A model of deformation of thin-wall surface parts during milling machining process

“…It analyzes and predicts the vibration and deflection behavior during thin-wall milling. In both cases, initial forces are calculated using mechanistic models based on experimental data [64] or commercial software such as AdvanEdgeTM [70], VERICUT ® [148] or DEFORMTM [77]. They are used as inputs for the initial conditions of the workpiece.…”

“…The workpiece deflection is predicted through iteration and considering a quasi-static situation [61,70]. The analysis is performed following the toolpath and iteration must be performed for every new tool position due to the change of the workpiece–tool contact and the workpiece stiffness.…”

“…Some of them studied the effect of the wall thickness [67,73], the depth of cut [66] or the feed rate [61,78] on the dimensional error. Others authors considered the tool position [49,70] and the fixture system [5]. Zhang et al [28] went further by including the effect of the distance to the clamping system.…”

Thin-Wall Machining of Light Alloys: A Review of Models and Industrial Approaches

“…It analyzes and predicts the vibration and deflection behavior during thin-wall milling. In both cases, initial forces are calculated using mechanistic models based on experimental data [64] or commercial software such as AdvanEdgeTM [70], VERICUT ® [148] or DEFORMTM [77]. They are used as inputs for the initial conditions of the workpiece.…”

“…The workpiece deflection is predicted through iteration and considering a quasi-static situation [61,70]. The analysis is performed following the toolpath and iteration must be performed for every new tool position due to the change of the workpiece–tool contact and the workpiece stiffness.…”

“…Some of them studied the effect of the wall thickness [67,73], the depth of cut [66] or the feed rate [61,78] on the dimensional error. Others authors considered the tool position [49,70] and the fixture system [5]. Zhang et al [28] went further by including the effect of the distance to the clamping system.…”

Thin-Wall Machining of Light Alloys: A Review of Models and Industrial Approaches

“…The proposed model performs a computationally efficient transient thermo-mechanical coupled field milling simulation, predicts the workpiece non-linear behavior during machining due to its changing geometry, allows the modelling of the effects of initial residual stresses on part deformations and integrated analytical machining load -cutting force and shear plane temperature. A model of deformations of thin-walled structures in the milling process and prediction of machining errors are investigated in [20,21]. In [20], a new model is proposed to predict surface form errors caused by milling force during the five-axis flank milling process.…”

“…The results showed that the surface deformation error of thin-walled structures is affected together by the instantaneous milling force and the local stiffness of the workpiece. On the other hand, in the paper [21] a three-dimensional finite element model was established for the milling of thin-walled parts, that predicts the elastic deformation law of the thin-walled blade.…”

Multi-Criteria Selection of the Optimal Parameters for High-Speed Machining of Aluminum Alloy Al7075 Thin-Walled Parts

Machining deformation prediction of large fan blades based on loading uneven residual stress