Prediction of Powder Stickiness along Spray Drying Process in Relation to Agglomeration

Prediction of Powder Stickiness along Spray Drying Process in Relation to Agglomeration

The spray drying process consists of a fast convective drying of liquid droplets by hot air. Initially, the water activity (a w ) of a drop is close to 1. During drying, the drop surface a w decreases while viscosity increases until reaching a sticky rubbery state before further drying. This can be...

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Bibliographic Details
Published in:Particulate science and technology Vol. 27; no. 5; pp. 415 - 427
Main Authors: Gianfrancesco, A., Turchiuli, C., Dumoulin, E., Palzer, S.
Format: Journal Article
Language:English
Published: Taylor & Francis Group 03-09-2009
Taylor & Francis
Subjects:
agglomeration
glass transition
Life Sciences
spray drying
stickiness
agglomeration
glass transition
spray drying
stickiness
Online Access:Get full text
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Summary:The spray drying process consists of a fast convective drying of liquid droplets by hot air. Initially, the water activity (a w ) of a drop is close to 1. During drying, the drop surface a w decreases while viscosity increases until reaching a sticky rubbery state before further drying. This can be observed for products such as carbohydrates, leading to particles sticking on walls (product losses) or to adhesion between particles leading to agglomeration. In this study, particle stickiness was investigated in a cocurrent pilot spray dryer by measuring drying air properties (temperature and relative humidity) at different positions. This allowed describing the evolution of temperature and mean water content of the drying drops. Two model products (maltodextrin DE12 and DE21) were spray dried varying process parameters liquid flow rate (1.8, 3.6, and 5.4 kg/h), air temperature (144°, 174°, and 200°C), airflow rate (80-110 kg/h), and rotary atomizer speed (22,500-30,000 rpm). The two products exhibit different drying behaviors in relation to their affinity towards water (sorption isotherms) and glass transition temperature evolution with a w (stickiness). Depending on drying conditions and product, the drop stickiness was observed very rapidly, close to the atomizer, or later, along the chamber. This approach can be used to identify conditions and positions corresponding to sticky particles.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
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content type line 23
ISSN:0272-6351
1548-0046
DOI:10.1080/02726350903129987