Abstract
Deviations between nominal and actual tolerances are a challenging problem during turning processes of thin-walled workpieces. One main cause of these deviations is the clamping force applied by the turning chuck to hold the workpiece. Due to the low stiffness of thin-walled workpieces, large workpiece deformations can occur even when clamping forces are low. For this reason, the clamping force needs to be precisely adjusted. A possible approach are chucks with integrated actuators. As a result of the more direct power transmission, these chucks have a potentially higher clamping force accuracy compared to conventional external actuation. However, integrated actuators are additional heart sources resulting in thermal loads and thermally induced deformations of the chuck components. Due to the resulting mechanical distortion of the chuck system, the precise adjustment of clamping forces is not possible. Thus, this paper evaluates the thermally induced clamping force deviations on a novel turning chuck with four integrated electric drives. A test bench is used to analyse both a single drive and the combination of all four drives regarding the temperature effect on the clamping force adjustability. A clamping force deviation of up to 26% is observed. Based on the measured chuck temperature, a compensation method is introduced leading to a clamping force accuracy of 96.9%.
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1 Introduction
Precision turning of thin-walled workpieces such as bearings, thin rings or turbines is of key importance in aerospace, automotive and medical applications [1]. One main cause of shape deviations is the clamping force applied by the turning chuck to hold the workpiece [2]. Due to the low stiffness of thin-walled workpieces, large workpiece deformations can occur even when clamping forces are low. For this reason, the appropriate clamping force has to be applied. To estimate the appropriate clamping force and thus to reduce shape deviations, FE-simulations or analytical calculations are used [3]. In this context, Sergeev et al. proposed an algorithm to adjust the appropriate clamping force by an external clamping cylinder leading to clamping force errors of 12–15% [4]. Since clamping force error and shape deviation are related linear proportional, shape deviations can occur in the same amount. Therefore, an external actuated chuck is insufficient to ensure tight tolerances. To avoid shape deviations, chucks with integrated actuators were developed [5, 6]. However, these chucks are only suitable for certain workpiece diameters or manufacturing processes. In contrast, the most commonly used clamping device in turning are chucks with three or four jaws [7]. Jaw-chucks allow a flexible clamping of different workpiece diameters. As a result, jaw-chucks are universally used for turning. For these reasons, a novel jaw-chuck for universal workpiece clamping is presented in this paper. Due to its integrated electric drives, higher clamping force accuracy and sensitivity are expected compared to a conventional external actuation. The design of the sensory chuck is explained in Sect. 2. In addition, the actuating concept is proofed using a test bench. In Sect. 3, the compensation method of thermally induced clamping force deviations is presented and the achievable clamping force accuracy is analysed.
2 Sensory Chuck for Thin-Walled Workpieces
2.1 Sensory Chuck Design
The design of the sensory chuck is shown in Fig. 1. It is composed of two different modules: A standard four-jaw-chuck HWR VT-S031 and a module with four actuator units. Each of the four actuator units consists of a Harmonic Drive SE FHA-14C gear motor and a leadscrew. The leadscrew allows the transmission of rotational movement of the motor into a linear positioning movement required to actuate the 4-jaw-chuck. The leadscrews are mechanically connected in parallel via a coupling element to transmit the actuation force Fact. In addition, the leadscrew is designed for self-locking to maintain the clamping force Fcl even when power failures of the motor occur.
A total of four EJ7411 measuring and control boards from Beckhoff Automation GmbH & Co. KG are integrated into the chuck. Each EJ7411-module can measure and control the drive signals (motor torque Mm, angular position p) in a closed feedback loop. Based on the drive signals, the clamping force Fcl is calculated and adjusted considering a previously experimentally identified lookup table (see Sect. 3). Due to the self-locking leadscrew, clamping force adjustments are only possible by a feedforward control. For this reason, instationary variations of the clamping force (e.g. as a result of the cutting force) can not be considered.
The four-jaw-chuck HWR VT-S031 is designed to apply a maximum clamping force of Fcl,max = 150 kN. To achieve this force, each of the four actuator units has to provide an actuation force Fact = 15 kN. To proof the actuation concept, the test bench shown in Fig. 2a) is used. The test bench represents one of the four actuator units including one FHA-14C gear motor and the leadscrew. A force sensor based on strain gauges (Hottinger Brül & Kjaer U9C-50KN) measures the actuation force Fact. This sensor can measure forces in both + Z- and -Z- direction. During the experiments, different motor torques Mm are applied on the leadscrew and the resulting actuation force Fact is measured. As friction condition variations can lead to a significant deviation in axial forces for screws [8], two leadscrew lubricants (OKS265 and HLP32) are used to evaluate these correlations. The measurement is carried out at five different torques up to the limit for continuous loads of the motor (Mm = 50%). The motor torque can be measured and adjusted by the EJ7411-module in percent of the peak motor torque.
The resulting correlations between the motor torque Mm and the actuation force Fact are presented in Fig. 2b). A linear proportional relationship between Mm and Fact can be observed. The highest force is Fact = 14.5 kN and occurs at the torque Mm = 50%. For short-time (t < 1 s) peak torques, a maximal actuation force of Fact,max = 18.3 kN could be achieved (not shown in Fig. 2). Thus, the used actuation concept provides sufficient high actuation forces to achieve a maximal clamping force of Fcl,max = 150 kN. However, it can be seen that the actuation force also depends on the force direction due to the bearing friction moment between force sensor and leadscrew. Lower actuation forces can be achieved in + Z-direction which are used for inside clamping of workpieces. For inside clamping, the clamping force is increased by centrifugal forces during turning and thus lower actuation forces are sufficient for safe clamping. However, the results show higher actuation forces using OKS 265 lubricant. For outside clamping, the actuation force can be increased by up to 18.8% (8.5% for inside clamping) compared to HLP 30. Therefore, the OKS 265 lubricant is used for the prototype (see Sect. 3) to ensure high clamping forces.
2.2 Thermal Influences on the Actuation Force
For leadscrews, the actuation force highly depends on the friction coefficient μ in the thread [8]. In addition, high temperatures result in a generally high viscosity of the lubricant leading to a lower friction coefficient [9]. A lower friction coefficient increases the actuation force and thus the clamping force. Power losses of the motor are a heat source and could therefore affect the actuation force. To evaluate the influence of thermal losses on the actuation force, a reversing sequence of the motor was carried out with the test bench. A cycle of the sequence represents the clamping and machining of a typical ring-shaped workpiece. One cycle consists of a stepwise increase of the motor torque to Mm = 50% with subsequent constant torque for the time tcl = 10 s (workpiece clamping and machining). For a complete cycle, the procedure is repeated in the opposite direction (workpiece removal and reloading). A total of n = 1.000 cycles are carried out while measuring the motor temperature with a type K thermocouple (Fig. 2a). In Fig. 3, the resulting correlation between the motor temperature ϑ and the actuation force deviation |ΔFact| is presented. This deviation is the difference between the measured force and the initial actuation force at a room temperature ϑ0 = 25 ℃. A linear proportional relationship between ϑ and |ΔFact| can be observed. The highest actuation force deviation |ΔFact,max| = 3.8 kN occurs for outside clamping at a temperature ϑ = 32.3 ℃. This corresponds to a 26.2% increase in force compared to the initial actuation force Fact,0 = 14.5 kN. Since the actuation force is proportional to the clamping force, thermally induced force deviations have a potentially significant influence on the clamping force. Therefore, this influence is evaluated in Sect. 3 using the assembled prototype.
3 Compensation of Thermally Induced Clamping Force Deviations
3.1 Clamping Force Adjustments with the Sensing Chuck Prototype
As shown in Sect. 2, thermal power losses of the actuation unit have a potentially significant influence on the clamping force. To evaluate this influence, the previously described experiments were repeated using the assembled prototype. First results showed, that the motor torque is not suitable to ensure a reliable clamping force adjustment. It is expected that highly non-linear friction between moving components of the chuck is the main cause of this issue. However, the measuring and control board of the chuck (see Fig. 1) provides an additional signal to adjust the clamping force: the angular position p. In order to verify whether the angular position allows a sufficiently high clamping force accuracy, the setup shown in Fig. 4a) was used. During the experiments, a reversing sequence of the motor was carried out. One cycle consists of a stepwise increase of the angular position up to the maximum achievable clamping force of the drives. A total of n = 1.000 cycles are carried out while measuring the motor temperature. During the experiments, the chuck temperature increased from ϑchuck = 23 ℃ (room temperature) to a value of ϑchuck = 33 ℃.
In Fig. 4b), the resulting correlation between the angular position p and the clamping force Fcl is presented. In the diagram, the angular position is represented in increments. One increment (inc) represents the smallest detectable change in position. In addition, only the curve at the beginning (ϑchuck = 23 ℃) and at the end (ϑchuck = 33 ℃) of the measurements are shown. It can be seen that the clamping force also depends on the chuck temperature ϑchuck, resulting in small clamping force differences. The highest difference is ΔFcl,ϑ = 2.8 kN (Fcl,ϑ=23 ℃ – Fcl,ϑ=33 ℃) and occurs at the position p = 600,800 inc. This corresponds to a relative clamping force error of ΔFrel = 3.04%. In comparison, available clamping force measurement devices have a typical clamping force error of 3%. Therefore, the presented method of using the angular position for clamping force adjustments has a similar accuracy compared to specialized measuring devices on the market. To evaluate whether the error can be reduced further, a compensation method is proposed in Sect. 3.2.
3.2 Compensation of Clamping Force Errors
To evaluate whether the error can be reduced further, the identified correlation between angular position p, clamping force Fcl and chuck temperature ϑ are combined into a multidimensional lookup table. The lookup table was implemented into the EJ7411-modules and additional PT 100-sensors were integrated on the drives surface to monitor the chuck temperatures. Thereafter, the previous experiments were repeated. Based on five repetitions, the relative clamping force error ΔFrel is calculated for each clamping force Fcl.
In Fig. 5, the resulting correlation between the clamping force Fcl and the clamping force error ΔFrel is shown. High errors (ΔFrel > 3%) can be observed for clamping forces Fcl ≤ 10 kN. According to [10], a minimum clamping force of Fcl,min ≈ 10 kN is required for safe clamping with the present chuck size. Below this clamping force, an uncontrollable workpiece release can occur. For this reason, clamping forces Fcl ≤ 10 kN are not applied in practice. However, as the clamping force increases, smaller clamping force errors are achieved. The highest relative errors occur for ϑchuck = 33 ℃ ranging from 0.35% to 3.10%. In addition, the highest absolute clamping force error is ΔFcl,max = 862 N at Fcl = 97 kN (not shown in Fig. 5). Compared to using only the angular position for clamping force adjustments (see Fig. 4, ΔFcl,ϑ = 2,800 N), applying the lookup table reduces the clamping force errors by 69.3%. Especially for room temperature, the error is reduced to at least 0.79% respectively ΔFcl,max = 325 N (Fcl = 80 kN). Consequently, applying a lookup table allows a precise measurement and adjustment of the clamping force based on position and temperature signals of the drive.
4 Conclusion
This paper presents the design of a novel sensing chuck for clamping force measurement and adjustment. Thermal influences on the measurement accuracy are described and a compensation method is shown. With the compensation method, clamping force errors are reduced by 69.3%. Compared to common chucks (ΔFrel ≈ 10%), a lower clamping force error of 3.1% is achieved. Since the resulting shape deviation of thin-walled workpieces is proportional to clamping force [11], it is assumed that geometry deviations can be reduced to the same extent. Thus, future work aims to evaluate the machining tolerance achieved in cutting processes. In addition, further possible influences on the chuck accuracy (e.g. workpiece diameter, clamping position) will be investigated.
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Acknowledgements
The results presented were obtained within research project “CyberChuck” (02P18K601). The authors thank the Federal Ministry of Education and Research for funding this project.
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Denkena, B., Klemme, H., Wnendt, E., Meier, M. (2023). Thermally Induced Clamping Force Deviations in a Sensory Chuck for Thin-Walled Workpieces. In: Ihlenfeldt, S. (eds) 3rd International Conference on Thermal Issues in Machine Tools (ICTIMT2023). ICTIMT 2023. Lecture Notes in Production Engineering. Springer, Cham. https://doi.org/10.1007/978-3-031-34486-2_15
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