Abstract
Reliable prediction of remaining useful life (RUL) plays an indispensable role in prognostics and health management (PHM) by reason of the increasing safety requirements of industrial equipment. Meanwhile, data-driven methods in RUL prognostics have attracted widespread interest. Deep learning as a promising data-driven method has been developed to predict RUL due to its ability to deal with abundant complex data. In this paper, a novel scheme based on a health indicator (HI) and a hybrid deep neural network (DNN) model is proposed to predict RUL by analyzing equipment degradation. Explicitly, HI obtained by polynomial regression is combined with a convolutional neural network (CNN) and long short-term memory (LSTM) neural network to extract spatial and temporal features for efficacious prognostics. More specifically, valid data selected from the raw sensor data are transformed into a one-dimensional HI at first. Next, both the preselected data and HI are sequentially fed into the CNN layer and LSTM layer in order to extract high-level spatial features and long-term temporal dependency features. Furthermore, a fully connected neural network is employed to achieve a regression model of RUL prognostics. Lastly, validated with the aid of numerical and graphic results by an equipment RUL dataset from the Commercial Modular Aero-Propulsion System Simulation(C-MAPSS), the proposed scheme turns out to be superior to four existing models regarding accuracy and effectiveness.
Highlights
The complexity of the equipment involved in modern industry has rapidly increased in the past decades [1]
In order to empirically evaluate the availability of the proposed scheme for remaining useful life (RUL) prognostics, the proposed scheme was tested with the testing set
Though some obvious errors exist between the prediction values and the true RUL values, the prognostic performance is good, especially when the equipment is close to failure
Summary
The complexity of the equipment involved in modern industry has rapidly increased in the past decades [1]. Any failure of equipment may cause catastrophic consequences [2,3], and reliability and maintenance are key for equipment [4]. It’s essential to have an effective strategy that positively coordinates scheduling and maintenance to ensure productivity, personal safety and manufacturing development [5]. Prognostics and health management (PHM) is a key technology that can guarantee the security of equipment and reduce maintenance costs [6]. As a crucial component of PHM, remaining useful life (RUL) prediction has evolved into an active research field due to its enhanced capability to determine the maintenance time [7]. RUL of equipment is defined as the length from the current time to the end of the useful life [8]. RUL prognostics approaches consist of model-based, data-driven, and fusion prognostics [9]
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