Your search keyword '"Wenzhe Zhang"' showing total 8 results

1. Organosiloxane-Modified Auricularia Polysaccharide (Si-AP): Improved High-Temperature Resistance and Lubrication Performance in WBDFs

Author

Fan Zhang, Yu Wang, Bo Wang, Yuan Geng, Xiaofeng Chang, Wenzhe Zhang, Yutong Li, and Wangyuan Zhang

Subjects

water-based drilling fluids, synthetic procedures and characterization, molecular diversity, high-temperature performance, organosiloxane-modified auricularia polysaccharide, Organic chemistry, QD241-441

Abstract

This study introduces a novel organosilicon-modified polysaccharide (Si-AP) synthesized via grafting and comprehensively evaluates its performance in water-based drilling fluids (WBDFs). The molecular structure of Si-AP was characterized using Fourier-transform infrared spectroscopy (FTIR) and 1H-NMR experiments. Thermalgravimetric analysis (TGA) confirmed the good thermal stability of Si-AP up to 235 °C. Si-AP significantly improves the rheological properties and fluid loss performance of WBDFs. With increasing Si-AP concentration, system viscosity increases, API filtration rate decreases, clay expansion is inhibited, and drilling cuttings hydration dispersion is suppressed, especially under high-temperature conditions. Additionally, mechanistic analysis indicates that the introduction of siloxane groups can effectively inhibit the thermal degradation of AP chains and enhance their high-temperature resistance. Si-AP can form a lubricating film by adsorbing on the surface of clay particles, improving mud cake quality, reducing the friction coefficient, and significantly enhancing the lubricating performance of WBDFs. Overall, Si-AP exhibits a higher temperature-resistance limit compared to AP and more effectively optimizes the lubrication, inhibition, and control of the filtration rate of WBDFs under high-temperature conditions. While meeting the requirements of drilling fluid systems under high temperatures, Si-AP also addresses environmental concerns and holds promise as an efficient solution for the exploitation of deep-seated oil and gas resources.

Published

2024

2. Preparation Method and Properties of Q235/5083 Composite Plate with 1060 Interlayer by Differential Temperature Rolling with Induction Heating

Author

Chao Yu, Wenzhe Zhang, Runwu Jiang, Yuhua Wu, and Hong Xiao

Subjects

steel/aluminum-alloy composite plates, rolling bonding, induction heating, bonding strength, Mining engineering. Metallurgy, TN1-997

Abstract

Due to their exceptional all-around performance, steel/aluminum-alloy composite plates have been frequently utilized in many different industries. However, when steel/aluminum-alloy composite plates are prepared by the rolling process, they will scarcely bond with high bonding strength under a lower reduction rate due to the inconsistent deformation the of steel/aluminum-alloy. Therefore, a method of adding a pure-aluminum interlayer by differential temperature rolling with induction heating was proposed to prepare steel/aluminum-alloy composite plates. The results showed that when the induction heating time was 10–18 s, the pure-aluminum interlayer became molten, and the temperature difference between the steel and aluminum alloy reached 350–500 °C. The interface shear strength of the composite plate reached more than 68 MPa under a 31% reduction rate. The shear fracture of the composite plate occurred in the pure-aluminum layer, and the steel/aluminum interface diffusion layer was 0.83–0.99 μm thick. There was no obvious compound formation at the bonding interface, however, the steel and aluminum alloy could not bond without the addition of an interlayer under the same conditions.

Published

2023

3. Dynamic Translational Landscape Revealed by Genome-Wide Ribosome Profiling under Drought and Heat Stress in Potato

Author

Hongju Jian, Shiqi Wen, Rongrong Liu, Wenzhe Zhang, Ziyan Li, Weixi Chen, Yonghong Zhou, Vadim Khassanov, Ahmed M. A. Mahmoud, Jichun Wang, and Dianqiu Lyu

Subjects

drought stress, heat stress, potato, ribosome profiling, upstream open reading frames, Botany, QK1-989

Abstract

The yield and quality of potatoes, an important staple crop, are seriously threatened by high temperature and drought stress. In order to deal with this adverse environment, plants have evolved a series of response mechanisms. However, the molecular mechanism of potato’s response to environmental changes at the translational level is still unclear. In this study, we performed transcriptome- and ribosome-profiling assays with potato seedlings growing under normal, drought, and high-temperature conditions to reveal the dynamic translational landscapes for the first time. The translational efficiency was significantly affected by drought and heat stress in potato. A relatively high correlation (0.88 and 0.82 for drought and heat stress, respectively) of the fold changes of gene expression was observed between the transcriptional level and translational level globally based on the ribosome-profiling and RNA-seq data. However, only 41.58% and 27.69% of the different expressed genes were shared by transcription and translation in drought and heat stress, respectively, suggesting that the transcription or translation process can be changed independently. In total, the translational efficiency of 151 (83 and 68 for drought and heat, respectively) genes was significantly changed. In addition, sequence features, including GC content, sequence length, and normalized minimal free energy, significantly affected the translational efficiencies of genes. In addition, 28,490 upstream open reading frames (uORFs) were detected on 6463 genes, with an average of 4.4 uORFs per gene and a median length of 100 bp. These uORFs significantly affected the translational efficiency of downstream major open reading frames (mORFs). These results provide new information and directions for analyzing the molecular regulatory network of potato seedlings in response to drought and heat stress.

Published

2023

4. Experimental and Numerical Study on Proppant Transport in a Complex Fracture System

Author

Zhaopeng Zhang, Shicheng Zhang, Xinfang Ma, Tiankui Guo, Wenzhe Zhang, and Yushi Zou

Subjects

slickwater fracturing, proppant transport, slot flow experiment, dense discrete phase method, Technology

Abstract

Slickwater fracturing can create complex fracture networks in shale. A uniform proppant distribution in the network is preferred. However, proppant transport mechanism in the fracture network is still uncertain, which restricts the optimization of sand addition schemes. In this study, slot flow experiments are conducted to analyze the proppant placement in the complex fracture system. Dense discrete phase method is used to track the particle trajectories to study the transport mechanism into the branch. The effects of the pumping rate, sand ratio, sand size, and branch angle and location are discussed in detail. Results demonstrate that: (1) under a low pumping rate or coarse proppant conditions, the dune development in the branch depends on the dune geometry in the primary fracture, and a high proportion of sand can transport into the branch; (2) using a high pumping rate or fine proppants is beneficial to the uniform placement in the fracture system; (3) sand ratio dominates the proppant placement in the branch and passing-intersection fraction of a primary fracture; (4) more proppants may settle in the near-inlet and large-angle branch due to the size limit. Decreasing the pumping rate can contribute to a uniform proppant distribution in the secondary fracture. This study provides some guidance for the optimization of proppant addition scheme in the slickwater fracturing in unconventional resources.

Published

2020

5. CoVSCode: A Novel Real-Time Collaborative Programming Environment for Lightweight IDE

Author

Hongfei Fan, Kun Li, Xiangzhen Li, Tianyou Song, Wenzhe Zhang, Yang Shi, and Bowen Du

Subjects

computer-supported cooperative work (cscw), collaborative computing, collaborative software development, real-time collaborative programming, software development environment, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Real-time collaborative programming is an emerging approach that supports a team of programmers to view and edit shared source code at the same time. Each programmer can edit any part of the source code, and changes become instantly visible at other collaborating sites. With a broad range of application scenarios and benefits, real-time collaborative programming has attracted increasing interest from academia and industry. Lightweight integrated development environments (lightweight IDEs) have rapidly grown in popularity in the recent years, but there are serious problems and limitations with existing real-time collaboration support for lightweight IDEs. In this study, we contribute a novel real-time collaborative programming environment named CoVSCode that supports unconstrained and flexible real-time collaboration based on Visual Studio Code, one of the most popular and widely used lightweight IDEs. We present design objectives and rationales, the workflow and functional design from collaborating programmers’ perspectives, major technical issues and solutions, and prototype implementation, as well as a set of experimental evaluations that have demonstrated the technical feasibility and good performance of the prototype system. All approaches, techniques and solutions derived in this work are generic, which can also be applied in building real-time collaborative programming environments for other lightweight IDEs.

Published

2019

6. Theoretical Prediction Method for Erosion Damage of Horizontal Pipe by Suspended Particles in Liquid–Solid Flows

Author

Guoqiang Liu, Wenzhe Zhang, Liang Zhang, and Jiarui Cheng

Subjects

0209 industrial biotechnology, Work (thermodynamics), Technology, Materials science, education, 02 engineering and technology, Liquid solid, Wall material, Article, Physics::Fluid Dynamics, 020901 industrial engineering & automation, 0203 mechanical engineering, Settling, horizontal pipe erosion, General Materials Science, erosion prediction model, liquid–solid suspension flow, Magnetosphere particle motion, Microscopy, QC120-168.85, Suspended particles, QH201-278.5, Mechanics, Engineering (General). Civil engineering (General), TK1-9971, Radial velocity, 020303 mechanical engineering & transports, Descriptive and experimental mechanics, Erosion, Electrical engineering. Electronics. Nuclear engineering, TA1-2040

Abstract

In order to study the erosion of a pipe wall via a liquid–solid suspension flow, a two-phase flow model combined with an erosion forecasting model for multiparticle impact on horizontal pipe wall surfaces was established in this work on the basis of low-cycle fatigue theory. In the model establishment process, the effects of particle motion and material damage were considered, and a simplified method for predicting horizontal wall erosion was obtained. The calculated results showed that the particles impact the wall at a small angle of most liquid flow velocities, causing cutting erosion damage of the wall. The settling velocity and fluctuating velocity of the particles together determine the radial velocity of the particles, which affects the impact angle of the particles. The cutting erosion caused by the small-angle impact of the particles in the pipe is more likely to cause rapid loss of the wall material. Therefore, the pipe wall is usually evenly thinned.

Published

2021

7. CoVSCode: A Novel Real-Time Collaborative Programming Environment for Lightweight IDE

Author

Wenzhe Zhang, Hongfei Fan, Kun Li, Bowen Du, Tianyou Song, Yang Shi, and Xiangzhen Li

Subjects

Source code, Computer science, media_common.quotation_subject, collaborative software development, 02 engineering and technology, lcsh:Technology, Set (abstract data type), lcsh:Chemistry, Design objective, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Programmer, Instrumentation, lcsh:QH301-705.5, media_common, Fluid Flow and Transfer Processes, real-time collaborative programming, software development environment, business.industry, lcsh:T, Process Chemistry and Technology, General Engineering, 020207 software engineering, Functional design, Microsoft Visual Studio, lcsh:QC1-999, Computer Science Applications, Technical feasibility, Workflow, collaborative computing, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, 020201 artificial intelligence & image processing, computer-supported cooperative work (cscw), Software engineering, business, lcsh:Engineering (General). Civil engineering (General), lcsh:Physics

Abstract

Real-time collaborative programming is an emerging approach that supports a team of programmers to view and edit shared source code at the same time. Each programmer can edit any part of the source code, and changes become instantly visible at other collaborating sites. With a broad range of application scenarios and benefits, real-time collaborative programming has attracted increasing interest from academia and industry. Lightweight integrated development environments (lightweight IDEs) have rapidly grown in popularity in the recent years, but there are serious problems and limitations with existing real-time collaboration support for lightweight IDEs. In this study, we contribute a novel real-time collaborative programming environment named CoVSCode that supports unconstrained and flexible real-time collaboration based on Visual Studio Code, one of the most popular and widely used lightweight IDEs. We present design objectives and rationales, the workflow and functional design from collaborating programmers&rsquo, perspectives, major technical issues and solutions, and prototype implementation, as well as a set of experimental evaluations that have demonstrated the technical feasibility and good performance of the prototype system. All approaches, techniques and solutions derived in this work are generic, which can also be applied in building real-time collaborative programming environments for other lightweight IDEs.

Published

2019

8. Experimental and Numerical Study on Proppant Transport in a Complex Fracture System

Author

Tiankui Guo, Wenzhe Zhang, Shicheng Zhang, Xinfang Ma, Zhang Zhaopeng, and Yushi Zou

Subjects

slickwater fracturing, proppant transport, slot flow experiment, dense discrete phase method, Control and Optimization, Flow (psychology), Energy Engineering and Power Technology, 02 engineering and technology, 010502 geochemistry & geophysics, lcsh:Technology, 01 natural sciences, 020401 chemical engineering, 0204 chemical engineering, Electrical and Electronic Engineering, Engineering (miscellaneous), 0105 earth and related environmental sciences, Petroleum engineering, lcsh:T, Renewable Energy, Sustainability and the Environment, Complex fracture, Grain size, Branch angle, Fracture (geology), Particle, Geology, Phase method, Energy (miscellaneous)

Abstract

Slickwater fracturing can create complex fracture networks in shale. A uniform proppant distribution in the network is preferred. However, proppant transport mechanism in the fracture network is still uncertain, which restricts the optimization of sand addition schemes. In this study, slot flow experiments are conducted to analyze the proppant placement in the complex fracture system. Dense discrete phase method is used to track the particle trajectories to study the transport mechanism into the branch. The effects of the pumping rate, sand ratio, sand size, and branch angle and location are discussed in detail. Results demonstrate that: (1) under a low pumping rate or coarse proppant conditions, the dune development in the branch depends on the dune geometry in the primary fracture, and a high proportion of sand can transport into the branch; (2) using a high pumping rate or fine proppants is beneficial to the uniform placement in the fracture system; (3) sand ratio dominates the proppant placement in the branch and passing-intersection fraction of a primary fracture; (4) more proppants may settle in the near-inlet and large-angle branch due to the size limit. Decreasing the pumping rate can contribute to a uniform proppant distribution in the secondary fracture. This study provides some guidance for the optimization of proppant addition scheme in the slickwater fracturing in unconventional resources.

Published

2020