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Future Trajectories of Computation in Design (pp. 276-293). Istanbul Turkey.Zhang H. Wang J. Zhang G. Gan Z. Pan Z. Hongliang Cui & Zhenqi Zhu (2005). Machining with flexible manipulator: Toward improving robotic machining performance. in proceedings. 2005 IEEE/ASME International Conference on Advanced Intelligent Mechatronics. IEEE. 1127–1132. DOI: 10.1109/AIM.2005.1511161.2636-862510.33725/mamad.14730632-s2.0-85219699468https://gcris.yasar.edu.tr/handle/123456789/10471https://search.trdizin.gov.tr/en/yayin/detay/1246225https://doi.org/10.33725/mamad.1473063Ahşap geleneksel endüstriyel yapı malzemelerine kıyasla sağladığı hafiflik ve çevresel avantajlar ile mimarlar iç mimarlar ve mobilya tasarımcıları için her zaman ilham kaynağı olmuştur. Ahşap uygun kalınlıklarda doğru kesim ve üretim teknikleri uygulandığında esnek bir yapıya dönüştürülebilmektedir. Bu esnekliği kazandırma yöntemlerinden birisi de kerf kesim tekniğidir. Kerf kesim tekniği bir panel üzerinde belirli bir desen veya şekil oluşturmak için kesimler yaparak sert bir malzemeyi esnek hale getirmeye dayanır. Bu sayede karmaşık fabrikasyon yöntemlerine ve ileri teknoloji malzemelere ihtiyaç duymadan esnek ve şekil değiştirme özelliğine sahip mimari elemanlar ve mobilya ürünleri tasarlanabilir. Bu çalışmada kerf kesim tekniğinin ahşap ürünlerdeki kullanım alanları incelenerek kesim teknolojileri üretim teknikleri kesim tipleri ve desen türleri üzerinden bir sınıflandırma yapılmaktadır. Kerf kesim tekniğinin ahşap işleri alanında önemini ve son yıllarda artan ilgiyi vurgulayan bu çalışma tasarımcılar ve üreticiler için yenilikçi bir üretim yöntemi sunmaktadır. Bu teknik esnek ve estetik açıdan özgün tasarımların geliştirilmesine katkıda bulunarak ahşap ürünlerin kullanım alanlarını genişletme potansiyeline sahiptir.Türkçeinfo:eu-repo/semantics/openAccessMimarlık-Malzeme Bilimleri- Kâğıt ve AhşapBendingAdaptive MaterialsMimarlıkAdaptation in ArchitectureKerf TechniqueWoodMalzeme Bilimleri, Kâğıt Ve AhşapArticle