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Fan Wang,Ziliang Yuan,Bing Liu,Shaohua Chen,Zehui Zhang 한국공업화학회 2016 Journal of Industrial and Engineering Chemistry Vol.38 No.-
In this study, a new ruthenium catalyst was used for the oxidation of biomass derived5-hydroxymethylfurfural (HMF) under mild conditions, which was prepared by the exchange of Ru3+with H+ in the structure of the zirconium phosphate (ZrP). The as-prepared ZrP–Ru catalyst showed highcatalytic activity towards the oxidation of HMF, affording 100% of HMF conversion at 130 8C after 12 hunder atmospheric oxygen pressure. 2,5-Furandicarboxylic acid (FDCA) and 2,5-diformylfuran (DFF)were detected to be the major oxidation products.
Lingbo Kong1,Ziliang Zhang,Yang Song,Junzhong Chen 한국펄프·종이공학회 2023 펄프.종이기술 Vol.55 No.4
With the purpose of improving molded pulp product (MPP) drying process, the present work investigated the microwave drying performance of MPP under the power level of 500 W and compared that with the convective drying method. The drying kinetics, the effective moisture diffusivity, and the energy consumption of the two drying methods were evaluated respectively. It was found that the drying time was shortened from 22.0 min for convective drying to 16.0 min for microwave drying due to 27% of drying rate enhancement, and the effective moisture diffusivity was increased from 3.01×10-10 to 4.49×10-10 m2/s. Additionally, 88% of energy consumption could be saved in the microwave drying process. An artificial neural network (ANN) was employed to predict the moisture removing kinetics of MPP. The results revealed that the ANN modeling could be used to predict the drying kinetics of MPP effectively and then determine the moisture content in the drying process.
The potential of Panax notoginseng against COVID-19 infection
Yeye Hu,Ziliang He,Wei Zhang,Zhiqiang Niu,Yanting Wang,Ji Zhang,Ting Shen,Hong Cheng,Weicheng Hu 고려인삼학회 2023 Journal of Ginseng Research Vol.47 No.5
The COVID-19 pandemic has changed the world and has presented the scientific community with unprecedentedchallenges. Infection is associated with overproduction of proinflammatory cytokines secondaryto hyperactivation of the innate immune response, inducing a cytokine storm and triggeringmultiorgan failure and significant morbidity/mortality. No specific treatment is yet available. For thousandsof years, Panax notoginseng has been used to treat various infectious diseases. Experimental evidenceof P. notoginseng utility in terms of alleviating the cytokine storm, especially the cascade, andimproving post-COVID-19 symptoms, suggests that P. notoginseng may serve as a valuable adjuncttreatment for COVID-19 infection.
Sequential Modeling of Paper Drying Process to Reduce Thermal Energy Use, Part 2: Simulation Results
Kong Lingbo,Jiahao Li,Ziliang Zhang 한국펄프·종이공학회 2022 펄프.종이기술 Vol.54 No.5
Paper drying is one of the unit operations that consumes the most amount of thermal energy in a papermaking machine. In this paper, a theoretical model for paper drying process was developed using the sequential modeling method based on the conservation laws of mass and energy. Aimed at simulating thermal energy flow, the overall framework of the drying model was constructed according to the specific drying process of a newsprint machine. It was composed of eight basic modules based on their different functions in the paper drying process, i.e., cylinder group module, steam separation module, surface condensation module, fan module, heat recovery module, air heating module, paper sheet module, and hood module. The results showed that it could be used to simulate the material and energy flow of each module, as well as the whole drying process in a more comprehensive manner with integrated thermal energy use and drying performance information. In addition, the effects of operating parameters, such as supply air temperature and exhaust air humidity, on thermal energy use in the newsprint drying process were also simulated. This work also demonstrates that the sequential modeling method is instructive to reduce thermal energy use for the industrial paper drying process.
Xin Lv,Yelidana Nuertai,Qiwei Wang,Di Zhang,Xumin Hu,Jiabao Liu,Ziliang Zeng,Renyuan Huang,Zhihao Huang,Qiancheng Zhao,Wenpeng Li,Zhilei Zhang,Liangbin Gao 대한척추신경외과학회 2024 Neurospine Vol.21 No.1
Objective: To compare the clinical outcomes and biomechanical characteristics of 1-, 2-, and 3-level pedicle subtraction osteotomy (PSO), and establish selection criteria based on preoperative radiographic parameters. Methods: Patients undergone PSO to treat ankylosing spondylitis from February 2009 to May 2019 in Sun Yat-sen Memorial Hospital of Sun Yat-sen University were enrolled. According to the quantity of osteotomy performed, the participants were divided into group A (1-level PSO, n = 24), group B (2-level PSO, n = 19), and group C (3-level PSO, n = 11). Clinical outcomes were assessed before surgery and at the final follow-up. Comparisons of the radiographic parameters and quality-of-life indicators were performed among and within these groups, and the selection criteria were established by regression. Finite element analysis was conducted to compare the biomechanical characteristics of the spine treated with different quantity of osteotomies under different working conditions. Results: Three-level PSO improved the sagittal parameters more significantly, but resulted in longer operative time and greater blood loss (p < 0.05). Greater stress was found in the proximal screws and proximal junction area of the vertebra in the model simulating 1-level PSO. Larger stress of screws and vertebra was observed at the distal end in the model simulating 3-level PSO. Conclusion: Multilevel PSO works better for larger deformity correction than single-level PSO by allowing greater sagittal parameter correction and obtaining a better distribution of stress in the hardware construct, although with longer operation time and greater blood loss. Three-level osteotomy is recommended for the patients with preoperative of global kyphosis > 85.95°, T1 pelvic angle > 62.3°, sagittal vertical alignment > 299.55 mm, and pelvic tilt+ chin-brow vertical angle > 109.6°.