Development and performance evaluation of a double chamber evaporative cooling system for storage of vegetables

Authors

DOI:

https://doi.org/10.15587/2706-5448.2022.267580

Keywords:

evaporative cooling system, Amaranthus, performance assessment, river sand, sawdust, ambient conditions

Abstract

The object of research is a double chamber evaporative cooling system for the storage of vegetables with one chamber filled River sand, the other Sawdust as absorbents and Ambient chamber storage conditions being the third treatment (control). Amaranthus was used as the test crop. The structure was developed both internally and externally using six (6) inches concrete blocks and plastered with cemented mortar.

460 g each of Garden fresh vegetables (Amaranthus) were collected and kept chambers of the evaporative cooling system and ambient chamber conditions (control), then, replicated twice respectively. Change in quality (weight reduction, withering, change in colour), temperature change, relative humility and cooling effectiveness were the parameter assessed during the experiment and were subjected to analysis of variance (ANOVA) using Duncan’s Multiply Test at 5 % level of significance. The experiment was conducted and analyzed at Crop Production Department of the Federal College of Forestry (Jericho Ibadan, Nigeria). The study revealed there were no significant difference between relative humidity (%), absorbent cooling efficiency (%) for absorbent materials in the evaporative cooling chambers were (89.90 %, 89.30 % and 75.80 %) and (88.50 %, 82.50 % and 80.40 %) for day 10 and 15 River Sand (RS), sawdust (SD) and Control (Cont.) respectively. While, Control had moderately highest temperature reading at day 13 (30 °C), followed by Sawdust (28.90 °C) and River Sand (27.80 °C). However, vegetables kept in the ambient chamber were observed to rot faster than those in the double chamber of the evaporative cooling system. Complete deterioration occurred at day 5 for ambient chamber conditions. The quality of the vegetables kept in double evaporative cooling chamber using river sand performed best in the storage of Amaranthus.

This research hereby recommended that evaporative cooling chambers filled with river sand and constant water supplied to keep the absorbent moist should be utilized for storage of Amaranths and other vegetables in an evaporative cooling system. Further studies should vary the use of different porous absorbent. Also, cooling fans should also be incorporated to the storage system to enhance cooling efficiency.

Supporting Agency

  • Presentation of research in the form of publication through financial support in the form of a grant from SUES (Support to Ukrainian Editorial Staff).

Author Biographies

Dare Ibiyeye, Federal College of Forestry

Lecturer

Department of Crop Production Technology

Oluwatoyin Olunloyo, Federal College of Forestry

Lecturer

Department of Crop Production Technology

Adeniyi Aderemi, Federal College of Forestry

Lecturer

Department of Agricultural Technology

Tolulope Bamigboye, Federal College of Forestry

Lecturer

Department of Crop Production Technology

Haastrup Nathaniel, Federal College of Forestry

Senior Research Fellow

Forest Conservation and Protection Department

References

  1. Singh, A. K., Surenda, P., Priysbrata, S., Misshra, D. (2017). Design, Development and Performance Evaluation of Low Cost Zero Energy Improved Passive Cool Chamber for Enhancing Shelf-life of Vegetables. Agricultural Engineering Today, 41 (4), 72–79.
  2. Odesola, I. F., Onyebuchi, O. (2009). A Review of Porous Evaporative Cooling for the Preservation of Fruits and Vegetable. The Pacific Journal of Science and Technology, 109 (2), 936–941.
  3. Dadhich, S. M., Dadhich, H., Verma, R. (2008). Comparative Study on Storage of Fruits and Vegetables in Evaporative Cool Chamber and in Ambient. International Journal of Food Engineering, 4 (1). doi: https://doi.org/10.2202/1556-3758.1147
  4. Jha, S. N., Chopra, S. (2006). Selection of bricks and cooling pad for construction of evaporative cooled storage structure. Journal of the Institution of Engineers (India): Agricultural Engineering Division, 87 (1), 25–28.
  5. Grubben, G. J. H.; Grubben, G. J. H., Denton, O. A. (Eds.) (2004). Amaranthus blitum L. PROTA 2. Vegetables/L`egumes. Wageningen: Prota, 74–83.
  6. Camargo, J. (2008). Evaporative cooling: water for thermal comfort. Ambiente e Agua – An Interdisciplinary Journal of Applied Science, 3 (2), 51–61. doi: https://doi.org/10.4136/ambi-agua.52
  7. Ronoh, E. K., Kanali, C. L., Ndirangu, S. N., Mang’oka, S. M., Annpurity, W. J. (2018). Performance Evaluatuon of Evaporative Charcoal cooler and its Effects on Quality of Leafy Vegetables. Journal of Postharvest Technology, 6 (3), 60–66.
  8. lal Basediya, A., Samuel, D. V. K., Beera, V. (2011). Evaporative cooling system for storage of fruits and vegetables – a review. Journal of Food Science and Technology, 50 (3), 429–442. doi: https://doi.org/10.1007/s13197-011-0311-6
  9. Aphane, J., Chadha, M. L., Oluoch, M. O. (2003). Increasing the consumption of micronutrient-rich foods through production of indigenous foods. FAO/AVRDC International Workshop Proceedings. AVRDC – The World Vegetable Centre Shanua, Taiwan: AVRDC Publication No. 03–561, 1–77.
  10. Olunloyo, O. O., Olunloyo, A. A., Fasunloye, K. S. (2017). Performance evaluation of two different Evaporative Pad Materials in Tomato storage. Proceedings of the 1st Intl. Conference of the Academic Staff union of polytechnic. Lagos state polytechnic chapter, 605–611.
  11. Grubben, G. J. H.; Grubben, G. J. H., Denton, O. A. (Eds.) (2004). Amaranthus cruentus L. PROTA 2. Vegetables/L`egumes. Wageningen: Prota, 205–213.
  12. Ambuko, J., Wanjiru, F., Chemining’wa, G. N., Owino, W. O., Mwachoni, E. (2017). Preservation of Postharvest Quality of Leafy Amaranth (Amaranthus spp.) Vegetables Using Evaporative Cooling. Journal of Food Quality, 2017, 1–6. doi: https://doi.org/10.1155/2017/5303156
  13. Ben-Yehoshua, S., Rodov, V. (2002). Transpiration and Water Stress. Postharvest Physiology and Pathology of Vegetables. doi: https://doi.org/10.1201/9780203910092.ch5
Development and performance evaluation of a double chamber evaporative cooling system for storage of vegetables

Downloads

Published

2022-11-27

How to Cite

Ibiyeye, D., Olunloyo, O., Aderemi, A., Bamigboye, T., & Nathaniel, H. (2022). Development and performance evaluation of a double chamber evaporative cooling system for storage of vegetables. Technology Audit and Production Reserves, 5(3(67), 34–39. https://doi.org/10.15587/2706-5448.2022.267580

Issue

Section

Food Production Technology: Reports on Research Projects