Modeling of heat and mass transfer for solid state fermentation process in tray bioreactor

A simple mathematical model for the interaction of mass transport with biochemical reaction in solid state fermentations (SSF) in static tray type bioreactors under isothermal conditions has been developed. The analysis has enabled scientific explanations to a number of practical observations, throu

## IlW?H3DF.JCI-f-ION S&b-state ~rm~~~~ti~~ @SF), a process in whi& the substrate is not a free liquid (Aidoo et al., I980), has been widely used to produce numer5us usefui products using m&oarganisms, mainly fungi. The most important advantages associated with SSF as compared with submerged ferme

## Abstract **BACKGROUND:** Heat removal is one of the major constraints in large‐scale solid‐state fermentation (SSF) processes. The effect of internal air circulation by forced convection on heat and water transfer has not been studied in SSF tray bioreactors. Formulation of a mathematical model

## Abstract The effect of wall cooling in tray‐type solid‐state fermenters was investigated by cultivation of __Aspergillus niger__ ATCC 10 864 on wheat bran. Temperature, moisture, pH and glucoamylase activity in the bed were monitored. Application of the heat exchanger plate reduced the overall w

## Abstract We present a mathematical model that describes heat and mass transfer during solid‐state fermentation (SSF) of __Aspergillus oryzae__ in a well‐mixed rotating drum bioreactor (RDB). In addition to the substrate bed and the headspace, the model recognises the bioreactor wall as a subsyst