Abstract
Real-time monitoring of the cutting force in the machining process is critical for improving machining accuracy, optimizing the machining process, and optimizing tool lifetime; however, the dynamometers are too expensive to be widely used by machine tool users. Therefore, this paper presents a simple and cheap apparatus—a smart tool holder—to measure the cutting force of turning tools in the finishing turning. The apparatus does not change the structure of the turning tool. It consists of a tool holder and a piezoresistive force sensor foil, and transmits the signal through Bluetooth wireless communication. Instead of dealing with the circuit hardware, this paper uses the Artificial Neural Network (ANN) model to successfully calibrate the warm-up shift problem of the piezoresistive force sensor. Such a software method is simple, and considerably cheaper than the hardware method. For the force measurement capability of the smart tool holder, the cross-interference between orthogonal forces are very small and thus can be ignored. The force reading of the smart tool holder possesses high repeatability for the same turning parameters and high accuracy within the experiment groups. The authors apply the smart tool holder to cut the low carbon steel S15C, and to determine its specific cutting force in fine turning. The resulting fine turning force model agrees very well with the measurement. Its mean absolute deviation is 3.87% and its standard deviation is 1.55%, which reveals that the accuracy and precision of the smart tool holder and the fine turning force model are both good.
Highlights
If the machine tool can monitor the cutting force in the machining process, it could detect and prevent chatter early in order to ensure the required surface roughness, to ensure the dimensional stability while needless of a downstream workpiece measurement, and to analyze the machining process and optimize the run and tool lifetime
The products related to the cutting force measurement are the spike® sensor system produced by promicron GmbH [1], and the dynamometer produced by Kistler GmbH [2]
One is to amplify the strain to be detectable, namely through a transmission structure that can transmit the cutting force and amplify the strain; and the other is to convert the mechanical strain into electrical signals, namely through a transducer
Summary
If the machine tool can monitor the cutting force in the machining process, it could detect and prevent chatter early in order to ensure the required surface roughness, to ensure the dimensional stability while needless of a downstream workpiece measurement, and to analyze the machining process and optimize the run and tool lifetime. The products related to the cutting force measurement are the spike® sensor system produced by promicron GmbH [1], and the dynamometer produced by Kistler GmbH [2]. Such products are too expensive to be widely used in the production lines of machine tool users. One is to amplify the strain to be detectable, namely through a transmission structure that can transmit the cutting force and amplify the strain; and the other is to convert the mechanical strain into electrical signals (voltage or current), namely through a transducer. The designs of the force transmission structures are varied, and there are three common types of force transducers: piezoresistive force sensors, capacitive force sensors, and piezoelectric force sensors
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