Laboratuvar Sorumlusu : Prof .Dr. Mustafa Bakkal

Laboratuvar Çalışanları

Araş. Gör.Ammar Tarık Dinçer
Araş. Gör. Mete Kayıhan
Araş. Gör. Vehbi Öztekin

CAM Laboratuvarında talaşlı imalat proseslerine yönelik çalışmalar gerçekleştirilmektedir. Laboratuvar bünyesinde bir adet CNC freze tezgahı; dinamometre, ivmeölçer ve mikrofon gibi ölçüm aletleri ve DAQ, amplifikatör gibi yardımcı ekipmanlar bulunmaktadır. Laboratuvarda, uygulamalı derslerin deneysel çalışmaları, yüksek lisans ve doktora tezi çalışmaları ve diğer çeşitli akademik araştırmalar sürdürülmektedir.

Laboratuvarda çalışılan konular genel olarak şu şekilde ifade edilebilir: Metalik ve kompozit malzemelerde freze ve delik delme operasyonları, kalıntı gerilme ölçme, imalat için ölçme, veri toplama, sinyal işleme ve makine öğrenmesi çalışmaları.

Laboratuvarda Yapılmış veya Yapılmakta Olan Önemli Projeler

• Bakkal, M., & Nakşiler, V. (2009). Cutting Mechanics of Bulk Metallic Glass Materials on Meso-End Milling. Materials and Manufacturing Processes Vol 24
• Serbest et al. (2010). The Effect of Cutting Speed in Metallic Glass Grinding. AIP Conference Proceedings
• Bakkal M, et al. (2010). Machinability of bulk metallic glass materials on milling and drilling. Advanced Materials Research.
• Kuzu, A. T., & Bakkal, M. (2012). Effects of Tool Geometry on Machinability of Textile Fabric Reinforced Termoplastic Matrix Composites. Advanced Materials Research
• Karaguzel et al. (2012). Process modeling of turn-milling using analytical approach. Procedia CIRP
• Uysal et al. (2014). Investigating eccentricity effects in turn-milling operations. Procedia CIRP
• Kuzu et al. (2014). Autonomous hole quality determination using image processing techniques, International Symposium on Industrial Electronics (ISIE)
• Karaguzel et al. (2015). Increasing tool life in machining of difficult-to-cut materials using nonconventional turning processes. The International Journal of Advanced Manufacturing Technology.
• Karaguzel et al. (2015). Analytical Modeling of Turn-milling Process Geometry, Kinematics and Mechanics. International Journal of Machine Tools and Manufacture.
• Karaguzel et al. (2016). Modeling and Measurement of Cutting Temperatures in Milling. Procedia CIRP.
• Kuzu et al. (2016). High-throughput Dry and Minimum Quantity Lubrication Drilling of Compacted Graphite Iron, Procedia CIRP.
• Putz et al. (2016). Improving Performance of Turn-milling by Controlling Forces and Thermally Induced Tool-center Point (TCP) Displacement, Procedia CIRP
• Kuzu et al. (2015). Thermal and force modeling of CGI drilling The International Journal of Advanced Manufacturing Technology
• Karaguzel et al. (2016). Effects of tool axis offset in turn-milling process, Journal of Materials Processing Technology
• Kuzu, A. T., & Bakkal, M. (2016). The effect of cutting parameters and tool geometry on machinability of cotton-fiber reinforced polymer composites: Cutting forces, burr formation, and chip morphology. Journal of Industrial Textiles
• Karaguzel et al. (2017). Mechanical and Thermal Modeling of Orthogonal Turn-milling Operation, Procedia CIRP
• Kuzu, A. T., & Bakkal, M. (2017). The thermal modeling of deep-hole drilling process under MQL condition, Journal of Manufacturing Processes
• Cakir et al. (2018). Investigation of temperature distribution in orthogonal cutting through dual-zone contact model on the rake face, The Int. J of Advanced Manufacturing Tech.
• Wu et al. (2018). Dry and minimum quantity lubrication high-throughput drilling of compacted graphite iron, Machining Science and Technology.
• Kayihan et al. (2021). Experimental analysis on drilling of Al/Ti/CFRP hybrid composites,Materials and Manufacturing Processes