인문학
사회과학
자연과학
공학
의약학
농수해양학
예술체육학
복합학
DBpia AI
AI 에이전트
AI 아이디어
AI 리더
AI 뷰어
Citeasy
크롬 서지관리 다운로드
지원사업
학술연구/단체지원/교육 등 연구자 활동을 지속하도록 DBpia가 지원하고 있어요.
커뮤니티
연구자들이 자신의 연구와 전문성을 널리 알리고, 새로운 협력의 기회를 만들 수 있는 네트워킹 공간이에요.
논문 기본 정보
- 자료유형
- 학술저널
- 저자정보
- 발행연도
- 2025.8
- 수록면
- 7 - 22 (16page)
- DOI
- 10.15187/adr.2025.08.38.3.7
이용수
초록· 키워드
Background : While digital fabrication primarily focuses on precise replication, its potential for sculptural exploration through deformations remains largely underexplored. Recent studies suggest embracing technical glitches as creative elements, and this study builds upon that perspective. Introducing the Error-Driven Design Fabrication Workflow, this research integrates deformations as an active component of the design process rather than unintended flaws.
Methods : To explore intentional deformations in 3D printing, this study examined three key variables: structural instability due to gravity, retraction effects, and curvature-induced deformation. The digital model was systematically adjusted, followed by an iterative printing process to observe and analyze the resulting deformation patterns. Rather than treating these distortions as mere errors, the study implemented an iterative reverse modeling feedback workflow, reframing unintended deviations as sculptural elements within the design process.
Results : The experimental analysis reveals that deformations emerging during fabrication broaden the scope of sculptural exploration. Gravity-induced instability generates collapse patterns, introducing new possibilities for form development. Retraction effects disrupt filament connectivity, resulting in intricate, web-like textures that can be utilized as surface design elements. Increased curvature leads to layering instability, shaping distinct geometric patterns and influencing overall structural articulation.
Conclusions : By shifting the perception of deformations from errors to design tools, this study presents an alternative fabrication approach that prioritizes sculptural exploration over rigid precision. Through iterative feedback, deformations are incorporated into the design process to expand formal possibilities. Future research will focus on real-time feedback integration and extend this approach across varied materials and fabrication techniques.
상세정보 수정요청해당 페이지 내 제목·저자·목차·페이지Methods : To explore intentional deformations in 3D printing, this study examined three key variables: structural instability due to gravity, retraction effects, and curvature-induced deformation. The digital model was systematically adjusted, followed by an iterative printing process to observe and analyze the resulting deformation patterns. Rather than treating these distortions as mere errors, the study implemented an iterative reverse modeling feedback workflow, reframing unintended deviations as sculptural elements within the design process.
Results : The experimental analysis reveals that deformations emerging during fabrication broaden the scope of sculptural exploration. Gravity-induced instability generates collapse patterns, introducing new possibilities for form development. Retraction effects disrupt filament connectivity, resulting in intricate, web-like textures that can be utilized as surface design elements. Increased curvature leads to layering instability, shaping distinct geometric patterns and influencing overall structural articulation.
Conclusions : By shifting the perception of deformations from errors to design tools, this study presents an alternative fabrication approach that prioritizes sculptural exploration over rigid precision. Through iterative feedback, deformations are incorporated into the design process to expand formal possibilities. Future research will focus on real-time feedback integration and extend this approach across varied materials and fabrication techniques.
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목차
- Abstract
- 1. Introduction
- 2. Related Work
- 3. Proposed Error-driven design Workflow
- 4. Workflow Implementation
- 5. Conclusion and Discussion
- References
참고문헌
참고문헌 신청최근 본 자료
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