物理精炼对植物油中选定微量成分的影响

W. Greyt, M. Kellens, A. Huyghebaert
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引用次数: 59

摘要

植物油的最终质量在很大程度上取决于脱臭过程。从感官的角度来看,油应该是浅色的,味道温和,具有良好的低温和/或氧化稳定性。然而,在今天,人们越来越关注真正的营养品质。油应该含有低反式脂肪酸水平,低聚合甘油三酯和二次氧化产物,同时富含天然抗氧化剂。为了满足这些新的质量要求,对脱臭技术进行了大量改进。建立了数学模型,描述了大豆油物理精制过程中不同工艺参数(时间、温度、蒸汽和压力)对反式脂肪酸形成、生育酚溶出以及氧化和聚合甘油三酯生产的影响。反式脂肪酸(TFA)的形成仅受时间和温度的影响。没有观察到压力或喷射蒸汽的显著影响。亚油酸(DI 18:2)和α-亚麻酸(DI 18:3)顺式/反式异构化相对程度的模型可以推广到其他油脂和除臭剂设计中。生育酚的去除主要受工艺温度和喷射蒸汽的影响。此外,生育酚的保留似乎取决于除臭剂的设计(蒸汽注入几何形状和喷射蒸汽分布)。在物理精制过程中,氧化和聚合三酰甘油不受任何工艺参数的显著影响。工业上,工艺条件被调整到最小化反式脂肪酸的形成和最大化生育酚的保留。这些目标都可以在所谓的DUAL TEMP®除臭剂中实现。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Effect of physical refining on selected minor components in vegetable oils
The final quality of vegetable oils is largely determined by the deodorization process. From an organoleptic point of view, oils should be light in color with a bland taste and a good cold and/or oxidative stability. Today, however, more and more attention is paid to the real nutritional quality. Oils should contain low trans fatty acid levels, low polymeric triglycerides, and secondary oxidation products and at the same time being rich in natural antioxidants. In order to comply to these new quality requirements, the deodorization technology has been modified substantially. Mathematical models were established describing the influence of different process parameters (time, temperature, steam, and pressure) on trans fatty acid formation, tocopherol stripping, and production of oxidized and polymeric triacylglycerides during physical refining of soybean oil. Trans fatty acid (TFA) formation was influenced only by time and temperature. No significant influence of pressure or sparging steam could be observed. Models expressing the relative degree of cis/trans-isomerization of linoleic (DI 18:2 ) and α-linolenic acid (DI 18:3 ) could be extra-polated to other oils and deodorizer designs. Tocopherol removal was mainly influenced by process temperature and sparging steam. Additionally, tocopherol retention seemed to be dependent on the deodorizer design (steam injection geometry and sparging steam distribution). During physical refining, oxidized and polymerized triacylglycerols were not significantly influenced by any of the investigated process parameters. Industrially, process conditions are adapted to minimize trans fatty acid formation and maximize tocopherol retention. These goals can be achieved in a so-called DUAL TEMP® deodorizer.
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