River Publishers Series in Proceedings
Editors:
Adolfo Senatore, University of Naples Federico II, Italy
Emma Frosina, University of Sannio, Benevento, Italy
On behalf of the Organizing Committee, we welcome you to the Conference Proceedings of the 2022 Global Fluid Power Society PhD Symposium (GFPS2022). The Symposium is a bi-annual event organized by the Global Fluid Power Society (GFPS) to showcase and brainstorm on research carried out by junior investigators in fluid power. GFPS Society was created in 2016 to merge two long-lasting fluid power organizations: Fluid Power Net International (FPNI) and Network of Fluid Power Centres in Europe (FPCE). GFPS inherits the spirit of both FPNI and FPCE and currently represents the world's largest scientific network of fluid power institutions.
Since its first edition, the GFPS PhD Symposium represents an international meeting place in the world of research in the field of Fluid Power involving national and international institutions, academia, and companies in a discussion on the most recent results of scientific and technological research for the fluid power industry, with particular emphasis to applications and new trends. Attention is paid to, but not limited to, new technology in the fluid power, power transmissions and motion control fields.
The first edition of the GFPS PhD Symposium was hosted by the University of Samara, Russia, in 2018; then, after two years of emergency, the COVID-19 outbreak forced the edition 2020 expected in Guilin, China, and organized by the Harbin Institute of Technology di Harbin, to be held online. 2022 is finally coming back to normality!
In 2022, our expectation of hosting you all in Italy and its world-famous Naples has been realized! The program is arranged to offer the possibility of visiting Naples before, during and after the Symposium!
The University of Naples and the University of Sannio coordinate the organization.
The GFPS2022 Program is highly varied, including plenary sessions, regular technical sessions with 61 oral presentations, two industry panel sessions, and special events devoted to students, young professionals, professors, and industries, scheduled over three days.
Presentations are organized in 2 General Sessions and 14 Special Sessions. Special Sessions aim to create a focus on specific topics, where researchers can gain knowledge, familiarize themselves, exchange ideas, and build cooperation.
The received papers were submitted for peer review. Relevance, quality, significance, and novelty of the scientific contribution were the main attributes for acceptance and publication in the Proceedings. The International Journal of Fluid Power publishes the Proceedings. We want to thank all the reviewers who actively contributed to the selection and quality improvement of the presented works.
GFPS PhD Symposium 2022 is honoured to have experts in Fluid Power as Invited Speakers.
We are grateful to the Invited Speakers for joining the Symposium.
To recognize the most outstanding papers presented at the bi-annual 2022 Global Fluid Power Society PhD Symposium, a Backé Medal sponsored by the Global Fluid Power Society, a Best Conference Paper Award sponsored by MDPI Fluids Journal, and a Best Conference Paper Award sponsored by the Symposium Organizers will be assigned.
We sincerely want to thank all the sponsors and the patronages who made this event possible.
The 2022 Global Fluid Power Society PhD Symposium is about to begin. Students, professors, and engineers enjoy the Workshop!
Chapter 1.1: Analysis of Compensation Ratios and Control
Torques of an Axial Piston Pump with Rotated
Valve Plates
by Thomas Heeger, Stephan Wegner, Liselott Ericson
https://doi.org/10.13052/rp-9788770047975.001
Chapter 1.2: Validated efficiency improvements by implementation of
structures on the slipper surface of an axial piston pump
by Svenja Horn, Roman Ivantysyn, Jürgen Weber
https://doi.org/10.13052/rp-9788770047975.002
Chapter 1.3: Analyses of engineered surfaces for performance
improvements of external gear pumps
by Paolo Casoli, Fabio Scolari, Carlo Maria Vescovini, Carlo Rossi, Antonio Lettini
https://doi.org/10.13052/rp-9788770047975.003
Chapter 1.4: Numerical Modeling of Helical External Gear Pump Through a Novel CFD Approach Using Simerics MP+
by Pietro Mazzei, Emma Frosina, Simone Bulleri, Adolfo Senatore.
https://doi.org/10.13052/rp-9788770047975.004
Chapter 1.5: Numerical Modeling of Helical External Gear Pump Through a Lumped Parameter Approach
by Pietro Mazzei, Emma Frosina, Simone Bulleri, Adolfo Senatore
https://doi.org/10.13052/rp-9788770047975.005
Chapter 1.6: High fidelity data generation and fault diagnosis of a gear pump
by Kayal Lakshmanan, Fabrizio Tessicini, Antonio J. Gil,
Ferdinando Auricchio
https://doi.org/10.13052/rp-9788770047975.006
Chapter 1.7: Simulation Model of a Helical Gear Pump for the Evaluation of the Filling Capability
by Alessandro Corvaglia, Massimo Rundo, Sara Bonati, Manuel Rigosi
https://doi.org/10.13052/rp-9788770047975.007
Chapter 1.8: MODELLING AND EXPERIMENTAL VALIDATION OF THE DYNAMIC STARTUP BEHAVIOR OF EXTERNAL SPUR GEAR MOTOR
by Ajinkya Pawar, Andrea Vacca, Manuel Rigosi
https://doi.org/10.13052/rp-9788770047975.008
Chapter 1.9: Design, Modeling, and Experimental Characterization of a Fast Additively Manufacturable MRI-Compatible Pneumatic Motor for Surgical Robots
by Mengtang Li, Jing Zhang, Xiyun Wu, Jieting Yuan,
Xiyu Wang, Yongyin Ye, and Beichen Ding
https://doi.org/10.13052/rp-9788770047975.009
Chapter 1.10: A Study on a Twin-Screw Pump for Thermal Management Systems by means of CFD using SimericsMP+®: experimental validation and focus on Pressure Pulsation
by Pasquale Borriello, Emma Frosina, Pierpaolo Lucchesi, Adolfo Senatore
https://doi.org/10.13052/rp-9788770047975.010
Chapter 2.1: An efficient simulation approach to determine the thermal equilibrium of drive systems in mobile machinery
by Eric Pohl, Sven Osterland, Jurgen Weber
https://doi.org/10.13052/rp-9788770047975.011
Chapter 2.2: Digital Electro Hydrostatic Actuator with Variable Speed Digital Hydraulic Pump: A Design Overview
by Dimitri Oliveira e Silva, Marcos Paulo Nostrani, Rodrigo Simões Lopes Junior, Gierri Waltrich, Petter Krus, Victor Juliano De Negri
https://doi.org/10.13052/rp-9788770047975.012
Chapter 2.3: A piezo-electrically actuated valve for hydraulic exoskeleton drives — modelling and measurement of a prototype
by Philipp Albrecht-Zagar, Rudolf Scheidl
https://doi.org/10.13052/rp-9788770047975.013
Chapter 2.4: Different Solutions for the Achievement of Variable Margin
Load Sensing Systems: Energy Saving and Increased Performance
by Davide Mesturini, Mattia Scolari, Francesco De Martino, Ulderico Busani
https://doi.org/10.13052/rp-9788770047975.014
Chapter 2.5: Numerical Simulations of a High Frequency Switching 4/2 ON/OFF Valve for Pulse Modulation Switching Digital Circuits
by Francesco Sciatti1, Paolo Tamburrano, Andrew R. Plummer, Elia Distaso, Pietro De Palma and Riccardo Amirante
https://doi.org/10.13052/rp-9788770047975.015
Chapter 2.6: Design for Structural Durability of an Hydraulic Main Valve for Mobile Applications
by Filippo Ciardo, Giovanni Meneghetti, Edoardo Caldesi, Cesare Dolcin, Alessandro Cervi, Davide Mesturini
https://doi.org/10.13052/rp-9788770047975.016
Chapter 2.7: Generation and validation of a real time multibody model for off-highway vehicles, aiming at the design of suspension systems
by Andrea Fornaciari, Barbara Zardin and Massimo Borghi
https://doi.org/10.13052/rp-9788770047975.017
Chapter 2.8: A Parametric Study on Architectures Using Common-Pressure Rail Systems and Multi-Chamber Cylinders.
by Mateus Bertolin, Andrea Vacca
https://doi.org/10.13052/rp-9788770047975.018
Chapter 2.9: Challenges in the designing process of hydraulic cylinders made of plastics
by Piotr Stryczek
https://doi.org/10.13052/rp-9788770047975.019
Chapter 2.10: dentifying The Future Research Trend for Using Speed-Controlled Hydraulic Cylinders in Offshore Applications through Literature Survey
by Wei Zhao, Morten Kjeld Ebbesen,Torben Ole Andersen
https://doi.org/10.13052/rp-9788770047975.020
Chapter 3.1: Loading system for wind turbine drivetrain test bench with
model-based compensation control strategy
by Danyang Li, Yajing Gu, Yonggang Lin, Jiajun Song, Xiangheng Feng , Hongwei Liu
https://doi.org/10.13052/rp-9788770047975.021
Chapter 3.2: Cartesian Damping Controller with Nonlinear Control for a Floating-Base Hydraulic Manipulator
by Pauli Mustalahti and Jouni Mattila
https://doi.org/10.13052/rp-9788770047975.022
Chapter 3.3: Real-time trajectory scaling algorithm for hydraulic manipulators subject to limited on-board power
by Lionel Hulttinen, Jouni Mattila
https://doi.org/10.13052/rp-9788770047975.023
Chapter 3.4: Compliance Motion Control of the Hydraulic Dual-Arm Manipulator Based on Virtual Decomposition Control
by Bolin Sun, Min Cheng, Ruqi Ding, Bing Xu, Jouni Mattila
https://doi.org/10.13052/rp-9788770047975.024
Chapter 3.5: Pressure Feedback Control Of Electro-Hydraulic Actuators Using Fixed Displacement Hydraulic Machines
by Shaoyang Qu, Hassan Assaf, Andrea Vacca, Enrique Busquets
https://doi.org/10.13052/rp-9788770047975.025
Chapter 3.6: Energy Saving Enhancement through 3 way Downstream Compensator Main Valve, a Viable Option for Efficient Off Highway Applications
by Cesare Dolcin, Gianluca Ganassi, Ulderico Busani, Francesco Ferdinando De Martino
https://doi.org/10.13052/rp-9788770047975.026
Chapter 4.1: System for recovering energy in hydraulic circuit by using a small Pelton turbine
by Marco Rizzoli, Giovanni Cillo, Barbara Zardin, Danilo Manfredi and Massimo Borghi
https://doi.org/10.13052/rp-9788770047975.027
Chapter 4.3: Development of a Bi-stable Mechanism for Efficiency Optimization of Pneumatic Pressure Boosters
by Matthias Schmid, Olivier Reinertz, Katharina Schmitz
https://doi.org/10.13052/rp-9788770047975.029
Chapter 5.1: Influence of the Pressure-Viscosity Behavior of Different Base Oils on the Formation of Lubricating Films in Tribological Contacts
by Sebastian Deuster, Achill Holzer, Katharina Schmitz
https://doi.org/10.13052/rp-9788770047975.030
Chapter 5.2: Topology optimization of fluid cooling systems for machine tools
by Christoph Steiert, Juliane Weber, Jürgen Weber
https://doi.org/10.13052/rp-9788770047975.031
Chapter 5.3: Elastodynamic Performance Evaluation and Comparison in Hydraulic and Electromechanical Linear Actuator Driven Heavy-Duty Manipulators
by Aleksi Vesterinen, Goran R. Petrovic´ and Jouni Mattila
https://doi.org/10.13052/rp-9788770047975.032
Chapter 6.1: Evaluation of Nonlinear MIMO Controllers for Independent Metering in Mobile Hydraulics
by Lukas Bachmann, Andr´e Sitte, J¨urgen Weber
https://doi.org/10.13052/rp-9788770047975.033
Chapter 6.2: Combined multidimensional approaches for the simulation of flow trough a wall-flow particulate filter
by A. N. Impiombato, G.Discepoli, F. Paltrinieri, M. Milano, L. Montorsi
https://doi.org/10.13052/rp-9788770047975.034
Chapter 6.3: Using nonlinear observers as virtual sensors in hydraulically actuated equipment in Industrial IoT systems
by Victor Zhidchenko, Yashar Shabbouei Hagh, Egor Startcev, Heikki Handroos
https://doi.org/10.13052/rp-9788770047975.035
Chapter 6.4: Dynamic fluid simulation of hydraulic oil flow inside fatigue cracks during transient loads
by Lukas Michiels, Marcus Geimer
https://doi.org/10.13052/rp-9788770047975.036
Chapter 6.5: Implementation of a Variational Autoencoder for Dimension Reduction of a Hydraulic System
by Faras Brumand-Poor, Faried Makansi, Jiakun Liao, Katharina
Schmitz
https://doi.org/10.13052/rp-9788770047975.037
Chapter 6.6: CFD simulations of Flow Field in Flapper-Nozzle Pilot Valve with Vortex Generators
by Tong Li,Jinghui Peng, Songjing Li
https://doi.org/10.13052/rp-9788770047975.038
Chapter 6.7: Study of a dual layout Input-to-Output Coupled hydromechanical transmission
by Antonio Rossetti, Nicola Andretta, Alarico Macor
https://doi.org/10.13052/rp-9788770047975.039
Chapter 6.8: Simulation model of hydraulic generator with variable flow direction
by Kacper Dąbek, Krzysztof Kędzia, Piotr Osiński
https://doi.org/10.13052/rp-9788770047975.040