A Dimensionless Empirical Model to Predict Heat Transfer Coefficients for Cooling High-Moisture Meat Analog with Rectangular Dies

IF 3.2 2区农林科学 Q2 FOOD SCIENCE & TECHNOLOGY

Journal of Food Science Pub Date : 2025-07-05 DOI:10.1111/1750-3841.70366

Caleb E. Wagner, Leon Levine, Girish M. Ganjyal

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Abstract

ABSTRACT

An empirical dimensionless relationship useful for estimating heat transfer coefficients during continuous cooling of high moisture meat analog (HMMA) in rectangular linear cooling dies is described here. This information is essential for designing better cooling dies, which is timely since the cooling rate has recently been demonstrated to be important in controlling the quality of HMMA. Wheat-based HMMA was extruded as per an experimental design that varied cooling media temperature (36–72°C), product mass flow rate (2.7–4.5 kg/h), and die aspect ratios (a* = 0.28 or 0.45). In situ product and cooling media temperatures and mass flow rates were measured continuously using penetrative thermocouples and flow meters, respectively. Dimensional scaling of the underlying differential equations governing heat transfer for this system demonstrated a relationship between dimensionless Nusselt ( $\bar{Nu}$ ), Graetz (Gz⁻¹), and conduit aspect ratio (a*) numbers. Values for these numbers derived from the described experimental data were fit via nonlinear regression to a dimensionless model of the form $\bar{Nu}$ = A∙(Gz⁻¹)^B∙(C+D∙[1−a*]^E) with a high degree of quality (root mean square error = $\bar{Nu}$ ± 4.9, p < 0.0001). The resulting fit parameters were deemed reasonable given that the model was logically bound within theoretical Nusselt number limits. The model documented here allows for the estimation of heat transfer coefficients relevant to HMMA cooling dies, while also illustrating the effect of altering cooling die aspect ratios and heat exchanger lengths as would be considered when scaling up an HMMA process.

Practical Application

Carefully balanced cooling rates are essential for producing whole-cut type meat analogs with a desirable texture and fibrous quality at an economically feasible scale. This work presents a useful model for estimating the required cooling rates of whole-cut type meat analogs as a function of key processing criteria such as production rate and product size. Models like this would be useful for engineers and scientists attempting to optimize their meat analog processes, with such efforts ultimately resulting in reduced costs and improved quality associated with meat analog production.

Abstract Image

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用无因次经验模型预测矩形模具冷却高水分肉类模拟物的传热系数

本文描述了一个经验的无量纲关系，用于估计矩形线性冷却模具中高水分肉类模拟物（HMMA）连续冷却期间的传热系数。这些信息对于设计更好的冷却模具是必不可少的，这是及时的，因为冷却速度最近被证明是控制HMMA质量的重要因素。小麦基HMMA按照不同冷却介质温度（36-72°C）、产品质量流量（2.7-4.5 kg/h）和模具长径比（a* = 0.28或0.45）的实验设计进行挤压。使用穿透式热电偶和流量计分别连续测量原位产物和冷却介质的温度和质量流量。该系统控制传热的基本微分方程的尺度缩放证明了无因次Nusselt (Nu¯$\overline {{\mathrm{Nu}}}$), Graetz （Gz−1）和管道长径比（a*）数字之间的关系。从所描述的实验数据中得出的这些数字的值通过非线性回归拟合到形式为Nu¯$\overline {{\ mathm {Nu}}}$ = a∙(Gz−1)B∙(C+D∙[1−a*]E)的无因次模型，具有很高的质量（均方根误差= Nu）¯$\overline {{\ mathm {Nu}}}$±4.9,p <；0.0001)。得到的拟合参数被认为是合理的，因为该模型在逻辑上限定在理论努塞尔数范围内。这里记录的模型允许估计与HMMA冷却模具相关的传热系数，同时也说明了在扩大HMMA工艺时要考虑的改变冷却模具长宽比和热交换器长度的影响。实际应用在经济可行的规模上，精心平衡的冷却速率对于生产具有理想质地和纤维质量的整块型肉类类似物是必不可少的。这项工作提出了一个有用的模型，用于估计全切型肉类类似物所需的冷却速率，作为关键加工标准（如生产率和产品尺寸）的函数。这样的模型对于试图优化肉类模拟过程的工程师和科学家来说是有用的，这样的努力最终会降低成本，提高肉类模拟生产的质量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Food Science 工程技术-食品科技

CiteScore

7.10

自引率

2.60%

发文量

412

审稿时长

3.1 months

期刊介绍： The goal of the Journal of Food Science is to offer scientists, researchers, and other food professionals the opportunity to share knowledge of scientific advancements in the myriad disciplines affecting their work, through a respected peer-reviewed publication. The Journal of Food Science serves as an international forum for vital research and developments in food science. The range of topics covered in the journal include: -Concise Reviews and Hypotheses in Food Science -New Horizons in Food Research -Integrated Food Science -Food Chemistry -Food Engineering, Materials Science, and Nanotechnology -Food Microbiology and Safety -Sensory and Consumer Sciences -Health, Nutrition, and Food -Toxicology and Chemical Food Safety The Journal of Food Science publishes peer-reviewed articles that cover all aspects of food science, including safety and nutrition. Reviews should be 15 to 50 typewritten pages (including tables, figures, and references), should provide in-depth coverage of a narrowly defined topic, and should embody careful evaluation (weaknesses, strengths, explanation of discrepancies in results among similar studies) of all pertinent studies, so that insightful interpretations and conclusions can be presented. Hypothesis papers are especially appropriate in pioneering areas of research or important areas that are afflicted by scientific controversy.