Abstract
The trochoidal milling mode is widely used in high-speed machining, and due to good adaptability and flexible posture adjustment, ball-end milling cutters are conducive to complex surface machining with this mode. However, the processes of material removal and formation of machined micro surfaces are very difficult to describe as the profile of cutter teeth is complex and the trajectory direction changes continuously during the trochoidal milling process. A modeling method for the generation of micro surface topography of ball-end milling in the trochoidal milling mode is put forward. In this method, the locus equation of each cutter tooth is established based on the principle of homogeneous coordinate transformation, after which a Z-MAP algorithm is designed to simulate the micro surface topography. The Z-MAP algorithm can quickly obtain the part grid nodes potentially swept by the cutter tooth within a unit time step through the establishment of servo rectangular encirclement and instantaneous sweeping quadrilateral of the element of cutter teeth; the part grid nodes actually swept are further determined through an angle summation method, and the height coordinate is calculated with the method of linear interpolation according to Taylor’s formula of multivariate functions. Experiments showed that the micro surface topography resulting from ball-end milling in the trochoidal milling mode had high consistency with the simulation, which indicates that the proposed method can predict micro surface topography in practical manufacturing. In addition, a comparison of micro surface topography between trochoidal milling and ordinary straight-linear milling was conducted, and the results showed that the former was overall superior to the latter in resulting characteristics. Based on this conclusion, the influences of cutting parameters of ball-end trochoidal milling on surface characteristics, particularly amplitude and function, were analyzed according to the simulated micro surface topography data.
Highlights
Ball-end milling is a very adaptable process which is widely used in the machining of complex parts for the aerospace, automotive, die and mold industries
Based on the principle of homogeneous coordinate matrix transformation, a cutter tooth trajectory equation for ball-end trochoidal milling is established, after which the Z-MAP method combined with the time step method is proposed to simulate the micro surface topography
This paper proposes a Z-MAP method for the modeling of ball-end trochoidal milling micro surface topography, based on which a comparison of surface characteristics between the results of ball-end trochoidal milling and linear milling was conducted, and the rules by which cutting parameters of the trochoidal milling influence the surface characteristics were revealed
Summary
Ball-end milling is a very adaptable process which is widely used in the machining of complex parts for the aerospace, automotive, die and mold industries. Based on the principle of homogeneous coordinate matrix transformation, a cutter tooth trajectory equation for ball-end trochoidal milling is established, after which the Z-MAP method combined with the time step method is proposed to simulate the micro surface topography. In this method, once the Z-MAP model of the part is established, the micro elements of cutter tooth and time step are set scientifically to ensure that the cutter tooth element can sweep no more than one workpiece grid point per time unit; subsequently a rounding method is used to determine a suspected grid node of a part which is close to the discrete point of the cutter tooth, and a nonlinear equation using Taylor expansion is used to solve the height coordinates of the suspected grid node. The influence of cutting parameters on the micro surface topography and its characteristics are investigated by simulation
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