Abstract
Late detection of cracks can lead to serious failures and damages of drilling components, especially drill pipes and drill bits. Currently, the widely used method of repairing rotary drilling systems after a failure is corrective maintenance. Although this strategy has shown its effectiveness in many cases, waiting for a failure to occur and then performing a repair can be an expensive and time-consuming operation. Thus, the use of preventive maintenance under the aspect of periodic inspections can solve this problem and help engineers detect cracks before they reach critical sizes. In this study, modal analysis and finite element analysis (FEA) combined with artificial neural networks (ANN) were used to dynamically estimate the depth and location of a circular arc crack in the drill pipes of rotary drilling systems. To achieve this goal, a detailed analytical approach based on Euler–Bernoulli beam theory was adopted to validate the first four natural frequencies found by FEA for an undamaged pipe. Afterwards, an arc crack was assigned to the pipe already created using Abaqus, and the first four natural frequencies were obtained for each depth and location of the crack. Simulations with FEA led to the generation of a dataset with two inputs—depth and location of cracks—and four outputs: natural frequencies. Moreover, a multilayer perceptron (MLP) was designed and trained by the data collected from simulations. Finally, a comparison between the results obtained by FEA and ANN was performed, where both approaches showed a good agreement in predicting the depth and location of cracks.
Highlights
The complex loading and the non-linear interactions with the borehole can lead to the appearance of several types of vibrations [5,6]. These vibrations could significantly accelerate the process of fatigue failure of the drilling system [7,8], especially if there are already cracks in the structure of the drill pipes [9]
The predicted depth and location are very close to the test data, which signifies that the artificial neural networks (ANN) model is well trained; the model can be used as an alternative approach to predict the depth and location of cracks for the pipes of rotary drilling systems
In some cases, nondestructive testing (NDT) and nondestructive inspection (NDI) cannot predict the exact location of cracks, and as a result, the latter can grow and reach a critical level for which failure is unavoidable
Summary
To extract oil and gas from sedimentary rocks [1], a deep hole of thousands of meters must be drilled. There have been several methods used to examine the effect induced by the presence of cracks on engineering structures, such as the analytical approach In this context, Murigendrappa et al [38] presented an experimental and theoretical approach to study the influence of crack location along a pipe filled with fluid. Combining finite element analysis and artificial neural networks (ANN), Maurya et al [45] carried out an analysis to investigate the influence of crack location on the first three natural frequencies of a cantilever beam; they designed and trained an ANN. The main contribution of this study can be summed up in three points: to create and simulate a special crack geometry inside a drill pipe, investigate the effect of crack depths and locations on the first four natural frequencies, and design an ANN that can predict crack positions using natural frequencies
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