Your search keyword '"ZHAO-PENG HAO"' showing total 14 results

1. A Self-Adaptive Selection of Subset Size Method in Digital Image Correlation Based on Shannon Entropy

Author

Xiao-Yong Liu, Xin-Zhou Qin, Rong-Li Li, Qi-Han Li, Song Gao, Hongwei Zhao, Zhao-Peng Hao, and Xiao-Ling Wu

Subjects

Digital image correlation, self-adaptive selection, subset size, Shannon entropy, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Digital image correlation (DIC) is a typical non-contact full-field deformation parameters measurement technique based on image processing technology and numerical computation methods. To obtain the displacements of each point of interrogation in DIC, subsets surrounding the point must be chosen in the reference image and deformed image before correlating. In the existing DIC techniques, the size of subset is always pre-defined by users manually according to their experiences. However, the subset size has proven to be a critical parameter for the accuracy of computed displacements. In the present paper, a self-adaptive selection of subset size method based on Shannon entropy is proposed to overcome the deficiency of existing DIC methods. To verify the effectiveness and accuracy of the proposed algorithm, a numerical translated test is performed on four actual speckle patterns with different entropies, and then another test is performed on four computer-generated speckle patterns with non-uniform displacement field. All the results successfully demonstrate that the proposed algorithm can significantly improve displacement measurement accuracy without reducing too much computational efficiency. Finally, a practical application of the proposed algorithm to micro-tensile of Q235 steel is conducted.

Published

2020

2. An insight into structure-activity relationships in subclass IIb bacteriocins: Plantaricin EvF

Author

Zhao, Peng-Hao, Cai, Jun-Wu, Li, Yan, Li, Qiao-Hui, Niu, Meng-Meng, Meng, Xiang-Chen, and Liu, Fei

Published

2024

3. Characterization of aroma-active compounds in sesame hulls at different roasting temperatures by SAFE and GC-O-MS

Author

Wang, Rui, Wu, Lin-Xuan, Guo, Bing-Xin, Zhao, Peng-Hao, Yin, Wen-Ting, Liu, Hua-Min, Mei, Hong-Xian, and Duan, Ying-Hui

Published

2024

4. Microscopic Study on the Mechanism of Tool Bond Wear in Cutting Ni–Fe-Cr-Co–Cu Series Nickel-Base Superalloy

Author

Yi Hang Fan, Zhao Peng Hao, Zai Zhen Lou, and Xue Han

Subjects

0209 industrial biotechnology, Materials science, Mechanical Engineering, Alloy, Stress–strain curve, Metallurgy, chemistry.chemical_element, 02 engineering and technology, engineering.material, Industrial and Manufacturing Engineering, Superalloy, Nickel, chemistry.chemical_compound, 020303 mechanical engineering & transports, 020901 industrial engineering & automation, 0203 mechanical engineering, chemistry, Machining, engineering, Silicon carbide, Extrusion, Electrical and Electronic Engineering, Tool wear

Abstract

In the process of nickel-based alloy machining, chips are easy to bond on the tool surface, which weaken the tool performance and make the tool wear. Therefore, it is very important to study the mechanism of tool bond wear in the process of nickel-based superalloy machining. In order to reflect the wear process of the tool from the perspective of micro cutting, the molecular dynamics simulation model for cutting Ni–Fe-Cr-Co–Cu nickel-based alloy with SiC tool was established. The Morse potential functions between the tool and workpiece are calculated, and the simulation results are analyzed visually. It is found that the bond wear is the main wear form of tool in the process of cutting nickel-based alloy, and the wear processes are divided into three stages: contact, adhesion and shedding. The stress and strain in the cutting area are calculated and it is found that the bond occurs when the tool-workpiece extrusion is strong. Through the calculation of radial distribution function and formation energy, it is found that Ni-Si compound is formed on the tool surface, and the newly generated Ni-Si compound reduces the tool performance compared with the silicon carbide structure. This study provides a more complete microscopic explanation of the tool wear mechanism, which is helpful to find a method to prolong tool life.

Published

2021

5. Mechanical properties and microstructure evolution of additive manufactured 316L stainless steel under dynamic loading

Author

Ji Ning Li, Dong Gao, Yong Lu, Zhao Peng Hao, and Zhi Qi Wang

Subjects

Mechanics of Materials, Mechanical Engineering, General Materials Science, Condensed Matter Physics

Published

2022

6. Material Response at Tool–Chip Interface and Its Effects on Tool Wear in Turning Inconel718

Author

Jie Qiong Lin, Yi Hang Fan, Zhi Xin Yu, and Zhao Peng Hao

Subjects

Materials science, Bond strength, Mechanical Engineering, Metallurgy, Alloy, Work hardening, engineering.material, Edge (geometry), Industrial and Manufacturing Engineering, Carbide, Substrate (building), Mechanics of Materials, engineering, General Materials Science, Cold welding, Tool wear

Abstract

Because nickel-based alloy Inconel718 has poor thermal conductivity and serious work hardening, it is identified as a difficult-to-process material. The serious tool wear leads to short tool life. In this study, physical vapor deposition-coated carbide tools were used to machine Inconel718. The material response for different cutting speeds at the tool–chip interface and its effect on tool wear were studied. The results showed that at low cutting speed (v c = 20 m/min), cold welding and adhesion occurred at the tool–chip interface under high stress, and then the built-up edge (BUE) formed. The peeling off of BUE led to chipping. When the cutting speed (v c) was 45 m/min, diffusion and oxidation occurred at the tool–chip interface. The new generated material reduced tool hardness and bond strength of Co. The wear debris was generated in tool rake face. Flakes of wear debris fell from the tool substrate, which increased tool wear. When the cutting speed was 32 m/min, the softer oxides generated at the tool–...

Published

2014

7. Tool Diffusion Wear Mechanism in High Efficiency Machining Ti6Al4V

Author

Feng Lian Sun, Zhao Peng Hao, Suo Liang Niu, Min Li Zheng, and Yi Hang Fan

Subjects

Engineering, Flank, business.industry, Mechanical Engineering, Metallurgy, Rake, Titanium alloy, Mechanical engineering, Machining, Mechanics of Materials, General Materials Science, Resilience (materials science), Tool wear, Diffusion (business), Contact area, business

Abstract

Ti6Al4V has great affinity with tool material in machining process, which easily leads to tool diffusion wear. Turning experiments were carried out to study cutting temperature and pressure at tool-chip/workpiece. Based on the analysis, a scanning electron microscopy (SEM) equipped with energy dispersive X-ray spectrometer (EDS) was used to analyze tool wear morphology. The affinity of tool and workpiece material using the Ti-W, Ti-Co diagram was also studied to elaborate the diffusion mechanism in this present study. The results shows that the cutting temperature is very high and the temperature increases with the increase of cutting speeds in machining Ti6Al4V. At the contact area, the highest temperature is located in tool rake face near to tool tip. The resilience of workpiece results in serious attrition between tool flank face and the machined surface. The highest pressure is located in tool flank face near to tool tip and the pressure in tool-workpiece interface is much higher than that in tool-chip interface. Under the high cutting temperature and high pressure at tool-chip/workpiece interface, diffusion occurred both at tool rake an flank face in machining Ti6Al4V. Because of the higher temperature at tool rake face diffusion at tool rake face ia more sever than that at tool flank face.

Published

2013

8. Performance of Alloyed CVD-Coated and PVD-Coated Carbide Tools in Dry Machining Nickel Based Alloy Inconel718

Author

Yan Li Chang, Zhao Peng Hao, Rong Di Han, and Dong Gao

Subjects

Materials science, Metallurgy, Alloy, General Engineering, chemistry.chemical_element, Nickel based, engineering.material, Carbide, Nickel, Thermal conductivity, chemistry, Cutting force, engineering, Tool wear, Tin

Abstract

Nickel-based alloy Inconel718 is a difficult-to-cut material due to lower thermal conductivity, affinity to react with tool material, the cutting tools wear very rapidly due to the high cutting temperature and high cutting force. It is important to choose tool material reasonably. In this paper, cutting performance of the multi-layer CVD-coated (TiN/Al2O3/TiC) tool and PVD-coated (TiAlN) tool were evaluated by cutting temperature, cutting force, tool wear and tool life. The results showed that PVD-coated (TiAlN) tool was suitable for cutting Inconel718.

Published

2012

9. Study on Steady-State Temperature Field and Thermal Deformation for Permanent Magnet Synchronous Motorized Spindle

Author

Zhao Peng Hao, Sheng Dong Gao, and Yong Lu

Subjects

Engineering, Bearing (mechanical), business.product_category, Field (physics), business.industry, General Engineering, Base (geometry), Mechanical engineering, Finite element method, law.invention, Machine tool, law, Magnet, Thermal, Lubrication, business

Abstract

Motorized spindle thermal deformation is a major factor affecting the accuracy of high-speed machine tool, previous studies have focused on asynchronous motorized spindle, however, in this paper, permanent magnet synchronous motorized spindle is the research object. At first, the finite element model of thermal characteristics of motorized spindle is established base on its thermal characteristics analysis. The second, study on the distribution of the spindle steady-state temperature field, effect of spindle speed and bearing lubrication on thermal deformation of spindle. The results provide a strong theoretical basis for the design and use of spindle.

Published

2011

10. The Effect of Cut Tool Geometric Parameters on Tool Tear of Machining Nickel-Base GH4169 Super Alloys

Author

Dong Gao, Zhao Peng Hao, and Rong Di Han

Subjects

Materials science, Cutting tool, business.industry, Metallurgy, chemistry.chemical_element, General Medicine, Edge (geometry), Superalloy, Nickel, Rake angle, Thermal conductivity, Machining, chemistry, Aerospace, business

Abstract

Nickel-based super alloy GH4169 has been widely used in aerospace industry because of its good mechanical properties under high temperature. However, it is difficult to machine for its high strength, poor thermal conductivity and serious work-hardening. The effects of tool geometric parameters on tool life are studied by machining experiments using YG8 tools with different cutting edge angle in this paper. The tool with cutting edge angle 45°has longer tool life than 75°. The cutting experiments have been carried out using TiAlN (PVD) coated tools (AC520U) with different rake angle. It shows that the tool life with rake angle 9° were increased by 50% and 25% compared to tool with rake angle 3°and 6° when cutting speed is 30m/min. The tool with rake angle 9° is not suitable for cutting GH4169 when cutting speed is more than 35m/min. The results show that geometric parameter of cutting tool is one of the important factors affecting tool life.

Published

2010

11. Experimental Study on Thermostatic Cutting Nickel-Base Superalloy GH4169

Author

Rong Di Han, Zhao Peng Hao, and Dong Gao

Subjects

Superalloy, Thermal conductivity, Materials science, Cutting tool, Metallurgy, General Engineering, Empirical formula, Process (computing), Drilling, Tool wear, Carbide

Abstract

Nickel-base super alloy GH4169 is difficult to cutting and tool wear is very serious, because of its high strength, poor thermal conductivity, and serious work-hardening. In order to choose reasonable cutting parameters as to improve the processing efficiency, the cutting experiments were crarried out and the changes of workpiece material physical in cutting process were studied, and then thermostatic cutting method based on the longest distance is proposed in this paper. The best cutting temperature of carbide cutting tool YG8-GH4169 has been given. The experiments using diferent cutting parameters has proved the feasibility of thermostatic cutting method. Finally, the empirical formula of thermostatic cutting based on the cutting speed and feed rate is proposed, when using YG8 cutting GH4169.

Published

2010

12. Tribological characteristics and wear mechanism of cemented carbide tool in dry machining Ti-6Al-4V

Author

Jie Qiong Lin, Zhao Peng Hao, and Yi Hang Fan

Subjects

0209 industrial biotechnology, Materials science, Scanning electron microscope, Mechanical Engineering, Metallurgy, Titanium alloy, 02 engineering and technology, Tribology, 021001 nanoscience & nanotechnology, Industrial and Manufacturing Engineering, 020901 industrial engineering & automation, Lubricity, X-ray photoelectron spectroscopy, Machining, Mechanics of Materials, Cemented carbide, Tool wear, 0210 nano-technology, Safety, Risk, Reliability and Quality

Abstract

In dry machining titanium alloys, tool wear is serious and machining efficiency is very low due to its low thermal conductivity and high chemical activity. The uncoated cemented carbide tool was used for the experiments of turning titanium alloy Ti-6Al-4V. Based on analysing the tribological characteristic of tool-chip and tool-workpiece interface using FEM, a scanning electron microscopy (SEM) equipped with energy dispersive X-ray spectrometer (EDS) and X-ray photoelectron spectroscopy were used to analyse tool wear mechanism. The results showed that there existed great differences of the friction between tool-chip/workpiece interface and general friction. There existed serious adhesion, diffusion and oxidation at the tool-workpiece interface. There was an optimal cutting condition under which the equilibrium of oxidation wear and adhesion wear can be achieved, which made tool wear reduce.

Published

2017

13. Precision forming of the 3D curved structure parts in flexible multi-points 3D stretch-bending process.

Author

Song Gao, Ji-cai Liang, Yi Li, Zhao-peng Hao, Qi-han Li, Yi-hang Fan, and Ying-li Sun

Subjects

THREE-dimensional imaging, BENDING (Metalwork), LIGHTWEIGHT materials, ALUMINUM alloys, STRENGTH of materials, FINITE element method

Abstract

The lightweight aluminum 3D curved structure part has the characteristics of high structural strength, excellent aerodynamic performance, and flowing geometric shape. It is increasingly used in the fields of railway transportation, aerospace, and other high-end vehicle manufacture industry. However, with the increase of forming dimensions, as well as the large, thin-walled, complex forming features, it is urgent to study the precise plastic forming method for this kind of difficult-to-deform materials. Based on the new type of flexible multi-points 3D stretch-bending (3D FSB) process, the precision forming method for these hard-to-deform parts was studied in this paper. Extensive numerical simulations for the 3D FSB forming of the target parts have been performed by finite element methods. The simulation results show good agreement with the experiment results, and the max shape error of springback prediction is less than 0.3 mm. Then, based on the measured shape error of the 3D formed parts, an iterative overbending method for envelope surface of the multi-point die (MPD) is proposed to realize precise forming of the 3D curved structure parts. After four times adjustment of MPD, the simulation results show that the contour error is reduced from 1.01 to 0.06%, the maximum springback error changes from 30.16 to 1.66 mm. According to the adjustment parameters acquired in the optimization process, the actual experimental measured contour error is 0.05%, the maximum springback error is 1.41 mm, which achieved the forming requirements of the target parts and verified the effectiveness of the compensation method. [ABSTRACT FROM AUTHOR]

Published

2018

14. A FOURTH-ORDER COMPACT ADI SCHEME FOR TWO-DIMENSIONAL NONLINEAR SPACE FRACTIONAL SCHRÖDINGER EQUATION.

Author

XUAN ZHAO, ZHI-ZHONG SUN, and ZHAO-PENG HAO

Subjects

COMPACT operators, LINEAR operators, SCHRODINGER equation, PARTIAL differential equations, RIESZ spaces, LAPLACIAN operator

Abstract

In this paper, a novel compact operator is derived for the approximation of the Riesz derivative with order α ∈ (1, 2]. The compact operator is proved with fourth-order accuracy. Combining the compact operator in space discretization, a linearized difference scheme is proposed for a two-dimensional nonlinear space fractional Schrödinger equation. It is proved that the difference scheme is uniquely solvable, stable, and convergent with order O(τ² + h4), where τ is the time step size, h = max{h1, h2}, and h1, h2 are space grid sizes in the x direction and the y direction, respectively. Based on the linearized difference scheme, a compact alternating direction implicit scheme is presented and analyzed. Numerical results demonstrate that the compact operator does not bring in extra computational cost but improves the accuracy of the scheme greatly. [ABSTRACT FROM AUTHOR]

Published

2014