THERMOCHEMICAL BATTERY FOR POULTRY EGG INCUBATION
Hassan, S., Mustafa, M., Abdo, M., Attar, M. (2022). THERMOCHEMICAL BATTERY FOR POULTRY EGG INCUBATION. EKB Journal Management System, 39(3), 475-492. doi: 10.21608/mjae.2022.140944.1077
Shaymaa A. Hassan; Mubarak M. Mustafa; Marwa S. Abdo; Mahmoud Z. Attar. "THERMOCHEMICAL BATTERY FOR POULTRY EGG INCUBATION". EKB Journal Management System, 39, 3, 2022, 475-492. doi: 10.21608/mjae.2022.140944.1077
Hassan, S., Mustafa, M., Abdo, M., Attar, M. (2022). 'THERMOCHEMICAL BATTERY FOR POULTRY EGG INCUBATION', EKB Journal Management System, 39(3), pp. 475-492. doi: 10.21608/mjae.2022.140944.1077
Hassan, S., Mustafa, M., Abdo, M., Attar, M. THERMOCHEMICAL BATTERY FOR POULTRY EGG INCUBATION. EKB Journal Management System, 2022; 39(3): 475-492. doi: 10.21608/mjae.2022.140944.1077

THERMOCHEMICAL BATTERY FOR POULTRY EGG INCUBATION

Misr Journal of Agricultural Engineering
Article 8, Volume 39, Issue 3, July 2022, Page 475-492  XML PDF (2.02 MB)
Document Type: Original Article
DOI: 10.21608/mjae.2022.140944.1077
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Authors
Shaymaa A. Hassan1; Mubarak M. Mustafa2; Marwa S. Abdo3; Mahmoud Z. Attar email orcid 4
1Assist. Lect., Ag. Eng. Dept., Fac. of Ag., Ain Shams U., Cairo, Egypt.
2Prof., Ag. Eng. Dept., Fac. of Ag., Ain Shams U., Cairo, Egypt.
3Assist. Prof., Ag. Eng. Dept., Fac. of Ag., Ain Shams U., Cairo, Egypt.
4Assoc. Prof., Ag. Eng. Dept., Fac. of Ag., Ain Shams U., Cairo, Egypt.
Abstract
The current research aims to identify the possibilities of adopting stored solar energy in thermochemical ‎batteries (TCM batteries) to accommodate ‎optimum ‎thermotolerance of chick embryo ‎development during incubation.‎ ‎A twenty-five-egg capacity TCM incubator was constructed to test the performance of ‎three rechargeable and changeable (self-indicating silica gel, white-silica gel, and ‎natural ‎zeolite) thermochemical ‎batteries in modifying the ambient temperature of the incubated ‎eggs through TCM humidification.‎ And an electrical heating backup unit was used ‎as an emergency thermal compensation unit. The incubated eggs were turned horizontally every ‎hour by an automatic turning mechanism. The overall performance of the TCM incubator was ‎compared with that of a traditional -locally manufactured- electrical incubator. Results showed that the TCM‎ ‎incubator consumed , while the electrical ‎incubator consumed  during ‎the 21 days-cycle of incubation and hatchery. The total ‎heat loss from incubator walls and ventilation was 1.5 W, 9.8 W respectively. The twenty-five incubated eggs released  of metabolic energy. The calculated overall energy ‎efficiency of the TCM self-indicating silica gel - ‎incubator was 53.9% ‎and decreased to 44.4% ‎for natural zeolite cells, while white silica gel cells reached . The TCM ‎incubator was more ‎efficient in energy consumption by  compared to the traditional electrical incubator at the ‎same operating conditions. The hatchability ratio for the TCM ‎incubator was ‎‎  and ‎  for the electrical incubator regarding egg fertility ratios were ‎ and 84% ‎respectively. Using a TCM ‎incubator can significantly reduce power consumption and production ‎costs in the poultry industry.‎
Keywords
Poultry incubator; Solar energy; Thermochemical battery
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