Your search keyword '"Xingdong Sun"' showing total 29 results

1. Detection of Orchard Apples Using Improved YOLOv5s-GBR Model

Author

Xingdong Sun, Yukai Zheng, Delin Wu, and Yuhang Sui

Subjects

apple detection, GhostNetV2, bi-level routing spatial attention module (BRSAM), repulsion loss, YOLOv5s, Agriculture

Abstract

The key technology of automated apple harvesting is detecting apples quickly and accurately. The traditional detection methods of apple detection are often slow and inaccurate in unstructured orchards. Therefore, this article proposes an improved YOLOv5s-GBR model for orchard apple detection under complex natural conditions. First, the researchers collected photos of apples in their natural environments from different angles; then, we enhanced the dataset by changing the brightness, rotating the images, and adding noise. In the YOLOv5s network, the following modules were introduced to improve its performance: First, the YOLOv5s model’s backbone network was swapped out for the GhostNetV2 module. The goal of this improvement was to lessen the computational burden on the YOLOv5s algorithm while increasing the detection speed. Second, the bi-level routing spatial attention module (BRSAM), which combines spatial attention (SA) with bi-level routing attention (BRA), was used in this study. By strengthening the model’s capacity to extract important characteristics from the target, its generality and robustness were enhanced. Lastly, this research replaced the original bounding box loss function with a repulsion loss function to detect overlapping targets. This model performs better in detection, especially in situations involving occluded and overlapping targets. According to the test results, the YOLOv5s-GBR model improved the average precision by 4.1% and recall by 4.0% compared to those of the original YOLOv5s model, with an impressive detection accuracy of 98.20% at a frame rate of only 101.2 fps. The improved algorithm increases the recognition accuracy by 12.7%, 10.6%, 5.9%, 2.7%, 1.9%, 0.8%, 2.6%, and 5.3% compared to those of YOLOv5-lite-s, YOLOv5-lite-e, yolov4-tiny, YOLOv5m, YOLOv5l, YOLOv8s, Faster R-CNN, and SSD, respectively, and the YOLOv5s-GBR model can be used to accurately recognize overlapping or occluded apples, which can be subsequently deployed in picked robots to meet the realistic demand of real-time apple detection.

Published

2024

2. Type-II GaSe/MoS2 van der Waals Heterojunction for High-Performance Flexible Photodetector

Author

Shuai Wang, Xiaoqiu Tang, Ezimetjan Alim, Xingdong Sun, Zheng Wei, Hualong Tao, Yang Wen, Sumei Wu, Yongqing Cai, Yingying Wang, Yao Liang, and Zhihua Zhang

Subjects

type-II vdW heterojunction, GaSe, MoS2, flexible photodetector, Crystallography, QD901-999

Abstract

In recent years, two-dimensional (2D) type-II van der Waals (vdW) heterojunctions have emerged as promising candidates for high-performance photodetectors. However, direct experimental evidence confirming the enhancement of photoelectric properties by the heterojunction’s type and structure remains scarce. In this work, we present flexible photodetectors based on individual GaSe and MoS2, as well as a vertically stacked type-II GaSe/MoS2 vdW heterojunction on polyethylene terephthalate (PET) substrate. These devices demonstrate outstanding responsivities and rapid response speeds, ensuring stable and repeatable light detection. It is notable that the GaSe/MoS2 heterojunction photodetector exhibits the highest on-off ratio and fastest response speed, attributed to the formation of type-II band alignment. Furthermore, the GaSe/MoS2 heterojunction photodetector maintains robust stability even in a bent state, highlighting remarkable flexibility. This work exemplifies the type-II vdW heterojunctions in enhancing photoelectric properties through direct in-situ experimentation, laying the groundwork for practical applications of 2D flexible photodetectors.

Published

2023

3. Controllable Growth of Large-Scale Continuous ReS2 Atomic Layers

Author

Xingdong Sun, Ezimetjan Alim, Yang Wen, Sumei Wu, Yongqing Cai, Zheng Wei, Yingying Wang, Yao Liang, and Zhihua Zhang

Subjects

2D materials, ReS2, chemical vapor deposition, photodetector, optoelectronics, Crystallography, QD901-999

Abstract

In recent years, two-dimensional (2D) layered transition metal dichalcogenides (TMDs) have received significant attention due to their exceptional electrical and optical properties. Among these 2D materials, ReS2 distinguishes itself through its unique optical and conductance anisotropy. Despite concerted efforts to produce high-quality ReS2, the unique interlayer decoupling properties pose substantial challenges in growing large-area ReS2 thin films, with the preparation of single layers proving even more complex. In this work, large-scale continuous monolayer and bilayer ReS2 films were successfully grown on mica substrates using low-pressure chemical vapor deposition (LPCVD). Photodetectors were fabricated using the prepared high-quality ReS2 films, and the devices presented stable photoresponse and enhanced response sensitivity. The production of continuous ReS2 atomic layers heralds promising prospects for large-scale integrated circuits and advances the practical application of optoelectronics based on 2D layered materials.

Published

2023

4. Optimization design of negative pressure adsorption car for internal defect detection of wind turbine blades on UAV

Author

Xingdong Sun, Wandi Wu, Jie Wang, Liangyuan Xu, Rui Jiang, Yan Sun, and Liangfei Fang

Subjects

Physics, QC1-999

Abstract

The wind turbine blade is the core component of the wind turbine. However, wind turbine blades will suffer fatigue and internal crack defects, which seriously affect the safety service performance in harsh environments. The current detection mode is mainly traditional manual detection and shutdown maintenance, with high risk and low efficiency. Therefore, this research proposed a method to conduct a non-stop online inspection of the wind turbine blade’s internal defects using ultrasonic inspection mounted unmanned aerial vehicle. As the vital component of this inspection system, the optimized design of the negative pressure adsorption car was carried out. The structural characteristics of the negative pressure adsorption car were determined experimentally, followed by multivariate analysis and an integrated development and performance test study of the test system. Based on the test results, the detection rate of this test system for internal wind power blade faults is 100%. This research offers novel concepts of and theoretical insights into the intelligent and security identification of internal flaws in wind turbine blades.

Published

2023

5. Batch Production of Wafer-Scale Monolayer MoS2

Author

Zheng Wei, Xingdong Sun, Yongqing Cai, Yao Liang, and Zhihua Zhang

Subjects

two-dimensional materials, batch production, MoS2, oxygen doping, Crystallography, QD901-999

Abstract

Monolayer MoS2 has emerged as a highly promising candidate for next-generation electronics. However, the production of monolayer MoS2 with a high yield and low cost remains a challenge that impedes its practical application. Here, a significant breakthrough in the batch production of wafer-scale monolayer MoS2 via chemical vapor deposition is reported. Notably, a single preparation process enables the growth of multiple wafers simultaneously. The homogeneity and cleanliness of the entire wafer, as well as the consistency of different wafers within a batch, are demonstrated via morphology characterizations and spectroscopic measurements. Field-effect transistors fabricated using the grown MoS2 exhibit excellent electrical performances, confirming the high quality of the films obtained via this novel batch production method. Additionally, we successfully demonstrate the batch production of wafer-scale oxygen-doped MoS2 films via in situ oxygen doping. This work establishes a pathway towards mass preparation of two-dimensional materials and accelerates their development for diverse applications.

Published

2023

6. Mechanical response and in-situ deformation mechanism of cortical bone materials under combined compression and torsion loads

Author

Xingdong Sun, Wandi Wu, Renbo Zhang, Hongru Qu, Jie Wang, Ke Xu, Liangfei Fang, Liangyuan Xu, and Rui Jiang

Subjects

Medicine, Science

Abstract

Bone fracture is an extremely dangerous health risk to human. Actually, cortical bone is often subjected to the complicated loading patterns. The mechanical properties and deformation mechanism under the complicated loading pattern could provide a more precise understanding for the bone fracture. For this purpose, the mechanical response and multi-scale deformation mechanism of cortical bone material were investigated by in-situ experimental research using the compression-torsion coupling loads as an example. It was found that the torsion strength and shear modulus all decreased under the compression-torsion coupling loads than single torsion load. This indicated bone would suffer greater risk of fracture under the compression-torsion coupling loads. Based on in-situ observation, it was found that the rapid reduction of the anisotropy of bone material under the compression load was the potential influencing factor. Because of the redistribution of the principal strain and the variations of cracks propagation, the comprehensive fracture pattern containing both transverse and longitudinal fracture was shown under the coupling loads, and finally resulted in the reduction of the torsion properties. This research could provide new references for researches on mechanical properties of cortical bone material under complicated loading patterns.

Published

2022

7. Fracture Analysis of Compacted Clay Soil Beams with Offset Notches Based on Three-Point Bending Test: Experimental Characterization and Numerical Simulation

Author

Liangfei Fang, Chengmao Cao, Qing Li, Kuan Qin, Xingdong Sun, and Jun Ge

Subjects

Engineering (General). Civil engineering (General), TA1-2040

Abstract

The design and performance of tillage components such as subsoiler are generally characterized by the fracture features of soil mass in agricultural engineering, thus making the improvements of those tillage tools challenging due to the fact that the soil fracture mechanisms cannot be accurately explored and implemented. To alleviate this issue, in this paper, a physical three-point bending (TPB) test is conducted for investigating the fractural and fragmental characteristics of the compacted clay beams (CCB) with offset notches under the framework of mixed-mode I + II fracture, and the crack initiation as well as its propagation of the CCB is observed and fractural mechanisms of the CCB are discussed. Meanwhile, numerical simulation is also conducted utilizing two finite element methods, i.e., the extended finite element method (XFEM) and the combined finite-discrete element method (FDEM), for the CCB under three typical scenarios with notch offset ratios C = 0, C = 0.375, and C = 0.625, respectively. The authenticity and availability of both experimental test and numerical simulation are validated correspondingly. Results indicate the following: (1) The average peak load, the distance between the terminal crack point and the center line of the CCB, and the average displacement will be increased with increases of the offset ratio, while initial crack angle will be decreased with increases of the offset ratio. (2) The initial crack will be extended from the bottom center of the CCB rather than the offset notch when the offset ratio is higher than 0.717. (3) The crack propagation and its mechanical properties (e.g., load-displacement curves) predicted by numerical simulation match well with those obtained from the physical test.

Published

2022

8. Investigation of the mechanical response and deformation mechanism of cortical bone material under combined compression and bending loads

Author

Xingdong Sun, Ke Xu, Jie Wang, Liangyuan Xu, Liangfei Fang, Rui Jiang, and Yingchun Yang

Subjects

mechanical properties, cortical bone, deformation mechanism, combined loads, experiment, Materials of engineering and construction. Mechanics of materials, TA401-492, Chemical technology, TP1-1185

Abstract

Objective service load is the load pattern of cortical bone in practical conditions. The objective service load conditions of cortical bone are complicated, usually including two or more load patterns. The mechanical behavior and deformation mechanism of cortical bone material under coupling load pattern and single load pattern are diametrically different. However, nowadays, researches on the mechanical response of cortical bone have been heavily focused on the single load pattern, which couldn’t reveal the potential deformation mechanism accurately. For the purpose of obtaining the objective mechanical properties under complicated loading patterns, the mechanical response and deformation mechanism of bone material under compression-bending coupling load were investigated by in-situ test. The research shows that bending strength increased under the compression-bending coupling load than the single bending load. By in-situ observation, the variations of surface strain distribution and cracks directions were the potential reasons for the increase of the bending strength. It was found that the cracks changed from transverse fracture to integrated patterns with transverse fracture and longitudinal fracture. Larger fracture range and tortuous crack propagation increased the fracture energy dissipation, which led to an enlarged bending strength under the compression-bending coupling load. Through theoretical analysis and numerical calculation, the impeded effect to the increasing of bending deflection was dominant before the final fracture with the adding of the compression load. The numerical calculation result was consistent with the result of the experiment. This present work would provide new references to further studies on the mechanical behavior of cortical bone under complicated loading patterns.

Published

2022

9. Nanoindentation response of monocrystalline copper under various tensile pre-deformations via molecular dynamic simulations

Author

Lijia Li, Xingdong Sun, Yue Guo, Dan Zhao, Xiancheng Du, Hongwei Zhao, and Zhichao Ma

Subjects

Mechanical engineering and machinery, TJ1-1570

Abstract

The mechanical properties of a material can be positively or negatively affected by its applied or residual stress. In this article, a series of molecular dynamic simulations were adopted to investigate the nanoindentation response of monocrystalline copper under tensile pre-deformation. Nanoindentation simulation under stress-free condition was compared with those under pre-tension strain values of 1.2%, 2.4% and 3.6%. Load–displacement curves with hardness value and recovery rates of total work for nanoindentation based on various tensile pre-deformations were obtained and discussed. It indicated that tensile pre-deformations resulted in a higher potential energy in substrate and a lower external energy will be introduced to realize the same elastic or plastic deformation during indentation. Moreover, the evolution of interior defects during indentation was also observed and analysed. The results showed that tensile pre-strain can influence dislocation nucleation behaviour of material during indentation. This article proposed a special molecular dynamic simulation method to characterize the mechanical properties of the material under tensile pre-deformations via nanoindentation, which gives an effective approach to characterize residual stresses in micro- and nanoscale and will have promising application in mechanical characterization of Microelectro Mechanical Systems devices and structures. Further analysis based on experiments will be done in our further research work.

Published

2018

10. Influence and evolution mechanism of different sharpness contact forms to mechanical property of cortical bone by nanoindentation

Author

Xingdong Sun, Yue Guo, Lijia Li, Zeyang Liu, Di Wu, Dong Shi, Hongwei Zhao, and Shizhong Zhang

Subjects

Physics, QC1-999

Abstract

Based on different damage forms of various contact forms to bone, the mechanical response and mechanism were investigated by nanoindentation under different sharpness contact forms. For the purpose of simulating the different sharpness contact forms, two kinds of indenters were used in experiments and finite elements simulations. Through nanoindentation experiments, it was concluded that the residual depth of sharp indenter was bigger than that of blunt indenter with small penetration depth. However, the contrary law was obtained with bigger penetration depth. There was a turning point of transition from blunt tendency to sharp tendency. By calculation, it was concluded that the sharper the indenter was, the bigger the proportion of plastic energy in total energy was. Basically, results of finite elements simulation could correspond with the experimental conclusions. By the observation of FE-SEM, the surface of cortical bone compressed was more seriously directly below the blunt indenter than the lateral face. For the berkovich indenter, the surface of indentation compressed was less directly below the indenter, but seriously on three lateral faces. This research may provide some new references to the studies of bone fracture mechanism in different load patterns in the initial press-in stage and offer new explanation for bone trauma diagnosis in clinical treatment and criminal investigation.

Published

2018

11. Influences of organic component on mechanical property of cortical bone with different water content by nanoindentation

Author

Xingdong Sun, Lijia Li, Yue Guo, Hongwei Zhao, Shizhong Zhang, Yang Yu, Di Wu, Hang Liu, Miao Yu, Dong Shi, Zeyang Liu, Mingxing Zhou, Luquan Ren, and Lu Fu

Subjects

Physics, QC1-999

Abstract

The phenomenon that water in bone has important influences on mechanical properties of cortical bone has been known. However, the detail of the influence mechanism is not clear, especially in the component hierarchy. The main objective of this paper is to investigate the mechanical properties of deproteinization bone and cortical bone with different water content by nanoindentation experiments. The deproteinization bone is cortical bone removed organic component, and demineralization bone is cortical bone removed inorganic component. The experiments results showed that the elastic modulus and hardness all increased with the decreasing of water content in both cortical bone and deproteinization bone. However, variations of deproteinization bone were more significant than the normal one. Without organic component, the shape and size of inorganic component (hydroxyapatite particles) turned to irregular. The plastic energy of both cortical bone and deproteinization bone all decreased with the decreasing of water content and the variations range of deproteinization bone was wider than cortical bone. This research may give some deeply understanding for the studies of influence of water on mechanical properties of cortical bone.

Published

2018

12. Influence of scratch type on tensile strength in in situ tensile test

Author

Ning Li, Hongwei Zhao, Mingjun Jin, Jianping Li, Xiaohang Dai, Zhanwei Huo, Shunbo Wang, Liguo Yang, and Xingdong Sun

Subjects

Mechanical engineering and machinery, TJ1-1570

Abstract

In this article, the specimen of Q235 (low carbon steel, C ≤ 0.22%, Mn: 0.3%–0.8%, Si ≤ 0.3%, P ≤ 0.045%, S ≤ 0.05%) has been tested in in situ tensile tests. Especially, different types of scratches are prefabricated with 1, 2, and 3 µm in depth. In addition, three scratch angles ( θ = 0°, 45°, and 90°) are adopted to explore the changes of tensile strength. The cross profile of the scratch groove is measured with in situ observation method (Olympus DSX500), which is taken as an important indicator to verify the experiments. According to the results of experiments, scratch depth and angle can influence the tensile strength of material. When the depth and scratch angle increase, there is a decrement in the value of tensile strength. This indicates that the surface damage really has effect on the tensile strength of specimen.

Published

2017

13. Effects of Flotage on Immersion Indentation Results of Bone Tissue: An Investigation by Finite Element Analysis

Author

Mingxing Zhou, Zunqiang Fan, Zhichao Ma, Yue Guo, Liguo Yang, Long Qian, and Xingdong Sun

Subjects

Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

In reality, nanoindentation test is an efficient technique for probing the mechanical properties of biological tissue that soaked in the liquid media to keep the bioactivity. However, the effects of flotage imposed on the indenter will lead to inaccuracy when calculating mechanical properties (for instance, elastic modulus and hardness) by using depth-sensing nanoindentation. In this paper, the effects of flotage on the nanoindentation results of cortical bone were investigated by finite element analysis (FEA) simulation. Comparisons of nanoindentation simulation results of bone samples with and without being soaked in the liquid media were carried out. Conclusions show that the difference of load-displacement curves in the case of soaking sample and without soaking sample conditions varies widely based on the change of indentation depth. In other words, the nanoindentation measurements in liquid media will cause significant error in the calculated Young’s modules and hardness due to the flotage. By taking into account the effect of flotage, these errors are particularly important to the accurate biomechanics characterization of biological samples.

Published

2017

14. Variations of mechanical property of out circumferential lamellae in cortical bone along the radial by nanoindentation

Author

Xingdong Sun, Hongwei Zhao, Yang Yu, Shizhong Zhang, Zhichao Ma, Ning Li, Miao Yu, and Pengliang Hou

Subjects

Physics, QC1-999

Abstract

Because the out circumferential lamellae have a special protective effect on the cortical bone, it is very important to understand the variations of the mechanical property of the out circumferential lamellae in cortical bone. For the purpose, the elasticity modulus and hardness of out circumferential lamellae in cortical bone were investigated in two orthogonal planes by nanoindentation, and the comparisons were made for both elasticity modulus and hardness between the two orthogonal planes. From the experiments, the decreasing trend was discovered for elasticity modulus from inside to outside in the transverse plane and ruleless variations tendency was presented in the longitudinal plane. The hardness presented the same variations in two orthogonal planes with elasticity modulus in respective plane. In the same layer, the elasticity modulus in the transverse plane was higher than that in the longitudinal plane, and the difference values between them turned to be smaller. In contrast, the hardness in the longitudinal plane was higher than that in the transverse plane in all the layers. From the heterogeneity and the microstructure of the material, the influence factors were discussed. A soft to hard structure model was put forward, and the coordinating protection mechanism of buffer and support was described. Investigation of variations of mechanical properties of out circumferential lamellae in cortical bone can provide some new understanding in researches of fracture of bone, interface load effect and design of bone graft.

Published

2016

15. Investigation on the Material Removal and Surface Generation of a Single Crystal SiC Wafer by Ultrasonic Chemical Mechanical Polishing Combined with Ultrasonic Lapping

Author

Yong Hu, Dong Shi, Ye Hu, Hongwei Zhao, and Xingdong Sun

Subjects

single crystal SiC, material removal, surface generation, ultrasonic chemical mechanical polishing, ultrasonic lapping, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

A new method of ultrasonic chemical mechanical polishing (CMP) combined with ultrasonic lapping is introduced to improve the machining performance of carbide silicon (SiC). To fulfill the method, an ultrasonic assisted machining apparatus is designed and manufactured. Comparative experiments with and without ultrasonic assisted vibration are conducted. According to the experimental results, the material removal rate (MRR) and surface generation are investigated. The results show that both ultrasonic lapping and ultrasonic CMP can decrease the two-body abrasion and reduce the peak-to-valley (PV) value of surface roughness, the effect of ultrasonic in lapping can contribute to the higher MRR and better surface quality for the following CMP. The ultrasonic assisted vibration in CMP can promote the chemical reaction, increase the MRR and improve the surface quality. The combined ultrasonic CMP with ultrasonic lapping achieved the highest MRR of 1.057 μm/h and lowest PV value of 0.474 μm. Therefore this sequent ultrasonic assisted processing method can be used to improve the material removal rate and surface roughness for the single crystal SiC wafer.

Published

2018

16. Effects of Temperature and Strain Rate on the Fracture Behaviors of an Al-Zn-Mg-Cu Alloy

Author

Yue Guo, Mingxing Zhou, Xingdong Sun, Long Qian, Lijia Li, Yingjie Xie, Zeyang Liu, Di Wu, Liguo Yang, Tong Wu, Dan Zhao, Jinguo Wang, and Hongwei Zhao

Subjects

quasi-static tensile deformation, Al-Zn-Mg-Cu alloy, plastic deformation, fracture morphology, microstructure, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Effects of temperature and strain rate on the fracture behaviors of an Al-Zn-Mg-Cu alloy are investigated by isothermal uniaxial tensile experiments at a wide range of temperatures and strain rates, from room temperature (RT) to 400 °C and from 10−4 s−1 to 10−1 s–1, respectively. Generally, the elevation of temperature leads to the increasing of elongation to fracture and the reduction of peak stress, while higher strain rate results in the decreasing of elongation to fracture and the increasing of peak stress. Interestingly, we found that the coefficient of strain rate sensitivity (m-value) considerably rises at 200 °C and work of fracture (Wf) fluctuates drastically with the increase of strain rate at RT and 100 °C, both of which signify a non-uniform and unstable deformation state below 200 °C. A competition of work hardening (WH) and dynamic recrystallization (DRX) exists at 200 °C, making it serve as a transitional temperature. Below 200 °C, WH is the main deformation mechanism of flow stress, and DRX dominates the flow stress above 200 °C. It has been found that from RT to 200 °C, the main feature of microstructure is the generation of dimples and microvoids. Above 200 °C, the coalescence of dimples and microvoids mainly leads to the failure of specimen, while the phenomenon of typically equiaxed dimples and nucleation appear at 400 °C. The observations of microstructure are perfectly consistent with the related macroscopic results. The present work is able to provide a comprehensive understanding of flow stress of an Al-Zn-Mg-Cu alloy at a wide range of temperatures and strain rates, which will offer valuable information to the optimization of the hot forming process and structural design of the studied alloy.

Published

2018

17. Effects of different factors on the friction and wear mechanical properties of titanium alloy materials with cortical bones at near service conditions

Author

Xingdong, Sun, primary, Jianfei, Zhou, additional, Wandi, Wu, additional, Renbo, Zhang, additional, Liangyuan, Xu, additional, Chengmao, Cao, additional, Rui, Jiang, additional, and Liangfei, Fang, additional

Published

2023

18. Preparation of Micro-Iron Ore Tailings by Wet-Grinding and Its Application in Sulphoaluminate Cement

Author

Yingchun Yang, Xingdong Sun, Yuguang Mao, and Liqing Chen

Subjects

Cement, Materials science, Iron ore, Materials Science (miscellaneous), Wet grinding, Metallurgy, engineering, Environmental Science (miscellaneous), engineering.material, Tailings

Published

2022

19. Effects of different protein sources completely replacing fish meal in low‐protein diet on growth performance, intestinal digestive physiology, and nitrogen digestion and metabolism in nursery pigs

Author

De-Xing Hou, Xingdong Sun, Gaifeng Hou, Zehe Song, Xuxiang Xiang, Xi He, Cong Wu, Jianfei Zhao, Zhiyong Fan, and Rui Li

Subjects

Nitrogen, Swine, medicine.medical_treatment, Cottonseed, 03 medical and health sciences, Animal science, Fish meal, Pepsin, Low-protein diet, Fish Products, Diet, Protein-Restricted, medicine, Animals, 030304 developmental biology, 0303 health sciences, Meal, biology, Chemistry, 0402 animal and dairy science, 04 agricultural and veterinary sciences, General Medicine, 040201 dairy & animal science, Small intestine, Intestines, medicine.anatomical_structure, Digestive enzyme, biology.protein, Digestion, Dietary Proteins, General Agricultural and Biological Sciences

Abstract

The study compared the effects of selected proteins replacing fish meal in low-protein diets on piglets' growth performance, intestinal digestive physiology, and nitrogen digestion and metabolism. Five reduced CP, amino acid (AA)-supplemented diets containing 4% of either S50, HP300, concentrated degossypolized cottonseed protein (CDCP), P50, or fish meal were assigned to six pens with 11 pigs for a 28-day study period. Compared with fish meal, dietary proteins did not affect growth performance, apparent total tract digestibility (ATTD) of nutrients, serum hormone levels and biochemical parameters, apparent ileal digestibility (AID) of CP and most AA, colonic short-chain fatty acid (SCFA) contents, duodenal and ileal morphology, digestive enzyme activity, and pH in small intestine of piglets. However, HP300, CDCP, and P50 decreased (p < 0.05) fecal N excretion per weight gain. AID of Ile in S50 and HP300 and Glu in P50 were improved (p < 0.05), and AID of Gly in other proteins was reduced (p < 0.05). S50 and P50 lowered (p < 0.05) the contents of colonic isobutyric and isovaleric. S50 and HP300 reduced (p < 0.05) jejunal villus height. CDCP increased (p < 0.05) the pepsin activity in stomach. S50, HP300, and CDCP decreased (p < 0.05) pH in the proximal colon. Overall, the selected proteins could completely replace fish meal in low-protein diet without impairing piglets' growth via maintaining intestinal digestive physiology, and nitrogen digestion and metabolism.

Published

2019

20. In situ monitoring the properties of 20 carbon steel and ductile iron under combined tension and three-point bending loadings

Author

Hongwei Zhao, Hou Pengliang, Fuyuan Wang, Bo Zhu, Tongtong Xu, Li Cong, Hai Zhou, and Xingdong Sun

Subjects

Materials science, Microscope, Carbon steel, Three point flexural test, Mechanical Engineering, Metals and Alloys, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Finite element method, law.invention, 020303 mechanical engineering & transports, 0203 mechanical engineering, Flexural strength, Mechanics of Materials, law, Plastic bending, Deflection (engineering), Ductile iron, Materials Chemistry, engineering, Composite material, 0210 nano-technology

Abstract

This paper is concerned with the bending strength of the materials that is improved under the combined tension and three-point bending loadings. During the tension and three-point bending process, the whole evolution of metallographic structures of the specimens is in situ monitored by the microscope of in situ monitoring module. Moreover, a finite element analysis (FEA) model is established by using ABAQUS to analyze the distribution of stress, when the pre-tensile stress is different, but the deflection of the three-point bending is same, 3.0 mm. The simulation results are consistent with the experiment results. Therefore, it is clearly that the bending strength is increased with the increase of pre-tensile stress, when the bending load is 1750N every time. And the yield point of material is obviously disappeared under combined tension and three-point bending loadings. Meanwhile, the in situ metallographic images verify from the microscopic point of prospective that the bending strength of the material has been improved.

Published

2017

21. Effects of Flotage on Immersion Indentation Results of Bone Tissue: An Investigation by Finite Element Analysis

Author

Fan Zunqiang, Long Qian, Zhichao Ma, Mingxing Zhou, Liguo Yang, Xingdong Sun, and Yue Guo

Subjects

Materials science, Article Subject, 0206 medical engineering, General Engineering, Biomechanics, 02 engineering and technology, Nanoindentation, 021001 nanoscience & nanotechnology, Bone tissue, 020601 biomedical engineering, Finite element method, medicine.anatomical_structure, Indentation, lcsh:TA401-492, Immersion (virtual reality), medicine, lcsh:Materials of engineering and construction. Mechanics of materials, General Materials Science, Cortical bone, Composite material, 0210 nano-technology, Elastic modulus

Abstract

In reality, nanoindentation test is an efficient technique for probing the mechanical properties of biological tissue that soaked in the liquid media to keep the bioactivity. However, the effects of flotage imposed on the indenter will lead to inaccuracy when calculating mechanical properties (for instance, elastic modulus and hardness) by using depth-sensing nanoindentation. In this paper, the effects of flotage on the nanoindentation results of cortical bone were investigated by finite element analysis (FEA) simulation. Comparisons of nanoindentation simulation results of bone samples with and without being soaked in the liquid media were carried out. Conclusions show that the difference of load-displacement curves in the case of soaking sample and without soaking sample conditions varies widely based on the change of indentation depth. In other words, the nanoindentation measurements in liquid media will cause significant error in the calculated Young’s modules and hardness due to the flotage. By taking into account the effect of flotage, these errors are particularly important to the accurate biomechanics characterization of biological samples.

Published

2017

22. Investigation on the Material Removal and Surface Generation of a Single Crystal SiC Wafer by Ultrasonic Chemical Mechanical Polishing Combined with Ultrasonic Lapping

Author

Ye Hu, Dong Shi, Hongwei Zhao, Yong Hu, and Xingdong Sun

Subjects

0209 industrial biotechnology, Materials science, Abrasion (mechanical), 02 engineering and technology, lcsh:Technology, Article, single crystal SiC, 020901 industrial engineering & automation, Machining, Chemical-mechanical planarization, surface generation, Surface roughness, General Materials Science, Wafer, Composite material, lcsh:Microscopy, lcsh:QC120-168.85, lcsh:QH201-278.5, lcsh:T, material removal, ultrasonic lapping, ultrasonic chemical mechanical polishing, 021001 nanoscience & nanotechnology, Lapping, lcsh:TA1-2040, Ultrasonic sensor, lcsh:Descriptive and experimental mechanics, lcsh:Electrical engineering. Electronics. Nuclear engineering, 0210 nano-technology, lcsh:Engineering (General). Civil engineering (General), Single crystal, lcsh:TK1-9971

Abstract

A new method of ultrasonic chemical mechanical polishing (CMP) combined with ultrasonic lapping is introduced to improve the machining performance of carbide silicon (SiC). To fulfill the method, an ultrasonic assisted machining apparatus is designed and manufactured. Comparative experiments with and without ultrasonic assisted vibration are conducted. According to the experimental results, the material removal rate (MRR) and surface generation are investigated. The results show that both ultrasonic lapping and ultrasonic CMP can decrease the two-body abrasion and reduce the peak-to-valley (PV) value of surface roughness, the effect of ultrasonic in lapping can contribute to the higher MRR and better surface quality for the following CMP. The ultrasonic assisted vibration in CMP can promote the chemical reaction, increase the MRR and improve the surface quality. The combined ultrasonic CMP with ultrasonic lapping achieved the highest MRR of 1.057 &mu, m/h and lowest PV value of 0.474 &mu, m. Therefore this sequent ultrasonic assisted processing method can be used to improve the material removal rate and surface roughness for the single crystal SiC wafer.

Published

2018

23. Effects of Temperature and Strain Rate on the Fracture Behaviors of an Al-Zn-Mg-Cu Alloy

Author

Xie Yingjie, Hongwei Zhao, Long Qian, Jin-Guo Wang, Xingdong Sun, Zhou Mingxing, Liu Zeyang, Yue Guo, Wu Di, Dan Zhao, Lijia Li, Tong Wu, and Liguo Yang

Subjects

plastic deformation, Materials science, Al-Zn-Mg-Cu alloy, microstructure, 02 engineering and technology, Work hardening, Flow stress, lcsh:Technology, 01 natural sciences, Article, 0103 physical sciences, General Materials Science, Composite material, lcsh:Microscopy, lcsh:QC120-168.85, 010302 applied physics, quasi-static tensile deformation, lcsh:QH201-278.5, lcsh:T, Strain rate, 021001 nanoscience & nanotechnology, Microstructure, Deformation mechanism, lcsh:TA1-2040, Dynamic recrystallization, fracture morphology, lcsh:Descriptive and experimental mechanics, lcsh:Electrical engineering. Electronics. Nuclear engineering, Deformation (engineering), Elongation, lcsh:Engineering (General). Civil engineering (General), 0210 nano-technology, lcsh:TK1-9971

Abstract

Effects of temperature and strain rate on the fracture behaviors of an Al-Zn-Mg-Cu alloy are investigated by isothermal uniaxial tensile experiments at a wide range of temperatures and strain rates, from room temperature (RT) to 400 &deg, C and from 10&minus, 4 s&minus, 1 to 10&minus, 1 s&ndash, 1, respectively. Generally, the elevation of temperature leads to the increasing of elongation to fracture and the reduction of peak stress, while higher strain rate results in the decreasing of elongation to fracture and the increasing of peak stress. Interestingly, we found that the coefficient of strain rate sensitivity (m-value) considerably rises at 200 &deg, C and work of fracture (Wf) fluctuates drastically with the increase of strain rate at RT and 100 &deg, C, both of which signify a non-uniform and unstable deformation state below 200 &deg, C. A competition of work hardening (WH) and dynamic recrystallization (DRX) exists at 200 &deg, C, making it serve as a transitional temperature. Below 200 &deg, C, WH is the main deformation mechanism of flow stress, and DRX dominates the flow stress above 200 &deg, C. It has been found that from RT to 200 &deg, C, the main feature of microstructure is the generation of dimples and microvoids. Above 200 &deg, C, the coalescence of dimples and microvoids mainly leads to the failure of specimen, while the phenomenon of typically equiaxed dimples and nucleation appear at 400 &deg, C. The observations of microstructure are perfectly consistent with the related macroscopic results. The present work is able to provide a comprehensive understanding of flow stress of an Al-Zn-Mg-Cu alloy at a wide range of temperatures and strain rates, which will offer valuable information to the optimization of the hot forming process and structural design of the studied alloy.

Published

2018

24. ADE1Supplementary_Material – Supplemental material for Nanoindentation response of monocrystalline copper under various tensile pre-deformations via molecular dynamic simulations

Author

Lijia Li, Xingdong Sun, Guo, Yue, Zhao, Dan, Xiancheng Du, Hongwei Zhao, and Zhichao Ma

Subjects

FOS: Other engineering and technologies, 99999 Engineering not elsewhere classified

Abstract

Supplemental material, ADE1Supplementary_Material for Nanoindentation response of monocrystalline copper under various tensile pre-deformations via molecular dynamic simulations by Lijia Li, Xingdong Sun, Yue Guo, Dan Zhao, Xiancheng Du, Hongwei Zhao and Zhichao Ma in Advances in Mechanical Engineering

Published

2018

25. Influence and evolution mechanism of different sharpness contact forms to mechanical property of cortical bone by nanoindentation

Author

Hongwei Zhao, Yue Guo, Xingdong Sun, Dong Shi, Shizhong Zhang, Liu Zeyang, Wu Di, and Lijia Li

Subjects

Materials science, Biomechanics, General Physics and Astronomy, 02 engineering and technology, Bone fracture, Plasticity, Nanoindentation, 021001 nanoscience & nanotechnology, medicine.disease, lcsh:QC1-999, Finite element method, body regions, 020303 mechanical engineering & transports, medicine.anatomical_structure, 0203 mechanical engineering, Indentation, medicine, Cortical bone, Composite material, 0210 nano-technology, Penetration depth, lcsh:Physics

Abstract

Based on different damage forms of various contact forms to bone, the mechanical response and mechanism were investigated by nanoindentation under different sharpness contact forms. For the purpose of simulating the different sharpness contact forms, two kinds of indenters were used in experiments and finite elements simulations. Through nanoindentation experiments, it was concluded that the residual depth of sharp indenter was bigger than that of blunt indenter with small penetration depth. However, the contrary law was obtained with bigger penetration depth. There was a turning point of transition from blunt tendency to sharp tendency. By calculation, it was concluded that the sharper the indenter was, the bigger the proportion of plastic energy in total energy was. Basically, results of finite elements simulation could correspond with the experimental conclusions. By the observation of FE-SEM, the surface of cortical bone compressed was more seriously directly below the blunt indenter than the lateral face. For the berkovich indenter, the surface of indentation compressed was less directly below the indenter, but seriously on three lateral faces. This research may provide some new references to the studies of bone fracture mechanism in different load patterns in the initial press-in stage and offer new explanation for bone trauma diagnosis in clinical treatment and criminal investigation.

Published

2018

26. Influences of organic component on mechanical property of cortical bone with different water content by nanoindentation

Author

Lijia Li, Xingdong Sun, Mingxing Zhou, Yu Yang, Luquan Ren, Liu Hang, Yue Guo, Miao Yu, Lu Fu, Shizhong Zhang, Dong Shi, Di Wu, Hongwei Zhao, and Liu Zeyang

Subjects

Mechanical property, Chemistry, 0206 medical engineering, General Physics and Astronomy, 02 engineering and technology, Nanoindentation, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, lcsh:QC1-999, Demineralization, Plastic energy, medicine.anatomical_structure, medicine, Cortical bone, Organic component, 0210 nano-technology, Elastic modulus, Water content, lcsh:Physics, Biomedical engineering

Abstract

The phenomenon that water in bone has important influences on mechanical properties of cortical bone has been known. However, the detail of the influence mechanism is not clear, especially in the component hierarchy. The main objective of this paper is to investigate the mechanical properties of deproteinization bone and cortical bone with different water content by nanoindentation experiments. The deproteinization bone is cortical bone removed organic component, and demineralization bone is cortical bone removed inorganic component. The experiments results showed that the elastic modulus and hardness all increased with the decreasing of water content in both cortical bone and deproteinization bone. However, variations of deproteinization bone were more significant than the normal one. Without organic component, the shape and size of inorganic component (hydroxyapatite particles) turned to irregular. The plastic energy of both cortical bone and deproteinization bone all decreased with the decreasing of water content and the variations range of deproteinization bone was wider than cortical bone. This research may give some deeply understanding for the studies of influence of water on mechanical properties of cortical bone.

Published

2018

27. A DAMAGE MECHANISM OF MICRO-PARTICLES ON ARTICULAR CARTILAGE OF KNEE BY NANOINDENTATION

Author

Yuexi Zhong, Fan Zunqiang, Ren Luquan, Xingdong Sun, Shizhong Zhang, Hongwei Zhao, and Wu Di

Subjects

musculoskeletal diseases, 0301 basic medicine, Materials science, Micro particles, Biomedical Engineering, Articular cartilage, 02 engineering and technology, Nanoindentation, 021001 nanoscience & nanotechnology, 03 medical and health sciences, 030104 developmental biology, Plastic energy, 0210 nano-technology, Biomedical engineering

Abstract

Articular cartilage plays an important role in organism due to its excellent shock absorbing and buffering functions. Increasing problems about damages of articular cartilage are making a great deal of trouble to human beings. The damage mechanism of articular cartilage is very complicated and keeps unclear. In this research, the damage mechanism was investigated from the perspective of micro-particle attrition by nanoindentation experiments. The micro-particle was simulated by the indenter in experiments. The experimental results demonstrated that the load from micro-particle could not maintain when water content was adequate. However, the load could maintain and increase after dehydration. It was found that the partial surface of articular cartilage was crushed and adhered to the indenter. The plastic energy was bigger than elastic energy in the nanoindentation process. Therefore, water content was the crucial factor to protect the articular cartilage from damage. And the recurring partial dehydration owing to ongoing compression enhanced the damage of micro-particle to articular cartilage. This research may provide a new understanding to the damage mechanism of articular cartilage.

Published

2017

28. Influence of scratch type on tensile strength in in situ tensile test

Author

Jianping Li, Hongwei Zhao, Shunbo Wang, Ning Li, Huo Zhanwei, Liguo Yang, Xingdong Sun, Dai Xiaohang, and Jin Mingjun

Subjects

In situ, Materials science, Carbon steel, lcsh:Mechanical engineering and machinery, Mechanical Engineering, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, 020303 mechanical engineering & transports, Compressive strength, 0203 mechanical engineering, Scratch, Ultimate tensile strength, engineering, Forensic engineering, lcsh:TJ1-1570, Observation method, Composite material, 0210 nano-technology, computer, Groove (music), computer.programming_language, Tensile testing

Abstract

In this article, the specimen of Q235 (low carbon steel, C ≤ 0.22%, Mn: 0.3%–0.8%, Si ≤ 0.3%, P ≤ 0.045%, S ≤ 0.05%) has been tested in in situ tensile tests. Especially, different types of scratches are prefabricated with 1, 2, and 3 µm in depth. In addition, three scratch angles ( θ = 0°, 45°, and 90°) are adopted to explore the changes of tensile strength. The cross profile of the scratch groove is measured with in situ observation method (Olympus DSX500), which is taken as an important indicator to verify the experiments. According to the results of experiments, scratch depth and angle can influence the tensile strength of material. When the depth and scratch angle increase, there is a decrement in the value of tensile strength. This indicates that the surface damage really has effect on the tensile strength of specimen.

Published

2017

29. Variations of mechanical property of out circumferential lamellae in cortical bone along the radial by nanoindentation

Author

Ning Li, Pengliang Hou, Hongwei Zhao, Zhichao Ma, Yu Yang, Xingdong Sun, Miao Yu, and Shizhong Zhang

Subjects

Longitudinal plane, Mechanical property, Materials science, Plane (geometry), Quantitative Biology::Tissues and Organs, 0206 medical engineering, Biomechanics, General Physics and Astronomy, 02 engineering and technology, Nanoindentation, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, lcsh:QC1-999, Physics::Fluid Dynamics, Transverse plane, medicine.anatomical_structure, medicine, Cortical bone, Composite material, 0210 nano-technology, Elastic modulus, lcsh:Physics

Abstract

Because the out circumferential lamellae have a special protective effect on the cortical bone, it is very important to understand the variations of the mechanical property of the out circumferential lamellae in cortical bone. For the purpose, the elasticity modulus and hardness of out circumferential lamellae in cortical bone were investigated in two orthogonal planes by nanoindentation, and the comparisons were made for both elasticity modulus and hardness between the two orthogonal planes. From the experiments, the decreasing trend was discovered for elasticity modulus from inside to outside in the transverse plane and ruleless variations tendency was presented in the longitudinal plane. The hardness presented the same variations in two orthogonal planes with elasticity modulus in respective plane. In the same layer, the elasticity modulus in the transverse plane was higher than that in the longitudinal plane, and the difference values between them turned to be smaller. In contrast, the hardness in the longitudinal plane was higher than that in the transverse plane in all the layers. From the heterogeneity and the microstructure of the material, the influence factors were discussed. A soft to hard structure model was put forward, and the coordinating protection mechanism of buffer and support was described. Investigation of variations of mechanical properties of out circumferential lamellae in cortical bone can provide some new understanding in researches of fracture of bone, interface load effect and design of bone graft.

Published

2016