Mechanical behavior investigation of fused deposition modeling joints by using different bonding geometry with variable adhesive thickness

U. Kemiklioğlu, Sermet Demir, Caner Yüksel
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Abstract

Purpose Adhesively bonded joints are used in many fields, especially in the automotive, marine, aviation, defense and outdoor industries. Adhesive bonding offers advantages over traditional mechanical methods, including the ability to join diverse materials, even load distribution and efficient thermal-electrical insulation. This study aims to investigate the mechanical properties of adhesively bonded joints, focusing on adherends produced with auxetic and flat surfaces adhered with varying adhesive thicknesses. Design/methodology/approach The research uses three-dimensional (3D)-printed materials, polyethylene terephthalate glycol and polylactic acid, and two adhesive types with ductile and brittle properties for single lap joints, analyzing their mechanical performance through tensile testing. The adhesion region of one of these adherends was formed with a flat surface and the other with an auxetic surface. Adhesively bonded joints were produced with 0.2, 0.3 and 0.4 mm bonding thickness. Findings Results reveal that auxetic adherends exhibit higher strength compared to flat surfaces. Interestingly, the strength of ductile adhesives in auxetic bonded joints increases with adhesive thickness, while brittle adhesive strength decreases with thicker auxetic bonds. Moreover, the auxetic structure displays reduced elongation under comparable force. Originality/value The findings emphasize the intricate interplay between adhesive type, bonded surface configuration of adherend and bonding thickness, crucial for understanding the mechanical behavior of adhesively bonded joints in the context of 3D-printed materials.
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使用不同粘合几何形状和可变粘合剂厚度对熔融沉积模型接头的机械行为进行研究
用途粘接接头应用于许多领域,尤其是汽车、船舶、航空、国防和户外工业。与传统的机械方法相比,粘合剂粘接具有多种优势,包括能够粘接各种材料、均匀分布载荷以及高效的热电绝缘。本研究旨在研究粘合剂粘接接头的机械性能,重点研究用不同厚度的粘合剂粘接辅助表面和平面的粘合剂。研究使用三维(3D)打印材料聚对苯二甲酸乙二醇和聚乳酸,以及两种具有韧性和脆性的粘合剂类型,用于单搭接接头,通过拉伸测试分析其机械性能。其中一种粘合剂的粘合区域为平面,另一种粘合剂的粘合区域为辅助表面。研究结果表明,与平面相比,辅助粘合剂表面具有更高的强度。有趣的是,随着粘合剂厚度的增加,磁性粘合接头中韧性粘合剂的强度也随之增加,而脆性粘合剂的强度则随着磁性粘合剂厚度的增加而降低。原创性/价值研究结果强调了粘合剂类型、粘合剂表面结构和粘合厚度之间错综复杂的相互作用,这对于理解三维打印材料中粘合接头的机械行为至关重要。
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