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1. An integrated preforming-performance model for high-fidelity performance analysis of cured woven composite part with non-orthogonal yarn angles

Author

Biao Liang, Weizhao Zhang, and Sasa Gao

Subjects
Materials science, Orientation (computer vision), business.industry, Mechanical Engineering, Constitutive equation, Process (computing), Aerospace Engineering, Yarn, Structural engineering, Compression (physics), Finite element method, visual_art, visual_art.visual_art_medium, Material properties, business, Failure mode and effects analysis
Abstract

Preforming process would change yarn angle and yarn orientation, its influence on the material properties and material orientations needs to be considered in the performance analysis. However, most current performance models fail to account for the preforming effect. An integrated performance model accounting for the impact of preforming has been developed in this research. In this integrated model, part geometry, yarn angle and orientation after preforming of multiple prepreg layers are predicted by Finite Element Analysis (FEA) using a non-orthogonal constitutive law. Experiments were conducted to validate the preforming simulation for a single dome composites structure made by two prepreg layers with different initial fiber orientations. Performance analysis until failure was then conducted for the single dome structure to validate the integrated performance model. Comparison between simulation and experiment shows that not only the failure mode and failure zone, but also the force-displacement curve during compression process are captured correctly by the performance model, demonstrating the effectiveness of the newly proposed model in accounting for the impact of preforming process.

Published
2022

3. Characterization and Finite Element Modeling for Thermoset Resin of Carbon Fiber Prepregs During Curing

Author

Yuncong Feng, Weike Zheng, Zizhao Zhao, Biao Liang, Haitao Ye, Qi Ge, Xiangyi Zhang, and Weizhao Zhang

Subjects
Control and Systems Engineering, Mechanical Engineering, Industrial and Manufacturing Engineering, Computer Science Applications
Abstract

In this study, an epoxy resin, YZ-05, designed specifically for carbon fiber reinforced polymer prepregs, was characterized and modeled. A degassing method for the highly viscous YZ-05 was established for specimen preparation. To numerically model the behavior of YZ-05 in curing, several components, including the heat transfer, curing kinetics, and viscoelastic constitutive law ones, were developed, and the corresponding material properties to be input were tested. As YZ-05 shows severe creep at high temperature under mechanical loading, the combination of digital image correlation (DIC) and thermography technique was utilized to obtain its thermal expansion and chemical shrinkage. In the aspects of viscoelastic behavior, stress relaxation tests were performed based on time–temperature superposition principle with a numerical method to calculate shift factors. After development and input identification, these modeling components for YZ-05 resin were integrated and the modeling results were validated using experiments, where bending of resin beams was induced during curing.

Published
2022

4. Analysis of the influence of yarn angle on the mechanical behaviors of cured woven composites

Author

Biao Liang, Sasa Gao, and Weizhao Zhang

Subjects
Potential impact, Materials science, Polymers and Plastics, Manufacturing process, Organic Chemistry, 02 engineering and technology, Yarn, 021001 nanoscience & nanotechnology, 020303 mechanical engineering & transports, 0203 mechanical engineering, visual_art, Materials Chemistry, visual_art.visual_art_medium, Composite material, 0210 nano-technology, Material properties
Abstract

Manufacturing process would modify the yarn angle of woven composites. To have a high-fidelity mechanical analysis, it is necessary to study its potential impact. In this article, experimental tests were specifically designed and conducted to investigate the influence of yarn angle on the mechanical behaviors of cured woven composites. The results show that yarn angle variation has a significant impact on the elastic modulus, Poisson’s ratio, and yield stress. The tensile deformation along yarn directions and shear deformation between two yarns were also investigated and their coupling with yarn angle variation was analyzed. It shows that when the yarn angle variation (from 90°) is less than 10°, the influence of the tension–shear coupling on the tensile behavior along yarn directions and shear behavior between two yarn directions is small and can be neglected. When the yarn angle variation is more than 20°, the influence of tension–shear coupling is significant and must be accounted for in constructing the constitutive law for the cured non-orthogonal woven composites.

Published
2020

5. Blank geometry design for carbon fiber reinforced plastic (CFRP) preforming using finite element analysis (FEA)

Author

Weizhao Zhang, Jiaying Gao, and Jian Cao

Subjects
0209 industrial biotechnology, Computer science, Process (computing), Geometry, 02 engineering and technology, Fibre-reinforced plastic, Blank, Industrial and Manufacturing Engineering, Finite element method, Process conditions, 020303 mechanical engineering & transports, 020901 industrial engineering & automation, 0203 mechanical engineering, Artificial Intelligence, Transportation industry, Trimming, Thermoforming
Abstract

Carbon fiber reinforced plastics (CFRPs) have attracted growing attention from transportation industry because of their superior performance over metal counterparts. The thermoforming process has been invented for mass-production of CFRP parts. This thermoforming process involves multiple steps and numerous parameters, and one of the most important process parameters is the initial blank geometry. To optimize blank geometry in thermoforming and minimize trimming work for the final part, an innovative approach integrating automatic mesh adjustment and FEA modeling method for preforming is developed as foundation of design and reported in this paper. Preliminary trial-and-error optimization algorithm demonstrates that this newly-developed approach can accurately design blank geometry under various typical process conditions.

Published
2020

7. Experimental study of water jet incremental micro-forming with supporting dies

Author

Weizhao Zhang, Jian Cao, Kornel F. Ehmann, and Yi Shi

Subjects
0209 industrial biotechnology, Materials science, business.product_category, Metals and Alloys, Process (computing), Shell (structure), Water jet, Mechanical engineering, 02 engineering and technology, Industrial and Manufacturing Engineering, Computer Science Applications, 020303 mechanical engineering & transports, 020901 industrial engineering & automation, 0203 mechanical engineering, Metal foil, Buckling, Modeling and Simulation, visual_art, Ceramics and Composites, visual_art.visual_art_medium, Die (manufacturing), business, Sheet metal
Abstract

Water Jet Incremental Micro-Forming (WJIMF) is a novel alternative to Single-Point Incremental Micro-Forming (SPIMF). Instead of using a rigid tool to form the sheet metal, a high-speed and high-pressure water jet is employed to induce plastic deformation. Dieless WJIMF has the capability to form a variety of shapes, but the total depth of the formed shape, which is affected by several process parameters, cannot be well controlled. To alleviate this problem, supporting dies can be used. This paper systematically studies the WJIMF process with several types of micro-machined supporting dies to produce micro-scale shell parts with designed geometries. It has been shown that the design of the toolpath has a profound impact on the final geometry of the part even with the same supporting die. The experimental results suggest that supporting dies with different geometries require unique toolpath strategies to achieve high geometric accuracy. Furthermore, it has been determined that water jet pressure plays an important role in the plastic deformation of the metal foil and that inappropriate combinations of toolpath and water jet pressure lead to buckling which is not found in macro-scale Water Jet Incremental Forming (WJIF). A numerical model in ABAQUS was developed to simulate the process and predict part geometry.

Published
2019

8. Rock fails in shearing as a tuned critical system

Author

Weizhao Zhang, Demeng Che, Zhiwei Zhu, and Kornel F. Ehmann

Subjects
Coalescence (physics), Shearing (physics), Nucleation, 010502 geochemistry & geophysics, Geotechnical Engineering and Engineering Geology, Rock breakage, 01 natural sciences, Quantitative measure, Critical system, 0103 physical sciences, Geotechnical engineering, 010306 general physics, Geology, 0105 earth and related environmental sciences
Abstract

Shearing is the most widely exploited method to fracture and remove rock formations in many man-made rock-opening activities. During shearing, rock breaks into chips due to the periodic nucleation, propagation, and coalescence of numerous micro-cracks . The crack interactions along with the rock's complex physical properties lead to extreme challenges in reaching a consensus on the rock's failure behavior in shearing. In this paper, force-drop events, as a quantitative measure of the global rock breakage occurrence, were recorded and analyzed. A power-law distribution with a tunable cut-off between the frequency of the force-drop events and their magnitudes is shown. The obtained results, for the first time, reveal the rock's tuned critical behavior in shearing which is intrinsically similar to its failure behavior widely observed in earthquakes.

Published
2018

10. Kham Dialect Speech Synthesis Based on Deep Learning

Author

Hongwu Yang, Xiaolong Bu, and Weizhao Zhang

Subjects
Artificial neural network, Computer science, business.industry, Deep learning, Speech recognition, Speech synthesis, Artificial intelligence, computer.software_genre, Hidden Markov model, business, computer
Abstract

In this paper, we constructed speech synthesis corpus of Kham dialect. At the same time, we designed SAMP-Kham machine-readable phonetic label of Kham dialect, and proposed a framework of Kham dialect speech synthesis based on deep learning. The deep learning architecture includes deep neural network (DNN), hybrid long short-term memory (LSTM) and hybrid Bidirectional long short-term memory (BLSTM). The objective and subjective evaluations test showed that quality of synthesized speech of Kham dialect was satisfied.

Published
2019

11. The Speech Synthesis of Yi Language Based on DNN

Author

Xiaolong Bu, Weizhao Zhang, and Hongwu Yang

Subjects
Set (abstract data type), Artificial neural network, Computer science, Speech recognition, Mean opinion score, Text segmentation, Decision tree, Speech synthesis, computer.software_genre, Hidden Markov model, Minority language, computer
Abstract

This paper is mainly about a speech synthesis system based on Deep Neural Network (DNN) model of Yi languages, a kind of minority language in china. The system is composed of relatively complete text analysis of Yi, model training and speech synthesis module. Especially in front-end, the word segmentation, pause handling, word-to-phoneme conversion and label processing are used to analysis text of Yi language. We designed the question set for decision tree of DNN model training and used vocoder: WORLD for synthesis. The system achieves a relatively good Mean Opinion Score (MOS) of 3.93 by Yi undergraduates as evaluators compared with a MOS of 4.58 of original speech. To investigate the factors affecting the quality of synthesized Yi speech, this paper also objectively evaluates the performance of different training set and DNN model. The system successfully synthesized Yi speech for the first time and synthesized speech is relatively good as the result of an only complete minority language speech synthesis system.

Published
2019

12. A non-orthogonal material model of woven composites in the preforming process

Author

Qiangsheng Zhao, Jeffrey Scott Dahl, Huaqing Ren, Xuming Su, Mansour Mirdamadi, Biao Liang, Jian Cao, Danielle Zeng, and Weizhao Zhang

Subjects
0209 industrial biotechnology, Materials science, Tension (physics), business.industry, Finite element software, Mechanical Engineering, Composite number, Process (computing), 02 engineering and technology, Bending, Structural engineering, Non orthogonal, 021001 nanoscience & nanotechnology, Compression (physics), Industrial and Manufacturing Engineering, Shear (sheet metal), 020901 industrial engineering & automation, Composite material, 0210 nano-technology, business
Abstract

Woven composites are considered as a promising material choice for lightweight applications. An improved non-orthogonal material model that can decouple the strong tension and weak shear behavior of the woven composite under large shear deformation is proposed for simulating the preforming of woven composites. The tension, shear and compression moduli in the model are calibrated using the tension, bias-extension and bending experiments, respectively. The interaction between the composite layers is characterized by a sliding test. The newly developed material model is implemented in the commercial finite element software LS-DYNA® and validated by a double dome study.

Published
2017

13. An Experimental and Numerical Study of Dieless Water Jet Incremental Microforming

Author

Weizhao Zhang, Jian Cao, Kornel F. Ehmann, and Yi Shi

Subjects
0209 industrial biotechnology, Materials science, Mechanical Engineering, Water jet, 02 engineering and technology, Mechanics, Deformation (meteorology), 021001 nanoscience & nanotechnology, Rotation, Industrial and Manufacturing Engineering, Computer Science Applications, 020901 industrial engineering & automation, Control and Systems Engineering, visual_art, visual_art.visual_art_medium, 0210 nano-technology, Sheet metal
Abstract

Conventional single-point incremental forming (SPIF) is already in use for small batch prototyping and fabrication of customized parts from thin sheet metal blanks by inducing plastic deformation with a rigid round-tip tool. The major advantages of the SPIF process are its high flexibility and die-free nature. In lieu of employing a rigid tool to incrementally form the sheet metal, a high-speed water jet as an alternative was proposed as the forming tool. Since there is no tool-workpiece contact in this process, unlike in the traditional SPIF process, no lubricant and rotational motion of the tool are required to reduce friction. However, the geometry of the part formed by water jet incremental microforming (WJIMF) will no longer be controlled by the motion of the rigid tool. On the contrary, process parameters such as water jet pressure, stage motion speed, water jet diameter, blank thickness, and tool path design will determine the final shape of the workpiece. This paper experimentally studies the influence of the above-mentioned key process parameters on the geometry of a truncated cone shape and on the corresponding surface quality. A numerical model is proposed to predict the shape of the truncated cone part after WJIMF with given input process parameters. The results prove that the formed part's geometric properties predicted by the numerical model are in excellent agreement with the actually measured ones. Arrays of miniature dots, channels, two-level truncated cones, and letters were also successfully fabricated on stainless-steel foils to demonstrate WJIMF capabilities.

Published
2019

14. A DNN-based emotional speech synthesis by speaker adaptation

Author

Hongwu Yang, Weizhao Zhang, and Pengpeng Zhi

Subjects
Artificial neural network, Computer science, Speech recognition, 020206 networking & telecommunications, Speech corpus, Speech synthesis, 02 engineering and technology, computer.software_genre, 030507 speech-language pathology & audiology, 03 medical and health sciences, Naturalness, 0202 electrical engineering, electronic engineering, information engineering, Objective test, 0305 other medical science, Set (psychology), Hidden Markov model, computer, Speaker adaptation
Abstract

The paper proposes a deep neural network (DNN)-based emotional speech synthesis method to improve the quality of synthesized emotional speech by speaker adaptation with a multi-speaker and multi-emotion speech corpus. Firstly, a text analyzer is employed to obtain the contextual labels from sentences while the WORLD vocoder is used to extract the acoustic features from corresponding speeches. Then a set of speaker-independent DNN average voice models are trained with the contextual labels and acoustic features of multi-emotion speech corpus. Finally, the speaker adaptation is adopted to train a set of speaker-dependent DNN voice models of target emotion with target emotional training speeches. The target emotional speech is synthesized by the speaker-dependent DNN voice models. Subjective evaluations show that comparing with the traditional hidden Markov model (HMM)-based method, the proposed method can achieve higher opinion scores. Objective tests demonstrate that the spectrum of the emotional speech synthesized by the proposed method is also closer to the original speech than that of the emotional speech synthesized by the HMM-based method. Therefore, the proposed method can improve the emotion express and naturalness of synthesized emotional speech.

Published
2018

15. Emotional speech synthesis based on DNN and PAD emotional state model

Author

Weizhao Zhang, Hongwu Yang, and Pengpeng Zhi

Subjects
Artificial neural network, Point (typography), Computer science, Speech recognition, 020206 networking & telecommunications, Speech corpus, Speech synthesis, 02 engineering and technology, computer.software_genre, PAD emotional state model, Correlation, 030507 speech-language pathology & audiology, 03 medical and health sciences, 0202 electrical engineering, electronic engineering, information engineering, Objective test, 0305 other medical science, Hidden Markov model, computer
Abstract

An emotional speech synthesis method based on deep neural network (DNN) and Pleasure-Arousal-Dominance (PAD) emotional state model is proposed. Firstly, the PAD model is used to annotate the emotional state of multi-speaker and multi-emotion speech corpus by calculating the distance between the marked emotional point of speech corpus and the typical emotional point. Secondly, the DNN-based emotional speech synthesis method is used to generate acoustic features. Thirdly, the prosodic features of synthesized emotion speech are modified by using PAD model. Finally, the target emotional speech is synthesized by vocoder. The subjective evaluation results show that comparing with hidden Markov model (HMM)-based and DNN-based method, the proposed method can achieve better performance. Objective tests also demonstrate that the spectrum of the emotional speech synthesized by the proposed method is much closer to the original speech.

Published
2018

16. Investigating the roles of fiber, resin, and stacking sequence on the low-velocity impact response of novel hybrid thermoplastic composites

Author

Logesh Shanmugam, Dong Lu, M. Shakouri, Jinglei Yang, Lei Yang, M.E. Kazemi, Z. Du, Y. Hu, J. Wang, Weizhao Zhang, and A. Dadashi

Subjects
chemistry.chemical_classification, Thermoplastic, Materials science, Mechanical Engineering, Stacking, Thermosetting polymer, 02 engineering and technology, Epoxy, Polyethylene, Plasticity, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Industrial and Manufacturing Engineering, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Mechanics of Materials, Deflection (engineering), Hybrid system, visual_art, Ceramics and Composites, visual_art.visual_art_medium, Composite material, 0210 nano-technology
Abstract

This study investigates the effects of fiber type, resin type, and stacking sequence on the dynamic response of fiber-reinforced polymer composite (FRPC) laminates under low-velocity impact (LVI) tests. Novel thermoplastic (TP) laminates are fabricated with a newly developed liquid methyl methacrylate thermoplastic resin, Elium® 188, at room temperature. FRPCs comprising woven ultra-high molecular weight polyethylene (UHMWPE) fabrics, woven carbon fabrics, and two different hybrid systems with alternative stacking sequences of those fibers are fabricated by the vacuum-assisted resin infusion (VARI) method. Besides, equivalent thermosetting-based (TS) composites with two epoxy systems are fabricated to compare the role of matrix type. Impact tests at different energy levels are performed on the TP and TS laminates to investigate the impact characteristics, namely contact force, deflection, energy attributes, structural integrity, and failure/damage modes. Besides, the mechanics of structure genome (MSG) and the commercial finite element code ABAQUS are used to verify the experimental results for one of the developed laminates. The results demonstrate that the hybrid system with UHMWPE fibers on the sides exhibits lower structural loss up to 47% and lower absorbed energy by 18% compared to those presented by the other type of hybrid system comprising carbon fabrics on the sides. Besides, it is found that the newly developed TP laminate underwent extended plasticity and presented a ductile behavior. The newly developed TP laminate demonstrated lower structural loss up to 200%, lower contact force by 14%, and lower absorbed energy by 48% compared to those of TS counterparts.

Published
2021

17. An Analytical Model for the Tension-Shear Coupling of Woven Fabrics with Different Weave Patterns under Large Shear Deformation

Author

Yongxiang Li, Weizhao Zhang, Yanchao Wang, Furong Geng, Zengyu Zhu, Zheng-Ming Huang, and Huaqing Ren

Subjects
Materials science, Composite number, 02 engineering and technology, Transverse compression, lcsh:Technology, lcsh:Chemistry, 0203 mechanical engineering, General Materials Science, shear deformation, Composite material, lcsh:QH301-705.5, Instrumentation, tension-shear coupling, Parametric statistics, Fluid Flow and Transfer Processes, lcsh:T, Process Chemistry and Technology, General Engineering, analytical model, Yarn, Material Design, fabrics, 021001 nanoscience & nanotechnology, lcsh:QC1-999, Computer Science::Other, Computer Science Applications, 020303 mechanical engineering & transports, lcsh:Biology (General), lcsh:QD1-999, Shear (geology), lcsh:TA1-2040, Inflection point, weave pattern, visual_art, visual_art.visual_art_medium, lcsh:Engineering (General). Civil engineering (General), 0210 nano-technology, lcsh:Physics
Abstract

It is essential to accurately describe the large shear behavior of woven fabrics in the composite preforming process. An analytical model is proposed to describe the shear behavior of fabrics with different weave patterns, in which tension-shear coupling is considered. The coupling is involved in two parts, the friction between overlapped yarns and the in-plane transverse compression between two parallel yarns. By introducing the concept of inflection points of a yarn, the model is applicable for fabrics with different weave patterns. The analytical model is validated by biaxial tension-shear experiments. A parametric study is conducted to investigate the effects of external load, yarn geometry, and weave structure on the large shear behavior of fabrics. The developed model can reveal the physical mechanism of tension-shear coupling of woven fabrics. Moreover, the model has a high computational efficiency due to its explicit expressions, thus benefiting the material design process.

Published
2020

18. Experimental Characterization and Numerical Modeling of the Interaction Between Carbon Fiber Composite Prepregs During a Preforming Process

Author

Mansour Mirdamadi, Qian Jane Wang, Xuan Ma, Weizhao Zhang, Zixuan Zhang, Xuming Su, Jie Lu, Jian Cao, and Danielle Zeng

Subjects
Materials science, Mechanical Engineering, Numerical modeling, Compression molding, 02 engineering and technology, 021001 nanoscience & nanotechnology, Industrial and Manufacturing Engineering, Finite element method, Computer Science Applications, Molding (decorative), Characterization (materials science), 020303 mechanical engineering & transports, Carbon fiber composite, 0203 mechanical engineering, Control and Systems Engineering, Scientific method, Composite material, 0210 nano-technology, Friction test
Abstract

Carbon fiber reinforced composites have received growing attention because of their superior performance and high potential for lightweight systems. An economic method to manufacture the parts made of these composites is a sequence of forming followed by a compression molding. The first step in this sequence is called preforming that forms the prepreg, which is the fabric impregnated with the uncured resin, to the product geometry, while the molding process cures the resin. Slip between different prepreg layers is observed in the preforming step, and it is believed to have a non-negligible impact on the resulting geometry. This paper reports a method to characterize the interaction between different prepreg layers, which should be valuable for future predictive modeling and design optimization. An experimental device was built to evaluate the interactions with respect to various industrial production conditions. The experimental results were analyzed for an in-depth understanding about how temperature, relative sliding speed, and fiber orientation affect the tangential interaction between two prepreg layers. Moreover, a hydro-lubricant model was introduced to study the relative motion mechanism of this fabric-resin-fabric system, and the results agreed well with the experiment data. The interaction factors obtained from this research will be implemented in a preforming process finite element simulation model.

Published
2018

20. Experimental Characterization of the Interaction Between Carbon Fiber Composite Prepregs During the Preforming Process

Author

Xuming Su, Jie Lu, Jian Cao, Zixuan Zhang, Mansour Mirdamadi, Q. Jane Wang, Weizhao Zhang, and Danielle Zeng

Subjects
Carbon fiber composite, Materials science, Scientific method, Molding (process), Composite material, Characterization (materials science)
Abstract

Carbon fiber composites have received growing attention because of their high performance. One economic method to manufacturing the composite parts is the sequence of forming followed by the compression molding process. In this sequence, the preforming procedure forms the prepreg, which is the composite with the uncured resin, to the product geometry while the molding process cures the resin. Slip between different prepreg layers is observed in the preforming step and this paper reports a method to characterize the properties of the interaction between different prepreg layers, which is critical to predictive modeling and design optimization. An experimental setup was established to evaluate the interactions at various industrial production conditions. The experimental results were analyzed for an in-depth understanding about how the temperature, the relative sliding speed, and the fiber orientation affect the tangential interaction between two prepreg layers. The interaction factors measured from these experiments will be implemented in the computational preforming program.

Published
2017

21. Multi-scale modeling of mechanical behavior of cured woven textile composites accounting for the influence of yarn angle variation

Author

Wing Kam Liu, Jian Cao, Biao Liang, Xuming Su, Yi Shi, Jiaying Gao, Danielle Zeng, Joel S. Fenner, and Weizhao Zhang

Subjects
Materials science, Structure analysis, business.industry, Constitutive equation, Accounting, 02 engineering and technology, Yarn, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Mechanics of Materials, visual_art, Ceramics and Composites, visual_art.visual_art_medium, Textile composite, Composite material, 0210 nano-technology, Material properties, business, Scale model
Abstract

In most current works related to the structure analysis of cured woven composites, the influence of yarn angle variation on the local material properties is neglected. In this paper, its influence was studied, and an integrated preforming-performance simulation model, accounting for the influence of yarn angle variation, was proposed. The multi-scale modeling approach was adopted to predict the material properties of cured woven composites with different yarn angles. The results were compared with experiments to validate its effectiveness. In the integrated preforming-performance simulation model, non-orthogonal constitutive law was used in the preforming simulation to compute yarn orientations and yarn angle distribution. To demonstrate the capabilities of the integrated simulation model, simulations were conducted and compared with experiments. The results show that the proposed simulation model has more accurate prediction than the simulation model without considering the influence of yarn angle, and the impact of yarn angle shouldn’t be neglected.

Published
2019

22. Chip Formation and Force Responses in Linear Rock Cutting: An Experimental Study

Author

Kornel F. Ehmann, Demeng Che, and Weizhao Zhang

Subjects
Mechanical Engineering, Chip formation, Metallurgy, 0211 other engineering and technologies, Mechanical engineering, 02 engineering and technology, 010502 geochemistry & geophysics, 01 natural sciences, Industrial and Manufacturing Engineering, Rock cutting, Computer Science Applications, Control and Systems Engineering, Geology, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences
Abstract

Polycrystalline diamond compact (PDC) cutters, as a major cutting tool, have been widely applied in oil and gas drilling processes. The understanding of the complex interactions at the rock and cutter interfaces is essential for the advancement of future drilling technologies; yet, these interactions are still not fully understood. Linear cutting of rock, among all the testing methods, avoids the geometric and process complexities and offers the most straightforward way to reveal the intrinsic mechanisms of rock cutting. Therefore, this paper presents an experimental study of the cutter’s cutting performance and the rock’s failure behaviors on a newly developed linear rock cutting facility. A series of rock cutting tests were designed and performed. The acquired experimental data was analyzed to investigate the influences of process parameters and the rock’s mechanical properties on chip formation and force responses.

Published
2016

23. Rock Cutter Interactions in Linear Rock Cutting

Author

Kornel F. Ehmann, Demeng Che, and Weizhao Zhang

Subjects
Engineering, Cutting tool, business.industry, Chip formation, Process (computing), Mechanical engineering, Drilling, Geotechnical engineering, Process variable, business, Polycrystalline diamond, Rock cutting
Abstract

Polycrystalline diamond compact (PDC) cutter, as a major cutting tool, has been widely applied in oil and gas drilling processes. The understanding of the complex interactions at the rock and cutter interfaces are essential for the advancement of future drilling technologies, yet, these interactions are still not fully understood. Linear cutting of rock, among all the testing methods, avoids the geometric and process complexities and offer the most straightforward way to reveal the intrinsic mechanisms of rock cutting. Therefore, this paper presents an experimental study of the cutter’s cutting performance and the rock’s failure behaviors on a newly developed linear rock cutting facility. A series of rock cutting tests were designed and performed. The acquired experimental data was analyzed to investigate the influences of process parameter and the rock’s mechanical properties on chip formation and force responses.Copyright © 2016 by ASME

Published
2016

24. Design of ECG Signal Acquisition System Based on DSP

Author

Jing Feng, Weizhao Zhang, Shengqian Ma, Dan Zhao, Manhong Fan, and Kening Wang

Subjects
Engineering, Digital signal processor, business.industry, Small volume, Human heart, General Medicine, Filter (signal processing), Field (computer science), Power consumption, Electronic engineering, ComputerSystemsOrganization_SPECIAL-PURPOSEANDAPPLICATION-BASEDSYSTEMS, Ecg signal, business, DSP, ECG signal, Filter, Data collectionl, Computer hardware, Digital signal processing, Engineering(all)
Abstract

A real-time ECG signal acquisition system with the DSP chip TMS320VC5509A as its core is introduced in this paper. It introduces the design of ECG signal acquisition circuit in detail. ECG signal is analog filtered and amplified and then converted from analog to digital field. Finally, it is displayed in the LCD after digital low-pass filtering in DSP. The collected ECG data can truly reflect the condition of human heart's health. The system has advantages of small volume, little power consumption, low cost and real-time processing

Published
2012
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25. Design of the Self-Tracking Filter Based on Frequency to Voltage Conversion

Author

Xingping Ran, Shengqian Ma, Juanfang Liu, and Weizhao Zhang

Subjects
Physics, Voltage-controlled filter, Filter design, Frequency multiplier, Low-pass filter, Electronic engineering, Butterworth filter, High-pass filter, Active filter, All-pass filter
Abstract

In order to make cutoff frequency of filter that can be changed automatically with the time-varying signal, this chapter presents a new self-tracking filter structure which is based on frequency to voltage conversion. Input signal is converted into voltage signal through the F/V circuit. The output voltage of F/V is used to control cutoff frequency of the filter which is constituted of analog multiplier MLT04, current feedback amplifier AD844, a few resistors and capacitors. The design principle is introduced in detail, the design formulas are derived, and the circuit of self-tracking one-order low-pass and high-pass filter are given. When the input signal’s frequency is in the range of 10–100 kHz, the simulated and measured results show the effectiveness of this new method. The cutoff frequency of the filter can be adjusted automatically by the voltage which is proportional to frequency of input signal. So it realizes the frequency self-tracking.

Published
2013

26. XML Query Algorithm Based on Matching Pretreatment Optimization

Author

Heming Ye, Weizhao Zhang, Yi Wang, and Haixia Ma

Subjects
Matching (statistics), computer.internet_protocol, Computer science, Node (networking), Response time, Scale (descriptive set theory), Function (mathematics), computer.software_genre, Tree (data structure), Data mining, computer, Algorithm, XML, Scope (computer science)
Abstract

In the XML query algorithm based on matching pretreatment, three important existing tree matching models are used and the match results of data sets are presented according to the match cost in a descending order. The function of matching pretreatment is added to improve the existing algorithm, and a series of experiments are conducted. The results show that this algorithm can remove the unwanted node in the tree to promote the efficiency of data sets retrieval especially the recall ratio, the precision ratio and the average response time, when the data scale is quite large. This algorithm is applied in the unity retrieval system of scientific and technological resources database. It can facilitate the navigation of resources, narrow the search scope and promote the efficiency of this system.

Published
2011

27. Multiscale modeling of Carbon Fiber Reinforced Polymer (CFRP) for integrated computational materials engineering process

Author

Biao Liang, Weizhao Zhang, Wei Chen, Jiaying Gao, Ramin Bostanabad, Jian Cao, Puikei Cheng, Xuming Su, Wing Kam Liu, Zeliang Liu, Danielle Zeng, and John Zhao

Subjects
Carbon fiber reinforced polymer, Materials science, Integrated computational materials engineering, Scale (ratio), Process (engineering), Mesoscale meteorology, Mechanical engineering, Multiscale modeling, Nanoscopic scale, Microscale chemistry
Abstract

In this work, a multiscale modeling framework for CFRP is introduced to study hierarchical structure of CFRP. Four distinct scales are defined: nanoscale, microscale, mesoscale, and macroscale. Information at lower scales can be passed to higher scale, which is beneficial for studying effect of constituents on macroscale part’s mechanical property. This bottom-up modeling approach enables better understanding of CFRP from finest details. Current study focuses on microscale and mesoscale.

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