Measuring and modelling of process forces during tapping using single tooth analogy process

The geometry of a tap is basically determined by the thread to be produced. The sizes for describing the tap are given in DIN 2197 [21], but these are not sufficient to describe the tap unambiguously. Sizes such as the position and size of the first tooth that have a decisive influence on the chip cross-section of each individual tooth, are not specified in DIN 2197. The definition of these sizes is left to the tool manufacturers [22]. In addition, manufacturing variations may lead to deviations in the geometry. Therefore, when comparing simulated and experimental results, it is necessary to refer to the real geometry of a tap and evaluate the cross-sections of the undeformed chip for each tooth.

To evaluate the real tool geometry (Fig. 2a), the surface of the three fluted M8x1.25 tap, according to DIN 371 [23], used in the experiments is recorded with the optical surface measuring device Alicona Infinite Focus G5 of Alicona Imaging GmbH with connected rotatory unit. The digital representation of the tool surface (Fig. 2b) can be exported in standard tessellation language (stl). In this file format, the tool surface is represented by numerous faces S, each specified by three vertices V. For the given tool, there are 1,013,833 faces and 508,018 vertices with a vertical and lateral resolution of \(0.100 \, \upmu \hbox {m}\) and \(5.918 \, \upmu \hbox {m}\) respectively. The selected resolution represents a good compromise between manageable file size and accuracy. In the following, the vertices are transformed into cylindrical coordinates with the origin in the tool centre point. Thus, each vertex position is defined by its distance to the tool centerline r, the direction angle \(\varphi \) and the height z. To extract plane elements representing the individual teeth, the following procedure is applied for each tooth \(T_i\), with index i as consecutive numbering of the teeth.

For the analysis of the tooth, the region of interest (ROI) is specified including only relevant faces \(S_{n_i}\) and their vertices \(V_{j_i}\), with the indices \(n_i\) and \(j_i\) being counting variables for the faces and vertices of the tooth \(T_i\) respectively. The focus is mainly on the rake face and the cutting edge of the tooth. To generate a two-dimensional representation of the tooth \(T_i\), the tooth reference plane \(E_{T_i}\), containing the centre axis of the tool and the tooth tip, is defined. This corresponds to the tool reference plane described in DIN 6581 [24]. Each vertex \(V_{j_i}\) in the defined ROI is then projected to a vertex \(V^\prime _{j_i}\) within the plane \(E_{T_i}\). To follow the tooth trajectory in the cutting process, the pitch P of the thread is considered in the projection. Thus, it is possible to determine the orthogonal cross-section of the tooth as it passes through the plane under ideal conditions.Here \(r_{j_i}\), \(\varphi _{j_i}\) and \(z_{j_i}\) are the respective coordinates of point \(V_{j_i}\) and \(\varphi _{T_i}\) is the position angle of the plane \(E_{T_i}\). Due to the projection of the vertices \(V^\prime _{j_i}\) the faces \(S^\prime _{n_i}\) lie within the plane \(E_{T_i}\). The polygon \(T_i\) representing the tooth can be described as the union of all \(m_i\) projected faces \(S^\prime _{n_i}\).By combining the individual plane elements of each tooth, the tool can be mapped as an 2D element set model (Fig. 2c), as described by Zabel [25].

Based on the extracted geometry of each tooth \(T_i\), the cross-section area of the undeformed chip \(A_i\) can be calculated by a boolean operation of the workpiece W and the two consecutive teeth \(T_i\) and \(T_{i-1}\), assuming that the teeth are projected to the same reference plane, for example the x–z-plane, considering the pitch of the tool, as shown in Fig. 2d). The absolute value of \(A_i\) is then calculated using Gauss’s area formula.According to [26], the undeformed chip thickness h results from the radial depth of cut \(h^\prime \) tilted by the chamfer angle \(\kappa \), as shown in Fig. 1. The calculation of the undeformed chip width b is performed analogously.The intersection length L (as shown in Fig. 1) can be described as the length of the boundary \({\varGamma }_i\) of the tooth \(T_i\) within the workpiece W and can be used to describe edge forces in tapping [12].The chip sizes assuming a pilot bore diameter of \(d_k = 6.8 \, \hbox {mm}\) are shown in Table 1. Referring to Ahn [27], the teeth are clearly assigned by a combination of a letter for the land of the tap and a number for the tooth on the respective land.

In order to determine the individual force components on each tooth experimentally, a modified plunge turning test is used, as shown in Fig. 3. The kinematic reversal with rotating component and stationary tool allows to measure forces in the stationary tool coordinate system. By switching from machining an internal thread to an external groove, the engagement of a single tooth in the component material can be realized. To reduce uncertainty in form of lateral deflection due to the single sided forces, the tap is clamped in a special holding device using a half thread supporting the teeth on the opposite side of the tooth engaged (see Fig. 3). Thus, a stationary chip removal with constant cross-section area of the undeformed chip can be guaranteed during the cut. In addition to lateral support, the half thread also serves for positioning in z-direction when positioning the tap on the next tooth. For exact positioning, therefore, only the angle of rotation of the tap needs to be adjusted. This is done using a setting gauge which positions the centre of the tooth perpendicular to the component surface. The set position after the adjustment can be seen in Fig. 3.

Essential for the force measurement of each individual tooth is that there is a temporally separated tooth engagement. Some papers therefore describe analogous processes in which parts of the tool are ground back [28‐30]. This however results in a destruction of the tool, making further tests with the exact tool impossible. In this work a non-destructive method is presented, where the tool stays intact and the separated engagement of the tooth is realized by modification of the workpiece geometry. For this purpose, circumferential ridges are applied to the test component, into which the thread is successively cut. To cut a circumferential groove in the ridge face, the pitch P of the tap is compensated by tilting the tool relative to the rotation axis of the part. The required adjustment corresponds to the pitch angle \(\beta \) and can be calculated according to DIN 13-28 [31] as follows:For force measurement during the cut, the tool is infeed to a specified x-position while the component is rotating. The workpiece rotation, the x-position of the tool and the measured forces for one tooth of the tap are shown in Fig. 4. The x-position is chosen so that the distance between the ridge surface and the tool center axis is half the diameter of the pilot bore \(d_k\). In this position, the tap cuts a constant chip over the entire circumference of the workpiece, generating the forces shown in Fig. 4. To ensure complete chip removal over one revolution the total dwell time after infeed is set to 1.5 revolutions. The tool is then moved away in positive x-direction. After the measurement procedure for one tooth is finished, the tap is unclamped, turned to the next tooth, adjusted and reclamped. As a result, all teeth of the tap cut in the same groove successively, in analogy to the real tapping process. The procedure is repeated for the first four teeth of each land.

For the experiments a lathe DMG CTX 800 beta is used. The process forces are recorded by a Kistler dynamometer Type 9121B and evaluated in Matlab. 42CrMo4 is used as workpiece material. The tool used is a M8 machine tap. It has a pitch of 1.25 mm, a helix angle \(\gamma _f\) of \(45{^{\circ }}\) and chamfer form C according to DIN 2197 [21]. The tolerance class is ISO2/6H. The tap is made of HSS-E and has a GLT-1 coating. An emulsion with 8.8% oil content is used as cooling lubricant, which is fed directly to the cutting point via a nozzle (see Fig. 3). The tests are carried out at cutting speeds of 5, 15 and 25 m/min, each with three repetitions. To ensure that the results are not influenced by manufacturing uncertainty, the same tool is used for all experiments (Table 2).

The tangential, radial and axial forces relative to the tool can be calculated by transforming the measured force signals into the tool coordinate system:

Analysing the extracted tooth elements shows, that the tip of the first tooth of the tap, referred to as A1, has a radius of 3.319 mm. With the pilot bore radius \(d_k/2= 3.4 \,\hbox {mm}\), as recommended in DIN 336 [32], the tooth A1 does not remove a chip. The first tooth with chip removal is therefore tooth B1. The largest cross-section area of the undeformed chip is measured for tooth B2, since this is the first tooth of the tool, which no longer increases the width of the thread, but only the depth. This also reflects in a lower increase of the contact length. The cross-section areas of the undeformed chip for the following teeth then continue to decrease, because of the thread flanks converging in an \(60{^{\circ }}\) angle. The last tooth to cut material from the thread is C3. All the following teeth do not perform any chip removal. The undeformed chip width shows a largely similar distribution (see Fig. 5). However, it should be noted that due to the trapezoidal chip shape of the cross-section of the undeformed chip in tapping, the cross-section area is not equal to the product of the thickness and width of the undeformed chip.Except for the first and last cutting tooth engaged, the measured undeformed chip thickness h is largely constant over the cutting teeth at approximately \(0.12 \, \hbox {mm}\). Since the tool has a constant lead angle \(\kappa \), this can be idealised calculated by the following formula, where Z represents the number of flutes of the tool, P is the pitch and \(\gamma _f\) is the angle of the helical flute, as shown in Fig. 2a).

The forces on each tooth of the tap are shown in Fig. 6. As described in Sect. 5.1, with the analogy process being set to map a pilot bore diameter of \(d_k= 6.8 \, \hbox {mm}\), there is no interaction between tooth A1 and the component during the tests leading to no measurable process forces. For teeth B1 to C3 in the cutting section of the tap, the tangential forces recorded are proportional to the measured cross-section area of the undeformed chip. Here, a slight influence of the cutting speed can be observed, which leads to a reduction of the tangential force with increasing cutting speed. For teeth A4–C4 in the guiding section of the tap, no further material is cut out of the thread, but forces can still be measured. It is evident that these are friction forces due to the contact between the tooth and the flanks of the thread.

The proportionality to the cross-section area of the undeformed chip can also be seen in the radial forces in the cutting section. The magnitude of these forces is about 50% less than the tangential forces (see Fig. 6). However, for the first teeth of the guiding section (A4–C4), the passive forces measured are considerably larger. Furthermore, these contact forces show a strong influence of cutting speed. It can be noted that for equal cutting speeds the forces of teeth A4–C4 are nearly constant. In the real process it can therefore be assumed that they compensate each other to a large extent and lead to a lateral stabilization of the tool.

Concerning the axial force, the chip shape must be considered more closely. Generally, in blind hole tapping, the negative axial forces can be explained by the angle of the helical flute of the tap. However, the contact of the tooth flanks with the workpiece can partly compensate the axial forces. Since there is no contact between the lower tooth flank and the workpiece for teeth B1–A2, there is no support to compensate negative forces (see Fig. 7). From tooth B2 onwards, there is also contact between the tooth and the lower thread flank, adding not measurable contact forces to the equation. From tooth B3 onwards, the measured axial forces change their sign. It can be assumed that the tooth flanks already compensate the chip induced axial forces to a large extent and the measured axial forces are mainly affected by the friction against the feed direction.

During tapping, the resulting radial force, combining all force components in the x–y-plane, causes tool deflection. According to the mechanistic approach these process forces can be described as the product of the specific cutting force K and the cross-section area of the undeformed chip A [3]. For each individual tooth the tangential force \(F_{tan,i}\) and the radial force \(F_{rad,i}\) can be described as follows:According to Ehmann [5] however, the specific process forces are generally not constant. Therefore, the model includes the influences of the undeformed chip thickness h and cutting speed \(v_c\). Following Dogra et al. [1], the specific forces can be described using the following equations.In the calculation of the specific forces, large deviations can be seen for teeth with small undeformed chip cross-section areas such as B1, since measurement uncertainty in the force signals is amplified when divided by a small value. Therefore, only the teeth C1–C3, having a sufficiently large cross-section area of the undeformed chip, are considered for the calibration of the force model. The coefficients shown in Table 3 are estimated using a multivariate regression analysis with least squares method.

The specific tangential and radial forces in relation to the undeformed chip thickness h and the cutting speed \(v_c\) are shown in Fig. 8. For large undeformed chip thicknesses, the cutting speed has a small effect on the specific forces in the considered parameter range. The influence however increases with decreasing values of the undeformed chip thickness h. It can be assumed, that this is due to the relatively higher share of contact and friction forces.

Since no more chips are removed in the guiding section of the tool, no specific force can be calculated here. Therefore, the specific edge forces \(K_E\) are calculated according to Puzović [12] based on the measured edge forces \(F_E\) and the geometrically determined contact length L.The thus calculated specific edge forces in radial direction can be related to the cutting speed \(v_c\). Using linear regression the relation can be described as:With an adjusted coefficient of determination of \(R^2 = 0.928\), the regression shows a good fit for \(K_{E,rad}\). This shows a decrease in radial edge forces with increasing cutting speed for the tested tooth of the guiding section. For \(K_{E,tan}\) however, no significant correlation to the cutting speed can be seen. The specific tangential edge force for the measured teeth of the guiding section can therefore be seen as constant.

The empirical cutting force model is validated by implementing it within a simulation model, as shown in [33], based on the mechanistic framework and comparing the resulting torque to experimental data. In the simulation the tool-workpiece intersection is calculated with a chip cross-section model [6] using the extracted 2D element set model from Sect. 4.1 as input. The tapping tests are, performed on a GROB G350 machining center, using a tool holder with minimum length compensation and internal cooling with an emulsion with 8.8% oil content. The pre-drilled bore is a blind hole with a measured diameter of 6.82 mm. Within the simulation, the torque is calculated by summing up the products of the tangential forces and the radius of the undeformed chip centerpoint. The measured and simulated torque signals are plotted in Fig. 9, showing a good agreement. The increase in the measured signal at greater immersion depth can be attributed to chip removal against the feed direction during blind hole tapping. However, this effect is not represented in the force model, which explains the deviation at this point.