Abstract
Single-lip deep hole drilling (SLD) is characterized by a high surface quality and compressive residual stress in the subsurface of the drill hole. These properties are strongly dependent on the cutting parameters of the SLD process and the actual geometry of the insert and the guide pads. In the present work, full 3D FE simulations of the SLD process were carried out to analyze the thermo-mechanical as-is state in the drilling contact zone by evaluating the feed force, the temperature, as well as the residual stress in the drill hole subsurface. An extensive simulation study was conducted on the effect of the process parameters on the properties using design of experiments (DoE). For the simulations, the Johnson–Cook (JC) constitutive law and the element elimination technique (EET) were applied to represent the material behavior of the workpiece, including chip formation. In-process measurements as well as results from the hole-drilling method to determine residual stresses were conducted to verify the numerical results. By means of DoE and analysis of variance (ANOVA), regression models were developed to describe the effect of the feed rate, cutting speed, and guide pad height on the temperature, feed force, and residual stress in the subsurface.
Highlights
The global drilling machine market has been growing for years
The FE simulations of the highly dynamic and unsteady-state single-lip deep hole drilling (SLD) process were conducted with the commercial solver ABAQUS with an explicit simulation scheme
Based on the results obtained in this study for the design of experiments (DoE) analysis, the following conclusions can be drawn: 1
Summary
The global drilling machine market has been growing for years. Based on the application, the whole market is classified into different drilling machines. The significant growth rate of deep hole drilling machines, which is a method of drilling holes of a high length-to-diameter ratio, is due to the increasing demand for drilling deep holes in a wide variety of machines and equipment across aerospace, automotive, military, defense, as well as oil and gas industries. Another aspect that characterizes deep hole drilling processes is the high surface quality and the evacuation of chips during the operation, which is carried out by means of a cooling lubricant. SLD is used for small-diameter machining in the range of 0.5–40 mm, for example, for the production of diesel fuel injectors in the automotive industry [2]
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