Effects of indirect air cooling combined with direct evaporative cooling on the quality of stored tomato fruit

Sibanda, Sipho; Workneh, Tilahun Seyoum

doi:10.1080/19476337.2019.1622595

Cited by 7 publications

(5 citation statements)

References 32 publications

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“…The values of 85 > RH < 95 are ideally storage conditions for produce like avocados, bananas, cucumbers, mangoes, oranges, papaya, sweet potatoes and tomatoes [36]. The IAC þ EC system increased ambient RH from 47% to 87-93%, which is in agreement with [14] that obtained values of 75-88%. However, the result of average ambient RH ranging from 44 to 65% between 10h00 and 17h00 was below that recommended by [37] and hence this will reduce the shelf life of fresh FV storage.…”

Section: Variation Of Relative Humiditysupporting

confidence: 83%

“…This demonstrates that the use of IAC þ EC significantly increases the storage chamber RH and thus prolonging the shelf life of tomatoes and many other fresh produce. The results of incorporating a heat exchanger in this study indicate that the EC system increased the relative humidity of the air when extended to hot and sub-humid to humid conditions, indicating reduction in physiological weight loss from FV as evidenced by the working of [14].…”

Section: Variation Of Relative Humiditymentioning

confidence: 74%

“…It is therefore important to develop, evaluate the performance and determine the cooling efficiency of small-scale farming sized IAC þ EC system as there is dearth of information. This work is a continuation of the work reported by [14]. To adopt an IAC þ EC system, an energy source to power the heat exchanger (desiccation unit), fans and water pump for air and water circulation is required [15].…”

Section: Introductionmentioning

confidence: 86%

“…The array system consisted of a 3 string-3 series 330W solar modules with 44.80 V rated voltage and 8.69 A current, a 145 VDC-60 A (SANTAKUPS PC16-6015F) solar charge controller, 5 kW-60A (Sinowave, P11-LW5000NC48-C) inverter, 3 string-4 series 230 AH batteries. This translated to practical power output from the solar panels of 2 639 W against the design load for all electrical appliances of 2 310 W as determined by [14] in a parallel work to this manuscript.…”

Section: Description Of the Indirect Air Cooling System Combined Withmentioning

confidence: 97%

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Performance evaluation of an indirect air cooling system combined with evaporative cooling

Sibanda

Workneh

2020

Heliyon

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This study developed an indirect air-cooling combined with evaporative cooling (IAC þ EC) system for temporary storage of fruit and vegetables (FV) to improve the shelf life of fresh produce under hot and humid climatic conditions. The aim of the study was to investigate the effect of IAC þ EC in providing optimum storage environment of temperature and relative humidity (RH) for the tomato fruit compared to storage under ambient conditions. The IAC þ EC system had a 53-m 3 storage chamber able to store 3.8 tons of tomatoes. Solar energy during the day and a battery bank facility at night powered the cooling system. The structure was constructed and assembled at Ukulinga research center in Pietermaritzburg. The performance of the IAC þ EC was evaluated based on the temperature and the RH measured hourly from 05h00-22h00 daily during a period of 28 days. Temperature and RH were measured in the psychometric unit, various positions in the storage chamber and at ambient conditions. There were significant variations (P < 0.001) in temperature and RH between storage and ambient conditions. The temperature inside the storage chamber was on average 7 C-16 C lower while the average RH was 13%-41% higher than ambient conditions. Temperature and RH at the exhaust end of the IAC þ EC storage chamber were 16.40 C and 88.9% compared to 30.9 C and 47.6% under ambient conditions. Such conditions can enhance the shelf life of FV of moderate respiration rates. Inside the storage chamber, temperature was 15.7 C-16.4 C while the RH was 89.6%-93.8% depending on location. The cooler efficiency varied from 88.04% to 95.6%. The IAC þ EC system performed at the same level as evaporative cooling under dry and arid conditions. The results in this study are evidence that IAC þ EC system can provide optimum storage conditions for FV as well as being a low-cost technology utilizable in hot and sub-humid to humid areas in sub-Saharan Africa.

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Section: Variation Of Relative Humiditysupporting

confidence: 83%

Section: Variation Of Relative Humiditymentioning

confidence: 74%

Section: Introductionmentioning

confidence: 86%

Section: Description Of the Indirect Air Cooling System Combined Withmentioning

confidence: 97%

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Performance evaluation of an indirect air cooling system combined with evaporative cooling

Sibanda

Workneh

2020

Heliyon

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“…Active and passive cooler types exist, where active coolers apply forced airflow generation to evaporate water from a cooling medium. A lot of work has already been done on evaporative cooling (Anyanwu, 2004;Mittal et al, 2006;Dadhich et al, 2008;Getinet et al, 2008;Vanndy et al, 2008;Olosunde et al, 2016;Olosunde et al, 2009;Chinenye, 2011;Mogaji and Fapetu, 2011;Shitanda et al, 2011;Manuwa and Odey, 2012;Chinenye et al, 2013;Mogaji et al, 2013;Samira et al, 2013;Deoraj et al, 2015;Ogbuagu et al, 2016;Zakari et al, 2016;Alam et al, 2017;Ambuko et al, 2017;Korir et al, 2017;Poku et al, 2017;Nkolisa et al, 2018;Adekanye et al, 2019;Sibanda and Workneh, 2019;Abaranji et al, 2021;Patel et al, 2021;Raza et al, 2021;Sibanda and Seyoum Workneh, 2021). Based on this literature, postharvest storage us usually done using active (~50%) and passive (~30%) direct coolers.…”

Section: Introductionmentioning

confidence: 99%

Passive evaporative coolers for postharvest storage of fruit and vegetables: Where to best deploy them and how well do they perform

Defraeye

Shoji

Schudel

et al. 2023

Front. Food. Sci. Technol.

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Passive evaporative coolers have a huge potential to help smallholder farmers to preserve their fresh fruit and vegetables longer after harvest. However, we could benefit from more transparent information on where evaporative coolers perform sufficiently well to extend the postharvest life of the fresh produce significantly. Unsatisfactory evaporative cooler performance is a potential cause for farmers' limited adoption of this technology to reduce food losses. Our objective is to present easy-to-use tools that help to better scope regions with the best potential for direct passive evaporative coolers and for effectively deploying it. This information should help avoid installing evaporative coolers in areas with environmental conditions that only induce a temperature depression of a few degrees Celsius. Concretely, we developed design charts of the achievable temperature depression by evaporative cooling based on the local air temperature and humidity. We quantified for apple, banana, mango, and tomato the resulting additional days in postharvest life gained by storing the produce in an evaporative cooler. For these fruits, the gain in postharvest life using passive cooling is roughly 2–15 days for temperate climates with an ambient temperature of 20°C and a humidity of 50%. We present geographical maps of India, Nigeria, and the entire world at a 30 km resolution that answer how much evaporative cooling can maximally decrease the produce temperature and extend postharvest life for banana fruit. We found that passive evaporative cooling could induce up to a 7-day gain in postharvest life. We make these maps available online. We also quantify how well evaporative coolers perform concerning reducing the temperature and how they should be sized. Our results will facilitate installing evaporative coolers only in suitable regions. Our data also show in which months the cooler can be operated with the best performance. We thereby help avoid disillusion and loss of trust in the technology with smallholder farmers, policymakers, farmers, or farmer cooperatives. Further catalyzing the implementation of small-scale evaporative coolers can bring farmers significant gains in postharvest life, reduce food losses, and increase revenues.

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The charcoal cooling blanket: A scalable, simple, self-supporting evaporative cooling device for preserving fresh foods

Defraeye,

Schudel,

Shrivastava

et al. 2024

Biosystems Engineering

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Effects of indirect air cooling combined with direct evaporative cooling on the quality of stored tomato fruit

Cited by 7 publications

References 32 publications

Performance evaluation of an indirect air cooling system combined with evaporative cooling

Performance evaluation of an indirect air cooling system combined with evaporative cooling

Passive evaporative coolers for postharvest storage of fruit and vegetables: Where to best deploy them and how well do they perform

The charcoal cooling blanket: A scalable, simple, self-supporting evaporative cooling device for preserving fresh foods

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