilia University.

Author of several papers and of two patents, his main research interests are energy saving architectures for mobile machines, lumped parameter simulation and innovative sensors.

Davide Mesturini, Walvoil SpA, Reggio Emilia, Italy

Davide Mesturini has been Research & Development Manager at Walvoil, Interpump Group, since 2015. Graduated in Mechanical Engineering at Politecnico di Torino in 1998 and specialized in Hydraulics, he obtained a Master in Technology & Innovation Management at Bologna Business School. Since 1999 he has been working in the hydraulic field as Project Leader, Application Engineer and Technical Manager, focusing in particular on Directional Control Valves. He has published several works and participated in several conferences; he has acquired various patents and recently received an international award for hydraulic innovation. Today he carries out research mainly on efficient and sustainable solutions for the mobile machinery hydraulic.

Cesare Dolcin, Walvoil SpA, Reggio Emilia, Italy

Cesare Dolcin received his M.S. Degree in Mechanical Engineering from University of Bologna in 1996; after being appointed Army’s Officer by SACA of Sabaudia in 1997 and getting a post-degree in Space System from University of Padua in 1998, he took a B.S. in Physics from University of Modena in 2011. After working seven years in the field of components for alternative fuels and low emission vehicles, in 2005 he joined Walvoil (now member of Interpump Group) as Test Department Manager. His research activities regard fluid power components application to off-highway mobile machines, mainly involving aspects of energy management (saving and recovery) and metal fatigue behaviour.

Ulderico Busani, Walvoil SpA, Reggio Emilia, Italy

Ulderico Busani has been Head of Directional Control Valves Design at Walvoil, Interpump Group, since 2001. He graduated in Mechanical Engineering at University of Bologna in 1986. He worked in After Sales for 7 years, then he joined the design team, where he developed several Directional Control Valves especially for off-road construction, agriculture and material handling vehicles. He published several works and patents, for example the DPX100. His research is currently focused in increasing components efficiency.

References

A. Bonavolontà, C. Dolcin, P. Marani, E. Frosina, A. Senatore (2019) “Comparison of Energy Saving and Recovery Systems for Hydraulic Mobile Machines”, 74rd Conference of the Italian Thermal Machines Engineering Association, ATI 2019, Modena, Italy.

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D. Mesturini, C. Dolcin, U. Busani, P. Marani, A. Bonavolontà, E. Frosina (2020), “Optimization Of Directional Control Valves Through Downstream Compensation Approach”, 10th International Fluid Power Conference, Dresden, Germany.

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Published

2023-01-17

How to Cite

Bonavolontà, A. ., Frosina, E. ., Marani, P. ., Mesturini, D. ., Dolcin, C. ., & Busani, U. . (2023). Experimental and Modelling Analysis of a Downstream Compensation System: Energy Optimization of the Directional Control Valves. International Journal of Fluid Power, 24(01), 99–124. https://doi.org/10.13052/ijfp1439-9776.2415

Issue

2023: Vol 24 Iss 1

Section

GFPS 2020

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