Energy indices in irrigated wheat production under conservation and conventional tillage and planting methods

Hosseini, S. M.; Afzalinia, S.; Mollaei, K.

doi:10.22067/jam.v6i1.29328

Document Type : Research Article

Authors

¹ Department of Soil and Water Research, Fars Research and Training Center for Agriculture and Natural Resources, AREEO, Shiraz, Iran

² Department of Agricultural Engineering Research, Fars Research and Training Center for Agriculture and Natural Resources, AREEO, Shiraz, Iran

³ Department of Agricultural Machinery, Eghlid Azad University, Eghlid, Iran

https://doi.org/10.22067/jam.v6i1.29328

Abstract

Introduction: Conservation tillage system was recommended for soil erosion control in North America for the first time 60 years ago (Wang et al., 2006). Using this tillage system including minimum and zero tillage has been rapidly developed in recent years. Thearea covered by zero tillage in 2006 was 95 million ha all over the world (Dumanski et al., 2006). In addition to saving soil and water resources, conservation tillage system reduces energy consumption and improves energy indices by combining different tillage and planting operations. Results of research conducted in Fars province shows that conservation tillage saves fuel consumption for 77% compared to the conventional system (Afzalinia et al., 2009). Conservation tillage also reduces energy consumption from 23.6 to 42.8% in comparison to the conventional tillage (Rusu, 2005). Since energy indices would be affected by reduced input energies in conservation tillage, this research was conducted to evaluate the effect of different tillage and planting methods on energy inputs and energy indices in irrigated wheat production in Eghlid region.
Materials and Methods: This research was performed to evaluate and compare the energy indices in irrigated wheat production under different tillage and planting methods. The study was conducted in the form of a randomized complete block experimental design with five treatments and three replications in Eghlid region. The treatments were included, conventional tillage and seed broadcasting (A), conventional tillage and planting with Machine Barzegar grain drill (B), reduced tillage and seeding with Roto-seeder (C), direct seeding with Jairan Sanaat grain drill (D), and direct seeding with Sfoggia direct drill (E). Experimental plots with 10 by 50 m dimensions were used in this study. Loss crop residues were taken out of the experimental plots and standing crop residues were retained in the plots. In the conventional tillage method, primary tillage was performed using a moldboard plow and secondary tillage operation was done using a disk harrow and land leveler. Seed bed was prepared in the reduced tillage method using a tine and disc cultivator which was able to complete the primary and secondary tillage operations simultaneously. Wheat seed was directly planted using direct planter without any seed bed preparation in the zero tillage method. Surface irrigation method was used to irrigate the plots and 11970 m3/ha water was consumed in each treatment. Input energies including direct energy (diesel and electricity) and indirect energy (water, labor, seed, fertilizer, chemicals, and machinery) were measured and calculated. Output energies (energy of grain and straw) were measured in each treatment and the share of each input energy, energy ratio, net energy gain, and energy productivity were determined and compared. Collected data were analyzed using SAS software and Duncan’s multiple range tests was used to compare the treatments means.
Results and Discussion: Results showed that tillage and planting methods had a significant effect on fuel and machinery energies; while, the total input energy, crop grain yield, and crop biologic yield were not affected by the tillage and planting methods (Table 4). Fertilizers and chemicals had the highest contribution in input energy of all treatments. Results also indicated that reduced tillage and seeding with Roto-seeder had the highest energy ratio (1.46) and the lowest energy ratio (1.40) was related to the conventional tillage methods (Fig.1). The highest net energy gain (47653 MJ) was obtained from the reduced tillage and seeding with Roto-seeder; while, the lowest amount of net energy gain (41388 MJ) was related to the conventional tillage and planting with Machine Barzegar grain drill (Fig.3). Results also showed that the reduced tillage and seeding with Roto-seeder had the highest energy productivity (0.115 kg MJ-1) and the conventional tillage treatments had the lowest energy productivity of 0.110 kg MJ-1 (Fig.4).
Conclusions: Results of this study showed that conservation tillage treatments (minimum and zero tillage) reduced total energy consumption (input energy) by decreasing fuel consumption and mechanical energy (energy of machinery) compared to the conventional tillage. Therefore, conservation tillage treatments had the higher energy ratio, net energy gain, and energy productivity compared to the conventional treatments. For this reason, conventional tillage and planting methods could be replaced with conservation tillage systems in Eghlid region. Meanwhile, in order to obtain more accurate results in energy indices comparison, differences in water consumption in various tillage and planting methods should be also considered.

Keywords

20.1001.1.22286829.1395.6.1.21.9

References

1. Afzalinia, S., S. E. Dehghanian, and M. H. Talati. 2009. Effect of conservation tillage on soil physical properties, fuel consumption, and wheat yield. 4th Conference on Energy Efficiency and Agricultural Engineering, Rousse, Bulgaria.

2. Bilalis, D., P. E. Kamariari, A. Karkanis, A. Efthimladou, A. Zorpas, and I. Kakabouk. 2013. Energy inputs, output and productivity in organic and conventional maize and tomato production, under Mediterranean conditions. Notulae Botanicae Horti Agrobotanici 41 (1): 190-194.

3. Chen, G., and C. Baillie. 2009. Development of a framework and tool to assess on-farm energy uses of cotton production. Energy Conversion and Management 50 (7): 1256-1263.

4. Friedrich, T., R. Derpsch, and A. Kassam. 2012. Overview of the global spread of conservation agriculture. The Journal of Field Actions Science Reports (Especial Issue) 6: 1-7.

5. Erenstein, O., and V. Laxmi. 2008. Zero tillage impacts in India’s rice–wheat systems: A review. Soil Tillage Research 100: 1-14.

6. Hobbs, P. R., G. S. Giri, and P. Grace. 1997. Reduced and zero tillage options for the establishment of wheat after rice in South Asia. Rice-Wheat Consortium Technical Bulletin 6.

7. Kaihani, A. 2006. Preliminary evaluation of human energy in agricultural mechanization projects. Evaluation of energy trend in sugarcane production in an Agro-industry unit in south Ahvaz. 4th Congress on Agricultural Engineering and Mechanization, Tabriz, Iran. (In Farsi).

8. Kitani, O., T. Jungbluth, R. M. Peart, and A. Ramdani. 1999. CIGR Handbook of Agricultural Engineers, Energy and Biomass Engineering, vol. 5, ASAE Publication, MI.

9. Kraatz, S. 2008. Energy inputs for corn production in Wisconsin and Germany. ASABE Annual International Meeting, Rhode, Island.

10. Loghvi, M., and A. Hoseinpour. 2004. Attachment of a v-wheel packer to a moldboard plow for combining primary and secondary tillage operations. Iranian Journal of Agricultural Science 35 (4): 1015-1024. (In Farsi).

11. McLaughlin, N. B., C. F. Drury, W. D. Reynolds, X. M. Yang, Y. X. Li, T. W. Welacky, and G. Stewart. 2008. Energy inputs for conservation and conventional primary tillage implements in a clay loam soil. Transactions of the ASABE 51 (4): 1153-1163.

12. Moraditochaee, M. 2012. Investigation energy indices of corn production in north of Iran. ARPN Journal of Agricultural and Biological Science 7 (5): 376-379.

13. Nasirian, N., M. Almasi, S. Minaee, and H. Bakhoda. 2006. Evaluation of energy trend in sugarcane production in an Agro-industry unit in south Ahvaz. 4th Congress on Agricultural Engineering and Mechanization, Tabriz, Iran. (In Farsi).

14. Ovtit-Canavate, J., and J. L. Hernanz. 1999. Handbook of Agricultural Engineering, Energy and Biomass Engineering, vol. 5, ASAE Publication, MI, USA.

15. Pishgar Komleh, S. H., A. Keyhani, Sh. Raﬁee, and P. Sefeedpary. 2011. Energy use and economic analysis of corn silage production under three cultivated area levels in Tehran province of Iran. Energy 36: 3335-3341.

16. Raﬁee, S., S. H. Mousavi Avval, and A. Mohammadi. 2010. Modeling and sensitivity analysis of energy inputs for apple production in Iran. Energy 35: 3301-3306.

17. Razzaghi, M., A. Waismoradi, and H. Rahmati. 2012. Energy efficiency of different tillage systems in forage corn production. International Journal of Agriculture and Crop Sciences 4 (22):1644-1652.

18. Rusu, T. 2005. The influence of minimum tillage systems upon the soil properties, yield and energy efficiency in some arable crops. Journal of Central European Agriculture 6 (3): 287-294.

19. Safa, M., and A. Tabatabaeefar. 2002. Energy consumption in wheat production in irrigatedand dryland farming. International Agricultural Engineering Conference, Wuxi, China.

20. Shahin, S., A. Jafari, H. Mobli, S. Rafiee, and M. Karimi. 2008. Effect of farm size on energy ratio for wheat production: A case study from Ardabil province of Iran. American-Eurasian Journal of Agricultural and Environmental Sciences 3 (4): 604-608.

21. Singh, S., and J. P. Mittal. 1992. Energy in Production Agriculture. Mittal Publications, New Delhi.

22. Valadiani, A., A. Hassanzadeh Ghoortape, and R. Valadiani. 2005. Evaluation of energy balance in rain fed wheat seed production in East Azerbaijan and its effect on environment. Agricultural Knowledge 15 (2): 1-12. (In Farsi).

23. Wang, X. B., D. X. Cai, W. B. Hoogmoed, O. Oenema, and U. D. Perdok. 2006. Potential effect of conservation tillage on sustainable land use: A review of global long-term Studies. Pedosphere 16 (5): 587-595.

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Journal of Agricultural Machinery

Energy indices in irrigated wheat production under conservation and conventional tillage and planting methods

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Volume 6, Issue 1 - Serial Number 11
Spring and Summer
2016
Pages 236-249

Energy indices in irrigated wheat production under conservation and conventional tillage and planting methods

References

References

Send comment about this article

Volume 6, Issue 1 - Serial Number 11Spring and Summer 2016Pages 236-249

Volume 6, Issue 1 - Serial Number 11
Spring and Summer
2016
Pages 236-249