T. Hoffmann, A. Ronzoni, D. Silva, S. Bertoli, C. K. Souza
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The mass loss results demonstrated a greater reduction for lettuce (21.7 %) than for strawberry (16.7 %) samples, which is related to the larger surface to mass ratio of lettuce. The strawberry transpiration rate presented a stable behavior after the first day of storage (1.31 g kg-1 h-1), which provides a linear reduction in the strawberry mass, while lettuce had a higher transpiration rate at the beginning (4.25 g kg-1 h-1) and showed a gradual reduction during cold storage until reaching 1.81 g kg-1 h-1. Water loss in food occurs through evaporative heat from respiration and a reduction in the water content leads to an increase in the internal food temperature. A gradual increase in the food temperatures was observed for both lettuce and strawberry (by 0.5 °C and 0.1 °C, respectively) during storage due to vegetable physiology. Based on the thermal history, a faster thermal response was observed for lettuce. 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引用次数: 9
摘要
水果和蔬菜是高度易腐的新鲜产品,在收获后的条件下,冷藏被广泛应用于延长食品的保质期。与制冷过程有关的主要现象是传热和传质,它们直接影响食品的腐烂。因此,本研究的目的是评估新鲜草莓和生菜在冷藏条件下的热量和质量分布。草莓和生菜样品从水培系统中收获,在5±1°C低相对湿度条件下(50- 60%)储存5天。为了将这两种主要现象联系起来,对传质和冷却动力学参数进行了量化。质量损失结果表明,生菜(21.7%)比草莓(16.7%)减少得更多,这与生菜的表面质量比更大有关。草莓的蒸腾速率在贮藏第一天后表现稳定(1.31 g kg-1 h-1),草莓的质量呈线性下降,而生菜的蒸腾速率在贮藏初期较高(4.25 g kg-1 h-1),在冷藏过程中逐渐下降,达到1.81 g kg-1 h-1。食物中的水分是通过呼吸作用产生的蒸发热量流失的,水分含量的减少会导致食物内部温度的升高。由于蔬菜生理原因,生菜和草莓的食物温度在储存期间逐渐升高(分别升高0.5°C和0.1°C)。根据热历史,生菜的热响应更快。生菜(8.7°C h-1)的冷却速率高于草莓(6.9°C h-1),生菜和草莓的半冷却时间分别为0.2 h和0.3 h。这些发现有助于更好地理解采后食物的行为,并可能导致新的保存技术。
Cooling Kinetics and Mass Transfer in Postharvest Preservation of Fresh Fruits and Vegetables Under Refrigerated Conditions
Fruits and vegetables are fresh products that are highly perishable and refrigeration is widely applied to extend food shelf-life under postharvest conditions. The main phenomena associated with the refrigeration process are heat and mass transfer, which directly influence food decay. For this reason, the objective of this research is to evaluate the thermal and mass profiles of fresh strawberry and lettuce, under refrigeration. Strawberry and lettuce samples were harvested from a hydroponic system and stored at 5 ± 1 °C for 5 days under low relative humidity conditions (50-60 %). In order to correlate the two main phenomena, the mass transfer and cooling kinetics parameters were quantified. The mass loss results demonstrated a greater reduction for lettuce (21.7 %) than for strawberry (16.7 %) samples, which is related to the larger surface to mass ratio of lettuce. The strawberry transpiration rate presented a stable behavior after the first day of storage (1.31 g kg-1 h-1), which provides a linear reduction in the strawberry mass, while lettuce had a higher transpiration rate at the beginning (4.25 g kg-1 h-1) and showed a gradual reduction during cold storage until reaching 1.81 g kg-1 h-1. Water loss in food occurs through evaporative heat from respiration and a reduction in the water content leads to an increase in the internal food temperature. A gradual increase in the food temperatures was observed for both lettuce and strawberry (by 0.5 °C and 0.1 °C, respectively) during storage due to vegetable physiology. Based on the thermal history, a faster thermal response was observed for lettuce. Also, the cooling rate was higher for lettuce (8.7 °C h-1) than for strawberry (6.9 °C h-1) and the half-cooling times were 0.2 h and 0.3 h for the lettuce and strawberry samples, respectively. These findings aid a better understanding of postharvest food behavior and could lead to novel preservation technologies.
期刊介绍:
Chemical Engineering Transactions (CET) aims to be a leading international journal for publication of original research and review articles in chemical, process, and environmental engineering. CET begin in 2002 as a vehicle for publication of high-quality papers in chemical engineering, connected with leading international conferences. In 2014, CET opened a new era as an internationally-recognised journal. Articles containing original research results, covering any aspect from molecular phenomena through to industrial case studies and design, with a strong influence of chemical engineering methodologies and ethos are particularly welcome. We encourage state-of-the-art contributions relating to the future of industrial processing, sustainable design, as well as transdisciplinary research that goes beyond the conventional bounds of chemical engineering. Short reviews on hot topics, emerging technologies, and other areas of high interest should highlight unsolved challenges and provide clear directions for future research. The journal publishes periodically with approximately 6 volumes per year. Core topic areas: -Batch processing- Biotechnology- Circular economy and integration- Environmental engineering- Fluid flow and fluid mechanics- Green materials and processing- Heat and mass transfer- Innovation engineering- Life cycle analysis and optimisation- Modelling and simulation- Operations and supply chain management- Particle technology- Process dynamics, flexibility, and control- Process integration and design- Process intensification and optimisation- Process safety- Product development- Reaction engineering- Renewable energy- Separation processes- Smart industry, city, and agriculture- Sustainability- Systems engineering- Thermodynamic- Waste minimisation, processing and management- Water and wastewater engineering
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