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Article

Study on the Formation Mechanism of Surface Adhered Damage in Ball-End Milling Ti6Al4V

1
Key Laboratory of Advanced Manufacturing and Intelligent Technology, Ministry of Education, Harbin University of Science&Technology, Harbin 150080, China
2
Georgia Institute of Technology, George W. Woodruff School of Mechanical Engineering, Atlanta, GA 30332, USA
*
Author to whom correspondence should be addressed.
Materials 2021, 14(23), 7143; https://doi.org/10.3390/ma14237143
Submission received: 7 September 2021 / Revised: 13 November 2021 / Accepted: 18 November 2021 / Published: 24 November 2021

Abstract

:
Ball-end cutters are widely used for machining the parts of Ti-6Al-4V, which have the problem of poor machined surface quality due to the low cutting speed near the tool tip. In this paper, through the experiments of inclined surface machining in different feed directions, it is found that the surface adhered damages will form on the machined surface under certain tool postures. It is determined that the formation of surface adhered damage is related to the material adhesion near the cutting edge and the cutting-into/out position within the tool per-rotation cycle. In order to analyze the cutting-into/out process more clearly under different tool postures, the projection models of the cutting edge and the cutter workpiece engagement on the contact plane are established; thus, the complex geometry problem of space is transformed into that of plane. Combined with the case of cutting-into/out, chip morphology, and surface morphology, the formation mechanism of surface adhered damage is analyzed. The analysis results show that the adhered damage can increase the height parameters Sku, Sz, Sp, and Sv of surface topographies. Sz, Sp, and Sv of the normal machined surface without damage (Sku ≈ 3) are about 4–6, 2–3, and 2–3 μm, while Sz, Sp, and Sv with adhered damage (Sku > 3) can reach about 8–20, 4–14, and 3–6 μm in down-milling and 10–25, 7–18, and 3–7 μm in up-milling. The feed direction should be selected along the upper left (Q2: β ∈ [0°, 90°]) or lower left (Q3: β ∈ [90°, 180°]) to avoid surface adhered damage in the down-milling process. For up-milling, the feed direction should be selected along the upper right (Q1: β ∈ (−90°, 0°]) or upper left (Q2: β ∈ [0°, 90°)).

1. Introduction

The titanium alloy Ti-6Al-4V is widely used in aerospace, chemical, and medical industries due to its advantages of high strength, low density, corrosion resistance, and good performance at high temperatures [1,2]. High strength and low thermal conductivity are the causes of difficulties with the machinability of Ti-6Al-4V [3,4], and it is important to find ways to increase machinability by cutting titanium alloys. Although the development of additive manufacturing provides a new way for the process of titanium alloy parts [5,6,7], the cutting-based subtractive manufacturing is still the main processing method for high-precision parts such as integral bladed disks, casings, and key components of aircraft [8,9]. Ball-end cutters are the commonly used tools in the milling process of Ti-6Al-4V, which have strong adaptability to the change of surface curvature [10]. However, the ball-end cutter has the problem of zero cutting speed at the tool tip, which often leads to the deterioration of surface quality and the phenomenon of ploughing [11,12]. In the machining process, high cutting temperature, large milling force, and serious tool wear are common problems, which have adverse effects on the surface quality of parts [13].
Surface topography is one of the parameters of surface integrity, including roughness, waviness, and surface defects [14]. The surface topography mainly affects the contact condition and stress concentration, which will further affect the performance of the machined components [15]. In most mechanical parts, a smoother surface with lower surface roughness is usually preferred [16]. At present, many scholars have done related research on the surface topography of ball-end cutters under different tool postures and proved that the participation of tool tip in cutting is not conducive to the improvement of surface quality [17,18,19,20]. However, in the experimental study on the inclined surface machining of ball-end cutters with different feed directions, it is found that more serious surface smeared/adhered damage will be formed on the machined surface under some tool posture conditions.
At present, several studies have been published about surface smeared/adhered defects produced by machining on titanium alloys. Pawade et al. [21] found metal debris adhesion and material smear damage on the machined surface by a scanning electron microscope (SEM) in the study of Inconel 718 surface damage in high-speed turning, and the surface smeared/adhered damage decreased with the increase in cutting speed. Ginting et al. [22] conducted toroidal end milling experiments on the titanium alloy Ti-6242S, and the surface smeared/adhered damage was also found in the reported surface defects, which is a chip layer formation caused by a molten chip deposited on the machined surface. It is considered that the mechanism of the smeared/adhered defect needs to be further studied. Ulutan and Ozel [23] reported a review of machining-induced surface integrity in titanium and nickel alloys and thought that smeared/adhered damage is typical when machining titanium alloys and can result in underlying surface damage being obscured as well as geometrical accuracy errors. Hood et al. [24] conducted the experiments on ball-end milling burn-resistant titanium alloy and machined flat surfaces with an inclination angle of 0° and 45°. Workpiece surface damage was observed in the tests, and adhered material of varying size was found on all surfaces. They found that the severity of these features depended on the operating parameters, and the application of high-pressure cutting fluid reduced the levels of this damage but did not eliminate it. García-Barbosa et al. [25] performed several experiments with ball-end milling Ti-6Al-4V and aluminum alloy 7075; they designed an experimental test part, which was made up of flat, concave, and convex surfaces of variable curvatures, to be fabricated in a four-axis machining center. The experimental results show that smeared/adhered material was found in some areas of the concave and convex surfaces of the titanium alloy and not found in the aluminum alloy. At the same time, they believed that the formation of surface smeared/adhered damage is related to tool postures and the chip formation process.
In summary, there are relatively few published reports on surface adhered damage, and the defects have only been found in the study of machined surface integrity of titanium alloy or nickel-based superalloy. It is confirmed that this kind of damage is more likely to occur under some tool posture conditions. However, the specific reasons for the formation of surface adhered damage are not clear in the existing research, and the formation mechanism needs to be further revealed.
The subject of this paper is to study the formation mechanism of surface adhered damage in ball-end milling of Ti6Al4V, and it is considered that this damage is related to the case of cutting into/out within the tool per-rotation cycle. In the present work, the projection models of the cutting edge and the cutter workpiece engagement on the contact plane are established for the analysis of cutting into/out, and the experiments of ball-end milling the inclined surface of Ti6Al4V for down-milling and up-milling are carried out respectively. Through the comprehensive analysis of the geometric relationship of cutting into/out, chip morphology, and surface topography in different feed directions, the conditions for the formation of surface adhered damage are determined.

2. Materials and Methods

2.1. Materials

The workpiece material used in the experimental trials was Ti6Al4V, and the chemical composition is given in Table 1. Due to its high reactivity with cutting tool materials and its low thermal conductivity, titanium alloys have a poor machinability, which causes repeated material adhesions between tool and chip caused by the elevation of temperature in the cutting field. Some properties are listed in Table 2.
The tool material is tungsten–cobalt cemented carbide (CTS20D), and Table 3 shows the specification of cemented carbide CTS20D. The tool used is uncoated, and the reason is that related studies have proven while machining titanium alloys that the coating materials fails rapidly due to plastic deformations and high temperatures in the machining process [27]. This failure is mainly due to the coating delamination phenomenon [28], proven by the use of different types of coating materials.

2.2. The Method for Cutting Into/Out Analysis

2.2.1. The Definition of Cutting Into/Out

In a previous work [30], a single-toolpath cutting experiment of a ball-end milling 15° inclined surface was carried out to study the influence of the tool feed direction on the machined surface quality of Ti6Al4V. Through the experimental results, it is found that the cutting into/out position within the tool per-rotation cycle has a great influence on the machined surface quality.
The concept of “cutting into/out” in this paper means that the cutting edge enters/leaves the cutter workpiece engagement area within the tool per-rotation cycle. The geometric relationship of cutter workpiece engagement under the single-toolpath cutting condition is shown in Figure 1, where OXYZ is the tool coordinate system, PXcYcZc is the tool contact coordinate system, Zc points to the spherical center (O) along the normal direction of the machined surface, Yc is the projection of the central axis of the tool on the contact plane T, and Xc is parallel to the horizontal tangent t of the hemisphere at P. The feed direction of the tool is f, and the angle between f and Yc is β, which can be either positive or negative following the principle of the right-hand coordinate system. As shown in the figure, the cutting edge cuts into the cutter workpiece engagement area (CWE) from the point N1, and cuts out from the point N2, so the side of N1 is defined as the cutting into side, and the side of N2 is defined as the cutting out side.
The tool paths and workpiece after single-toolpath cutting are shown in Figure 2, and the partial enlarged detail on the path with the feed direction of −67.5° corresponds to the engagement area on the contact plane T in Figure 1. The 16 feed directions were selected for toolpaths on the inclined surface, and the cutting was from the outside of the workpiece to the center without coolant. As shown in Figure 2, there are differences in the machining surface quality in each direction, where the surface quality of some paths on the left-hand side are worse than those of other paths. Especially on the paths of −45° and −67.5°, there is an obvious phenomenon of material smeared/adhered on the side of the cutting-into; however, the side of cutting out is good and neat. The difference shows that the ball-end cutter is difficult to cut into the workpiece in certain feed directions, but the cutting out is relatively stable. Therefore, inspired by the experimental results, this paper analyzes the cutting into and cutting out cases under different tool postures so as to control the feed direction of the tool and make the cutting edge cut into from the position away from the tool contact point to avoid the phenomenon of material adhering on the machined surface and improve the quality of the machined surface.

2.2.2. The Projection Model on the Contact Plane

In order to study the cutting into/out process of tools under multiple-toolpath milling, the models of cutting edge curve and cutter workpiece engagement (CWE) area should be carried out at first. Many researches have been reported in literatures [31,32,33,34,35] addressing the issue related to the CWE model. The analytical method proposed in reference [35] is used to determine the CWE area under different tool posture conditions. The tool studied in this paper is an equal-lead helical ball end mill, and its simplified geometry model is shown in Figure 3. Where OXjYjZj is the cutter tooth coordinate system, which rotates with the cutting edge at an angular velocity ω. The coordinates of any point Pj on the helix cutting edge under OXjYjZj are expressed as Equation (1) [36,37].
{ x j = R × sin κ 1 cos ψ y j = R × sin κ 1 sin ψ z j = R × cos κ 1 ψ = tan β 0 ( 1 cos κ 1 )
where, R is tool radius, κ1 is the axial position angle of the reference point Pj on the cutting edge, ψ is the lag angle, and β0 is the cylindrical helix angle of the ball end cutter. The cutting edge rotates in the tool coordinate system OXYZ, the spindle speed is n and the tool rotation angular speed is ω, then the relationship between them is: ω = 2πN/60 (rad/s), and the rotation angle of the cutting edge at the time t is: ϕc = −ωt (rad). According to the principle of rotation transformation, the coordinates of Pj on the cutting edge in the tool coordinate system OXYZ are as follows:
( X j Y j Z j ) = ( x j y j z j ) × ( cos ϕ c sin ϕ c 0 sin ϕ c cos ϕ c 0 0 0 1 )
In the case of the tool radius R = 5 mm, the cylindrical helix angle β0 = 50°, the tool path stepover s = 0.2 mm, the cutting depth e = 0.25 mm, and the machining inclination angle αp = 15°, the cutter workpiece engagement geometric relations of ball-end milling inclined surface for down-milling and up-milling are established as shown in Figure 4a,b.
Where the CWE area is surrounded by the three curves: AB, BC and AC. P is the cutter contact point, which is located on the curve BC and contacts with the machined surface. The cutting state of the cutting edge passing through the cutter contact point will directly affect the machined surface quality [38]. The boundary AC is on the contact circle, and the tool tip E is inside the contact circle. The intersection points of the inner circle with the boundaries AB and BC are recorded as D and D` respectively. With the change of β, the tool tip E may enter into the CWE area and participate in cutting, that will not be conducive to the improvement of machined surface quality. In this paper, the feed direction β is divided into 4 ranges on the contact plane T (Q1: β∈[−90°,0°], Q2: β∈[0°, 90°], Q3: β∈[90°, 180°] and Q4: β∈[−180°, −90°], which correspond to upper right, upper left, lower left and lower right).
In order to determine the position of cutting into/out at any time, the cutting edge curve and CWE boundaries are projected to the contact plane T, and the projection curves are transformed into the tool contact coordinate system PXcYcZc. The spatial geometry problem can be transformed into that of plane.
In the tool coordinate system OXYZ, the projection of the cutting edge space curve on the contact plane can be expressed as follows:
{ X j 0 = R × sin κ 1 [ cos ψ cos ( ϕ c ) sin ψ sin ( ϕ c ) ] Y j 0 = R × sin κ 1 [ cos ψ sin ( ϕ c ) + sin ψ cos ( ϕ c ) ] + R × tan α p sin κ 1 [ cos ψ sin ( ϕ c ) + sin ψ cos ( ϕ c ) ] R × cos κ 1 + R / cos α p tan 2 α p + 1 × tan α p Z j 0 = R × cos κ 1 + R × tan α p sin κ 1 [ cos ψ sin ( ϕ c ) + sin ψ cos ( ϕ c ) ] R × cos κ 1 + R / cos α p tan 2 α p + 1
The model of the cutting edge projection on the contact plane is transformed into OXcYcZc, as shown by Equation (4), and the coordinates in PXcYcZc are (Xjt Yjt 0).
( X j t Y j t Z j t ) = ( X j 0 Y j 0 Z j 0 ) × ( 1 0 0 0 cos α p sin α p 0 sin α p cos α p )
In the coordinate system PXcYcZc, the projections of AB, BC and AC on the contact plane T can be obtained by Equations (5)–(7):
{ X A B t = N × ( R sin κ s ) × cos β ( R sin κ ) 2 ( R sin κ s ) 2 × sin β Y A B t = N × ( R sin κ s ) × sin β + ( R sin κ ) 2 ( R sin κ s ) 2 × cos β Z A B t = 0
{ X B C t = N × R × sin κ cos β Y B C t = N × R × sin κ sin β Z B C t = 0
{ X A C t = N × R 2 ( R e ) 2 ( ( R sin κ ) 2 ( R sin κ s ) 2 ) × cos β ( R sin κ ) 2 ( R sin κ s ) 2 × sin β Y A C t = N × R 2 ( R e ) 2 ( ( R sin κ ) 2 ( R sin κ s ) 2 ) × sin β + ( R sin κ ) 2 ( R sin κ s ) 2 × cos β Z A C t = 0
where, N is the down and up-milling coefficient, 1 and −1 for down and up-milling, respectively, and κ is the relative axial position angle of the reference point on the CWE boundary under the coordinate system OXcYcZc.
Based on the above model, the projection relationship between the cutting edge curve and the CWE boundaries on the contact plane can be obtained as Figure 5, and the position of cutting into/out in different feed directions can be determined for the analysis of experiment results.

2.3. Experimental Set-Up

The cutting experiment was set to 15° inclined surface machining on a three-axis CNC machine tool (VDL-1000E, Dalian Machine Tool Group, Dalian, China), and two square blanks with the same size 100 mm × 100 mm × 50 mm were selected. The two workpieces were machined by down-milling and up-milling respectively, and the toolpaths are shown in Figure 6. The feed directions β were selected with 16 angles on the inclined surface, which are [−90°, −67.5°, −45°, −22.5°] in the Q1 range, [0°, 22.5°, 45°, 67.5°] in the Q2 range, [90°, 112.5°, 135°, 157.5°] in the Q3 range and [±180°, −157.5°, −135°, −112.5°] in the Q4 range. All paths are machined from the outside of the workpiece to the center of the workpiece by dry cutting. The tilting fixture was used to install the workpiece, and the inclination angle of the fixture was adjusted to 15°.
The tool selected was a solid uncoated carbide ball end mill with 10 mm of diameter, the cylindrical helix angle β0 = 50°, the number of teeth zn =2, the spindle speed n = 4000 rpm, the feed rate F = 640 m/min, the feed per tooth fz = 0.08 mm, the cutting depth e = 0.3 mm, and the toolpath stepover s = 0.15 mm.
With the variation of the feed direction of the tool path, the case of the tool cutting into/out will change. Based on the method for cutting into/out analysis in Section 2.2, the cases of cutting into/out of different feed directions for down-milling and up-milling can be obtained as Table 4 and Table 5.
In the above tables, the cutting into/out position corresponds to that in Figure 5, where, B/P is near the side of cutter contact point, and A/C is far from the side of cutter contact point. The specific analysis results will be shown in Section 3.2.
After the process of the experimental workpiece, the white light interference surface profiler (Talysurf CCI, Taylor Hobson, Warrenville, IL, USA) and super-depth microscope (VHX-1000, Keyence, Osaka, Japan) were used to detect the surface quality of each path, and the chip samples were collected at the end of each cutting. The instruments and equipment used in the machining are shown in Figure 7.
The measurement setup of white light interference (Talysurf CCI) was as follows: the lens type was 20 × WD = 4.7 mm, the zoom option: ×1, the measurement area was 0.86 mm × 0.86 mm with 1024 × 1024 received measured points, and the spacing was 0.82 um, respectively. Under the setting standard, the equipment was sufficient to show normal surface topographies or surface adhered damages of different sizes. In the process of measuring the surface topography of a direction, three different positions on the machined surface are selected as the measuring points by the interval about 10 mm, and the final surface topography parameters of each path are the average of the three measurements. Due to the clamping error in the machining process, the machined surface in all directions is not exactly in the same horizontal plane, so it is necessary to refocus and locate the middle position, upper limit, and lower limit of the interference fringes in each measurement process. The operation of ‘levelling’ in TalyMap was set up to the raw measured results after each measurement by application of a polynomial plane of first order. The errors caused by the measuring method, the digitization process, data processing, and other errors in a single measurement [39,40] were not taken into account in the paper, only the errors caused by the measurements of surface adhered damages at different positions on each direction.

3. Results and Discussion

3.1. Experimental Results

The machining textures obtained by Talysurf CCI in different directions of down-milling are shown in Figure 8, and the surface textures correspond to the surface topography figures in Section 3.2. Through the comparison of the machining surface textures in different directions, it can be seen that the machining surfaces in the nine directions within [0°, 180°] located on Q2 and Q3 areas are relatively smooth, with only the normal cutting texture of the tool and no other obvious surface damage. In the seven directions from −22.5° to −157.5° in the Q1 and Q4 ranges, beyond the normal cutting texture, there are obvious smeared/adhered materials on the machined surface.
Figure 9 shows the microstructure of adhered defects in the direction of −67.5° and the normal surface texture of 67.5°. The images were taken under a 1000-fold lens using the super-depth microscope. Through the comparison, it can be found that the smeared/adhered damage is higher than the machined surface, which should mean that the broken chips in the machining process are extruded and bonded to the machined surface under some tool posture conditions, and the surface structure in the direction of 67.5° is normal and smooth without damage. Moreover, after the machining in each area is completed, the tool is tested by an industrial camera with a red light source, and it is also found that there is a phenomenon of material adhesion on the tool rake face and the cutting edge, as shown in Figure 10. The advantage of using the red light source is that it is easier to distinguish the adhered material on the tool rake face. This tendency of the workpiece material ‘sticking’ to the cutting tool was also highlighted by Su et al. [41] when dry- and wet-milling Ti-6Al-4V.
The machining textures obtained in different directions for up-milling are shown in Figure 11. Through the comparison of the machining surface textures in different directions, it can be seen that the machining surfaces in the nine directions in [90°, 180°] and [−157.5°, −90°] are relatively poor, with more obvious smeared/adhered material on the machined surface. In the seven directions [−67.5°, 67.5°] located in the Q1 and Q2 ranges, there are no obvious surface damages. As a result, it can be seen that with the variation of the cutting mode of down-milling and up-milling, the areas of surface residual damage have changed accordingly.

3.2. Discussion

This section mainly discusses the influence of cutting into/out on the surface damage caused by the change of the feed direction. The variation of tool posture causes the change in actual cutting speed in the engagement area, which can influence the final material characteristics and the chip-forming mechanism [42,43], and it is one of important factors affecting the surface quality. In order to further explore the formation mechanism of adhered damage on the machined surface, the chip morphology, the case of cutting into/out, and machined surface topography in different directions are analyzed, respectively, under the conditions of down-milling and up-milling.

3.2.1. The Analysis of Down-Milling

The analyses of the four feed directions in the Q1 range for down-milling are shown in Figure 12; the CWE area is located in the lower half of the contact circle, and Q1 is a low-speed range. The direction of −90° is the critical position of the range variation, where the position of cutting into just begins to shift to point B, and the tool tip E is just on the boundary BC of the engagement area. For chip morphology, the chip shape is similar to the dovetail shape in the directions of −90° and −67.5°, which is marked by red dotted line in Figure 12. In the cutting process, the chip center is close to the tool tip, which will lead to a ploughing phenomenon. In the directions of −45° and −22.5°, the shape of the chip is similar to that of CWE, the chip twists at the initial stage of cutting-into, and the edge of chip is not neat due to the low cutting speed. In terms of surface topography, as the cutting edge cutting into the engagement area from B and cutting out from the side of AC, the surface adhered damage appeared in the four directions, especially −67.5° and −45°, and the maximum heights of color scales in surface topographies range from 8 to 18 μm. (All the locations of the surface adhered damages on surface topographies in Figures 12, 15, 20, 22, and 23 have been marked, and the surface topographies of the down-milling and up-milling are consistent with the surface textures in Figure 8 and Figure 11.)
The analyses of the directions in the Q2 range are shown in Figure 13, the CWE area is located in the upper half of the contact circle, and Q2 is a high-speed range. The direction of 0° is the critical position of the range, the chip shape is similar to −22.5°, and the phenomenon of chip edge burr still exists. With the increase in cutting speed, the chip edge of 22.5° has been gradually neat. In the directions of 45° and 67.5°, the chip shape is closer to the CWE without curling deformation. However, there is the phenomenon of chip adhesion in both directions. Due to the higher cutting temperature caused by the increase in cutting speed, the chips are melted and bonded to the rake face of the tool, as the high speed rotation of tool, and the chips are carried into the next cutting process, resulting in the adhesion between chips. It also shows that the adhered material on the tool is taken away by the chip without causing damage to the machined surface. In terms of surface topography, although the cutting into position is at Point B, there is no adhered damage on the machined surface in this range, and the maximum heights of color scales in surface topographies range from 4.4 to 5 μm.
The analyses of the directions in the Q3 range are shown in Figure 14, the CWE area is located in the upper half of the contact circle, and Q3 is a high-speed range. The chip shapes of 90°, 112.5°, and 135° are similar to those of 45° and 67.5°, and the phenomenon of chip adhesion also occurs, indicating that the cutting states of these paths are similar under high cutting speed conditions. Correspondingly, the chip burrs appear again at 157.5°, probably due to the ploughing phenomenon caused by downward milling. In terms of surface topography, from the direction of 90°, the cutting into position is gradually transferred from B to A, and the cutting out position is gradually transferred from C to B, and no adhered damage occurs on the machined surface in the Q3 range, and the maximum heights of color scales in surface topographies range from 3.8 to 4.2 μm.
The analyses of the directions in the Q4 range are shown in Figure 15, the CWE area is located in the lower half of the contact circle, and Q4 is a low-speed range. The critical direction of the range variation is 180°, and the chip shape is similar to that of 157.5°. Compared with −22.5° and 0°, the chip burrs are more obvious, which indicates that the ploughing phenomenon in downward milling is more serious than that in upward milling. In the directions of −157.5° and −135°, the chips gradually change to the dovetail shape as the engagement area is close to the tool tip. The tool tip completely enters into the engagement area at −112.5°, where several dovetail chips are connected to each other in the center and form a series of spiral chips. This is caused by the fact that the tool tip participates in cutting, and there is no chip breaking. In terms of cutting into/out, the cutting edge cuts into from A and cuts out from B in the four directions. For surface topography, the surface quality of 180° is good (the maximum height: 4.2 μm), and there is no adhered damage. However, as the cutting speed decreases, the ploughing phenomenon will gradually increase in downward milling, and the surface adhered damage will form again in the other directions (the maximum heights of −157.5°, −135°, and −112.5° are about 9.2, 16.5, and 13.5 μm).
From the above analysis, it can be seen that the surface adhered damage is the material bonded to the normal machined surface, which can be displayed as Figure 16. The location of the damage will be significantly higher than that of the normal machined surface, which will cause significant changes in surface height parameters. According to the international standard of surface topography ISO25178, Sku (kurtosis) indicates the presence or lack of inordinately high peaks/deep valleys (Sku > 3.00) or (Sku < 3.00), respectively. As shown in Figure 16, Sp (maximum peak height) is the height between the mean plane and the highest peak, Sv (maximum pit height) is the height between the deepest valley and the mean plane, and Sz (maximum height, Sz = Sp + Sv) is the height between the deepest valley and the highest peak. In this paper, Sku is used to judge the occurrence of surface adhesion damage. If the value of Sku increases significantly, the adhered damage may occur, which should be judged by the comparison of surface topography and surface texture. The formation of surface adhered damage can raise the mean plane height of the surface topography, as shown in Figure 16, which leads to the increases of Sp, Sv, and Sz, and the parameters are used to measure the severity of surface adhered damage.
The above analyses of the four ranges for down-milling can be summarized as shown in Figure 17. Figure 17a depicts the cutting speed variations of six points in the CWE area [30] (A, B, C, D, D‘, and P in Figure 4), and Figure 17b illustrates the changing trend of the selected height parameters (Sku, Sz, Sp, and Sv) of surface topographies in different feed directions.
The measured results of Sku, Sp, Sv, and Sz for down-milling surface topographies are shown in Table 6, and three measurements results are obtained from different positions on each path. Because the severity of adhered damage at different locations on the same path can be different, three different positions are selected for the measurement on each path. The parameters values of different directions in Figure 17b are the average of the three measurements results, and the error bars of three measurements are added in the figure for the selected parameters. The errors are mainly caused by different sampling positions, and the average values of three different measurement results can describe the severity of adhered damage on the surface in each direction more accurately.
From the variation trends of cutting speed values and selected height parameters, it can be seen that the surface quality of the high-speed range is better than that of the low-speed range for down-milling. Sku > 3 in the low-speed ranges of Q4 and Q1, and the average values of Sz, Sp, and Sv can reach about 8–20, 4–15, and 3–6 μm, respectively, which is due to the formation of adhered damage on the machined surface. It can be also found that the increase in Sp is higher than that of Sv when the surface adhered damage is formed. For the Q4 range, the tool tip participates in cutting with the cutting into/out transition and the ploughing phenomenon, which should be the reason for the deterioration of surface quality. For the Q1 range, the cutting edge cuts into from the point B near the cutter contact point P, which leads to the aggravation of surface adhered damage at −67.5° and −45°, and it is consistent with the experimental result of single-toolpath milling in Section 2.1. The surface adhered damage at −22.5° is relatively alleviated with the increase in cutting speed.
On the other hand, in the high-speed ranges of Q2 and Q3, Sku ≈ 3 indicates that the surface is smooth, and there is no presence of inordinately high peaks or deep valleys caused by surface adhered damage. The values of Sz, Sp, and Sv are highly similar in the directions and do not produce excessive height difference (Sz: 4–6 μm, Sp & Sv: 2–3 μm). In the Q3 range, the cutting edge cuts into from the side of AC and cuts out from B, which avoids the appearance of surface adhered damage. However, the cutting edge also cuts into the engagement area from B in the Q2 range, compared with Q1, and there is no adhered damage on the machined surface. The possible reason for the difference between Q1 and Q2 need to be to be further discussed.
The CWE geometric analyses of any direction in the ranges of Q1 and Q2 are shown as Figure 18a,b. In the two figures, t0 is the moment of cutting into from B, and ti is any time in the cutting process. K is the intersection point of the cutting edge and boundary BC at ti, and κ is the angle between OK and OP. The tool contact point P is located on the curve BC and directly contacts the machined surface. Therefore, in the cutting process, the state of the cutting edge passing through P will directly affect the quality of the machined surface [32]. The material adhesion is easy to occur near the cutting edge of in the process of machining titanium alloy, and the adhered material may be squeezed by the cutting layer in the cutting process, which may slip to both sides of the CWE area.
When the feed direction is in the Q1 range, the variation trend of Zk (Z coordinate of K) with κ is shown in Figure 19a, and Zk decreases with the increase in κ. Therefore, when the cutting edge cuts into from B and passes through near the cutter contact Point P, as shown in Figure 18a, the adhered material will be subjected to the downward extrusion trend of BC. Moreover, under the conditions of dry cutting and high temperature, the adhered material is molten and bonded to the lower machined surface. However, when the feed direction is in the Q2 range, the variation trend of Zk with κ is shown in Figure 19b, and Zk increases with the increase in κ. The cutting edge cuts into from B and passes through P, and the position of K shows an upward trend. In this case, as shown in Figure 18b, the adhered material on the cutting edge cannot be extruded to the machined surface below, so there is no surface adhered damage in this range.
To sum up, under the condition of down-milling, in order to avoid surface adhered damage, the feed direction should be selected in the ranges of Q2 and Q3. In the process of tool path planning, the feed direction should be along that of the upper left or lower left.

3.2.2. The Analysis of Up-Milling

The analyses of the directions in the Q1 range for up-milling are shown in Figure 20, the CWE area is located in the upper half of the contact circle, and Q1 is a high-speed range. The chip shapes of the four directions are similar to the shape of CWE, and the phenomenon of chip adhesion also occurs at −67.5°. In terms of surface topography, the adhered damage occurs on the machined surface in the direction of −90° (the maximum height is about 14.5 μm), because the cutting into position is located at B near the cutter contact point. However, in the directions of −67.5°, −45°, and −22.5°, the cutting into position transfers from B to C, the cutting out position shifts from A to B, and no surface adhered damage occurs in the three directions (the maximum heights of color scales in surface topographies range from 4.6 to 5 μm).
The analyses of the directions in the Q2 range are shown in Figure 21, the CWE area begins to shift to the lower half of the contact circle at 0°, and Q2 is a low-speed range. The chips of the four directions begin to distort gradually with changing from the CWE shape to dovetail shape. In terms of surface morphology, as the cutting edge cuts into the engagement area from C and cuts out from B, although the cutting speed is relatively low, the ploughing effect in the upward milling process is not significant, and there is no surface adhered damage in the Q2 range. The maximum heights of color scales in surface topographies range from 5 to 6 μm in the four directions.
The analyses of the directions in the Q3 range are shown in Figure 22, the CWE area is located in the lower half of the contact circle, and Q3 is a low-speed range. The critical direction of the cutting range variation is 90°, where the tool tip E is on the boundary BC of CWE, the ploughing effect is aggravated, and the chips show the dovetail shape. In the direction of 112.5°, the tool tip is inside the engagement area and participates in cutting, which leads to the reappearance of spiral chips formed by the superposition of several dovetail chips. As the tool tip leaves the engagement area, the chips at 135° show the state of separation again, but the chip shape remains in a dovetail shape. In the direction of 157.5°, the chips gradually show the CWE shape due to CWE away from the tool tip. In the Q3 range, the cutting into position is gradually changed from A to B, and the cutting out position is transferred from B to A. In terms of surface topography, the surface adhered damage appears at 90° (the maximum height: 12 μm), 112.5° (the maximum height: 14 μm), and 135° (the maximum height: 16 μm) due to the ploughing effect and the variation of cutting into/out. However, the adhered damage on the surface of 157.5° (the maximum height: 27 μm) is obviously aggravated, although the cutting speed is relatively increased, which is caused by the fact that the cutting edge cuts into the engagement area from B.
The analyses of the directions in the Q4 range are shown in Figure 23, the CWE area begins to shift to the upper half of the contact circle at 180°, and Q4 is a high-speed range. The chips in the four directions show the shape of CWE with curling deformation, and the degree of deformation gradually weakens with the increase in the feed direction. The cutting edge cuts into the engagement area from B near the cutter contact point and cuts out from A. In terms of surface topography, the aggravated surface damage occurs in the directions of 180° (the maximum height: 21 μm), −157.5° (the maximum height: 25 μm), and−135° (t the maximum height: 19 μm). With the further upward transfer of CWE, the cutting speeds in the direction of −112.5° increase more, which leads to the relative improvement of cutting condition. The surface adhered damage in the direction of −112.5° is relatively alleviated (the maximum height: 11 μm).
In the same way, the above analyses for up-milling can be summarized as shown in Figure 24, and the measured results of Sku, Sz, Sp, and Sv for up-milling surface topographies are shown in Table 7. From the overall trends of cutting speed curves and selected height parameters, the surface quality of high-speed range Q4 and low-speed range Q3 is poor, the average values of Sz, Sp, and Sv can reach about 10–25, 7–18, and 3–7 μm, respectively, with the adhered damage (Sku > 3), and it can be also found that the increase in Sp is higher than that of Sv. The position of cutting into is B/P in Q4, and the tool tip is inside CWE with the transition of cutting into/out in Q3. On the other hand, the surface quality of high-speed range Q1 and low-speed range Q2 is better, the average values of Sz can reach about 4–6 μm, and Sp and Sv are similar in the range of 2–3 μm. The cutting edge cuts into the engagement area from the side of AC and cuts out from B/P without the appearance of surface adhered damage in both ranges. For the up-milling process, the influence of cutting into/out on the surface quality is higher than that of the cutting speed. Therefore, under the condition of up-milling, the feed direction should be selected in the range of Q1 and Q2, which should be along the upper right or upper left.

4. Conclusions

In this paper, based on the principle of projection geometry, a plane geometry analysis method is established to describe the cutting into/out process within the tool per-rotation cycle. Through the comprehensive analysis of the case of cutting into/out, chip morphology, and surface topography in different feed directions, the formation mechanism of surface adhered damage in ball-end milling Ti6Al4V is studied, and the following conclusions are obtained:
  • Surface adhered damage is caused by the extrusion of the adhered material on the tool rake face to the normal machined surface, which will lead to the changes in the selected height parameters Sku, Sz, Sp, and Sv of the surface topography. The values of Sz, Sp, and Sv without damage are about 4–6, 2–3, and 2–3 μm, while the values of Sz, Sp, and Sv with adhered damage can reach about 8–20, 4–14, and 3–6 μm in down-milling and 10–25, 7–18, and 3–7 μm in up-milling, respectively.
  • The formation of surface adhered damage is related to the cutting into/out position of the cutting edge on the engagement area within the tool per-rotation cycle. When the cutting edge participates in cutting near the cutter contact point, the possibility of surface adhered damage will increase; on the contrary, when the cutting edge cuts out from near the cutter contact point, there is no adhered damage on the machined surface.
  • When the engagement area of the ball-end cutter is close to the tool tip, the chip will change from the CWE shape to that of a dovetail, and the spiral chips formed by the superposition of several dovetail chips will appear when the tool tip enters the engagement area completely; the ploughing effect and the transition of cutting into/out can also lead to the formation of surface adhered damage.
  • The optimal ranges of tool feed direction under the conditions of down-milling and up-milling are different. For down-milling, the feed direction should be selected in the ranges of Q2: [0°, 90°] and Q3: [90°, 180°] along the upper left or lower left. For up-milling, the feed direction should be selected in the ranges of Q1: (−90°, 0°] and Q2: [0°, 90°) along the upper right or upper left.

Author Contributions

A.Z.: conceptualization, methodology, software, and writing—original draft preparation; C.Y.: data curation, resources, writing—review and editing; X.L.: funding acquisition, project administration, writing—review and editing; S.Y.L.: writing—review and editing. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by Projects of the National Key Research and Development Project of China (Grant Number 2019YFB1704800).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

Abbreviations

Physical quantities: Density (g/cm3); hardness (HB/HRA/V); modulus E (GPa); tensile Strength (MPa); thermal conductivity (W/m.K); melting point (°C); transverse rupture strength (PSI); fracture toughness (MPa·m1/2); grain size (μm).
OXYZTool coordinate system
OwXwYwZwProcessing coordinate system
PXcYcZcTool contact coordinate system
CWECutter Workpiece Engagement
fTool feed direction
βFeed direction angle
N1The cutting into side of single-toolpath cutting
N2The cutting out side of single-toolpath cutting
ETool tip
PCutter contact point
TTool contact plane
OXjYjZjCutter tooth coordinate system
PjAny point on the helix cutting edge
(xj yj zj)The coordinates of Pj under cutter tooth coordinate system OXjYjZj
(Xj Yj Zj)The coordinates of Pj under tool coordinate system OXYZ
RTool radius
κ1The axial position angle of the reference point Pj
ψThe lag angle of Pj
β0The cylindrical helix angle of the ball end cutter
nSpindle speed
ωThe tool rotation angular speed
ϕcThe rotation angle of the cutting edge
sThe toolpath stepover
eThe cutting depth
αpThe machining inclination angle
A, B, CIntersection points of CWE boundaries
D, D`Intersection points between CWE boundaries and the inner circle
Q1The feed direction range to upper right, β∈[−90°,0°]
Q2The feed direction range to upper left, β∈[0°, 90°]
Q3The feed direction range to lower left, β∈[90°, 180°]
Q4The feed direction range to lower right, β∈[−180°, −90°]
(Xj0Yj0Zj0)The coordinates of the cutting edge space curve projection under the tool coordinate system OXYZ
(Xjt Yjt Zjt)The coordinates of the cutting edge space curve projection under the coordinate system OXcYcZc
NThe down and up-milling coefficient
κThe relative axial position angle under the coordinate system OXcYcZc
FThe feed rate
znThe number of teeth
KThe intersection point of the cutting edge and boundary BC
t0The moment of cutting into from B, and is
tiAny time in the cutting process
ZkZ coordinate of K
fzThe feed per tooth
Talysurf CCIThe white light interference surface profiler
VHX-1000The super-depth microscope
VDL-1000EThe machine tool
CNCComputer Numerical Control
SkuKurtosis of the scale-limited surface
SpMaximum peak height
SvMaximum pit height
SzMaximum height (height between the deepest valley and the highest peak)

References

  1. Sun, J.; Guo, Y. A comprehensive experimental study on surface integrity by end milling Ti–6Al–4V. J. Mater. Process. Technol. 2009, 209, 4036–4042. [Google Scholar] [CrossRef]
  2. Ezugwu, E.O.; Wang, Z.M. Titanium alloys and their machinability—A review. J. Mater. Process. Technol. 1997, 68, 262–274. [Google Scholar] [CrossRef]
  3. Pimenov, D.Y.; Mia, M.; Gupta, M.K.; Machado, A.R.; Tomaz, V.; Sarikaya, M.; Wojciechowski, S.; Mikolajczyk, T.; Kaponek, W. Improvement of machinability of Ti and its alloys using cooling-lubrication techniques: A review and future prospect. J. Mater. Res. Technol. 2021, 11, 719–753. [Google Scholar] [CrossRef]
  4. Jamil, M.; Zhao, W.; He, N.; Gupta, M.K.; Sarikaya, M.; Khan, A.M.; Sanjayr, S.M.; Siengchin, S.; Pimenov, D.Y. Sustainable milling of Ti–6Al–4V: A trade-off between energy efficiency, carbon emissions and machining characteristics under MQL and cryogenic environment. J. Clean. Prod. 2021, 281, 125374. [Google Scholar] [CrossRef]
  5. Liu, S.; Shin, Y.C. Additive manufacturing of Ti6Al4V alloy: A review. Mater. Des. 2019, 164, 107552. [Google Scholar] [CrossRef]
  6. Ghods, S.; Schur, R.; Schultz, E.; Pahuja, R.; Montelione, A.; Wisdom, C.; Arola, D.; Ramulu, M. Powder reuse and its contribution to porosity in additive manufacturing of Ti6Al4V. Materialia 2021, 15, 100992. [Google Scholar] [CrossRef]
  7. Bambach, M.; Sizova, I.; Szyndler, J.; Bennett, J.; Hyatt, G.; Cao, J.; Papke, T.; Merklein, M. On the hot deformation behavior of Ti-6Al-4V made by additive manufacturing. J. Mater. Process. Technol. 2021, 288, 116840. [Google Scholar] [CrossRef]
  8. Tong, X.; Song, Y. Influence of micro-textured parameters on cutting performance and chip formation of milling Ti6Al4V. J. Mech. Sci. Technol. 2020, 34, 1–8. [Google Scholar] [CrossRef]
  9. Nespor, D.; Denkena, B.; Grove, T.; Pape, O. Surface topography after re-contouring of welded Ti-6Al-4V parts by means of 5-axis ball nose end milling. Int. J. Adv. Manuf. Technol. 2016, 85, 1585–1602. [Google Scholar] [CrossRef]
  10. Hsieh, J.-M. Manufacturing models for design and NC grinding of truncated-cone ball-end cutters. Int. J. Adv. Manuf. Technol. 2008, 35, 1124–1135. [Google Scholar] [CrossRef]
  11. De Souza, A.F.; Berkenbrock, E.; Diniz, A.E.; Rodrigues, A.R. Influences of the tool path strategy on the machining force when milling free form geometries with a ball-end cutting tool. J. Braz. Soc. Mech. Sci. Eng. 2014, 37, 675–687. [Google Scholar] [CrossRef]
  12. De Souza, A.F.; Diniz, A.E.; Rodrigues, A.R.; Coelho, R. Investigating the cutting phenomena in free-form milling using a ball-end cutting tool for die and mold manufacturing. Int. J. Adv. Manuf. Technol. 2014, 71, 1565–1577. [Google Scholar] [CrossRef]
  13. Celis, P.; Vazquez, E.; Soria-Hernández, C.G.; Bargnani, D.; Rodriguez, C.A.; Ceretti, E.; García-López, E. Evaluation of Ball End Micromilling for Ti6Al4V ELI Microneedles Using a Nanoadditive Under MQL Condition. Int. J. Precis. Eng. Manuf. Technol. 2021, 1–16. [Google Scholar] [CrossRef]
  14. Kumar, D.; Idapalapati, S.; Wang, W.; Narasimalu, S. Effect of Surface Mechanical Treatments on the Microstructure-Property-Performance of Engineering Alloys. Materials 2019, 12, 2503. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  15. Hua, Y.; Liu, Z.; Wang, B.; Hou, X. Surface modification through combination of finish turning with low plasticity burnishing and its effect on fatigue performance for Inconel 718. Surf. Coatings Technol. 2019, 375, 508–517. [Google Scholar] [CrossRef]
  16. Suraratchai, M.; Limido, J.; Mabru, C.; Chieragatti, R. Modelling the influence of machined surface roughness on the fatigue life of aluminium alloy. Int. J. Fatigue 2008, 30, 2119–2126. [Google Scholar] [CrossRef] [Green Version]
  17. Zhao, H.W.; Zhang, S.; Wang, G.Q.; Zhao, B. Effect of machining inclination angle of ball-nose end mill on surface topography. Computer Integrated Manufacturing Systems. CIMS 2013, 19, 2438–2444. [Google Scholar] [CrossRef]
  18. Ko, T.; Kim, H.; Lee, S. Selection of the Machining Inclination Angle in High-Speed Ball End Milling. Int. J. Adv. Manuf. Technol. 2001, 17, 163–170. [Google Scholar] [CrossRef]
  19. Quinsat, Y.; Sabourin, L.; Lartigue, C. Surface topography in ball end milling process: Description of a 3D surface roughness parameter. J. Mater. Process. Technol. 2008, 195, 135–143. [Google Scholar] [CrossRef] [Green Version]
  20. Lavernhe, S.; Quinsat, Y.; Lartigue, C. Model for the prediction of 3D surface topography in 5-axis milling. Int. J. Adv. Manuf. Technol. 2010, 51, 915–924. [Google Scholar] [CrossRef] [Green Version]
  21. Pawade, R.; Joshi, S.S.; Brahmankar, P.; Rahman, M. An investigation of cutting forces and surface damage in high-speed turning of Inconel 718. J. Mater. Process. Technol. 2007, 192-193, 139–146. [Google Scholar] [CrossRef]
  22. Ginting, A.; Nouari, M. Surface integrity of dry machined titanium alloys. Int. J. Mach. Tools Manuf. 2009, 49, 325–332. [Google Scholar] [CrossRef]
  23. Ulutan, D.; Ozel, T. Machining induced surface integrity in titanium and nickel alloys: A review. Int. J. Mach. Tools Manuf. 2011, 51, 250–280. [Google Scholar] [CrossRef]
  24. Hood, R.; Johnson, C.; Soo, S.; Aspinwall, D.; Sage, C. High-speed ball nose end milling of burn-resistant titanium (BuRTi) alloy. Int. J. Comput. Integr. Manuf. 2013, 27, 139–147. [Google Scholar] [CrossRef]
  25. García-Barbosa, J.A.; Arroyo-Osorio, J.M.; Córdoba-Nieto, E. Influence of tool inclination on chip formation process and roughness response in ball-end milling of freeform surfaces on Ti-6Al-4V alloy. Mach. Sci. Technol. 2017, 21, 121–135. [Google Scholar] [CrossRef]
  26. Mhamdi, M.B.; Boujelbene, M.; Bayraktar, E.; Zghal, A. Surface integrity of titanium alloy Ti-6Al-4V in ball end milling. Physics Procedia 2012, 25, 355–362. [Google Scholar] [CrossRef] [Green Version]
  27. Nabhani, F. Machining of aerospace titanium alloys. Robot. Comput. Manuf. 2001, 17, 99–106. [Google Scholar] [CrossRef]
  28. Liao, Y.; Shiue, R. Carbide tool wear mechanism in turning of Inconel 718 superalloy. Wear 1996, 193, 16–24. [Google Scholar] [CrossRef]
  29. Habrat, W. Effect of Bond Type and Process Parameters on Grinding Force Components in Grinding of Cemented Carbide. Procedia Eng. 2016, 149, 122–129. [Google Scholar] [CrossRef] [Green Version]
  30. Zhang, A.; Liu, X.; Yue, C.; Li, R.; Liang, S.Y.; Wang, L. Velocity effect sensitivity analysis of ball-end milling Ti-6Al-4 V. Int. J. Adv. Manuf. Technol. 2021, 1–20. [Google Scholar] [CrossRef]
  31. Kim, G.; Cho, P.; Chu, C. Cutting force prediction of sculptured surface ball-end milling using Z-map. Int. J. Mach. Tools Manuf. 2000, 40, 277–291. [Google Scholar] [CrossRef]
  32. Lazoglu, I. Sculpture surface machining: A generalized model of ball-end milling force system. Int. J. Mach. Tools Manuf. 2003, 43, 453–462. [Google Scholar] [CrossRef]
  33. Imani, B.; Sadeghi, M.; Elbestawi, M. An improved process simulation system for ball-end milling of sculptured surfaces. Int. J. Mach. Tools Manuf. 1998, 38, 1089–1107. [Google Scholar] [CrossRef]
  34. Wei, Z.; Wang, M.; Zhu, J.; Gu, L. Cutting force prediction in ball end milling of sculptured surface with Z-level contouring tool path. Int. J. Mach. Tools Manuf. 2011, 51, 428–432. [Google Scholar] [CrossRef]
  35. Wei, Z.C.; Wang, M.J.; Wang, X.W.; Zhao, D.Y. A Semi-analytical Cutter Workpiece Engagement Model for Ball End Milling of Sculptured Surface. J. Mech. Eng. 2017, 53, 198–205. [Google Scholar] [CrossRef]
  36. Altintaş, Y.; Lee, P. A General Mechanics and Dynamics Model for Helical End Mills. CIRP Ann. 1996, 45, 59–64. [Google Scholar] [CrossRef]
  37. Yongheng, D.; Shujuan, L.; Xiantao, H.; Pengyang, L.; Yan, L.; Qi, L. Modeling on the Milling Force of Ball-end Milling Cutter Based on Z-MAP Method. Chin. J. Mech. Eng. 2019, 55, 201–212. [Google Scholar] [CrossRef]
  38. Habibi, M.; Kilic, Z.M.; Altintas, Y. Minimizing Flute Engagement to Adjust Tool Orientation for Reducing Surface Errors in Five-Axis Ball End Milling Operations. J. Manuf. Sci. Eng. 2020, 143, 1–35. [Google Scholar] [CrossRef]
  39. Pawlus, P. Digitisation of surface topography measurement results. Measurement 2007, 40, 672–686. [Google Scholar] [CrossRef]
  40. Podulka, P. Improved Procedures for Feature-Based Suppression of Surface Texture High-Frequency Measurement Errors in the Wear Analysis of Cylinder Liner Topographies. Metals 2021, 11, 143. [Google Scholar] [CrossRef]
  41. Su, Y.; He, N.; Li, L.; Li, X. An experimental investigation of effects of cooling/lubrication conditions on tool wear in high-speed end milling of Ti-6Al-4V. Wear 2006, 261, 760–766. [Google Scholar] [CrossRef]
  42. Wang, B.; Liu, Z.; Cai, Y.; Luo, X.; Ma, H.; Song, Q.; Xiong, Z. Advancements in material removal mechanism and surface integrity of high speed metal cutting: A review. Int. J. Mach. Tools Manuf. 2021, 166, 103744. [Google Scholar] [CrossRef]
  43. Molnar, T.G.; Berezvai, S.; Kiss, A.K.; Bachrathy, D.; Stepan, G. Experimental investigation of dynamic chip formation in orthogonal cutting. Int. J. Mach. Tools Manuf. 2019, 145, 103429. [Google Scholar] [CrossRef]
Figure 1. Geometric analysis of single-toolpath cutting.
Figure 1. Geometric analysis of single-toolpath cutting.
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Figure 2. Workpiece after single-toolpath cutting, (a) tool paths, (b) the center of workpiece, (c) local magnification of −67.5 and (d) workpiece. (Adapted with permission from Ref. [30], Copyright © 2021, Springer-Verlag London Ltd., part of Springer Nature.)
Figure 2. Workpiece after single-toolpath cutting, (a) tool paths, (b) the center of workpiece, (c) local magnification of −67.5 and (d) workpiece. (Adapted with permission from Ref. [30], Copyright © 2021, Springer-Verlag London Ltd., part of Springer Nature.)
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Figure 3. The equal-lead helical ball end mill, (a) 3D view and (b) top view. (Adapted from Ref. [37].)
Figure 3. The equal-lead helical ball end mill, (a) 3D view and (b) top view. (Adapted from Ref. [37].)
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Figure 4. Geometric analysis of multiple-toolpath cutting, (a) down-milling and (b) up-milling.
Figure 4. Geometric analysis of multiple-toolpath cutting, (a) down-milling and (b) up-milling.
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Figure 5. Projection on the contact plane, (a) down-milling and (b) up-milling.
Figure 5. Projection on the contact plane, (a) down-milling and (b) up-milling.
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Figure 6. The toolpaths for cutting, (a) down-milling and (b) up-milling.
Figure 6. The toolpaths for cutting, (a) down-milling and (b) up-milling.
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Figure 7. Instruments and equipment used, (a) the machine tool, VDL-1000E, Dalian Machine Tool Group, Dalian, China, (b) the white light interferometer, Talysurf CCI, Taylor Hobson, Warrenville, IL, USA and (c) the super-depth microscope, VHX-1000, Keyence, Osaka, Japan.
Figure 7. Instruments and equipment used, (a) the machine tool, VDL-1000E, Dalian Machine Tool Group, Dalian, China, (b) the white light interferometer, Talysurf CCI, Taylor Hobson, Warrenville, IL, USA and (c) the super-depth microscope, VHX-1000, Keyence, Osaka, Japan.
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Figure 8. Surface textures in different directions of down-milling.
Figure 8. Surface textures in different directions of down-milling.
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Figure 9. The microstructure of surface adhered defects and normal surface texture, (a) β = −67.5° and (b) β = 67.5°.
Figure 9. The microstructure of surface adhered defects and normal surface texture, (a) β = −67.5° and (b) β = 67.5°.
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Figure 10. Material adhesion on the tool rake face, (a) β = −67.5°, (b) β = −157.5°, (c) β = 67.5°, and (d) β = 157.5°.
Figure 10. Material adhesion on the tool rake face, (a) β = −67.5°, (b) β = −157.5°, (c) β = 67.5°, and (d) β = 157.5°.
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Figure 11. Surface textures in different directions of up-milling.
Figure 11. Surface textures in different directions of up-milling.
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Figure 12. The analyses of the feed directions in the Q1 range for down-milling.
Figure 12. The analyses of the feed directions in the Q1 range for down-milling.
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Figure 13. The analyses of the feed directions in the Q2 range for down-milling.
Figure 13. The analyses of the feed directions in the Q2 range for down-milling.
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Figure 14. The analyses of the feed directions in the Q3 range for down-milling.
Figure 14. The analyses of the feed directions in the Q3 range for down-milling.
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Figure 15. The analyses of the feed directions in the Q4 range for down-milling.
Figure 15. The analyses of the feed directions in the Q4 range for down-milling.
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Figure 16. Effect of surface adhered damage on height parameters of surface topography, (a) normal machined surface, and (b) surface adhered on the machined surface.
Figure 16. Effect of surface adhered damage on height parameters of surface topography, (a) normal machined surface, and (b) surface adhered on the machined surface.
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Figure 17. (a) Cutting speed variation of the critical points in the CWE area and (b) the selected height parameters of surface topographies.
Figure 17. (a) Cutting speed variation of the critical points in the CWE area and (b) the selected height parameters of surface topographies.
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Figure 18. The CWE geometric analyses, (a) Q1 range and (b) Q2 range.
Figure 18. The CWE geometric analyses, (a) Q1 range and (b) Q2 range.
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Figure 19. The variation trend of Zk with κ, (a) Q1 range and (b) Q2 range.
Figure 19. The variation trend of Zk with κ, (a) Q1 range and (b) Q2 range.
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Figure 20. The analyses of the feed directions in the Q1 range for up-milling.
Figure 20. The analyses of the feed directions in the Q1 range for up-milling.
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Figure 21. The analyses of the feed directions in the Q2 range for up-milling.
Figure 21. The analyses of the feed directions in the Q2 range for up-milling.
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Figure 22. The analyses of the feed directions in the Q3 range for up-milling.
Figure 22. The analyses of the feed directions in the Q3 range for up-milling.
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Figure 23. The analyses of the feed directions in the Q4 range for up-milling.
Figure 23. The analyses of the feed directions in the Q4 range for up-milling.
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Figure 24. (a) Cutting speed variation of the critical points in CWE area and (b) the selected height parameters of surface topographies.
Figure 24. (a) Cutting speed variation of the critical points in CWE area and (b) the selected height parameters of surface topographies.
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Table 1. Chemical composition (%) of Ti–6Al–4V alloy. (Reprinted from Ref. [26].)
Table 1. Chemical composition (%) of Ti–6Al–4V alloy. (Reprinted from Ref. [26].)
ElementAlVFeCNHOTi
%5.5~6.753.5~4.50.30.080.050.010.2Balance
Table 2. Mechanical and thermal properties of Ti-6Al-4V. (Reprinted from Ref. [26].)
Table 2. Mechanical and thermal properties of Ti-6Al-4V. (Reprinted from Ref. [26].)
Density
(g/cm3)
Hardness
(HB)
Modulus E
(GPa)
Tensile Strength
(MPa)
Thermal Conductivity
(W/m.K)
Melting Point
(°C)
4.42345113.89957.31670
Table 3. Specification of cemented carbide CTS20D. (Reprinted from Ref. [29].)
Table 3. Specification of cemented carbide CTS20D. (Reprinted from Ref. [29].)
ParameterValue
Tungsten carbide90%
Cobalt10%
Hardness (HRA)91.9
Hardness (HV)1600
TRS—transverse rupture strength (PSI)580.100
Fracture toughness (MPa·m1/2)10.4
Density (g/cm3)14.38
Grain Size (μm)submicron 0.8
ISO range:K20–K40
Table 4. Cutting conditions and case of cutting into/out for down-milling.
Table 4. Cutting conditions and case of cutting into/out for down-milling.
Cutting ConditionsFeed RangesFeed Directions The Case of Cutting Into/Out
Spindle speed:
n = 4000 rpm;
Feed rate:
F = 640 m/min;
Cutting depth:
e = 0.3 mm;
Toolpath stepover:
s = 0.15 mm;
machining inclination angle: αp = 15°;
Cooling mode:
dry cutting;
Q1β = −90°Tool tip is inside of CWE area with cutting into/out transition
β = −67.5°Cutting into from B/P, and Cutting out from C
β = −45°Cutting into from B/P, and Cutting out from C
β = −22.5°Cutting into from B/P, and Cutting out from C
Q2β = 0°Cutting into from B/P, and Cutting out from C
β = 22.5°Cutting into from B/P, and Cutting out from C
β = 45°Cutting into from B/P, and Cutting out from C
β = 67.5°Cutting into from B/P, and Cutting out from C
Q3β = 90°Cutting into from AB, and Cutting out from C
β = 112.5°Cutting into from A, and Cutting out from B/P
β = 135°Cutting into from A, and Cutting out from B/P
β = 157.5°Cutting into from A, and Cutting out from B/P
Q4β = 180°Cutting into from A, and Cutting out from B/P
β = −157.5°Cutting into from A, and Cutting out from B/P
β = −135°Cutting into from A, and Cutting out from B/P
β = −112.5°Tool tip is inside of CWE area with cutting into/out transition
Table 5. Cutting conditions and case of cutting into/out for up-milling.
Table 5. Cutting conditions and case of cutting into/out for up-milling.
Cutting ConditionsFeed RangesFeed Directions The Case of Cutting Into/Out
Spindle speed:
n = 4000 rpm;
Feed rate:
F = 640 m/min;
Cutting depth:
e = 0.3 mm;
Toolpath stepover:
s = 0.15 mm;
machining inclination angle: αp = 15°;
Cooling mode:
dry cutting;
Q1β = −90°Cutting into from B/P, and Cutting out from A
β = −67.5°Cutting into from BC, and Cutting out from A
β = −45°Cutting into from C, and Cutting out from B/P
β = −22.5°Cutting into from C, and Cutting out from B/P
Q2β = 0°Cutting into from C, and Cutting out from B/P
β = 22.5°Cutting into from C, and Cutting out from B/P
β = 45°Cutting into from C, and Cutting out from B/P
β = 67.5°Cutting into from C, and Cutting out from B/P
Q3β = 90°Tool tip is inside of CWE area with cutting into/out transition
β = 112.5°
β = 135°Cutting into from B/P, and Cutting out from A
β = 157.5°Cutting into from B/P, and Cutting out from A
Q4β = 180°Cutting into from B/P, and Cutting out from A
β = −157.5°Cutting into from B/P, and Cutting out from A
β = −135°Cutting into from B/P, and Cutting out from A
β = −112.5°Cutting into from B/P, and Cutting out from A
Table 6. The measured results of selected height parameters for down-milling surface topographies.
Table 6. The measured results of selected height parameters for down-milling surface topographies.
Feed Directions SkuSz (μm)Sp (μm)Sv (μm)
1st2nd3rd1st2nd3rd1st2nd3rd1st2nd3rd
β = −157.5°4.370 5.985 3.462 4.201 3.664 5.069 2.180 2.095 2.386 2.021 1.569 2.682
β = −135°6.819 4.494 14.194 9.458 9.666 5.461 4.600 4.702 2.508 4.858 4.964 2.953
β = −112.5°19.985 29.699 22.076 13.584 8.317 10.398 8.407 2.993 3.998 5.969 5.325 6.400
β = −90°23.160 29.699 12.016 13.712 8.314 12.510 9.841 6.840 7.978 3.871 1.474 4.532
β = −67.5°36.242 29.928 31.046 8.321 9.194 8.202 6.291 6.284 6.016 2.029 2.910 2.185
β = −45°30.028 26.121 29.610 16.350 15.137 25.891 12.526 10.720 20.210 3.825 4.417 5.681
β = −22.5°10.574 16.915 15.456 18.394 13.665 15.849 14.040 10.007 11.107 4.354 3.658 4.742
β = 0°2.932 2.894 4.421 11.795 11.591 12.183 8.744 7.388 8.806 3.051 4.203 3.377
β = 22.5°3.168 3.956 3.208 4.883 6.113 7.664 2.529 3.098 4.692 2.353 3.016 2.972
β = 45°3.251 2.822 3.352 4.953 8.149 5.248 2.172 5.320 2.631 2.781 2.828 2.617
β = 67.5°2.822 3.061 2.858 4.760 4.498 6.756 2.070 2.103 3.077 2.691 2.395 3.679
β = 90°2.764 2.838 2.861 4.499 5.493 5.009 2.103 2.760 2.760 2.396 2.733 2.249
β = 112.5°3.086 2.965 2.995 3.916 5.085 4.167 1.990 2.639 2.006 1.926 2.445 2.160
β = 135°2.998 3.041 2.958 4.363 3.772 5.352 2.282 2.072 2.382 2.081 1.700 2.969
β = 157.5°3.036 3.179 2.942 3.873 4.040 5.384 1.833 2.101 2.272 2.040 1.939 3.112
β = 180°2.899 2.929 2.773 4.039 3.964 4.943 2.243 1.952 2.099 1.796 2.012 2.844
Table 7. Measurement results of the selected height parameters for up-milling surface topographies.
Table 7. Measurement results of the selected height parameters for up-milling surface topographies.
Feed Directions SkuSz (μm)Sp (μm)Sv (μm)
1st2nd3rd1st2nd3rd1st2nd3rd1st2nd3rd
β = −157.5°13.211 16.473 20.073 25.508 30.278 22.699 18.904 22.456 15.635 6.604 7.822 7.064
β = −135°26.120 37.778 32.647 18.979 21.243 22.399 13.831 14.178 16.424 5.148 7.065 5.975
β = −112.5°22.462 44.487 18.960 10.897 13.805 15.946 8.325 10.025 11.370 2.572 3.780 4.576
β = −90°22.022 34.336 10.429 14.570 8.031 11.969 9.878 6.547 7.685 4.692 1.484 4.284
β = −67.5°3.249 3.045 2.969 4.841 5.330 4.897 2.616 2.699 2.470 2.226 2.631 2.427
β = −45°3.399 3.114 3.270 4.605 5.439 4.877 2.499 2.792 2.368 2.106 2.646 2.509
β = −22.5°3.268 3.140 3.193 4.693 5.111 5.891 2.371 2.410 2.865 2.321 2.701 3.026
β = 0°3.270 3.294 3.169 5.796 6.912 5.054 3.085 3.537 2.687 2.710 3.375 2.367
β = 22.5°3.075 3.083 2.868 5.675 5.423 4.806 3.059 2.699 2.365 2.616 2.724 2.441
β = 45°3.006 2.969 2.933 5.884 6.075 4.883 2.984 3.642 2.865 2.899 2.433 2.017
β = 67.5°3.030 3.273 3.165 5.021 5.195 4.987 2.558 2.658 2.303 2.463 2.537 2.683
β = 90°4.788 5.134 4.128 12.225 9.316 8.356 7.900 5.965 5.362 4.325 3.350 2.994
β = 112.5°25.356 32.619 11.970 14.309 14.993 12.449 8.053 8.569 9.565 6.256 6.423 2.884
β = 135°33.651 20.068 25.437 16.186 18.398 20.660 10.253 12.569 13.670 5.933 5.829 6.990
β = 157.5°34.446 21.405 28.679 26.726 26.398 22.470 18.942 19.069 15.650 7.785 7.330 6.820
β = 180°20.018 41.030 35.036 21.489 19.818 25.987 15.188 13.663 18.749 6.300 6.155 7.238
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Zhang, A.; Yue, C.; Liu, X.; Liang, S.Y. Study on the Formation Mechanism of Surface Adhered Damage in Ball-End Milling Ti6Al4V. Materials 2021, 14, 7143. https://doi.org/10.3390/ma14237143

AMA Style

Zhang A, Yue C, Liu X, Liang SY. Study on the Formation Mechanism of Surface Adhered Damage in Ball-End Milling Ti6Al4V. Materials. 2021; 14(23):7143. https://doi.org/10.3390/ma14237143

Chicago/Turabian Style

Zhang, Anshan, Caixu Yue, Xianli Liu, and Steven Y. Liang. 2021. "Study on the Formation Mechanism of Surface Adhered Damage in Ball-End Milling Ti6Al4V" Materials 14, no. 23: 7143. https://doi.org/10.3390/ma14237143

APA Style

Zhang, A., Yue, C., Liu, X., & Liang, S. Y. (2021). Study on the Formation Mechanism of Surface Adhered Damage in Ball-End Milling Ti6Al4V. Materials, 14(23), 7143. https://doi.org/10.3390/ma14237143

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