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Master-Slave Coordinated Control of Fast and Slow Tool Servos for Diamond Turning of Complex-Shaped Optics

Abstract

Diamond turning based on tool servos is gaining applications increasingly in the surface forming of complex-shaped optics. However, current fast/slow tool servo techniques encounter inherent limitations in terms of stroke or bandwidth, posing a significant challenge for high-precision and high-efficiency machining of structures with relatively large strokes. To handle this dilemma, this study proposes a master-slave coordinated control strategy for fast and slow cooperative tool servo diamond turning. Specifically, the slow tool servo (STS) serves as the master servo to follow the desired toolpath, while an additional fast tool servo (FTS) axis acts as the slave servo to track the motion error of the master servo in real time. To enhance the tracking performance of the slave servo, a frequency response data-based enhanced real-time iterative compensation method is developed to control the fast axis. As a validation, the ultraprecision diamond turning experiments are conducted on a three-axis lathe equipped with a custom-designed FTS. The servo motion is performed with high accuracy and a microlens array is generated with high quality, suggesting that the proposed strategy effectively eliminates the motion errors of the STS and significantly improves the form accuracy of the fabricated surfaces.

article Article; Early Access

date_range 2024

language English

link Link of the paper

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Meng Yixuan

Wang Xiangyuan

Wu Hao

Zhu Zhiwei

Zhang Xinquan

Zhu Limin

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Featured Keywords

Servomotors

Tracking

Real-time systems

Diamonds

Turning

Bandwidth

Surface topography

Complex-shaped optics

cooperative tool servo

machining dynamics

master-slave coordinated control (MSCC)

ultraprecision diamond turning

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Effect of corrosion on flexural strength of reinforced concrete beams with polypropylene fibers

Abstract

An experimental study was performed to investigate the effects of polypropylene fibers on uncorroded and corroded reinforced concrete beams. Three different volume fractions of polypropylene fibers having 0, 0.5, and 1.5%, were tested at four corrosion levels of 0% and approximately 5, 7, and 9%. A full scale of an accelerated corrosion pool was used for the accelerated corrosion process. Reinforced concrete beams were used for an under monotonic bending test. The contribution of the actual corrosion levels of transverse and longitudinal reinforcement bars to the total corrosion levels were obtained from reinforcement bars fully extracted from concrete. Flexural strength, bond-slip, and moment-curvature relationships were examined for uncorroded and corroded reinforced concrete beams. A new model was developed to predict the flexural strength of corroded reinforced concrete beams. The proposed model for predicting the residual flexural strength of corroded beams was compared with test data published in previous studies. Furthermore, a novel model is presented for improved predictions between the actual and theoretically estimated corrosion mass losses, based on Faraday’s law, with the aid of fully extracted reinforcement bars. The model used to predict the flexural strength of corroded reinforced concrete beams with large sizes demonstrated good agreement with current and previously published literature data. In the case of corroded beams comprising differing amounts of polypropylene fibers, the performance of the corroded beams was limited by a fiber volume fraction of 1.5% at low corrosion levels.

article Article

date_range 2018

language English

link Link of the paper

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