Your search keyword '"Lu, Yuanbo"' showing total 9 results

1. The use of coal gangue as a planting substrate in arid mining areas

Author

Lu, Yuanbo, Song, Chunwu, Yan, Cheng, Jin, Zhengzhong, Li, Yajuan, Lai, Chengyun, and Wang, Danhua

Published

2024

2. Review of sewage flow measuring instruments

Author

Sun, Bin, Chen, Shizhe, Liu, Quan, Lu, Yuanbo, Zhang, Chao, and Fang, Hongyuan

Published

2021

3. Study of ablation phase in double-wire Z-pinch based on optical Thomson scattering.

Author

Wang, Wei, Wu, Jian, Jiang, Zhiyuan, Lu, Yuanbo, Wang, Zhenyu, Zhao, Yiming, Shi, Huantong, Chen, Li, Li, Xingwen, and Qiu, Aici

Subjects

LIGHT scattering, THOMSON scattering, MAGNETIC fields, WIRE, ELECTRON temperature

Abstract

Measurement of plasma parameters during the ablation phase in the Z-pinch is crucial for investigating the dynamic behaviors. In this study, optical Thomson scattering was employed to measure the temperature and velocity of the ablation plasma in a double-wire Z-pinch. The scattering spectra profiles were fitted using a model that considered the velocity distribution. The experimental results revealed the energy evolution of ablation plasma, the establishment of the global magnetic field and the development of axial non-uniformities. The precursor plasma was found to play a key role in strengthening the global magnetic field. A resistive layer near the wire core with a size of 1.5 mm was observed in the ablation plasma after the precursor plasma column formed. The plasma underwent rapid heating in this layer, the electron temperature rises from 17 eV to 22 eV. Upon leaving this layer, electron the temperature is stable at around 22 eV. The radial distribution of the ablation rate increases and decreases, indicating the axial motion of the ablation plasma, which could be caused by the tilt motion of the stream and the secondary modulation of the natural wavelength. [ABSTRACT FROM AUTHOR]

Published

2024

4. Spatiotemporal Changes in and Driving Factors of Potential Evapotranspiration in a Hyper-Arid Locale in the Hami Region, China.

Author

Lu, Yuanbo, Sun, Lingxiao, Li, Chunlan, He, Jing, Guo, Zengkun, Duan, Li, Zhang, Jing, Łupikasza, Ewa, Malik, Ireneusz, Wistuba, Małgorzata, and Yu, Yang

Subjects

*EVAPOTRANSPIRATION, *WATER supply, *IRRIGATION management, *IRRIGATION water, *SPRING, *GLOBAL warming

Abstract

Potential evapotranspiration (PET) is a crucial variable for implementing adaptation measures to mitigate the potential impacts of climate change on water resources. In the context of global warming, PET is essential for predicting water resource supply and demand, guiding irrigation and water management decisions. However, there is limited understanding of the spatiotemporal changes in PET and its driving factors in the hyper-arid regions of Northwest China. In this study, the Hargreaves model was employed to estimate PET in the Hami region from 1991 to 2020. By combining relevant climate data and partial correlation analysis, we investigated the spatiotemporal distribution patterns of PET within the study area and analyzed the factors influencing these patterns. The results showed the following: (1) From 1991 to 2020, the overall PET in the Hami region demonstrated a tendency to rise. The interannual trend rates of PET for the full year, spring, summer, autumn, and winter were 0.933, 2.744, 0.906, 0.488, and −0.406 mm·a-1, respectively. Despite a decreasing trend in winter PET, the other seasonal PET values and the annual PET values exhibited an increasing trend. (2) The spatial distribution of both annual and seasonal PET showed significant regional heterogeneity, following a consistent pattern marked by lower values in the central part and higher values in the surrounding areas. The southern region tended to have relatively high PET, while the northwestern region experienced comparatively low PET. (3) Partial correlation analysis indicated significant differences in the impact of various climatic factors on PET. The maximum temperature emerged as the dominant factor influencing annual PET variation, while precipitation played a leading role in influencing autumn PET variation. This study underscores the influence of climate change on PET in the Hami region, contributing to an enhanced comprehension of PET variations. [ABSTRACT FROM AUTHOR]

Published

2024

5. Optimization of double-wire X-pinch using prepulse current.

Author

Jiang, Zhiyuan, Wu, Jian, Wang, Wei, Chen, Ziwei, Wang, Zhenyu, Lu, Yuanbo, Zhao, Yiming, and Shi, Huantong

Subjects

RADIATION sources, FARADAY effect, CURRENT distribution, MAGNETIC fields, PLASMA flow, STARTLE reaction

Abstract

The radiation properties including size, intensity, and pulse width of the double-wire X-pinch were optimized using prepulse current. The optimization mechanism was investigated using optical diagnostics. The X-pinch driven by a current with a peak intensity of ∼250 kA and a rise rate of 0.95 kA/ns was difficult to produce strong radiation. The application of prepulse effectively enhances the current rise rate and intensity of the radiation source. The radiation source also exhibited reduced spatial dimensions and radiation duration, thereby improving spatial and temporal resolution while used in x-ray projection shadow radiography. The magnetic field and current distribution were measured using Faraday rotation. During the early stage, the current predominantly flows in the corona plasma at a larger radius generated by the prepulse current, consequently reducing the load inductance. As the time delay between the main and prepulse current increased, the intensity of the radiation source further increased. This study provides an approach for controlling radiation sources and enables different applications of X-pinches with adjustable prepulse current. [ABSTRACT FROM AUTHOR]

Published

2023

6. Numerical and Experimental Study of Turbulent Mixing Characteristics in a T-Junction System.

Author

Sun, Bin, Liu, Quan, Fang, Hongyuan, Zhang, Chao, Lu, Yuanbo, and Zhu, Shun

Subjects

CROSS-flow (Aerodynamics), TURBULENT mixing, DIMENSIONAL analysis, NONLINEAR regression, REGRESSION analysis, QUANTITATIVE research, NONLINEAR analysis

Abstract

The mixing, migration, and degradation of pollutants in sewers are the main causes for pipeline corrosion and the increased pollution scope. The clarification of the turbulent mixing characteristics in pipelines is critical for finding the source of pollution in a timely fashion and inspecting pipelines' damaged locations. In this paper, numerical simulations and experiments were conducted to investigate the turbulent mixing characteristics in pipelines by studying a T-junction system, of which four variables (main pipe diameter φ, cross-flow flux Q, mixing ratio δ, the incident angle of T-junctions θ) were considered. The coefficient of variation (COV) of the salt solution was selected as the evaluation index and effective mixing length (LEML) was defined for quantitative analysis. The numerical results were found to be in good agreement with the experimental results. The results reveal that the values of LEML rise as Q or φ increase and decrease with the increase of δ, where the influence of φ is much greater than Q and δ, and there is no obvious regularity between LEML and θ. By dimensional analysis and multivariate nonlinear regression analysis, a dimensionless relationship equation in harmony with the dimensional analysis was fitted, and a simplified equation with the average error of 4.01% was obtained on the basis of correlation analysis. [ABSTRACT FROM AUTHOR]

Published

2020

7. Support Vector Machine response surface method based on fast Markov chain simulation.

Author

Yuan Xiukai, Lu Zhenzhou, and Lu Yuanbo

Published

2009

8. Experimental and Numerical Analyses on Mixing Uniformity of Water and Saline in Pipe Flow.

Author

Sun, Bin, Lu, Yuanbo, Liu, Quan, Fang, Hongyuan, Zhang, Chao, and Zhang, Jinping

Subjects

PIPE flow, SALINE waters, PIPELINES, WATER pipelines, COMPUTATIONAL fluid dynamics, NUMERICAL analysis, AGRICULTURAL water supply

Abstract

Liquid—liquid mixing is commonly observed in many applications such as the chlorination of water supplies and the agricultural fertigation. In order to study the mixing law of water-chlorine or water-fertilizer in a turbulent pipeline, saline was selected as a tracer injected into the pipeline. In this paper, the computational fluid dynamics (CFD) software was employed to study flow fields in water-saline pipelines. Four variates (mixing ratio δ, pipe diameter D, volume flow rate in the main pipe Q, saline density ρs) were considered to investigate the effects of multiple variates on mixing uniformity. The coefficient of variation (COV) was selected as the evaluation index of mixing uniformity, effective mixing length (LEML, the distance from the saline inlet to the fully mixed position) was chosen to quantitatively analyze the fully mixed position of water and saline in pipelines. The results of this numerical model agree well with experimental measurements and it shows that this model can effectively predict the concentration field of water and saline in the pipeline. Based on the experimental and simulated results, it was found that for the fixed mixing ratio, saline density and volume flow rate, the values of LEML increased significantly with increasing pipe diameters. Furthermore, dimensional analysis (D-A) was adopted to examine the influences of the four variates on LEML, and their correlation coefficient of the curve-fitting equation was calculated to be 0.996. [ABSTRACT FROM AUTHOR]

Published

2020

9. Experimental study of the mechanism of prepulse current on Z-pinch plasma using Faraday rotation diagnosis.

Author

Jiang Z, Wu J, Chen Z, Wang W, Wang Z, Lu Y, Zhao Y, Shi H, and Li X

Subjects

Rotation, Magnetic Fields, Plasma

Abstract

The prepulse current is an effective way to optimize the load structure and improve the implosion quality of the Z-pinch plasma. Investigating the strong coupling between the preconditioned plasma and pulsed magnetic field is essential for the design and improvement of prepulse current. In this study, the mechanism of the prepulse current on the Z-pinch plasma was revealed by determining the two-dimensional magnetic field distribution of preconditioned and nonpreconditioned single-wire Z-pinch plasma with a high-sensitivity Faraday rotation diagnosis. When the wire was nonpreconditioned, the current path was consistent with the plasma boundary. When the wire was preconditioned, the distributions of current and mass density presented good imploding axial uniformity, and the imploding speed of the current shell was higher than that of the mass shell. In addition, the mechanism of the prepulse current suppressing the magneto-Rayleigh-Taylor instability was revealed, which formed a sharp density profile of the imploding plasma and slowed the shock wave driven by the magnetic pressure. This discovery is essential and instructive for the design of preconditioned wire-array Z-pinch experiments.

Published

2023