14 results on '"Wang, Zhenlong"'
Search Results
2. Influence of helical electrode and its structure on EDM small hole machining.
- Author
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Hu, Yizhou, Wang, Han, and Wang, Zhenlong
- Subjects
ELECTRIC metal-cutting ,HELICAL structure ,COMPUTATIONAL fluid dynamics ,MACHINING ,ELECTRIC dipole moments - Abstract
Although helical electrodes have been proven to improve the EDM (electrical discharge machining) speed of small holes, there are few studies on the morphological characteristics of the machined small holes and the influence of electrode structures. In this paper, the influence of the helical electrode structure on the machining effect is studied by the method of orthogonal experiment, and the internal mechanism of the influence of the helical electrode on the machining is explained by the method of CFD (computational fluid dynamics) simulation. The results show that the larger depth and width of the helical groove and the helix angle of 60° are beneficial to increase the machining speed and reduce the relative loss rate, and at the same time, avoid serious defects in the small hole morphology. These conclusions provide a valuable reference for future researchers to choose the reasonable structure of the helical electrode, which is of great significance. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
3. Complex Rotary Structures Machined by Micro-WEDM
- Author
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Guo Cheng, Wang Zhenlong, Gan Weimin, Chen Xiang, and Wang Yukui
- Subjects
0209 industrial biotechnology ,Engineering ,business.industry ,Process (computing) ,Mechanical engineering ,02 engineering and technology ,Structural engineering ,021001 nanoscience & nanotechnology ,020901 industrial engineering & automation ,Electrical discharge machining ,Machining ,Electrode ,Surface roughness ,General Earth and Planetary Sciences ,0210 nano-technology ,business ,General Environmental Science ,Voltage - Abstract
In this paper, a method of complex rotary structures machined by micro wire electrical discharge machining (micro-WEDM) is presented. A high-speed rotating spindle has been designed and installed to the self-developed precise micro-WEDM equipment with two axis to enable the processing of complex rotary structures. The feasibility of the device for machining rotary structures is verified by performing many preliminary experiments. Meanwhile, the effects of open voltage and revolving speed on material removing rate (MRR) and average surface roughness (Ra) are investigated. A multiple cutting method for micro ball-ended probe using micro-WEDM is proposed, which includes rough machining with high machining parameters and finish machining with low machining parameters. What's more, the reuse of the reciprocated fine wire electrode with 30 μm diameter was realized in both process steps. Ultimately, a typical experimental sample, micro ball-ended probe with 97.6 μm in diameter and 0.7 μm in Ra was successfully fabricated.
- Published
- 2016
- Full Text
- View/download PDF
4. Effects of Complexing Agent on Electrochemical Micro Machining of Stainless Steel
- Author
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Zhao Wan-sheng, Wang Zhenlong, Wang Yukui, and Chen Hui
- Subjects
Materials science ,Precipitation (chemistry) ,fungi ,Metallurgy ,General Medicine ,Electrolyte ,Electrochemical machining ,Electrochemistry ,Anode ,chemistry.chemical_compound ,chemistry ,Machining ,Electrode ,Hydroxide - Abstract
Problem statement: Electrochemical Machining (ECM) is a prospective technique in micro machining. The productions of work piece in ECM are precipitation of hydroxide, which will block the machining gap. To prevent the formation of hydroxide, acids were often used. To machining work piece which is not acid-resistant, acids are not suitable. Approach: This study is conducted to find the effects of complexing agent on Electrochemical Micro Machining (ECM) of stainless steel. Compared to acids, the complexing agent is non-toxic and non-corrosive. ECM of stainless steel by applying short pulses in sodium chlorate electrolyte added with complexing agent is researched. Ethylenediaminetetraacetic acid disodium salt (EDTA-Na2) is a kind of widely used complexing agent. The usage of EDTA-Na2 prevented the formation of hydroxide. On the other hand, without EDTA-Na2, the electrode was attached with precipitation of hydroxide and short circuit occurred frequently. Results: Experiments results indicated that EDTA-Na2 can avoid the short circuit and not increase the side gap of electrochemical machining. Conclusion: EDTA-Na2 can form complex compound with ions of anode and dissolved in electrolyte. It is a kind of effective complexing agent in electrochemical machining of stainless steel.
- Published
- 2010
5. Micro-EDM and micro-USM combined milling of ZrB2-SiC-graphite composite for 3D micro-cavities.
- Author
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Li, Huichao, Wang, Zhenlong, Wang, Yukui, Liu, Hongzheng, and Zhao, Zhaoxi
- Subjects
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MACHINING , *MILLING (Metalwork) , *GRAPHITE composites , *SURFACE topography , *SURFACE finishing - Abstract
The ZrB2-SiC-graphite composite is one of the most promising ceramics, which show significant potential in manufacturing parts served in ultra-high temperature. Micro-electrical discharge machining (micro-EDM) is an effective method in machining this conductive hard ceramic. However, the recast layer characterized by craters and micro-cracks is formed on the machined surface, resulting in poor surface quality. In this paper, micro-EDM and micro-ultrasonic machining (micro-USM) combined milling is proposed for manufacturing 3D micro-cavities in the ZrB2-SiC-graphite composite. The micro-cavity is firstly machined by micro-EDM milling, followed by micro-USM finish milling to remove the recast layer in the same system without changing the micro-tool. The machining performances are investigated with consideration of the surface topography and finishing depth. It is found that the more recast layer is removed when a higher ultrasonic amplitude, larger abrasive grain size, and lower tool feedrate are employed. Based on the preliminary experiments, the proper machining parameters are obtained and applied to the fabrication of micro-cavities. The machining results show that the surface quality is improved with the low surface roughness and absence of defect layer. Meanwhile, the high machining accuracy in the depth direction and processing efficiency are achieved. It is verified that the micro-EDM and micro-USM combined milling process is feasible for fabricating 3D micro-cavities in the ZrB2-SiC-graphite composite. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
6. Graded layer identification and open voltage adjustment for EDM process of Ni-Al2O3 FGMs.
- Author
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Liu, Hongzheng, Chi, Guanxin, Wang, Zhenlong, Wang, Yukui, and Li, Huichao
- Subjects
ELECTRIC potential measurement ,MACHINING ,WAVE analysis ,PARAMETER estimation ,SUPPORT vector machines - Abstract
Ni-Al
2 O3 functionally graded materials (FGMs) have become important for high-temperature applications due to a continuous change in graded layers. However, the manufacturing process of Ni-Al2 O3 FGMs with the traditional pulse power is a long process because the pulse power cannot real-timely adjust machining parameters to adapt the change of graded layers. This paper designed a real-time monitoring module and a parameter adjustment module, which can identify different graded layers and actively adjust machining parameters to adapt the change of graded layers. By means of the monitoring module, four major discharge states, normal, arc, insufficiency, and long pulse discharge state have been discriminated real-timely. The 70% Ni/30%Al2 O3 layer and 30% Ni/70%Al2 O3 layer have been distinguished based on the quantitative analysis of insufficiency and long pulse discharge waveforms. Multi-layers of Ni-Al2 O3 FGMs are machined to validate the machining performance of the parameter adjustment module. Experiment results demonstrate that by adjusting the open voltage, the machining efficiency of 30% Ni/70%Al2 O3 layer has been increased by six times, resulting in more time-efficient EDM process of Ni-Al2 O3 FGMs. [ABSTRACT FROM AUTHOR]- Published
- 2018
- Full Text
- View/download PDF
7. Experimental research on eliminating the stair-stepping effect of laminated 3D microelectrodes by micro-ECM.
- Author
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Lei, Jianguo, Wu, Xiaoyu, Wu, Bo, Xu, Bin, Jiang, Kai, Wang, Zhenlong, and Ruan, Shuangchen
- Subjects
MICROELECTRODES ,MACHINING ,SURFACES (Technology) ,DIFFUSION ,ELECTRODES - Abstract
With three-dimensional (3D) microelectrodes used to machine microcavities in microelectrical discharge machining (micro-EDM), the processing efficiency can be greatly improved. However, the surfaces of a laminated 3D microelectrode always have stair steps, which will be further copied to the machined surfaces of the microcavities, reducing the processed surface quality. To solve the problems, the paper proposed using layer-by-layer scanning microelectrochemical machining (micro-ECM) to eliminate the stair-stepping effect of the laminated 3D microelectrodes. First, wire electrical discharge machining (WEDM) was chosen to cut Cu foils for obtaining multilayer two-dimensional (2D) microstructures. Second, the multilayer 2D microstructures were applied to thermal diffusion bonding to form 3D microelectrode blanks. Then, the 3D microelectrode blanks were processed via layer-by-layer scanning micro-ECM to eliminate the stair steps on the surfaces. The influences of applied voltage, offset distance, and layer thickness on the elimination of the stair-stepping effect were investigated in details. Experimental results show that the stair steps on the laminated 3D microelectrode surfaces were eliminated obviously under 4.0 V applied voltage, 200 μm offset distance, and 20 μm layer thickness. Finally, the laminated 3D microelectrodes without stair steps on the surfaces were applied to micro-EDM to process microcavities. Two typical microcavities without the stair steps were obtained. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
8. Ultrasonic and electric discharge machining to deep and small hole on titanium alloy
- Author
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DI Shi-chun, Wang Zhenlong, Zhao Wan-sheng, Chi Guanxin, and Wei Hongyu
- Subjects
business.product_category ,Materials science ,Machinability ,Metallurgy ,Metals and Alloys ,Titanium alloy ,Industrial and Manufacturing Engineering ,Computer Science Applications ,Grinding ,Machine tool ,Electrical discharge machining ,Machining ,Modeling and Simulation ,Ceramics and Composites ,Electric discharge ,Ultrasonic sensor ,Composite material ,business - Abstract
Being a difficult-to-cut material, titanium alloy suffers poor machinability for most cutting process, let alone the drilling of small and deep holes using traditional machining methods. Although electric discharge machining (EDM) is suitable to handle titanium alloys, it is not ideal for small and deep holes due to titanium alloys’ low heating conductivity and high tenacity. This paper introduces ultrasonic vibration into micro-EDM and analyzes the effect of ultrasonic vibration on the EDM process. A four-axis EDM machine tool which combines ultrasonic and micro-EDM has been developed. A wire electric discharge grinding (WEDG) unit which can fabricate a micro-electrode on-line, as well as a measuring unit, is set up on this equipment. With a cylindrical tool electrode, made of hard carbide, which has high stiffness, a single-side notch was made along the electrode. Ultrasonic vibration is then introduced into the micro-EDM. Experiments have been carried out and results have shown that holes with a diameter of less than O0.2 mm and a depth/diameter ratio of more than 15 can be drilled steadily using this equipment and technology.
- Published
- 2002
9. Micro-EDM drilling of ZrB-SiC-graphite composite using micro sheet-cylinder tool electrode.
- Author
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Li, Huichao, Wang, Zhenlong, Wang, Yukui, Liu, Hongzheng, and Bai, Yufei
- Subjects
- *
GRAPHITE composites , *CARBON composites , *MATERIALS , *MACHINING , *MANUFACTURING processes - Abstract
The ZrB-SiC-graphite composite is a promising engineering material for ultra-high temperature applications. However, the fabrication of micro-hole in this ceramic composite is difficult due to the high hardness. This paper presents micro-electrical discharge machining (EDM) drilling of the ZrB-SiC-graphite composite using the micro sheet-cylinder tool electrode to improve the machining efficiency and quality of micro-hole. The micro-hole is firstly drilled by the sheet segment of electrode under the high capacitance, and then finish drilling is conducted using the cylinder segment of electrode under the low capacitance. The material removal rate, surface roughness, surface microcracks, debris, and material removal mechanisms are investigated. It is found that the material is removed by melting/evaporation and thermal spalling during micro-EDM of the ZrB-SiC-graphite composite, and the thermal spalling effect produces the large size irregular debris. The electrode with the sheet shape can significantly increase the machining efficiency compared with the electrode with the cylinder shape. Furthermore, the surface roughness is reduced in finish drilling with the low capacitance. The experiment results of micro-holes machined by the sheet-cylinder electrode demonstrate that the presented method can improve the machining efficiency, surface quality, and machining accuracy. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
10. Effect of technological parameters on the process performance of pure AlO layer of Ni-AlO FGMs by self-induced EDM.
- Author
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Liu, Hongzheng, Wang, Zhenlong, Wang, Yukui, and Li, Huichao
- Subjects
- *
ELECTRIC metal-cutting , *MACHINING , *METALLIC composites , *CERAMICS , *FUNCTIONALLY gradient materials - Abstract
Wire electric discharge machining (WEDM) and electrical discharge machining (EDM) promise to be effective and economical methods for the machining of metal matrix composites and conducting ceramic blanks. However, the machining process of Ni-AlO functionally graded materials (FGMs) is extremely difficult because the insulating ceramic layer cannot be machined directly by EDM. In this paper, the pure AlO layer has been machined by self-induced EDM, using the conductive layers of Ni-AlO FGMs to trigger the discharges in the insulating ceramic layer. Machining experiments have been performed to investigate the effects of discharge capacitance, pulse off-time, and charging resistance on the process performance of the pure AlO layer using RC-type pulse generator. From the experimental results, the discharge waveform of pure AlO layer includes long pulse discharge waveform, in addition to conventional normal discharge of conductive layers. The shape of long pulse discharge waveform can be changed by pulse off-time. The appropriate pulse off-time not only improves the stability of EDM but also increases the material removal rate (MRR). Moreover, it was observed that the MRR increases with increasing discharge capacitance and decreasing charging resistance. The surface roughness increases with increasing discharge capacitance. Finally, a small hole with a depth-diameter ratio of 5, little tapper is machined based on the experimental analysis. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
11. Electrical discharge machining of micro grooves using laminated disc electrodes made of Cu and Sn foils.
- Author
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Lei, Jianguo, Wu, Xiaoyu, Wang, Zhenlong, Xu, Bin, Zhu, Likuan, and Wu, Wen
- Subjects
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WORKPIECES , *ELECTRODES , *MACHINING , *MICROSTRUCTURE , *ALLOYS , *MATERIALS - Abstract
Tool electrode wear varying with different materials in electrical discharge machining (EDM) is unavoidable, thus inevitably reducing the machining quality and accuracy of microstructures. To convert this disadvantageous phenomenon into a beneficial process, the paper proposed a wear-variation EDM (WV-EDM) approach to fabricate a laminated disc electrode (LDE) with stable-shape micro channels on the outer edge surface; this electrode was subsequently used to machine micro grooves on workpieces by EDM. The WV-EDM formation of the LDE, the relationship between relative volume wear rate of the disc foils and the machining depth, and flow field distribution in the machining gap of the LDE during processing were investigated. The results show that the method proposed herein could reliably produce LDEs with stable micro channels on the outer edge surfaces that could subsequently be employed to continuously machine micro groove arrays with the same machining depth on the same material workpiece by EDM, and especially LDE reshaping was unnecessary. Additionally, the "pump effect" of the vortex, located in the flow field between micro channels on the LDE and workpiece, was beneficial for debris removal. Using the proposed method, micro groove arrays and columnar microstructures were successfully fabricated on Ti–6Al–4V alloy workpieces. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
12. Material removal mechanisms, processing characteristics and surface analysis of Cf-ZrB2-SiC in micro-EDM.
- Author
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Gong, Sirui, He, Xiaolong, Wang, Yukui, and Wang, Zhenlong
- Subjects
- *
SURFACE analysis , *ELECTRIC metal-cutting , *MACHINING , *COMPOSITE materials , *SURFACE roughness , *SURFACE morphology - Abstract
C f -ZrB 2 -SiC is a new composite material with excellent properties for making the next-generation aerospace component. This material is extremely difficult to removal by mechanical machining, and there is a lack of research on feasible secondary processing methods of this composite at present. Micro-EDM is not limited by material hardness, so it is very suitable for machining this material. In this paper, the Material removal mechanisms and processing characteristics of C f -ZrB 2 -SiC by micro-EDM is analyzed. The removal mechanism of composite materials is explored though the discharge crater morphology, and the single-discharge experiments of each phase materials with different medium and different energies are also carried out as a reference. Electrical discharge milling experiments of C f -ZrB 2 -SiC are performed to explore the medium on processing index, and found that the best surface quality and maximum processing efficiency can be realized in kerosene. An experiment with four factors (pulse width, voltage, peak current, capacitance) and three indexes (surface roughness, MRR, TWR) is designed to analyze the C f -ZrB 2 -SiC process characteristics of micro-EDM and the response surface diagram and second-order regression equation are obtained. Milling the C f -ZrB 2 -SiC by electrical discharge according to the optimal combination of surface roughness parameters deduced above, the as-machined surface is analyzed including the surface morphology by SEM, element content by EDS and the surface phase by XRD. The feasibility and advantages of micro-EDM on machining C f -ZrB 2 -SiC are prove. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
13. A CAD/CAM system for micro-ED-milling of small 3D freeform cavity
- Author
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Zhao, Wansheng, Yang, Yang, Wang, Zhenlong, and Zhang, Yong
- Subjects
- *
MANUFACTURING processes , *MACHINING , *COMPUTER integrated manufacturing systems , *INDUSTRIAL engineering - Abstract
Micro-electro discharge milling (micro-ED-milling) with simply shaped electrode is highly regarded as a capable approach of machining 3D micro-structure because of its special machining mechanism and the variety of machinable materials. However, a specific CAD/CAM system is needed for generating tool path and related machining process. Due to nature of machining mode and tool electrode geometry, some vestige always remains on the machined surface during ED-milling of 3D structure especially on the complex surface which cannot be expressed with normal equations. To solve the problems of residual vestige, a slicing strategy for micro-ED-milling is proposed. The way of the tool path generation and the algorithm for smoother surface are studied systemically. Meanwhile, with the way of isoparametric interpolation, the machined freeform surfaces of lamination are significantly improved. As a result, some typical 3D structures are machined for verification, including an embossment of a human face within a circular area of 1 mm in diameter. [Copyright &y& Elsevier]
- Published
- 2004
- Full Text
- View/download PDF
14. Fabrication of micro gear with intact tooth profile by micro wire electrical discharge machining.
- Author
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Wang, Yukui, Chen, Xiang, Dong, Shuliang, and Wang, Zhenlong
- Subjects
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FABRICATION (Manufacturing) , *GEARING machinery , *MACHINING , *GRAVITY , *ELECTRIC capacity - Abstract
Micro wire electrical discharge machining (micro-WEDM) provides a promising alternative for micro gear machining. However, the processing defect of non-intact tooth profile often appears due to the influence of micro gear gravity, flushing force and explosive force in micro-WEDM process. This paper presents a process change of micro-WEDM to achieve the precise fabrication of micro gear with intact tooth profile, i.e. firstly reserving a sharp corner on the gear teeth where the processing defect exists and then removing it by the second processing of micro-WEDM. The locating and clamping of the micro gear with sharp corner has been achieved using a novel self-centering flexible fixture. The machining error during the second processing is analyzed, and whilst the process datum is accurately determined. Appropriate processing parameters are obtained by performing preliminary experiments on X153CrMoV12 workpiece, indicating that high open voltage and discharge capacitance cause large kerf width, moderate reference voltage and feed rate lead to narrow kerf width. The static contact between the core jig of the fixture and the micro gear with sharp corner is theoretically analyzed using ABAQUS software and experimentally proved to be in good condition. To verify the feasibility and repeatability of the proposed approach, five micro gears with 10 gear number, 0.1 mm module and 2 mm tooth width are machined using 50 μm diameter wire electrode, exhibiting excellent conformity, machining error with less than 1.5 μm and surface roughness Ra with 0.9 μm. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
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