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  • 1.
    Agic, Adnan
    et al.
    Department of Engineering Science, University West, Trollhättan, Sweden.
    Eynian, Mahdi
    Department of Engineering Science, University West, Trollhättan, Sweden.
    Hägglund, S.
    Seco Tools, Fagersta, Sweden.
    Ståhl, Jan-Eric
    Lund University, Production and Materials Engineering, Lund, Sweden.
    Beno, Tomas
    Department of Engineering Science, University West, Trollhättan, Sweden.
    Influence of radial depth of cut on dynamics of face milling application2016In: The 7th International Swedish Production Symposium, SPS16, Conference Proceedings: 25th – 27th of October 2016, Lund: Swedish Production Academy , 2016, p. 1-9Conference paper (Refereed)
    Abstract [en]

    The choice of milling cutter geometry and appropriate cutting data for certain milling application is of vital importance for successful machining results. Unfavourable selection of cutting conditions might give rise to high load impacts that cause severe cutting edge damage. The radial depth of cut in combination with milling cutter geometry might under some circumstances give unfavourable entry conditions in terms of cutting forces and vibration amplitudes. This phenomenon originates from the geometrical features that affect the rise time of the cutting edge engagement into work piece at different radial depths of cut. As the radial depth of cut is often an important parameter, particularly when machining difficult to cut materials, it is important to explore the driving mechanism behind vibrations generation. In this study, acceleration of the work piece is measured for different radial depths of cut and cutting edge geometries. The influence of the radial depth of cut on the dynamical behaviour is evaluated in time and frequency domains. The results for different radial depths of cut and cutting geometries are quantified using root mean square value of acceleration. The outcome of this research study can be used both for the better cutting data recommendations and improved tool design.

  • 2.
    Agic, Adnan
    et al.
    Seco Tools, Fagersta, Sweden ; University West, Department of Engineering Science, Trollhättan, Sweden.
    Eynian, Mahdi
    University West, Department of Engineering Science, Trollhättan, Sweden.
    Hägglund, S.
    Seco Tools, Fagersta, Sweden.
    Ståhl, J.-E.
    Lund University, Production and Materials Engineering, Sweden.
    Beno, Tomas
    University West, Department of Engineering Science, Trollhättan, Sweden.
    Influence of radial depth of cut on entry conditions and dynamics in face milling application2017In: Journal of Superhard Materials, ISSN 1063-4576, Vol. 39, no 4, p. 259-270Article in journal (Refereed)
    Abstract [en]

    The choice of milling cutter geometry and appropriate cutting data for certain milling application is of vital importance for successful machining results. Unfavorable selection of cutting conditions might give rise to high load impacts that cause severe cutting edge damage. Under some circumstances the radial depth of cut in combination with milling cutter geometry might give unfavorable entry conditions in terms of cutting forces and vibration amplitudes. This phenomenon is originated from the geometrical features that affect the rise time of the cutting edge engagement into workpiece at different radial depths of cut. As the radial depth of cut is often an important parameter, particularly when machining difficult-to-cut materials, it is important to explore the driving mechanism behind vibrations generation. In this study, acceleration of the workpiece is measured for different radial depths of cut and cutting edge geometries. The influence of the radial depth of cut on the dynamical behavior is evaluated in time and frequency domains. The results for different radial depths of cut and cutting geometries are quantified using the root mean square value of acceleration. The outcome of this research study can be used both for the better cutting data recommendations and improved tool design.

  • 3.
    Agic, Adnan
    et al.
    Seco Tools, Fagersta, Sweden ; Department of Engineering Science, University West, Trollhättan, Sweden.
    Eynian, Mahdi
    Department of Engineering Science, University West, Trollhättan, Sweden.
    Ståhl, Jan-Erik
    Production and Materials Engineering, Lund University, Sweden.
    Beno, Tomas
    Department of Engineering Science, University West, Trollhättan, Sweden.
    Dynamic effects on cutting forces with highly positive versus highly negative cutting edge geometries2019In: International Journal on Interactive Design and Manufacturing, ISSN 1955-2513, E-ISSN 1955-2505, Vol. 13, no 2, p. 557-565Article in journal (Refereed)
    Abstract [en]

    Understanding the influence of the cutting edge geometry on the development of cutting forces during the milling process is of high importance in order to predict the mechanical loads on the cutting edge as well as the dynamic behavior on the milling tool. The work conducted in this study involves the force development over the entire engagement of a flute in milling, from peak force during the entry phase until the exit phase. The results show a significant difference in the behavior of the cutting process for a highly positive versus a highly negative cutting edge geometry. The negative edge geometry gives rise to larger force magnitudes and very similar developments of the tangential and radial cutting force. The positive cutting edge geometry produces considerably different developments of the tangential and radial cutting force. In case of positive cutting edge geometry, the radial cutting force increases while the uncut chip thickness decreases directly after the entry phase; reaching the peak value after a certain delay. The radial force fluctuation is significantly higher for the positive cutting edge geometry. The understanding of such behavior is important for modelling of the milling process, the design of the cutting edge and the interactive design of digital applications for the selection of the cutting parameters.

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  • 4.
    Agic, Adnan
    et al.
    Seco Tools, Fagersta, Sweden ; University West, Department of Engineering Science, Trollhättan, Sweden.
    Eynian, Mahdi
    University West, Department of Engineering Science, Trollhättan, Sweden.
    Ståhl, J.-E.
    Lund University, Production and Materials Engineering, Sweden.
    Beno, Tomas
    University West, Department of Engineering Science, Trollhättan, Sweden.
    Experimental analysis of cutting edge effects on vibrations in end milling2019In: CIRP - Journal of Manufacturing Science and Technology, ISSN 1755-5817, E-ISSN 1878-0016, Vol. 24, p. 66-74Article in journal (Refereed)
    Abstract [en]

    The ability to minimize vibrations in milling by the selection of cutting edge geometry and appropriate cutting conditions is an important asset in the optimization of the cutting process. This paper presents a measurement method and a signal processing technique to characterize and quantify the magnitude of the vibrations in an end milling application. Developed methods are then used to investigate the effects of various cutting edge geometries on vibrations in end milling. The experiments are carried out with five cutting edge geometries that are frequently used in machining industry for a wide range of milling applications. The results show that a modest protection chamfer combined with a relatively high rake angle has, for the most of cutting conditions, a reducing effect on vibration magnitudes. Furthermore, dynamics of a highly positive versus a highly negative cutting geometry is explored in time domain and its dependency on cutting conditions is presented. The results give concrete indications about the most optimal cutting edge geometry and cutting conditions in terms of dynamic behavior of the tool.

  • 5.
    Devotta, Ashwin Moris
    et al.
    Sandvik Coromant AB, Sandviken, Sweden.
    Beno, Tomas
    University West, Trollhättan, Sweden.
    Eynian, Mahdi
    University West, Trollhättan, Sweden.
    Simulation-Based Product Development Framework for Cutting Tool Geometry Design2019In: International Conference on Competitive Manufacturing (COMA 19) Proceedings: 30 January 2019 – 1 February 2019 Stellenbosch, South Africa / [ed] Dimiter Dimitrov; Devon Hagedorn-Hansen; Konrad von Leipzig, Stellenbosch University , 2019, p. 47-52Conference paper (Refereed)
    Abstract [en]

    Cutting tool geometry design has traditionally relied on experimental studies; while engineering simulations, to the level of industrial deployment, have been developed only in the last couple of decades. With the development of simulation capability across length scales from micro to macro,cutting tool geometry development includes engineering data development for its efficient utilization. This calls for the design of a simulation-based approach in the design of cutting tool geometry so that the engineering data can be generated for different machining applications (e.g.digital twin). In this study, the needs for engineering model development of different stages of cutting tool design evaluation is assessed. To this end, some of the previously developed engineering models have been evaluated for evaluation of chip form morphology in industrially relevant nose turning process, work piece material behavior modeling and damage modeling for the prediction of chip shape morphology. The study shows the possibility for the developed models to act as building blocks of a digital twin. It also shows the need for engineering model development for different aspects of cutting tool design, its advantages, limitations, and prospects.

  • 6.
    Devotta, Ashwin Moris
    et al.
    Sandvik Coromant AB, Sandviken, Sweden ; University West, Department of Engineering Science, Trollhättan, Sweden.
    Beno, Tomas
    University West, Department of Engineering Science, Trollhättan, Sweden.
    Siriki, Ravendra
    Sandvik Materials Technology, Sandviken, Sweden.
    Löf, Ronnie
    Sandvik Coromant AB, Sandviken, Sweden.
    Eynian, Mahdi
    University West, Department of Engineering Science, Trollhättan, Sweden.
    Finite Element Modeling and Validation of Chip Segmentation in Machining of AISI 1045 Steel2017In: Procedia CIRP, E-ISSN 2212-8271, Vol. 58, p. 499-504Article in journal (Refereed)
    Abstract [en]

    The finite element (FE) method based modeling of chip formation in machining provides the ability to predict output parameters like cutting forces and chip geometry. One of the important characteristics of chip morphology is chip segmentation. Majority of the literature within chip segmentation show cutting speed (vc) and feed rate (f) as the most influencing input parameters. The role of tool rake angle (α) on chip segmentation is limited and hence, the present study is aimed at understanding it. In addition, stress triaxiality’s importance in damage model employed in FE method in capturing the influence of α on chip morphology transformation is also studied. Furthermore, microstructure characterization of chips was carried out using a scanning electron microscope (SEM) to understand the chip formation process for certain cutting conditions. The results show that the tool α influences chip segmentation phenomena and that the incorporation of a stress triaxiality factor in damage models is required to be able to predict the influence of the α. The variation of chip segmentation frequency with f is predicted qualitatively but the accuracy of prediction needs improvement. © 2017 The Authors.

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  • 7.
    Devotta, Ashwin Moris
    et al.
    R&D Turning, Sandvik Coromant AB, Sandviken, Sweden.
    Sivaprasad, P. V.
    R&D, Sandvik Materials Technology AB, Sandviken, Sweden.
    Beno, Tomas
    Department of Engineering Science, University West, Trollhättan, Sweden.
    Eynian, Mahdi
    Department of Engineering Science, University West, Trollhättan, Sweden.
    Predicting Continuous Chip to Segmented Chip Transition in Orthogonal Cutting of C45E Steel through Damage Modeling2020In: Metals, ISSN 2075-4701, Vol. 10, no 4, article id 519Article in journal (Refereed)
    Abstract [en]

    Machining process modeling has been an active endeavor for more than a century and it has been reported to be able to predict industrially relevant process outcomes. Recent advances in the fundamental understanding of material behavior and material modeling aids in improving the sustainability of industrial machining process. In this work, the flow stress behavior of C45E steel is modeled by modifying the well-known Johnson-Cook model that incorporates the dynamic strain aging (DSA) influence. The modification is based on the Voyiadjis-Abed-Rusinek (VAR) material model approach. The modified JC model provides the possibility for the first time to include DSA influence in chip formation simulations. The transition from continuous to segmented chip for varying rake angle and feed at constant cutting velocity is predicted while using the ductile damage modeling approach with two different fracture initiation strain models (Autenrieth fracture initiation strain model and Karp fracture initiation strain model). The result shows that chip segmentation intensity and frequency is sensitive to fracture initiation strain models. The Autenrieth fracture initiation strain model can predict the transition from continuous to segmented chip qualitatively. The study shows the transition from continuous chip to segmented chip for varying feed rates and rake angles for the first time. The study highlights the need for material testing at strain, strain rate, and temperature prevalent in the machining process for the development of flow stress and fracture models.

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  • 8.
    Devotta, Ashwin Moris
    et al.
    R&D Turning, Sandvik Coromant AB, Sandviken, Sweden ; Department of Engineering Science, University West, Trollhättan, Sweden.
    Sivaprasad, Palla Venkata
    R&D, Sandvik Materials Technology AB, Sandviken, Sweden.
    Beno, Tomas
    Department of Engineering Science, University West, Trollhättan, Sweden.
    Eynian, Mahdi
    Department of Engineering Science, University West, Trollhättan, Sweden.
    Hurtig, Kjell
    Department of Engineering Science, University West, Trollhättan, Sweden.
    Magnevall, Martin
    R&D, Sandvik Coromant AB, Sandviken, Sweden ; Department of Mechanical Engineering, Blekinge Institute of Technology, Karlskrona, Sweden.
    Lundblad, Mikael
    R&D, Sandvik Coromant AB, Sandviken, Sweden.
    A modified Johnson-Cook model for ferritic-pearlitic steel in dynamic strain aging regime2019In: Metals, ISSN 2075-4701, Vol. 9, no 5, article id 528Article in journal (Refereed)
    Abstract [en]

    In this study, the flow stress behavior of ferritic-pearlitic steel (C45E steel) is investigated through isothermal compression testing at different strain rates (1 s-1, 5 s-1, and 60 s-1) and temperatures ranging from 200 to 700 °C. The stress-strain curves obtained from experimental testing were post-processed to obtain true stress-true plastic strain curves. To fit the experimental data to well-known material models, Johnson-Cook (J-C) model was investigated and found to have a poor fit. Analysis of the flow stress as a function of temperature and strain rate showed that among other deformation mechanisms dynamic strain aging mechanism was active between the temperature range 200 and 400 °C for varying strain rates and J-C model is unable to capture this phenomenon. This lead to the need to modify the J-C model for the material under investigation. Therefore, the original J-C model parameters A, B and n are modified using the polynomial equation to capture its dependence on temperature and strain rate. The results show the ability of the modified J-C model to describe the flow behavior satisfactorily while dynamic strain aging was operative. © 2019 by the authors. Licensee MDPI, Basel, Switzerland.

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  • 9.
    Parsian, Amir
    et al.
    AB Sandvik Coromant, Sandviken, Sweden ; University West, Trollhättan, Sweden.
    Magnevall, Martin
    AB Sandvik Coromant, Sandviken, Sweden.
    Beno, Tomas
    University West, Trollhättan, Sweden.
    Eynian, Mahdi
    University West, Trollhättan, Sweden.
    A Mechanistic Approach to Model Cutting Forces in Drilling with Indexable Inserts2014In: Procedia CIRP, E-ISSN 2212-8271, Vol. 24, p. 74-79Article in journal (Refereed)
    Abstract [en]

    Holes are made in many industrial parts that need screws, pins or channels for passing fluids. The general method to produce holes in metal cutting is by drilling operations. Indexable insert drills are often used to make short holes at a low cost. However, indexable drills are prone to vibrate under certain circumstances, causing vibrations that affect tool life. Therefore, a good prediction of cutting-forces in drilling is important to get a good description of the cutting process for optimization of tool body and insert design. Reliable simulations of dynamic forces also aid in prediction of chatter vibrations that have significant effects on the quality of the manufactured parts as well as the tool life. In this paper, a mechanistic approach is used to model the cutting-forces. Cutting-force coefficients are identified from measured instantaneous forces in drilling operations. These coefficients are used for simulating torque around drill-axis, axial force and cutting-forces in the plane perpendicular to drill-axis. The forces are modeled separately for peripheral and central insert, which results in a detailed description of the cutting-forces acting on each insert. The forces acting on each insert are estimated by dividing the cutting edges into small segments and the cutting-forces acting on each segment are calculated. The total forces are predicted by summation of the forces acting on each segment. Simulated torque and forces are compared to measured cutting-forces for two different feeds. A good agreement between predicted and experimental results, especially in torque and axial-force, is observed.

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  • 10.
    Parsian, Amir
    et al.
    Sandvik Coromant, Sandviken, Sweden ; University West, Trollhättan, Sweden.
    Magnevall, Martin
    Sandvik Coromant, Sandviken, Sweden ; University West, Trollhättan, Sweden.
    Beno, Tomas
    University West, Trollhättan, Sweden.
    Eynian, Mahdi
    University West, Trollhättan, Sweden.
    Sound Analysis in Drilling, Frequency and Time Domains2017In: Procedia CIRP, E-ISSN 2212-8271, Vol. 58, p. 411-415Article in journal (Refereed)
    Abstract [en]

    This paper proposes a guideline for interpreting frequency content and time history of sound measurements in metal drilling processes. Different dynamic phenomena are reflected in generated sound in cutting processes. The footprint of such phenomena including torsional, lateral regenerative chatter and whirling in sound measurement results are discussed. Different indexable insert drills, at several cutting conditions, are covered. The proposed analysis could be used for studying, online monitoring and controlling of drilling processes. © 2017 The Authors.

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  • 11.
    Parsian, Amir
    et al.
    Sandvik Coromant, Sandviken, Sweden ; University West, Trollhättan, Sweden.
    Magnevall, Martin
    Sandvik Coromant, Sandviken, Sweden.
    Beno, Tomas
    University West, Trollhättan, Sweden.
    Eynian, Mahdi
    University West, Trollhättan, Sweden.
    Time-Domain Modeling of Torsional-Axial Chatter Vibrations in Indexable Drills with Low Damping2015Conference paper (Refereed)
    Abstract [en]

    In drills with helical chip flutes the coupling between axial and rotational degrees-of-freedom can cause chatter vibrations. These torsional-axial chatter vibrations can lead to a high frequency and unpleasant noise. It is desirable to design tools which are less prone to chatter vibrations and thus also makes less noise during operation. Dynamics of chatter vibrations in drilling is due to changes in chip-thickness that causes dynamic loads on the structure. These loads in return contribute and sustain vibrations. In this paper a simulation routine is proposed that can be used to model these chatter vibrations in drilling when damping of the drill-body is low. In case of low damping, the drill rotates backward in some instants. The importance of modeling of this phenomenon is emphasized in this paper and a method is proposed to model loads in case of backward rotations. The generated chip is calculated in each time-step and obtained chip-thickness is used to calculate dynamic loads. The structural responses are calculated in form of displacements by loading the drill with predicted dynamic loads based on the calculated chip thickness. Obtained displacements are used to calculate chip-thickness in the next time-step. Spectrum of simulated vibrations is compared with spectrum of measured noise and a good agreement between measurements and simulations is observed.

  • 12.
    Parsian, Amir
    et al.
    AB Sandvik Coromant, Sandviken, Sweden ; University West, Trollhättan, Sweden.
    Magnevall, Martin
    AB Sandvik Coromant, Sandviken, Sweden ; University West, Trollhättan, Sweden.
    Eynian, Mahdi
    University West, Trollhättan, Sweden.
    Beno, Tomas
    University West, Trollhättan, Sweden.
    Time Domain Simulation of Chatter Vibrations in Indexable Drills2017In: The International Journal of Advanced Manufacturing Technology, ISSN 0268-3768, E-ISSN 1433-3015, Vol. 89, no 1-4, p. 1209-1221Article in journal (Refereed)
    Abstract [en]

    Regenerative chatter vibrations are common in drilling processes. These unwanted vibrations lead to considerable noise levels, damage the quality of the workpiece, and reduce tool life. The aim of this study is to simulate torsional and axial chatter vibrations as they play important roles in dynamic behavior of indexable insert drills with helical chip flutes. While asymmetric indexable drills are not the focal points in most of previous researches, this paper proposes a simulation routine which is adapted for indexable drills. Based on the theory of regenerative chatter vibration, a model is developed to include the asymmetric geometries and loadings that are inherent in the design of many indexable insert drills. Most indexable insert drills have two inserts located at different radial distances, namely central and peripheral inserts. Since the positions of the central and peripheral inserts are different, the displacement and thereby the change in chip thickness differs between the inserts. Additionally, the inserts have different geometries and cutting conditions, e.g., rake angle, coating, and cutting speed, which result in different cutting forces. This paper presents a time-domain simulation of torsional and axial vibrations by considering the differences in dynamics, cutting conditions, and cutting resistance for the central and peripheral inserts on the drill. The time-domain approach is chosen to be able to include nonlinearities in the model arising from the inserts jumping out of cut, multiple delays, backward motions of edges, and variable time delays in the system. The model is used to simulate cutting forces produced by each insert and responses of the system, in the form of displacements, to these forces. It is shown that displacements induced by dynamic torques are larger than those induced by dynamic axial forces. Finally, the vibration of a measurement point is simulated which is favorably comparable to the measurement results.

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  • 13.
    Wanner, Bertil
    et al.
    University West, Trollhättan, Sweden.
    Eynian, Mahdi
    University West, Trollhättan, Sweden.
    Beno, Tomas
    University West, Trollhättan, Sweden ; Volvo Aero Corporation, Trollhättan, Sweden.
    Pejryd, Lars
    University West, Trollhättan, Sweden ; Volvo Aero Corporation, Trollhättan, Sweden ; Production Technology Center, Innovatum AB, Trollhättan, Sweden.
    Cutter Exit Effects during Milling of Thin-walled Inconel 7182012In: Advanced Materials Research, ISSN 1022-6680, E-ISSN 1662-8985, Vol. 590, p. 297-308Article in journal (Refereed)
    Abstract [en]

    During milling of thin-walled components, chatter vibrations give rise to process issues. These include dimensional inaccuracy, damaged and scrap parts, and damaged cutting tools. This, in turn, leads to loss of production time with increasing cost as a consequence. This paper identifies the force profile during a single cut milling process. It focuses on the exit and post-exit behavior of the cut and discusses the process dynamics. The force profiles of various tool-to-workpiece positions are analyzed as regards the exit and post exit phases. A standard on-the-market cutter and a specially designed zero rake cutter are used in the investigation. Finally, a time-domain simulation of the force is performed and compared to the experimental results. The study concludes that a small change in exit angle may result in a considerable improvement in cutting behavior. In addition, the tool position should be chosen so that the cutter exits in the least flexible direction possible for the workpiece.

  • 14.
    Wanner, Bertil
    et al.
    University West, Trollhättan, Sweden.
    Eynian, Mahdi
    University West, Trollhättan, Sweden.
    Beno, Tomas
    University West, Trollhättan, Sweden ; Volvo Aero Corporation, Trollhättan, Sweden.
    Pejryd, Lars
    University West, Trollhättan, Sweden ; Volvo Aero Corporation, Trollhättan, Sweden ; Production Technology Center, Innovatum AB, Trollhättan, Sweden.
    Milling Strategies for Thin-walled Components2012In: Advanced Materials Research, ISSN 1022-6680, E-ISSN 1662-8985, Vol. 498, p. 177-182Article in journal (Refereed)
    Abstract [en]

    Recent developments in the Aerospace industry have led to thin-walled, reduced-weight engine designs. Due to demands in manufacturing, production speeds and material removal rates (MRR) have increased. As component wall thickness gets thinner, the consequence oftentimes is an increase in chatter vibrations. This paper suggests that a correctly chosen tool-to-workpiece offset geometry may lead to a robust and chatter-free process. The results show the differences in force response for three geometries while varying the overhang of the workpiece. This is part of a concerted effort to develop a robust methodology for the prediction of chatter vibrations during milling operations of thin-walled Aerospace components. This paper outlines certain robust machining practices. It also analyzes the criticality of the choice of offset between tool and workpiece during milling setup as well as the effects that the entry and exit of cut have on system vibrations.

  • 15.
    Wanner, Bertil
    et al.
    University West, Trollhättan, Sweden.
    Eynian, Mahdi
    University West, Trollhättan, Sweden.
    Beno, Tomas
    University West, Trollhättan, Sweden ; Volvo Aero Corporation, Trollhättan, Sweden.
    Pejryd, Lars
    University West, Trollhättan, Sweden ; Volvo Aero Corporation, Trollhättan, Sweden ; Production Technology Center, Innovatum AB, Trollhättan, Sweden.
    Process Stability Strategies in Milling of Thin-walled Inconel 7182012In: The 4th Manufacturing engineering society international conference (MESIC 2011): 21–23 September 2011, Cadiz, Spain / [ed] Mariano Marcos; Jorge Salguero, American Institute of Physics (AIP), 2012, p. 465-472Conference paper (Refereed)
    Abstract [en]

    Trends in Aerospace development have led to thin-walled, reduced-weight engine designs. The demands in manufacturing have forced production speeds and material removal rates (MRR) to increase. As component wall thickness gets thinner, the consequence oftentimes is an increase in chatter vibrations. This paper suggests that a correctly chosen tool-to-workpiece offset geometry may lead to a robust and chatter free process. The results show the differences in force response for three geometries while varying the height overhang of the workpiece. This is part of a concerted effort to develop a robust methodology for the prediction of chatter vibrations during milling operations of thin-walled Aerospace components. This paper gives guidelines on how to accomplish robust machining practices. It also answers the following questions: How critical is the choice of offset between tool and workpiece during milling setup? And what effects do the entry and exit of cut have on system vibrations?

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