Optimizing precooling of large beef carcasses using a comprehensive computational fluid dynamics model

Delele, Mulugeta Admasu; Kuffi, Kumsa Delessa; Smet, Stefaan De; Nicolaı̈, Bart; Verboven, Pieter

doi:10.1111/jfpe.13053

Cited by 5 publications

(2 citation statements)

References 38 publications

(105 reference statements)

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“…[15]. WHC can be measured as drip loss dependent on the body temperature of the carcass and the velocity, humidity, and temperature of the air in the chilling room [16]. Many factors influence WHC, which include physiological (pH, breed, sex, age, muscle type, area of muscle), rearing conditions (feeding, administration, pre slaughter), slaughter conditions (killing method, handling, packing, storage, freezing, thawing, and aging) [17].…”

Section: Water Holding Capacitymentioning

confidence: 99%

Serum Markers for Evaluating Beef Meat Quality: Potential Applications in Cell-Cultured Meat Production

Kathera,

Kim

2024

Preprint

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Cell-culture meat is a novel concept to replace traditional meat produced from animals, and to satisfy rising food demands due to the world population growth. It is still a young field and requires to solve technical issues including cell sources and types, efficient culture for large scale production, taste and texture for customer satisfaction. The current review summarized traditional beef meat production and evaluation methods for customer satisfaction. In particular, serum biomarkers for beef meat evaluation are discussed, which can be applicated for cell-culture meat production.

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Section: Water Holding Capacitymentioning

confidence: 99%

Serum Markers for Evaluating Beef Meat Quality: Potential Applications in Cell-Cultured Meat Production

Kathera,

Kim

2024

Preprint

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“…The results revealed the advantage of utilizing a precooling unit that works with an optimum choice of velocity, cooling air temperature, and precooling time. They concluded that using low air velocity at −30°C is more beneficial than using a high airflow fan that consumes high energy value (Delele et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

A computational‐experimental investigation of thermal vapor compressor as an energy saving tool for the crystallization of sugar in a sugar processing plant

Fanaei

Nikbakht

Hassanpour

2021

J Food Process Engineering

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Energy saving in the food industry is of a great deal of importance. Thermal vapor compressors (TVCs) do not have moving parts which offer advantages including simplicity, low construction capital, and low maintenance costs. In this study, a TVC is designed, and simulated to recover waste vapor streams and reuse the recovered streams in the crystallization of sugar. Computational fluid dynamics is employed to simulate the flows. The effect of motive steam pressure on the entrainment ratio and compressor ratio is simulated. Thermodynamics parameters such as static pressure, temperature, velocity, Mach number, and mass ratios of motive steam and suction are assessed. As the flow is of jet flow type, the realizable k‐e turbulent model is used to model the turbulence. The results show that by applying the motive steam at a pressure of 28 bars (boiler outlet), the pressure and temperature of discharge vapor reach the values of 0.65 bar and 511 K, respectively. The average mass ratios of motive and suction flow at the output of the designed TVC diffuser are 0.59 and 0.41, respectively. As the crystallization pressure demand is 0.6 bar, the findings reveal that the discharged vapor from TVC has sufficient enthalpy to be consumed in the crystallization section, hence making the whole process more efficient. Practical application Equipping the crystallization section of the sugar factory with a thermal vapor compressor, beside the recovery of low‐pressure vapor with motive steam, can reduce energy consumption and play a key role in decreasing fossil pollution. Computational Fluid Dynamics is a validated tool in the simulation of the food processing phenomenon. In terms of TVC optimization, the results obtained from this research serve to designers and process managers to get a detailed perception of energy reduction scenarios and recovery of low enthalpy streams.

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Advanced Computational Tools for Enhanced Food Quality and Safety

S.,

B. K.,

Debnath

et al. 2023

Food Engineering Series

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Optimizing precooling of large beef carcasses using a comprehensive computational fluid dynamics model

Cited by 5 publications

References 38 publications

Serum Markers for Evaluating Beef Meat Quality: Potential Applications in Cell-Cultured Meat Production

Serum Markers for Evaluating Beef Meat Quality: Potential Applications in Cell-Cultured Meat Production

A computational‐experimental investigation of thermal vapor compressor as an energy saving tool for the crystallization of sugar in a sugar processing plant

Advanced Computational Tools for Enhanced Food Quality and Safety

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