Condition Monitoring of an Axial Piston Pump on a Mini Excavator

Authors

  • Nathan Keller Purdue University, 1500 Kepner Drive, Lafayette IN 47905, Indiana, United States https://orcid.org/0000-0002-1762-5176
  • Annalisa Sciancalepore Purdue University, 1500 Kepner Drive, Lafayette IN 47905, Indiana, United States
  • Andrea Vacca Purdue University, 1500 Kepner Drive, Lafayette IN 47905, Indiana, United States

DOI:

https://doi.org/10.13052/ijfp1439-9776.2422

Keywords:

Axial piston pump, machine learning, condition monitoring, Mobile Hydraulics, fault detection

Abstract

The focus of this paper is to show the process of developing a condition monitoring system for an axial piston pump mounted on a mini excavator. This work outlines some previous condition monitoring work on axial piston pumps but addresses the lack of research conducted on mobile hydraulics. The valve plate of the pump is chosen as a case study to demonstrate varying degrees of wear and damage to represent healthy and faulty pump conditions. The wear and damage of these valve plates is measured using an optical profilometer, and efficiency measurements were conducted to characterize the fault levels. Once the faults were characterized, the mini excavator was introduced and instrumented to demonstrate what parameters were being considered. Next, three duty cycles were introduced: controlled, digging, and different operator cycles. The controlled cycles are a very repeatable condition that eliminated the need of an operator. The digging cycle was more of a realistic cycle where an operator dug into a loose pile of soil. The different operator cycle is the same as the digging cycle, but a different operator was employed. The sensors that proved to be the most useful in detecting valve plate faults were the drain pressure, pump port pressures, engine speed, and pump displacement. Fault detectability accuracies of 100% were achievable under the controlled cycle utilizing the Fine KNN classification machine learning algorithm. The digging cycle could achieve a fault detection accuracy of 93.6% using the same algorithm and sensors. Finally, the cross-compatibility between a model trained under once cycle and using data from another cycle as an input was investigated. This study showed that a model trained under the controlled duty cycle does not give reliable and accurate fault detectability for data run in a digging cycle, below 60% accuracies. However, cross-compatibility may be achievable if more extreme faults are present. This work concluded by recommending a diagnostic function for mobile machines to perform a preprogrammed operation to reliably and accurately detect pump faults.

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Author Biographies

Nathan Keller, Purdue University, 1500 Kepner Drive, Lafayette IN 47905, Indiana, United States

Nathan Keller currently works for Moog, Inc., where he leads efforts in developing zero-emission mobile construction equipment. He has previously worked as a systems integrator for North America’s largest fluid power distributor. Dr. Keller earned his doctorate in Agricultural and Biological Engineering and a master’s degree in Mechanical Engineering from Purdue University at the Maha Fluid Power Research Center. Dr. Keller’s dissertation topic was on condition monitoring of axial piston pumps for mobile equipment, and his master’s thesis was on efficient hydraulic system architectures on mobile agricultural equipment.

Annalisa Sciancalepore, Purdue University, 1500 Kepner Drive, Lafayette IN 47905, Indiana, United States

Annalisa Sciancalepore earned her Ph.D. from Purdue University in 2023 at the Maha Fluid Power Research Center. She received her B.Sc. in Mechanical engineering in 2015 and her M.Sc. in Mechatronic Engineering in 2017 from the Polytechnic University of Turin, Italy. Dr. Sciancalepore doctoral research focused on hydraulic systems optimization for material-handling machines. Specifically, she investigated novel hydraulic circuits that use counterbalance valves with an adjustable pilot for energy-saving applications. Moreover, by combining her knowledge of hydraulics with her mechatronics background, she developed novel numerical and experimental methods for the condition monitoring of hydraulic systems and components. Dr. Sciancalepore is currently employed with the Helios Center of Engineering Excellence to support the acceleration and advancement of Helios Technologies integrated electro-hydraulic technologies.

Andrea Vacca, Purdue University, 1500 Kepner Drive, Lafayette IN 47905, Indiana, United States

Andrea Vacca is the Maha Fluid Power Faculty Chair at Purdue University. He leads the Maha Fluid Power Research Center which is the largest academic center dedicated to fluid power technology in the United States. His research aims at formulating novel concepts for hydraulic systems and components for a more efficient, quieter and environmental friendly actuation technology. Dr. Vacca is the author of more than 200 papers and received several research awards, including the 2019 J. Bramah medal of the Institution of Mechanical Engineers. He is a former chair of Fluid Power Systems and Technology Division (FPST) of ASME, and of the SAE Fluid Power division. Dr. Vacca is also Treasurer and Secretary of the Board of the Global Fluid Power Society (GFPS). Furthermore, he is also Editor in Chief of the International Journal of Fluid Power and he serves the editorial board of several other engineering journals.

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Published

2023-05-03

How to Cite

Keller, N. ., Sciancalepore, A. ., & Vacca, A. . (2023). Condition Monitoring of an Axial Piston Pump on a Mini Excavator. International Journal of Fluid Power, 24(02), 171–206. https://doi.org/10.13052/ijfp1439-9776.2422

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