Your search keyword '"Wang, Jiaoling"' showing total 5 results

1. Study on a Moisture Ratio Curve Model for Refractance Window Drying Based on a D‐Optimal Mixture Design.

Author

He, Jingyu, Song, Weidong, Li, Jianqiang, Ding, Tianhang, Guan, Jian, Wu, Jinji, Wang, Jiaoling, and Demiray, Engin

Subjects

DRYING apparatus, AIR speed, WIND speed, MODEL validation, DIFFUSION coefficients

Abstract

Refractance window (RW) drying is a new thin‐layer drying technology that can control well the heating temperature to effectively reduce the loss of heat‐sensitive substances. Here, an experiment on tomato pulp drying was carried out to study the drying characteristics of RW drying based on a D‐optimal mixture design. The fitting of the classical model of thin‐layer drying was studied, and SAS and 1stOpt calculation software were used to analyze the test data. The result showed that the RW drying equipment could dry 8 mm of tomato pulp in 120 min, and the maximum drying speed could reach 0.40 g/(g·min). Based on an effective diffusion coefficient under different conditions, the activation energy was 27.35 kJ/mol at an air speed of 3 m/s. When comparing the fitting of the moisture ratio curve in four classic thin‐layer drying models, it was found that the R‐square value of the modified Page model was 0.9960, which had better fitting properties. Then, the polynomial fitting model of thin‐layer drying reflects the regression relationship between the coefficient of the classic model and drying conditions including temperature, wind speed, and time. After comparison with the classic model and validation experiment, the results showed that there is no significant difference between the polynomial fitting model and the validations under a confidence level of 0.95, which could well predict the change in the water content ratio over time under different conditions. [ABSTRACT FROM AUTHOR]

Published

2024

2. Corrigendum to 'Research on Energy-Saving Experimental of Critical Dehumidification of Combined Drying by Dehumidification Wheel and Heat Pump'

Author

Wu Jinji, Wang Jiaoling, Chengqian Jin, Weidong Song, Ding Tianhang, and Mingyou Wang

Subjects

Materials science, Nutrition. Foods and food supply, law, Nuclear engineering, TX341-641, Safety, Risk, Reliability and Quality, Energy (signal processing), Food Science, Heat pump, law.invention

Published

2021

3. Corrigendum to “Research on Energy-Saving Experimental of Critical Dehumidification of Combined Drying by Dehumidification Wheel and Heat Pump”

Author

Wang, Jiaoling, primary, Song, Weidong, additional, Jin, Chengqian, additional, Ding, Tianhang, additional, Wang, Mingyou, additional, and Wu, Jinji, additional

Published

2021

4. Research on Energy-Saving Experimental of Critical Dehumidification of Combined Drying by Dehumidification Wheel and Heat Pump

Author

Weidong Song, Mingyou Wang, Chengqian Jin, Wang Jiaoling, Ding Tianhang, and Wu Jinji

Subjects

Desiccant, Materials science, Moisture, Article Subject, business.industry, Nutrition. Foods and food supply, 020209 energy, Humidity, 04 agricultural and veterinary sciences, 02 engineering and technology, Energy consumption, law.invention, Critical point (thermodynamics), law, 0202 electrical engineering, electronic engineering, information engineering, Relative humidity, TX341-641, 0405 other agricultural sciences, Safety, Risk, Reliability and Quality, Process engineering, business, Energy (signal processing), 040502 food science, Food Science, Heat pump

Abstract

In order to further decrease the energy consumption of desiccant wheel dehumidification, the drying medium circulation characteristics of a system combining heat pump drying with desiccant wheel dehumidification were investigated. Moreover, the critical dehumidification conversion mechanism was studied. The analysis of the heat pump hot air circulation system demonstrated that the heat pump system has the best dehumidification efficiency. Through the analysis of the system combining heat pump drying with desiccant wheel dehumidification, the critical conversion point was determined. The critical dehumidification mechanism was further verified using an online temperature and humidity measurement system. To investigate the effect of the critical point on energy consumption and drying quality and develop a drying model, response surface experiments were performed based on the effects of regeneration temperature, drying temperature, and conversion point relative humidity on rehydration, color difference, and specific moisture extraction rate (SMER). The optimal conversion point humidity was determined to be about 46% RH, which was slightly different from the test optimization value of 45.6% RH. In addition, comprehensive optimization and experimental verification of the influencing factors were conducted. The results demonstrated that the R2 values of the three models were greater than 0.98, and the experimental factors had a significant effect on drying quality and energy consumption. When the regeneration temperature was 96°C, the drying temperature was 53°C, the relative humidity of the conversion point was 46%, the color difference was 46.3, the rehydration ratio was 5.75, and the SMER was 1.62 kg/kW·h.

Published

2021

5. Research on Energy-Saving Experimental of Critical Dehumidification of Combined Drying by Dehumidification Wheel and Heat Pump

Author

Wang, Jiaoling, primary, Song, Weidong, additional, Jin, Chengqian, additional, Ding, Tianhang, additional, Wang, Mingyou, additional, and Wu, Jinji, additional

Published

2021