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43 results on '"Mao Shaohua"'

1. Analysis on the influence of turbulence model on elbow erosion calculation

Author

Liu Qi, Mao Shaohua, Liu Sheng, Hu Yangyang, Jiang Wei, and Long Xinping

Subjects
elbow flow, turbulence model, erosion prediction, Computational Fluid Dynamics(CFD), Naval architecture. Shipbuilding. Marine engineering, VM1-989
Abstract

[Objectives] The elbow is a common component of ship piping system. Efforts have been made in order to predict the elbow erosion accurately.[Methods] In this paper,the numerical simulation is conducted to calculate and analyze the flow field inside the pipe. From the two aspects,i.e. the influence of the turbulence model on the prediction of the flow field in the elbow and the influence of turbulence model on elbow erosion calculation,intensive research into the method to predict the erosion of elbow by solid and liquid flows.[Results] The results show that the SST k-ω turbulence model,together with the Oka erosion model,can accurately predict the flow field distribution in the elbow. Turbulence model brings a significant impact on the abrasion calculation,where it affects the calculated value of final erosion and also makes a great difference in the distribution of predicted relative erosion.[Conclusions] The obtained results can provide guidance for future pipe erosion prediction.

Published
2019
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20. Enhanced Soil Fertility and Carbon Sequestration in Urban Green Spaces through the Application of Fe-Modified Biochar Combined with Plant Growth-Promoting Bacteria.

Author

Niu, Guoyao, He, Chiquan, Mao, Shaohua, Chen, Zongze, Ma, Yangyang, and Zhu, Yi

Subjects
CARBON sequestration, NITROGEN in soils, RESTORATION ecology, COLLOIDAL carbon, SOIL fertility, PLANT growth
Abstract

Simple Summary: This study investigated the effects of plant growth promoting bacteria (Bacillus clausii) and Fe-modified biochar on soil fertility increases and mechanisms of carbon sequestration. Additionally, the impact on C-cycling-related enzyme activity and the bacterial community was also explored. The study results demonstrate that in comparison to the individual application of FeB and BC, the FeBBC treatment significantly relieves soil alkalization and enhances soil alkali-hydro nitrogen content and aggregate stability (particle size > 0.25 mm), thereby contributing to improved soil fertility and ecological function. Additionally, all biochar treatments exhibit higher soil organic carbon, thereby increasing organic carbon sequestration, particularly in the FeBBC treatment. Compared to a single ecological restoration method, FeBBC treatment can improve soil fertility and carbon sequestration, providing important reference values for urban green space soil ecological restoration projects. The soil of urban green spaces is severely degraded due to human activities during urbanization, and it is crucial to investigate effective measures that can restore the ecological functions of the soil. This study investigated the effects of plant growth promoting bacteria (Bacillus clausii) and Fe-modified biochar on soil fertility increases and mechanisms of carbon sequestration. Additionally, the effects on C-cycling-related enzyme activity and the bacterial community were also explored. Six treatments included no biochar or Bacillus clausii suspension added (CK), only Bacillus clausii suspension (BC), only biochar (B), only Fe-modified biochar (FeB), biochar combined with Bacillus clausii (BBC), and Fe-modified biochar combined with Bacillus clausii (FeBBC). Compared with other treatments, the FeBBC treatment significantly decreased soil pH, alleviated soil alkalization, and increased the alkali-hydro nitrogen content in the soil. Compared to the individual application of FeB and BC, the FeBBC treatment significantly improved aggregates' stability and positively improved soil fertility and ecological function. Additionally, compared to the individual application of FeB and BC, the soil organic carbon (SOC), particulate organic carbon (POC), and soil inorganic carbon (SIC) contents for the FeBBC-treated soil increased by 28.46~113.52%, 66.99~434.72%, and 7.34~10.04%, respectively. In the FeBBC treatment, FeB can improve soil physicochemical properties and provide bacterial attachment sites, increase the abundance and diversity of bacterial communities, and promote the uniform distribution of carbon-related bacteria in the soil. Compared to a single ecological restoration method, FeBBC treatment can improve soil fertility and carbon sequestration, providing important reference values for urban green space soil ecological restoration. [ABSTRACT FROM AUTHOR]

Published
2024
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36. Migration characteristics of heavy metals during simulated use of secondary products made from recycled e-waste plastic

Author

Mao Shaohua, Bin Dong, Weihua Gu, Jing Zhao, Zhuang Xuning, Jingwei Wang, Jianfeng Bai, Chenglong Zhang, Huang Qing, and Yuan Wenyi

Subjects
Environmental Engineering, 0208 environmental biotechnology, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, Electronic Waste, Metal, Environmental risk, Metals, Heavy, Soil Pollutants, Recycling, Waste Management and Disposal, Dissolution, 0105 earth and related environmental sciences, Heavy metals, Thermal aging, General Medicine, Pulp and paper industry, Microstructure, 020801 environmental engineering, visual_art, visual_art.visual_art_medium, Environmental science, Leaching (metallurgy), Groundwater quality, Plastics
Abstract

Recycling of plastics from e-waste can conserve resources, however, aging during the use of plastic products can cause the migration of heavy metals in additives. This study presents a methodology for evaluating the risks of heavy metals in waste plastic secondary products during long term use associated with heavy metal migration. The study processes were investigated by: (1) recycling waste plastics and producing secondary products; (2) thermal aging of secondary products; and (3) toxic leaching used to quantitatively analyse the dissolution of heavy metals. Combined with the changes in mechanical properties and microstructure, the effect of aging on the migration of heavy metals was observed. The results showed that the polymer appeared to delaminate, the adhesion of waste plastics to additives decreased, and the mechanical properties clearly decreased after the thermal aging experiment. Leaching experiments showed that the leached concentrations of Ni, Cu, Zn, Pb, and Sb in the three types waste plastic products increased over time. After 8 d of aging, the leached concentrations of Ni, Sb, and Pb exceeded the third, fourth, and third class of the groundwater quality standard, respectively. Specifically, the concentrations of Sb were 141, 289, and 21.1 times higher than the maximum permissible level. Therefore, management hierarchy and safe environmental recycling methods should be developed to reduce the risk of heavy metals in waste plastic secondary products.

Published
2019

37. Migration of heavy metal in electronic waste plastics during simulated recycling on a laboratory scale

Author

Mao Shaohua, Weihua Gu, Bin Dong, Jing Zhao, Huang Qing, Chenglong Zhang, Zhuang Xuning, Jianfeng Bai, Jingwei Wang, and Yuan Wenyi

Subjects
Environmental Engineering, Plastic recycling, Polymers, Health, Toxicology and Mutagenesis, 0208 environmental biotechnology, 02 engineering and technology, 010501 environmental sciences, Laboratory scale, 01 natural sciences, Electronic waste, Electronic Waste, Metal, Soil, Environmental risk, Metals, Heavy, Environmental Chemistry, Humans, Soil Pollutants, Recycling, Groundwater, 0105 earth and related environmental sciences, Waste management, Public Health, Environmental and Occupational Health, Heavy metals, General Medicine, General Chemistry, Pollution, 020801 environmental engineering, visual_art, visual_art.visual_art_medium, Environmental science, Leaching (metallurgy), Groundwater quality, Laboratories, Plastics
Abstract

Recycling is the primary method to handle electronic waste plastics, however, little attention has been paid to the risk posed by heavy metal migration in waste plastic products. The effect of multistage recycling processes on heavy metal migration and the environmental risk posed by heavy metals during recycling processes were investigated by: (1) Recycling waste plastics and determining the heavy metal contents in secondary products; (2) Using toxic leaching experiments to assess environmental risks of heavy metal migration in secondary products; and (3) Evaluating the effect of recycling processes on the mechanical properties and microstructure of plastics. Results showed that the contents of some harmful heavy metals in processed products exceeded the Safety of Toys Standard. Toxic leaching tests showed that Ni, Cu, Zn, Pb, and Sb migrated outward during secondary products use. With increased recycling times, concentrations of migrated Ni, Cu, Zn, Pb, and Sb increased, and the leached concentrations exceeded the limits stipulated in the Groundwater Quality Standard. Increased recycling times also accelerated waste plastics aging and caused the deterioration of mechanical properties. Furthermore, adhesion between layers decreased, stratification and cracking in polymers appeared, and adhesion of waste plastics to additives decreased. Therefore, the environmental risks of waste plastic recycling should be carefully considered.

Published
2019

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