A piezoelectric-driven actuator based on the lateral motion principle is proposed in this paper, it can achieve large-stroke linear motion with high resolution. One parallelogram-type flexure hinge mechanism and one piezoelectric stack are used to generate the lateral motion. The mechanical structure and working principle are discussed. A prototype was fabricated and a series of experiments were carried out to investigate its working performance. The results indicate that the maximum moving speed is about 14.25 mm s −1 , and the maximum output force is 3.43 N, the minimum stepping displacement is about 0.04 μm. The experiments confirm that the lateral motion can be used to design piezoelectric actuators with a large moving stroke and high accuracy with a compact size. This actuator can be used in fast tool servo systems for ultraprecision machining, precision motors for aerospace, focusing systems for optics, and so on.
Molecular dynamic (MD) simulation was applied to investigate surface quality and brittle–ductile transition of monocrystalline silicon with a diamond tool during elliptical vibration-assisted nanocutting (EVANC) and traditional nanocutting process.
The purpose of this study is to characterize the V pre-notched specimens with different relative depth ratio and the relative distance ratio by the AE signals in in situ three-point bending tests. Simultaneously, during the bending process, the V pre-notched specimen is in situ monitored by the opto-digital microscope. In order to analyze the depth of V-notch and the distance between the side V-notches and the middle V-notch effect on the specimens, a finite element analysis model is built by ABAQUS. Combining the in situ images, the AE signals and the finite element analysis (FEA) results, it is found that the experiment results are consistent with the FEA results. It is demonstrated that the amplitude of AE signals can effectively characterize the crack initiation, crack growth, and crack fast instability fracture.
Three-point bending is one of the most common methods of studying the mechanical performance of materials. The influence of punch radius in the measurements is not considered in the previous studies. This article focuses on the influence of the punch radius on the elastic modulus. The experiment is set up to measure the elastic modulus of 6061 aluminum alloy (6061 Al) and copper as the specimens, in which several different radii of punches are used. The maximum bending deflection of the middle point is 1.0 mm. Moreover, a finite element simulation is constructed to simulate the bending process of specimen, which is consistent with the experimental results. According to the results, the punch radius has affected the measurement of elastic modulus, and the elastic modulus, the contact length, and the peak load increase with the increase in the punch radius. Combining the experiment result (E 1 ) and the standard result (E 3 ) of Changchun research institute for testing machines, it is found that the appropriate punch radius is in the range from 2.5 to 3.0 mm for this experiment, when the specimen's dimension is 30.0 mm 3 6.0 mm 3 1.0 mm.
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