红外条件下驼绒藜（A. hirtifolium Boiss.）脱水的优化

Chayjan Reza Amiri, Fealekari Mosayeb

Department of Biosystems Engineering, Faculty of Agriculture, Bu-Ali Sina University, Iran.

Acta Sci Pol Technol Aliment. 2017 Apr-Jun;16(2):157-170. doi: 10.17306/J.AFS.0471.

BACKGROUND

In recent years, infrared drying has gained popularity as an alternative drying method for a va- riety of agricultural products. The use of infrared radiation technology in drying agricultural products has several advantages. These may include decreased drying time, high energy efficiency, high-quality finished products and uniform temperature in the product. With intermittent infrared and convection heating of a thick porous material, the drying time can be reduced compared to convection alone, while keeping good food quality and high energy efficiency.

METHODS

Response surface methodology (RSM) was employed to optimize the drying con- ditions of mooseer under infrared-convective drying. Experiments were performed at air temperatures of 40, 55 and 70°C, infrared powers of 500, 1000 and 1500 W, air velocities of 0.5, 1.5 and 2.5 m/s and slice thicknesses of 2, 4, and 6 mm. In this study, effective moisture diffusivity (Deff), shrinkage, color changes and specific energy consumption (SEC) were investigated. The central composite design (CCD) was selected for the design and optimization of the process.

RESULTS

Deff was obtained between 1.4×10 and 3.57×10 m /s. With increasing air temperature and slice –10 –9 2 thickness, Deff also increased. The level of shrinkage rose as slice thickness increased. The highest and lowest values of color changes were calculated at air temperatures of 70°C (52.3%) and 40°C (5.65%), respectively. Increasing air velocity led to an increase in SEC.

CONCLUSIONS

Optimum conditions for mooseer drying were achieved at air temperature of 70°C, infrared power of 867.46, air velocity of 0.59 m/s and slice thickness of 2 mm. At this point, Deff, shrinkage, color changes and SEC was obtained as 1.32×10–9 m2/s, 29.58%, 17.62% and 4.64 MJ/kg, respectively. The desir- ability value of 0.689 was achieved for the drying process. &nbsp.

背景

近年来，红外干燥作为一种用于多种农产品的替代干燥方法而受到欢迎。在农产品干燥中使用红外辐射技术具有多个优点。这些优点可能包括干燥时间缩短、能源效率高、成品质量高以及产品温度均匀。对于厚多孔材料进行间歇式红外和对流加热，与仅采用对流加热相比，干燥时间可以缩短，同时保持良好的食品质量和高能源效率。

方法

采用响应面法（RSM）来优化穆斯尔在红外 - 对流干燥条件下的干燥工艺。实验在空气温度为40、55和70°C、红外功率为500、1000和1500 W、空气流速为0.5、1.5和2.5 m/s以及切片厚度为2、4和6 mm的条件下进行。在本研究中，研究了有效水分扩散率（Deff）、收缩率、颜色变化和比能耗（SEC）。选择中心复合设计（CCD）进行工艺设计和优化。

结果

获得的Deff在1.4×10⁻¹⁰至3.57×10⁻⁹ m²/s之间。随着空气温度和切片厚度的增加，Deff也增加。收缩率水平随着切片厚度的增加而上升。颜色变化的最高值和最低值分别在空气温度为70°C（52.3%）和40°C（5.65%）时计算得出。空气流速增加导致SEC增加。

结论

穆斯尔干燥的最佳条件为空气温度70°C、红外功率867.46、空气流速0.59 m/s和切片厚度2 mm。此时，Deff、收缩率、颜色变化和SEC分别为1.32×10⁻⁹ m²/s、29.58%、17.62%和4.64 MJ/kg。干燥过程的可取性值达到0.689。

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