Journal of Agricultural Machinery

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Locating Advisory and Agricultural Engineering Service Network using Set Covering Model

Document Type : Research Article

Authors

1 Department of Agricultural Mechanzation Engineering, Faculty of Agricultural Sciences, University of Guilan, Rasht, Iran

2 Department of Mechanical Engineering of Agricultural Machinery, University of Tehran, Karaj, Iran

Abstract

Introduction
In this research, a part of the requirements for the establishment of a network of consultancy, agricultural engineering and technical services in the agricultural sector, which is related to the location of these centers, has been reviewed. The location of these centers has been done through the determination of the field of operation and the appropriate establishment of consulting, engineering, and agricultural consulting companies based on regional capacities and taking into account the distance between the types of customers of such centers.
 
Materials and Methods
In the issue of locating service centers three main types of customer can be classified. First-class customers, which have the largest number among different types of customers, are farms and units that produce agricultural products. Each point of demand for these categories of customers may require different types of services at different times. Due to the large number and dispersion, these category of customers are considered as a focal point for ease of modeling in rural areas where they are located. Also, due to various reasons, including access to various facilities, security, traffic congestion and etc., the nominations for deployment of service centers are also considered in the same rural areas. In order to transport agricultural products from the place of production, the current location is considered to be the distance from the manufacturer's place, and the destination of the product is not studied in this issue. Second and third-type customers are demanding access to services at their own place. These types of customers may exist in some areas and agricultural supply chains. These two groups of customers include refineries, warehouses and silos mainly operating in the post-harvest of agricultural production. To meet the demand for each of the different demand points of different types of customers, the number of different trips from service centers to customer premises or vice versa is required. Each service center does not offer the same type of service to its customers. A total of 127 service packages are available for provision at a service center.
 
Results and Discussion
The main basis for choosing the optimal location for covering models is the placement of demand points in the defined coverage radius for the candidate points. Different radius were tested to find the perfect coverage radius in each of the studied villages. For this purpose, a radius of five to 160 kilometers was examined. In some coverage radius, not only does the optimal location not change, but the number of served points is also fixed. The location of different types of customers is different, so that the first type of customers are fully located in the village, but second and third type customers are widespread in the Hamedan province.
 
Conclusion
To conclude, it is necessary to consider the demand of customers located in the further distances of the service center due to the nature of the agricultural service, which requires inevitable traffic over long distances, when adjusting the operational plans of the agricultural service centers. To provide sufficient justification for the distance, though within the radius of coverage. Thus, the results of this research show that if all service centers cover 130 kilometers of radius, the largest number of customers will be covered. It should be noted that for the full coverage of all customers, the coverage radius of the service centers varies, but with the same radius, the 130 km radius is the largest coverage of the agricultural service centers in the Razan city.

Keywords

References
1. Ahumada, O., and J. R. Villalobos. 2009. Application of planning models in the agri-food supply chain: a review. European Journal of Operational Research 195 (1): 1-20.
2. Anonymous. 2012. Guidance package supplemental plan for equipping the network of mechanization companies from the place of credit subsidies inputs and factors of agricultural production. Row 2-520000 Budget law of the year 2011. (In Farsi).
3. Berman, O., Z. Drezner, and G. O. Wesolowsky. 2008. The multiple location of transfer points the multiple locations of transfer points. Journal of the Operational Research Society 59 (6): 805-811.
4. Brandeau, M. L., and S. S. Chiu. 1989. An overview of representative problems in location research. Management Science 35 (6): 645-674.
5. Chipeta, S. 2006. Demand driven agricultural advisory services. Neuchatel Group. Denmark.
6. Chopra, S., and P. Meindl. 2003. Supply chain management: strategy, planning and operation. Pearson Education Inc. Upper Saddle River, New Jersey.
7. Church, R., and C. ReVelle. 1974. The maximal covering location problem. Papers Region Science Association 32 (1): 101-118.
8. Doh, J. P., K. Bunyaratavej, and E. D. Hahn. 2009. Separable but not equal: The location determinants of discrete services offshoring activities. Journal of International Business Studies 40 (6): 926-943.
9. Dorward, A., and E. Chirwa. 2011. The Malawi agricultural input subsidy programme: 2005/06 to 2008/09. International Journal of Agricultural Sustainability 9 (1): 232-247.
10. Ebrahimi, A. 2007. Design and support of the private network agricultural engineering consulting services. Organization of Agricultural Engineering and Natural Resources of the Country. Tehran. (In Farsi).
11. Farahani, R. Z., N. Asghari, N. Heidari, M. Hosseininia, and M. Goh. 2012. Covering problems in facility location: A review. Computers and Industrial Engineering 62 (1): 368-407.
12. Farrow, A., K. Risinamhodzi, S. Zingore, and R. J. Delve. 2011. Spatially targeting the distribution of agricultural input stockists in Malawi. Agricultural Systems 104 (9): 694-702.
13. Francis, R. L., L. F. McGinnis, and J. A. White. 1992. Facility layout and location: an analytical approach. Prentice Hall. Englewood.
14. Kayikci, Y. 2010. A conceptual model for intermodal freight logistics center location decisions. Procedia-Social and Behavioral Sciences 2 (3): 6297-6311.
15. Lak, M. B., and M. Almasi. 2011. An analytical review of parameters and indices affecting decision making in agricultural mechanization. Australian Journal of Agricultural Engineering 2 (5): 140-146.
16. Laporte, G., and A. Dasci. 2005. A continuous model for multi-store competitive location. Operations Research 53 (2): 263-280.
17. Lucas, M., and D. Chhajed. 2004. Applications of location analysis in agriculture: a survey. Journal of the Operational Research Society 55 (6): 561-578.
18. Mahdavi, M., and H. Karimzadeh. 2007. Zoning the central part of Varzaghan city to locate rural service centers using GIS. Geographical Researches 55: 203-224.
19. Satake, T., O. Sakata, Y. Ohta, and T. Furuya. 2003. Optimal layout design for agricultural facility using simulated annealing. The CIGR Journal 5: 1-11.
20. Sims, G. B., and J. Kienzle. 2009. Farm equipment supply chains; guidelines for policy-makers and service providers: experiences from Kenya, Pakistan and Brazil. FAO. Rome, Italy.
21. Sharifi, M., A. Akram, Sh. Rafiee, and M. Sabzeparvar. 2013. Prioritizing the cultivation of strategic crops in Alborz province using Delphi fuzzy and analytic hierarchy process. Journal of Agricultural Machinery 4 (1): 116-124. (In Farsi).
22. Timmer, C. P., W. P. Falcon, and S. R. Pearson. 1983. Food policy analysis. The Johns Hopkins University Press. Baltimore and London.
23. Zangeneh, M., M. Omid, and A. Akram. 2010. A comparative study on energy use and cost analysis of potato production under different farming technologies in Hamadan province of Iran. Energy 35 (7): 2927-2933.
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Journal of Agricultural Machinery
Volume 9, Issue 1 - Serial Number 17
Spring and Summer
2019
Pages 221-233
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History
  • Receive Date: 03 July 2017
  • Revise Date: 01 November 2017
  • Accept Date: 15 January 2018
  • First Publish Date: 21 March 2019
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