Determination of suitableprotected production areas: Lower Euphrates basin case

• Autorzy: Saltuk B. , Mikail N. , Atilgan A. , Tanriverdi C.

Identyfikatory

DOI

10.14597/infraeco.2017.2.2.053

• Języki publikacji: EN

Abstrakty

EN

As a result of the increase in the world population and the decrease in agricultural land, the need for food increases every day. Nowadays, breeding studies are carried out to increase the yield of plants to get more products from the same area. Furthermore, controlled production areas are created by optimizing climatic conditions and the continuity of production is ensured. It is called greenhouse, where production can be carried out throughout the year and the indoor temperature and humidity conditions can be controlled. Nowadays, greenhouses are now functioning as an industrial enterprise. However, greenhouses need to comply with the principles of quality production, efficient income growth and physical environmental protection. Almost all of the plant production in greenhouses in Turkey is done in the Mediterranean region, but in the Southeastern Anatolia Region, it is done in a very limited greenhouse area. The increase of protected agricultural areas in the Mediterranean region and the fact that the production volume cannot reach a certain limit makes it necessary to investigate alternative protected production areas. In this study, climate conditions of Antalya province and climate data of four provinces of the Lower Euphrates basin are compared with each other and statistically compared. As a result of, differences have been found between Antalya province and the provinces in the Lower Euphrates basin in terms of minimum, maximum, and average temperatures. However, there is no difference between the provinces in the basin except for Gaziantep in terms of climatic conditions. Therefore, it has been determined that Gaziantep province is not suitable for greenhouse cultivation. However, it has been concluded that if greenhouse cultivation is performed in this province, it is appropriate to perform cultivation in the areas where alternative energy sources can be used. It has been concluded that in the case that heating costs are reduced using alternative energy sources, Şanlıurfa and Kilis provinces are climatologically suitable for greenhouse cultivation and Adıyaman province is partially suitable for it.

Słowa kluczowe

EN

climatization; greenhouses; heat load; Lower Euphrates basin

• Wydawca: Stowarzyszenie Infrastruktura i Ekologia Terenów Wiejskich
• Czasopismo: Infrastruktura i Ekologia Terenów Wiejskich
• Rocznik: 2017
• Tom: nr II/2
• Strony: 701--714
• Opis fizyczny: Bibliogr. 11 poz., rys., tab., wykr.

Twórcy

autor

Saltuk B.

• Siirt University, Agriculture Faculty, Biosystem Department, 56100 Siirt-Turkey

autor

Mikail N.

• Siirt University, Agriculture Faculty, Biometry and Genetics Department, 56100 Siirt-Turkey

autor

Atilgan A.

• Süleyman Demirel University, Agriculture Faculty, Agricultural Structure and Irrigation Department, 32260 Isparta-Turkey

autor

Tanriverdi C.

• Sutcu Imam University, Agriculture Faculty Biosystem Department 46100 K.Maras-Turkey

Bibliografia

• Anonymous, (2002). SeradaSebze Yetiştiriciliği T.C. Tarım ve Köyişleri Bakanlığı Yayınları Temmuz - 2002 [Vegetable growing in the greenhouse, Turkish Ministry of Agriculture and Rural Affairs Publications, July - 2002].
• Anonymous, (2015). Greenhouses Sectoral Report in Turkeyhttp://www.dogaka. gov.tr/Icerik/Dosya/www.dogaka.gov.tr_622_LK5L43WG_Seracilik-ortualti-Bitki Yetistiriciligi-Sektor-Raporu-2015.pdf (In Turkish).
• Anonymous, (2016). METBIS Turkish State Meteorological Service, Meteorological Data.
• Boyacı ,S., Akyüz, A., Baytorun, A.N., Çaylı, A. (2016).Determination of Greenhouse Agriculture Potential of The Kırşehir Province Nevşehir Journal of Science and Technology 5(2):142-157 2016 (Date 30.03.2017) http://dergipark.ulakbim. gov.tr/nevbiltek/article/viewFile/5000202674/5000179626 (In Turkish).
• Dikmen, B.Ç., Gültekin, B.A. (2011). Usage of renewable energy resources in buildings in the context of sustainability, Journal of Engineering Science and Design, 1(3):96-100.
• Güler, T., Akdemir, U. (2012). ANOVA modeling on sintering parameters and frequencies, affecting microstructure and dielectric constant of Nb doped BaTiO3, Transactions of Nonferrous Metal Society of China, Vol. 22, 199-205.
• Krug, H., Liebig, HP., Stützel, H. (2002). Gemüseproduktion. Ulmer Verlag, Stuttgart web accept 30.03.2017 http://www.fao.org/3/a-i3284e.pdf
• Niedoba, T., Pięta, P. (2016). Applications of ANOVA in mineral processing. Mining Science, vol. 23, 43-54.
• Rao, S., Padmanabhan G. (2012). Application of Taguchi methods and ANOVA in optimization of process parameters for metal removal rate in electrochemical machining of Al/5%SiC composites, International Journal of Engineering Research and Applications (IJERA), Vol. 2, No. 3, 192-197.
• Raykov, T., Marcoulıdes, G.A. (2008). An introduction to applied multivariate statistics. New York, Routledge.
• Zabeltitz,C. (1988). Energy Conservation and Renewable Energies for Greenhouse Heating. Food and Agriculture Organization of The United Nations, ReurTechnical Series 3, Roma, Italy, p 107.

Uwagi

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).