Your search keyword '"Xu, Yangming"' showing total 5 results

1. Co-recovery of Mn and Fe from pyrolusite and copper slag with hydrometallurgy process: Kinetics and leaching mechanisms

Author

Wang, Lanbin, Chen, Yu, Xu, Yangming, Ma, Yanping, and Du, Yaguang

Published

2023

2. Cement from Copper smelting slag: Compressive strength, microfreeze-thaw tests and microstructural analysis.

Author

Xiang, Hao, Xu, Yangming, Ma, Mengyu, Du, Yaguang, Li, Jie, Li, Changyi, Ye, Hengpeng, and Chen, Yu

Subjects

*COPPER smelting, *MORTAR, *COMPRESSIVE strength, *COPPER slag, *CEMENT, *SLAG cement, *CARBON emissions

Abstract

Copper smelting slag (CSS) are waste slag obtained from smelters after reusing sulphur smelting slag. This study explores the potential of CSS to serve as a resource in cement mortar construction. Specifically, the study investigates the use of mechanical and chemical methods to enhance the volcanic ash activity of CSS, enabling them to replace up to 30 % of the cement content in cement mortar. The modified CSS was analyzed in terms of particle size and (Toxicity Characteristic Leaching Procedure) TCLP testing, while cement mortar specimens were subjected to a battery of tests including compressive strength, Freeze-thaw experiment, TCLP testing and cement stability testing. The results showed that compared with the unmodified CSS material, the copper smelting slag cement material with CaCO 3 meets the requirements of GB/T 1596–2017 on the standard compressive strength of OPC 42.5 grade, with a compressive strength of 38.88 MPa at 10 % CaCO 3 admixture, among which the CSS cement material with 10 % CaCO 3 is the best and meets the leaching toxicity standard. Moreover, the modified CSS reduced energy consumption by 7.15 %, CO 2 emissions by 27.41 %, and cost by 19.84 %. XRD, FTIR and SEM analysis showed that the mechanical activation of CaCO 3 doping more drastically damaged the crystal structure of CSS, and local lattice distortion occurred, which induced the transformation of CSS from crystalline phase to amorphous phase and destroyed the ordered structure of minerals, resulting in the volcanic ash activity increased. Overall, this study demonstrates that CSS can serve as a viable raw material in cement mortar samples, reducing environmental impact and achieving resourceful use of slag. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

3. Detoxification and resource utilization of soda ash chromite ore processing residue by copper slag.

Author

Wang, Lanbin, Xu, Yangming, Ma, Yanping, Chen, Yu, Yang, Anju, Gan, Guixiang, Du, Yaguang, and Sun, Yan

Subjects

*COPPER slag, *FERRIC oxide, *ORES, *INDUSTRIAL wastes, *RAW materials

Abstract

Chromite ore processing residue (COPR) and copper slag (CS) are industrial waste slags that cause environmental pollution and require effective treatment. This study proposes a new strategy for the co-treatment and resource utilization of COPR and CS. Under the optimal conditions (liquid-solid ratio of 9.99; H 2 SO 4 concentration of 0.85 M; the CS/COPR mass ratio of 9.98%; temperature of 88.20 ℃; and duration of 60 min), the reduction efficiency of Cr(VI) reached 99.48%, and the total Cr leaching concentration of residue reached 1.35 mg/L, which was below the USEPA regulatory limit of 5 mg/L. In addition, the detoxicated slag containing 61.44 wt% Fe 2 O 3 can be used as a raw material in the steel industry. Through kinetic, characterization, and DFT analyses, the effective remediation of Cr(VI) in COPR by CS is a combination of adsorption and reduction. The unreacted shrinkage nuclear reaction model under the control of the surface chemical reaction is the most suitable model to describe the process, and when the apparent activation energy is 63.90 kJ/mol, the apparent rate equation is: 1-(1-x)1/3= 1·371×107[CS/COPR]2·35004 [H 2 SO 4 ]2·3945 [L/S]1·95338 exp(–63·90/RT) This is an important study for waste-waste co-treatment and resource utilization of industrial waste. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

4. A novel way to prepare battery-grade FePO4 2H2O from copper slag and Life cycle assessment.

Author

Xu, Yangming, Wang, Lanbin, Xie, Wenjie, Chen, Yu, Zhang, Keshuo, and Du, Yaguang

Subjects

*PRODUCT life cycle assessment, *COPPER slag, *CARBON emissions, *SLAG, *LEACHATE, *WASTE lands, *CARBON dioxide

Abstract

[Display omitted] • Battery-grade FePO 4 ·2H 2 O was prepared by copper slag resource utilization. • FePO 4 ·2H 2 O was synthesized by selective sediment in the leachate. • Adding Na 2 HPO 4 ·12H 2 O without extra pH adjustment. • The battery performance of synthetic LFP/C is effective. • Life cycle assessment indicates that the technology is environmentally friendly. Copper slag (CS) contains a high content of valuable iron, the stockpile of CS occupies a large amount of land and leads to a waste of secondary resources. This study proposed producing battery-grade FePO 4 ·2H 2 O from CS through selective leaching, synthesis, and purification. The combined acid leaching/evaporation method was used to leach out Fe and inhibit Si from fayalite selectively, and then FePO 4 ·2H 2 O was formed by adding Na 2 HPO 4 ·12H 2 O without extra pH adjustment. The purity of FePO 4 ·2H 2 O obtained by using a reactor heated for 5 h at 180 ℃ with an HCl concentration of 2.5 M was 99.47 %, and the impurities were all by the industry standard for battery-grade FePO 4 ·2H 2 O (HG/T 4701–2021). The LiFePO 4 /C material was further synthesized and tested for battery performance. Under the test current of 0.1C, the charging-specific capacity of the battery in the first week was 175.8 mAh/g, and the discharge-specific ability was 159.3 mAh/g, which was close to the theoretical specific capacity and effective. Life cycle assessment (LCA) indicated that for each 1 kg of iron phosphate produced, the carbon emission of this study was reduced by 4.71 kg CO 2 eq compared with the traditional technology. [ABSTRACT FROM AUTHOR]

Published

2024

5. Two-stage method recovery of metals from copper slag: Realize the resource utilization of all components.

Author

Wang, Lanbin, Xu, Yangming, Tian, Liang, Chen, Yu, Yang, Anju, Gan, Guixiang, Ma, Yanping, and Du, Yaguang

Subjects

*COPPER slag, *FERRIC oxide, *METALS, *SILICATE minerals, *DLVO theory, *COPPER smelting, *SILICA gel

Abstract

[Display omitted] • A novel approach for the selective separation of Fe and Zn from copper slag was proposed. • The leaching efficiency of Fe and Zn reached 99.94% and 97.40%, respectively. • Silica gel aggregated to form amorphous silica, which effectively inhibits the leaching of Si. • 4. Copper slag was transformed into iron red, electrolytic zinc, and geopolymers through a two-stage process. The recovery of metal from copper slag is of great significance to the resource utilization of copper slag and the sustainable development of copper smelting industry. Currently, hydrometallurgy is the traditional method used to recover mineral metals. However, as copper slag is a silicate mineral, the traditional acid-leaching process of metal results in the leaching of Si, resulting in the formation of silica gel. The silica gel can inhibit the recovery of metal while making metal difficult to separate from Si and causing filtration problems. This study proposed a two-stage method (evaporation + water washing) to selectively recover Fe and Zn from copper slag. Under the optimal conditions (evaporation: H 2 SO 4 = 3 M; time = 60 min; temperature = 120℃; and liquid–solid ratio = 4; water washing: liquid–solid ratio = 5), the leaching efficiency of Fe, Zn, and Si reached 99.94 %, 97.40 %, and 0.15 % respectively. The separation mechanism was determined through mineral characterization (XRD, SEM, HRTEM-EDS, SAED, AFM, etc.) and the application of DLVO theory. It was found that H+ destroyed the Fe 2 SiO 4 structure in copper slag during the evaporation stage, which promoted the release of Fe and Zn, forming soluble sulfate crystals. Simultaneously, evaporation increased the ion concentration, reducing the repulsive force between colloids, resulting in the aggregation and precipitation of silica gel into stable amorphous silica. After washing, soluble sulfate is dissolved in water. The recovered Fe can be processed to get red iron oxide (96.32 % purity), the Zn-containing solution can be recycled for electrolytic Zn, and the residue can be used to prepare geopolymer (52.47 MPa, 28 days). The two-stage method for recovering metals from copper slag is highly efficient and provides valuable insights into resource utilization of metals and Si in silicon-containing solid wastes. [ABSTRACT FROM AUTHOR]

Published

2024