Pneumocentrifugal Classification of Dispersed Particles during Grain Milling

Q3 Economics, Econometrics and Finance

Food Processing: Techniques and Technology Pub Date : 2024-03-28 DOI:10.21603/2074-9414-2024-1-2494

Olga Terekhova, Yana Duyunova

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Abstract

Russia enjoys a stable demand for flour products, including those obtained by the dry method of starch and gluten production. This study featured pneumocentrifugal parameters of fine particles in a spiral separator that classified milled grain into fractions, separated the solid phase from air, and identified the high-protein flour fraction in the flow. Pneumatically classified flour was subjected to mathematical modeling and experimental research. The analysis of movement and deposition of particles in the working area covered particle mass, density, air-flow rate, and geometry, as well as their effect on the trajectory of particle movement and deposition. The experiment also involved the effect of air-flow rate and air-mix concentration on the classification efficiency. Particles from various grinding and break systems demonstrated classification modes that differed in soaring rate, size, and density. At an air-flow rate of 6–8 m/s, turn 1 of the spiral separator had the ratio of the internal coil radius to the inner pipe diameter as r1/dpipe = 7.9; it was r1/dpipe = 7 on turn 2 and fell down to r1/dpipe = 6.25 on turn 3; for all subsequent turns, the ratio was r1/dpipe < 5. Under these conditions, the fraction reached 160 µm and included small high-protein flour fractions with a particle size of 17–20 µm. The percentage of product accumulated on turns 1, 2, and 3 was 80, 12, and 8%, respectively. The maximal product separation efficiency of the third drain system was as high as 98% at an input rate of 6 m/s. The maximal separation efficiency for premium flour reached 99.2% at an input rate of 4.2 m/s. The separator proved efficient in classifying wheat grain flour into fractions as it was able to separate high-protein fraction and dispersed particles from the air flow. The separator could be used both as an independent device and as part of a complex technological scheme at the stage of pneumatic separators and unloaders.

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谷物研磨过程中分散颗粒的气离心分级

俄罗斯对面粉产品有着稳定的需求，其中包括用干法生产淀粉和面筋的产品。这项研究以螺旋分离器中细小颗粒的气动离心参数为特色，该分离器将碾磨过的谷物分类，从空气中分离出固相，并识别出气流中的高蛋白面粉部分。对气动分级面粉进行了数学建模和实验研究。对颗粒在工作区的运动和沉积进行了分析，包括颗粒质量、密度、气流速度和几何形状，以及它们对颗粒运动和沉积轨迹的影响。实验还涉及空气流速和空气混合浓度对分级效率的影响。来自不同研磨和破碎系统的颗粒表现出了不同的分级模式，其飙升速度、大小和密度也各不相同。当气流速度为 6-8 m/s 时，螺旋分离器第 1 圈的内部线圈半径与内管直径之比为 r1/dpipe = 7.9；第 2 圈为 r1/dpipe = 7，第 3 圈降至 r1/dpipe = 6.25；在随后的所有圈中，该比率均为 r1/dpipe < 5。在这些条件下，馏分达到 160 µm，其中包括粒径为 17-20 µm 的高蛋白小面粉馏分。积聚在第 1、2 和 3 圈的产品百分比分别为 80%、12% 和 8%。当输入速度为 6 米/秒时，第三排水系统的最大产品分离效率高达 98%。当输入速度为 4.2 米/秒时，优质面粉的最大分离效率达到 99.2%。事实证明，该分离器能从气流中分离出高蛋白部分和分散的颗粒，因此能有效地将小麦颗粒面粉分级。分离器既可作为独立设备使用，也可作为气动分离器和卸料器阶段的复杂技术方案的一部分。

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