https://scholars.lib.ntu.edu.tw/handle/123456789/448344
Title: | Adsorption and desorption of silica gel circulating fluidized beds for air conditioning systems | Authors: | Chen, C.-H. Ma, S.-S. Wu, P.-H. Chiang, Y.-C. Chen, S.-L. SIH-LI CHEN |
Keywords: | Circulating fluidized beds; Dehumidification; Low energy consumption; Low pressure drop | Issue Date: | 2015 | Journal Volume: | 155 | Start page/Pages: | 708-718 | Source: | Applied Energy | Abstract: | This article investigates low-energy consumption silica gel circulating fluidized beds for the dehumidification of air conditioning systems. The system consists of an adsorption bed, a desorption bed, and two fans. The fans drive silica gel particles upward to form fluidized beds; as the particles descend, funnels inside the beds allow particles to move between beds through connecting pipes. The particles circulate between absorption and desorption beds to create a continuous operating dehumidification air conditioning system. To achieve a fluidized state, air velocities between 4.0 m/s and 6.0 m/s and regeneration temperatures between 40 °C and 60 °C, which simulate low-temperature waste heat or solar thermal conditions, were chosen for the study. Altering funnel heights and adding oblique baffles to the system allowed us investigate different adsorption/desorption performances. The results show that single-tube fluidized bed can increase adsorption/desorption performance by 20% and lower the pressure drop by about 30%, compared to the packed bed. The circulating fluidized bed system has the highest Energy Factor by 0.554 kg/kW h, and improve the packed bed system by 124% due to the absence of a motor and has the largest total adsorption rate. Increasing air velocities and regeneration temperatures cause adsorption/desorption performance to rise in circulating fluidized bed systems. A regeneration temperature of 60 °C has the highest total adsorption rate of 343 g/h. Compared to the other funnel heights, a 200 mm funnel height with an oblique baffle that increases circulatory effects improves the total adsorption rate by 14% to reach an adsorption rate of 230 g/h. © 2015 Elsevier Ltd. |
URI: | https://scholars.lib.ntu.edu.tw/handle/123456789/448344 | DOI: | 10.1016/j.apenergy.2015.06.041 | SDG/Keyword: | Adsorption; Air; Air conditioning; Desorption; Drops; Energy utilization; Fluidization; Fluidized bed combustion; Fluidized bed process; Humidity control; Packed beds; Pressure drop; Silica; Silica gel; Waste heat; Absorption and desorptions; Adsorption and desorptions; Circulating fluidized bed; Dehumidification; Low energy consumption; Low pressure drop; Low-temperature waste heats; Regeneration temperature; Fluidized beds; adsorption; air conditioning; desorption; energy conservation; gel; low pressure; low temperature; operations technology; particulate matter; performance assessment; pressure effect; silica; temperature effect; velocity |
Appears in Collections: | 機械工程學系 |
Items in DSpace are protected by copyright, with all rights reserved, unless otherwise indicated.