Drying Modeling and Energy Consumption of Air Dried Sheet (ADS) Rubber by Solar and Biomass Energy

Choktawee Pupakapanpong; Supawan Tirawanichakul; Yutthana Tirawanichakul

doi:10.4028/www.scientific.net/AMM.541-542.1017

Paper Titles

Study of Heat Losses from Cylindrical Cavity Receiver of Solar Concentrator
p.996

Progressive Study of GIS Based Land Suitability for Wind Farm in the South Wales Area in UK via GIS
p.1002

Chemical Kinetic Mechanism Reduction Scheme for Diesel Fuel Surrogate
p.1006

Analysis of Spherical Cavity Receiver of Solar Concentrator for Heat Losses
p.1011

Drying Modeling and Energy Consumption of Air Dried Sheet (ADS) Rubber by Solar and Biomass Energy
p.1017

Open Fault Characteristics and Simple Diagnosis Scheme in a Back-to-Back Converter for Wind Power Conversion
p.1022

A New Backward/Forward Algorithm for Weakly Meshed Distribution Systems with Distributed Generation
p.1027

Innovative Development of Non-Contact Torque Sensor Applied to Wind Generator
p.1032

Dynamic Modeling Based on Screw Theory and Lagrange’s Equations of a 3-DOF Cable-Driven Surgical Instrument
p.1039

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 541-542Drying Modeling and Energy Consumption of Air...

Drying Modeling and Energy Consumption of Air Dried Sheet (ADS) Rubber by Solar and Biomass Energy

Abstract:

This research aims were to evaluate drying kinetics model for describing evolution of moisture transfer of air dried sheet (ADS) rubber by using solar and biomass drying, multi-stages solar and biomass drying [2 stages (2S) and 3 stages (3S)] and conventional open-sun (OS) drying. The experiments were carried out under the conditions of ADS rubber drying with temperature of 30-60°C. Initial moisture contents of sample rubber were varied between 20 and 50% dry-basis. The final moisture content for each drying strategies was fixed at 1±0.05% dry-basis. The experimental drying results were mathematical simulated by 7 common non-linear empirical models. The results showed that fresh rubber sheets drying with OS technique took longer drying time than those of solar and biomass drying. And the simulated data using approximation of diffusion model was the best fitting to experimental data of rubber sheet. Effective diffusivity of ADS rubber was also determined using the 2^nd Ficks law of diffusion and conclusion was that effectice diffusivity was dependent on drying temperature and was in order of 10^-7 m²/s. With various drying strategies, the results showed that specific energy consumption of 3-stages ADS rubber drying had a relatively low compared to the other drying techniques.