Selection of The Most Suitable Type of Poultry Saloon in terms of Energy Consumption in Khuzestan Province

Vakili, H.; Kiani Deh Kiani, M.; Changizian, M.

doi:10.22067/jam.v10i2.77393

Document Type : Research Article

Authors

Mechanical Engineering Department, Shahid Chamran University of Ahvaz, Ahvaz, Iran

https://doi.org/10.22067/jam.v10i2.77393

Abstract

Introduction
According to the importance of energy and the impact of this input on the final price of a product, selection of materials and components of poultry saloons is very important. Poultry saloons are divided into two types: open saloons and closed saloons. In closed saloons, the choice of materials and components of the saloon (door, window, etc.) are more sensitive than the open type. Due to the climatic conditions of Khuzestan province, all of the used saloons in this province are almost closed. Poultry farms in Khuzestan province have a lot of cooling load in the warm seasons. If the materials and components of the saloons are not chosen properly, energy losses increase, and as a result, the price of meat increases. Therefore, investigating of heating and cooling loads of saloons and use of suitable components to prevent energy losses is necessary. Energy modeling of saloons and buildings is done by various software (Plast Energy, Design Builder, Trnsys, etc.). One of the most efficient and precise of this software is Carrier.
Materials and Methods
This study was conducted to calculate heating and cooling loads in different climates of Khuzestan province. In this research, the cities of Izeh, Shoosh, Abadan and Andimeshk were selected as corresponding to different climates in the province.
Required data for software was collected in three categories: (a) Weather data (geographic information, location of the saloon, local time zone and local soil specifications), (b) Data about the physical properties of the building (general specifications of the space, internal sources of heat production (personslabors, poultry, equipment), (c) Specifications of walls, floor, windows and doors, ceiling and lighters, (d) Infiltration of air, (e) Systems, and (f) Information on power and fuel consumption.
In this research, a rectangular saloon with dimensions of 85×16 meter was considered for all three types of conventional saloons in the province (block, brick and panel), which are the common dimensions and the capacity of these saloons is 20,000 broiler chickens. In this study, Carrier software was used to calculate heating and cooling loads. The results of software were verified by the amount of fuel and power consumption.
Results and Discussion
The sand and soil floors had the highest cooling load by 48828 and 53012 kJ h^-1, respectively, while concrete and mosaic floors had lower cooling load than them. The heating load of these two floors (3906 kJ h^-1) was less than that in the sand and soil floors. Concrete floor had better conditions to choose because of the less cost than the mosaic floor.
Comparison of heating and cooling loads in different types of walls made of various materials showed that the block wall had the highest heating load of 429356 kJ h^-1 and the highest cooling load by 658356 kJ h^-1, while the sandwich panel wall had the lowest heating load by 116873 kJ h^-1 and the lowest cooling load by 123618 kJ h^-1.
Three types of doors are commonly used in poultry houses: iron, fiberglass and aluminum. The results showed that the iron and fiberglass doors had the highest and lowest heating and cooling loads, respectively. The investigation of the effect of different types of windows on heating and cooling loads showed that iron and plastic windows had the highest and lowest heating and cooling loads, respectively. The results showed that Irannait ceiling had the highest heating and cooling loads by 371416 kJ h^-1 and 787535 kJ h^-1, respectively, while the ceiling made of sandwich panel had the lowest heating and cooling loads by 72756 kJ h^-1 and 72429 kJ h^-1, respectively, because of low heat transfer coefficient.
Comparison of heating load of the saloons showed that the block saloon had the highest heating load by 891525 kJ h^-1and the suggested saloon in this study had the lowest heating load by 309068 kJ h^-1. The block and suggested saloons also had the highest and lowest cooling loads by 1604828 kJ h^-1 and 330795 kJ h^-1, respectively.
Conclusion
The amount of heating and cooling loads for suggested saloon were 29.6% and 18.24% lower than that of brick and block saloons, respectively. The difference in the cost of constructing suggested and brick (the most common saloon in the province) saloons was 28.9 million tomans. By considering the difference in the cost of energy consumption of them (11.726 million tomans), this amount will be compensated after 2 years and 5 months and then will be returned on investment.

Keywords

20.1001.1.22286829.1399.10.2.20.8

Open Access

©2020 The author(s). This article is licensed under Creative Commons Attribution 4.0 International License (CC BY 4.0), which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source.

References

1. AlQdah, K. 2010. Potential opportunities for energy savings in a Jordanian poultry company. Energy Conversion and Management 51: 1651-1655.

2. Bagi, M. 2015. Principles and breeding of broiler chickens. Marze Danesh. Tehran. (In Farsi).

3. Eskandar, M., H. Bakhoda, and M. Almasi. 2015. Economic study of broiler chickens in Ardebil. in International Conference on Economics and Management of Agricultural Sciences. Anzali. (In Farsi).

4. Hasani, A., M. Hir, and S. Farhang. 2013. Measuring Iranian provinces efficiency in meaty poultry production by use of Data Envelopment Analysis. International Research Journal of Applied and Basic Sciences 4: 3338-3346 (In Farsi).

5. Jafarian, M., H. Sadrneya, M. H. Aghkhani, and B. Safari. 2010. The Effect of Heat Damage in Poultry Using the Basic Equations (A Case Study of School of Agriculture of Ferdowsi University of Mashhad). Sixth National Congress of Agricultural Machinery Engineering and Mechanization. Tehran, Iran. (In Farsi).

6. Karbassi, A. R., H. Jafari, A. Naghikhani, and M. Ramezani. 2015. simulation of Energy Consumption by HVAC systems in a building located in Tehran and comparative study on impacts of orientation and windows sizes on energy consumption. International Conferences of Emerging Trends in energy coservation. Tehran, Iran. (In Farsi).

7. Kochakzadeh, A., and B. Tajari. 2015. Control of energy consumption in poultry industry. in Emerging Trends in Energy Conservation 4rd Conference. Tehran. (In Farsi).

8. Kythreotou, N., S. A. Tassou, and G. Florides. 2011. The contribution of direct energy use for livestock breeding to the greenhouse gases emissions of Cyprus. Energy 36: 6090-6097.

9. Lotfipour, M. S. 2008. Laying Chicken Breeding. Marze Danesh. Tehran. (In Farsi).

10. Mostashari Mohases, M. 2017. Principles of designing broiler chickens in accordance with new breeding methods and minimum energy losses. Agricultural Research, Training and Promotion Organization. (In Farsi).

11. Payandeh, Z., K. Kheiralipour, and M. Karimi. 2016. Evaluation of energy efficiency of broiler production farms using data envelopment analysis technique, case study: Isfahan Province. Iranian Journal of Biosystem Engineering 47: 577-585. (In Farsi).

12. Rajaniemi, M., and J. Ahokas. 2012. A case study of energy consumption measurement system in broiler production. Agronomy Research Biosystem Engineering Special. (In Farsi).

13. Sadrnia, H., M. Khojastehpour, H. Aghel, and A. Saiedi Rashk Olya. 2017. Analysis of different inputs share and determination of energy Indices in broilers production in Mashhad city. Journal of Agricultural Machinery 7: 285-297. (In Farsi).

14. Schwab, M., and C. Simonson. 2004. Review of building energy simulation tools that include moisture storage in building materials and HVAC systems. Draft Report IEA Annex 41.

15. Shekoohi Dehkordi, K. and M. Farhadian. 2017. Investigating the effect of Atrium-related Green Roof Cooling and Heating loads on Energy Management in Pedagogical Spaces in Cold Climate. Journal of Environmental Science and Technology 19: 573-583. (In Farsi).

16. Swan, L. G., and V. I. Ugursal. 2009. Modeling of end-use energy consumption in the residential sector: A review of modeling techniques. Renewable and Sustainable Energy Reviews 13: 1819-1835.

17. Vahedi, A., and M. Younesi Almoti. 2017. Determinination of Energy Indices of Broiler Units in Alborz province. Agricultural Mechanization and Systems Research 17: 41-54. (In Farsi).

18. Valade, R. E. 2009. Development and verification of a simplified building energy model. Georgia Institute of Technology.

19. Wang, Y., W. Zheng, H. Shi, and B. Li. 2018. Optimising the design of confined laying hen house insulation requirements in cold climates without using supplementary heat. Biosystems Engineering 174: 282-294.

20. Zanganeh, M., G. Haydari nejad, and S. Delfani. 2009. Determination of the amount of refrigerated load of the building using thermal comfort calculations and comparison with Karir software. 7th Annual Conference of Mechanical Engineering. Tehran, Iran. (In Farsi).

Name *

Email Address *

Affiliation *

Comments *

Security Code *

Journal of Agricultural Machinery

Selection of The Most Suitable Type of Poultry Saloon in terms of Energy Consumption in Khuzestan Province

References

References

Send comment about this article

Volume 10, Issue 2 - Serial Number 20
Fall and Winter
2020
Pages 361-373

Selection of The Most Suitable Type of Poultry Saloon in terms of Energy Consumption in Khuzestan Province

References

References

Send comment about this article

Volume 10, Issue 2 - Serial Number 20Fall and Winter 2020Pages 361-373

Volume 10, Issue 2 - Serial Number 20
Fall and Winter
2020
Pages 361-373