4.1. Desiccant based drying systems

4.1. Desiccant based drying systems for night operation
Drying with solar-heated air is satisfactory as long as the sun is shining. To continue this process through the night and periods of cloud cover, it is necessary to either store some of this energy in a thermal mass or incorporate desiccants within the drying system. Thoruwa et al. reported the results from studies undertaken to develop three low cost solar regenerative clay-CaCl2 based solid desiccant materials. They established their moisture sorption and regeneration characteristics ; asseaaed their performance when compared with commercial desiccants and the integration of these within a low cost solar drying system for small-scale village-based crop drying. The results showed that the bentonite-CaCl2 (type 1) desiccant gave a maximum moisture sorption of 45% dry weight basis (DWB) while bentonite-CaCl2 (type2) and kaolinite-CaCl2 (type3) solid desiccants each gave moisture sorption values of 30% (DWB). It was concluded from the moisture sorption and regeneration characteristics that their application in solar crop drying and air dehumidification is highly useful due to their low regeneration temperatures (sub 100 °C). An indirect forced convection solar dryer with integrated desiccants was built and tested by Shanmugam and Natarajan, with four main parts namely a flat-plate solar air collector, a drying chamber, desiccant bed and a centrifugal blower. The system was operated in two modes, sunshine hours and off sunshine hours, and drying experiments were conducted with and without the integration of desiccant unit was also investigated and the results showed that the inclusion of reflective mirror on the desiccant bed causes faster regeneration of the desiccant material. An indirect forced convection and desiccant integrated solar dryer, consisting of a flat-plate solar air collector, drying chamber and a desiccant unit, was designed and fabricated by Shanmugam and Natarajan to investigate its performance under the hot and humid climatic conditions of Chennai, India, with green peas. The system pickup efficiency, specific moisture extraction rate, dimensionless mass loss, mass shrinkage ratio and drying rate were discussed. The mathematical model for the Kathabar Spray-Cel System developed by Mahmouda and Ball was used to predict the temperature and humidity ratio of air was used to predict the temperature and humidity ratio of the air at the drying bin inlet. The existing unsteady grain cooling model was modified and coupled with the liquid desiccant system model to study the feasibility of using the system desiccated air in drying applications and the model showed the infeasibility of using desiccated air for grain drying. The liquid desiccant system was modified to simulate adiabatic operation and coupled to the drying modified to simulate adiabatic operation and coupled to the drying model and the new system gave much better results, but its use for grain drying was predicted to be economically unfeasible. An adsorption unit of silica gel was designed by Hodali and Bougard and integrated in a crop solar drying installation, consisting of a direct flat-plate forced convective solar dryer connected with a similar solar collector. The daily sorption cycle of the desiccant unit was first investigated and a suitable coupling of the collector, the dryer and the adsorption unit were selected and numerically simulated and applied to the drying of apricots in Morocco under real climatic conditions. The integration of the adsorption unit improved the quality of the dried product and permitted a cyclic operation of drying over two days by reducing the drying period from 52 h to 44 h. Thoruwa et al. described some of the performance aspects of an autonomous solar desiccant maize dryer developed for village use in Kenya. Since most commercial desiccants were expensive, a low cost solid desiccant was fabricated from bentonite clay and calcium chloride materials, which is capable of regeneration at 45 °C, has high moisture sorption of 45% (DWB), significantly extends the drying process at night and reduces aflatoxin contamination of the grain. Laboratory and field testing were performed to determine the drying performance and the results showed that the prototype dryer had the capability of drying 90 kg of fresh maize from 38% (DWB) within 24 h. Punlek et al. made a simulation design for a hybrid PV/T assisted desiccant integrated HA-IR drying system (HPIRD) which had two components : a photovoltaic air collector (PVAC), and a desiccant silica gel bed (DB). The two new models were used develop a new drying system and compared with a common system. The simulation results indicated that the PVAC and v-shape DB were suitable, and they also indicated consistent results when compared with the experiment. The drying time, drying rate and energy consumption were reduced considerably with the hybrid drying system.