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Development of a time temperature integrator for quantification of thermal treatment in scraped surface heat exchangers
Development of a time temperature integrator for quantification of thermal treatment in scraped surface heat exchangers
- Source :
- Innovative Food Science & Emerging Technologies. 9:516-526
- Publication Year :
- 2008
- Publisher :
- Elsevier BV, 2008.
-
Abstract
- When processing highly viscous fluids in scraped surface heat exchangers, it is often difficult to follow the real heat flux received by each part of the product. Only average temperatures are measured, and the process cannot always guarantee a correct thermal treatment. During a pasteurisation process, the average temperature is around 80 °C, but some parts of the product may not stay long enough at this temperature compared to the average residence time. The aim of this study is to develop a tracer in order to follow the thermal treatment of Newtonian or non Newtonian viscous fluids in an experimental scraped surface heat exchanger in conditions similar to a pasteurisation treatment. A natural coloured tracer (Betanin, from red beets) which thermal degradation is well known is used as time temperature integrator. Thermal degradation of the tracer is determined experimentally and compared with a dispersion RTD model. First results show that Betanin degradation diluted in viscous fluids follows a classical first order reaction in a batch system. However, this degradation is enhanced when mechanical treatments occur in a well identified shearing channel as well as in the SSHE, for shear rates higher than 20 000 s − 1 . The major concern was then to identify the origin of this enhancement. Temperature increase due to viscous friction was measured in the SSHE and compared with the prediction conversion factors. It was shown that thermal treatment received by the Betanin was highly dependent on the mechanical treatment delivered during the thermal treatment. Industrial relevance When processing highly viscous fluids in scraped surface heat exchangers, it is often difficult to follow the real heat flux received by each part of the product, especially in industrial apparatus. Only average temperatures are measured, and the process cannot always guarantee a correct thermal treatment. During a pasteurisation process, the average temperature is around 80 °C, but some part of the product may not stay long enough at this temperature compared to the average residence time. The aim of this study is to develop a tracer in order to follow the thermal treatment in an experimental scraped surface heat exchanger in conditions similar to a pasteurisation treatment. When this tracer is found to be appropriate, it will be used directly in industrial equipments, in order to help industrials in: first, understanding their processes; verifying that their actual operating conditions are feasible for a correct thermal treatment; if not, in optimising these operating conditions. Betanin, representative of sensitive food products treated in a scraped surface heat exchanger was found to be, not only sensitive to temperature but also to mechanical treatment. This rather unexpected result has to be taken into account very carefully by industrials in order to insure a content product quality, whereas the mechanical treatment undergone by the product can lead to an accentuated degradation of thermally sensitive products.
- Subjects :
- Dynamic scraped surface heat exchanger
Thermodynamics
General Chemistry
Thermal treatment
Mechanics
Residence time distribution
Residence time (fluid dynamics)
Industrial and Manufacturing Engineering
Non-Newtonian fluid
chemistry.chemical_compound
chemistry
Heat flux
Newtonian fluid
Food Science
Betanin
Subjects
Details
- ISSN :
- 14668564
- Volume :
- 9
- Database :
- OpenAIRE
- Journal :
- Innovative Food Science & Emerging Technologies
- Accession number :
- edsair.doi...........2295cb3876b22a174eb623fd63b3ae93
- Full Text :
- https://doi.org/10.1016/j.ifset.2008.01.003