A Vibration Signal-Based Method for Fault Identification and Classification in Hydraulic Axial Piston Pumps

Casoli, Paolo; Pastori, Mirko; Scolari, Fabio; Rundo, Massimo

doi:10.3390/en12050953

Cited by 39 publications

(36 citation statements)

References 39 publications

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“…The search displayed almost 100 research works, all focusing on various engineering setups utilising hydraulic components (Gomes et al 2016;Xu et al 2017a;Hao et al 2020;Pugin 2020). Aside from the general maintenance of the hydraulic system, other research works focus on specific key components such as the valve (Vianna et al 2015;Karanović et al 2019;Lei et al 2019), pump (Wang et al 2016;Xu et al 2017b;Casoli et al 2019), accumulator (Niu et al 2016;Pfeffer et al 2016;Leon-Quiroga et al 2020), cooler (Hathaway et al 2018).…”

Section: Related Workmentioning

confidence: 99%

Hybrid Intelligent Predictive Maintenance Model for Multiclass Fault Classification

Buabeng

Simons

Frimpong

et al. 2021

Preprint

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Data recorded from monitoring the health condition of industrial equipment are often high-dimensional, nonlinear, nonstationary and characterised by high levels of uncertainty. These factors limit the efficiency of machine learning techniques to produce desirable results when developing effective fault classification frameworks. This paper sought to propose a hybrid artificial intelligent predictive maintenance model based on Improved Complete Ensemble Empirical Mode Decomposition with Adaptive Noise (ICEEMDAN), Principal Component Analysis (PCA) and Least Squares Support Vector Machine (LSSVM) optimised by the combination of Coupled Simulated Annealing and Nelder-Mead Simplex optimisation algorithms (ICEEMDAN-PCA-LSSVM). Here, ICEEMDAN was first employed as a denoising technique to decompose signals into series of Intrinsic Mode Functions (IMFs) of which only relevant IMFs containing the relevant fault features were retained for signal reconstruction. PCA was then employed as a dimension reduction technique through which the resulting set of uncorrelated features extracted served as input for LSSVM for classifying various fault types. The proposed technique is compared with three established methods (Linear Discriminant Analysis (LDA), Support Vector Machine (SVM) and Artificial Neural Network (ANN)) with multiclass classification capabilities. The various techniques were tested on an experimental UCI machine learning benchmark data obtained from multi-sensors of a hydraulic test rig. The results from the analysis revealed that the proposed ICEEMDAN-PCA-LSSVM technique is versatile and outperformed all the compared classifiers in terms of accuracy, error rate and other evaluation metrics considered. The proposed hybrid technique drastically reduced the redundancies and the dimension of features, allowing for the efficient consideration of relevant features for the enhancement of classification accuracy and convergence speed.

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Section: Related Workmentioning

confidence: 99%

Hybrid Intelligent Predictive Maintenance Model for Multiclass Fault Classification

Buabeng

Simons

Frimpong

et al. 2021

Preprint

View full text Add to dashboard Cite

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“…In terms of extraction of fault features, Wang et al applied the minimum entropy deconvolution, Walsh transform denoising, Teager energy operator (TEO) demodulation, and other methods to the fault diagnosis of axial piston pump, which effectively solved the technical problem of extracting fault features from vibration signals contaminated by strong background noise [11][12][13]. Casoli et al presented a feature extraction using principal components analysis (PCA) techniques and different classification to detect the health state of a variable displacement axial-piston pump based on vibration signals [14]. Li et al proposed a fault feature selection method for axial piston pump based on quantum genetic algorithm [15].…”

Section: Introductionmentioning

confidence: 99%

Fault Diagnosis of Axial Piston Pump Based on Extreme‐Point Symmetric Mode Decomposition and Random Forests

Lei

Jiang

Niu

et al. 2021

Shock and Vibration

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Aiming at fault diagnosis of axial piston pumps, a new fusion method based on the extreme-point symmetric mode decomposition method (ESMD) and random forests (RFs) was proposed. Firstly, the vibration signal of the axial piston pump was decomposed by ESMD to get several intrinsic mode functions (IMFs) and an adaptive global mean curve (AGMC) on the local side. Secondly, the total energy was selected as the data of feature extraction by analyzing the whole oscillation intensity of the signal. Thirdly, the data were preprocessed and the labels were set, and then, they were adopted as the training and testing set of machine learning samples. Lastly, the RFs model was created based on machine learning service (MLS) to diagnose the faults of the axial piston pump on the cloud. Using the test and verifying the data set for comparative testing, the fault diagnosis precision rates of the model are above 90.6%, the recall rates are more than 90.9%, the F1 score is higher than 90.7%, and the accuracy rate of this model reached 97.14%. A benchmark data simulation of mechanical transmission systems and an experimental data investigation of an axial piston pump are performed to manifest the superiority of the present method by comparing with classification and regression trees (CART) and support vector machine (SVM).

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“…Cavitation and aeration affect both the machine efficiency and the noise emissions, as well as the duration of the component. This issue is very challenging to be simulated but advanced CFD analysis combined with lumped parameters approach and experimental vibrational analysis are able to locate the areas where these phenomena occur and to test any design solution introduced to avoid or limit the damage ( [14,15,16]). No surprises, hence, that modelling and simulation have become essential when addressing the design of PDMs to improve the performances under different aspects.…”

Section: Introductionmentioning

confidence: 99%

Lumped parameter model of vane pumps developed in OpenModelica environment

et al. 2021

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In this paper, the authors present a 0D fluid dynamic model of a vane pump used to refill tanks with fuel. The model is entirely developed in OpenModelica environment, where the authors have created specific libraries of elements suitable for the physical modelling of fluid power components and systems. Among the different approaches, the zero-dimension (0D) fluid-dynamic modelling of positive displacement machines is suitable to study many aspects as: the instantaneous flow rate, pressure and torque transients, the fluid borne noise related to the flow rate and pressure irregularity, the dynamic behaviour of the variable displacement control. Overall, this approach in modelling allows to link the geometrical features of the machine with its dynamic behaviour and for this reason is particularly useful in guiding the design. The model of the vane pump is described together with the main design features that can be analysed in terms of their influence on the pump behaviour. Besides the specific results obtained regarding the design of the pump, the paper also demonstrates the use of OpenModelica language and environment, and its efficacy, into the applications of fluid power modelling and simulation.

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A Vibration Signal-Based Method for Fault Identification and Classification in Hydraulic Axial Piston Pumps

Cited by 39 publications

References 39 publications

Hybrid Intelligent Predictive Maintenance Model for Multiclass Fault Classification

Hybrid Intelligent Predictive Maintenance Model for Multiclass Fault Classification

Fault Diagnosis of Axial Piston Pump Based on Extreme‐Point Symmetric Mode Decomposition and Random Forests

Lumped parameter model of vane pumps developed in OpenModelica environment

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