Analysis study of whole stillage, thin stillage and syrup

Thumbnail Image
Date
2016-01-01
Authors
Yang, Lu
Major Professor
Advisor
Kurt A. Rosentrater
Committee Member
Journal Title
Journal ISSN
Volume Title
Publisher
Altmetrics
Authors
Research Projects
Organizational Units
Organizational Unit
Agricultural and Biosystems Engineering

Since 1905, the Department of Agricultural Engineering, now the Department of Agricultural and Biosystems Engineering (ABE), has been a leader in providing engineering solutions to agricultural problems in the United States and the world. The department’s original mission was to mechanize agriculture. That mission has evolved to encompass a global view of the entire food production system–the wise management of natural resources in the production, processing, storage, handling, and use of food fiber and other biological products.

History
In 1905 Agricultural Engineering was recognized as a subdivision of the Department of Agronomy, and in 1907 it was recognized as a unique department. It was renamed the Department of Agricultural and Biosystems Engineering in 1990. The department merged with the Department of Industrial Education and Technology in 2004.

Dates of Existence
1905–present

Historical Names

  • Department of Agricultural Engineering (1907–1990)

Related Units

Journal Issue
Is Version Of
Versions
Series
Abstract

Ethanol is used as a fuel additive has resulted in rapid of growth of ethanol production. Thus the bio-based ethanol production has been one of the fastest growing industries in the U.S. The dry grinding corn ethanol process is more predominant than other ethanol production process in the U.S. In the dry grinding process, the corn is fermented to produce ethanol and distillers dried grains with solubles (DDGS). The generated DDGS are primarily used by farmers to feed livestock. However, drying distillers grains consume energy and costs money. As a result, DDGS are more expensive than other distiller grains (Gorden, 2008). To reduce operational costs through drying process, some other distiller grains with relatively high moisture content, including whole stillage, thin stillage, and syrup could be considered as an alternative animal feed ingredient.

The physical and biological properties tests provided the information background information about operational processes, and valuable components change over time. The thin stillage and whole stillage had high initial average moisture contents of 92% (w.b.) and 87% (w.b.) respectively, and initial water activity of 0.99; the high water content marked samples easily susceptible to rapid spoilage. Time had a significant effect (P < 0.05) on properties of co-products. Both thin stillage and whole stillage samples got mold growth after 5 days incubation at 32oC. Thin stillage had the greatest separation rate in settling experiment. However, syrup had relative low initial average moisture content of 62% and initial water activity of 0.92. No mold growth and settling separation happened in syrup samples. There were no evidence showing a linear relationship exists between Hunters L*, a* and b*, and mold growth. The Solvitaà ® test showed that high-temperature treatment caused high CO2 production in all samples. The exponential models described the relationship between storage time (from 0 to 5 days at 25oC and 35oC) and CO2 concentration for three co-products.

Evaporation is the typical method used to concentrate solids in these co-products, but it requires a large amount of water and energy consumption. In order to overcome the problems that associated with the evaporator, membrane filtration could be applied that may provide a cheaper and efficient way to improve value for whole stillage, thin stillage, and syrup. Fractionation of these wet co-products by using ultrafiltration was conducted to evaluate membranes as an alternative to evaporators in ethanol production. A study has been showed that ultrafiltration required less energy than evaporation (Rausch and Belyea 2006). This study indicates that ultrafiltration could be a better choice that can be applied in biotechnology industries to concentrate valuable components. However, an important problem associated with membrane technologies is flux decline and membrane fouling. An understanding of causes of flux decline is necessary to minimize or avoid fouling and to make membrane application economic.

The membrane size, stirring speed and volume capacity had significant effects (P < 0.05) on flux during the ultrafiltration for whole stillage and thin stillage. The flux increased by 30% maximum as siring speed increased from 160 to 320 rpm for YM 10 membrane (10KDa) in these two samples. The effect of membrane size on solid recovery was significant (P < 0.05). The solid recovery for YM 100 membrane in whole stillage ranged from 75% to 83%, and 74% to 84% for thin stillage, however, the YM 10 kDa was ranging from 80% to 90% in whole stillage, and 84% to 90%. Retentate products from ultrafiltration could be further used as an ingredient to feed animals, and the permeate stream could be recycled in dry grind plants to help in reducing process water requirement.

Comments
Description
Keywords
Citation
Source
Subject Categories
Copyright
Fri Jan 01 00:00:00 UTC 2016