ProtoSpray: Combining 3D Printing and Spraying to Create Interactive Displays with Arbitrary Shapes

被引:0
|
作者
Hanton, Ollie [1 ]
Wessely, Michael [2 ]
Mueller, Stefanie [2 ]
Fraser, Mike [3 ]
Roudaut, Anne [1 ]
机构
[1] Univ Bristol, Bristol, Avon, England
[2] MIT CSAIL, Cambridge, MA USA
[3] Univ Bath, Bath, Avon, England
来源
CHI'20: EXTENDED ABSTRACTS OF THE 2020 CHI CONFERENCE ON HUMAN FACTORS IN COMPUTING SYSTEMS | 2020年
基金
英国工程与自然科学研究理事会;
关键词
3D Printing; Spraying; Display; Electroluminescence; Rapid Prototyping; Fabrication;
D O I
10.1145/3334480.3383174
中图分类号
TP3 [计算技术、计算机技术];
学科分类号
0812 ;
摘要
ProtoSpray is a new fabrication method that combines 3D printing and spray coating, to create touch-sensitive displays of arbitrary shape. Our approach makes novel use of 3D printed conductive channels to create base electrodes and shape displays. A channelled 3D printed object is then combined with spraying active, electroluminescent, materials to produce illumination. This demonstration involves multiple different devices, created through the ProtoSpray process, showing its free-form applicability to irregular shapes such as a mobius strip and spherical surfaces. Our work provides a platform to empower makers with displays as a fabrication material.
引用
收藏
页数:4
相关论文
共 50 条
  • [1] ProtoSpray: Combining 3D Printing and Spraying to Create Interactive Displays with Arbitrary Shapes
    Hanton, Ollie
    Wessely, Michael
    Mueller, Stefanie
    Fraser, Mike
    Roudaut, Anne
    [J]. PROCEEDINGS OF THE 2020 CHI CONFERENCE ON HUMAN FACTORS IN COMPUTING SYSTEMS (CHI'20), 2020,
  • [2] Advances in interactive, holographic 3D displays
    Slinger, C
    Cameron, C
    Coomber, S
    Miller, R
    Payne, D
    Smith, A
    Smith, M
    Stanley, M
    [J]. 2002 IEEE/LEOS ANNUAL MEETING CONFERENCE PROCEEDINGS, VOLS 1 AND 2, 2002, : 29 - 30
  • [3] Screen Printing to Create 3D Tissue Models
    Pandala, Narendra
    Haywood, Sydney
    LaScola, Michael A.
    Day, Adam
    Leckron, Joshua
    Lavik, Erin
    [J]. ACS APPLIED BIO MATERIALS, 2020, 3 (11) : 8113 - 8120
  • [4] Detection of arbitrary planar shapes with 3D pose
    Cózar, JR
    Guil, N
    Zapata, EL
    [J]. IMAGE AND VISION COMPUTING, 2001, 19 (14) : 1057 - 1070
  • [5] Simulated filament shapes in embedded 3D printing
    Friedrich, Leanne M.
    Seppala, Jonathan E.
    [J]. SOFT MATTER, 2021, 17 (35) : 8027 - 8046
  • [6] Automated Geometric Registration for Multi-Projector Displays on Arbitrary 3D Shapes Using Uncalibrated Devices
    Tehrani, Mahdi Abbaspour
    Gopi, M.
    Majumder, Aditi
    [J]. IEEE TRANSACTIONS ON VISUALIZATION AND COMPUTER GRAPHICS, 2021, 27 (04) : 2265 - 2279
  • [7] Improving 3D printing methods to create versatile sleeves for the printing industry
    Wei, Xueying
    Urban, Peter
    Ritzmann, Sven
    [J]. JOURNAL OF PRINT AND MEDIA TECHNOLOGY RESEARCH, 2021, 10 (03): : 153 - 162
  • [8] 3D Printing of Arbitrary Perovskite Nanowire Heterostructures
    Chen, Mojun
    Zhou, Zhiwen
    Hu, Shiqi
    Huang, Nan
    Lee, Heekwon
    Liu, Yu
    Yang, Jihyuk
    Huan, Xiao
    Xu, Zhaoyi
    Cao, Sixi
    Cheng, Xiang
    Wang, Ting
    Yu, Siu Fung
    Chan, Barbara Pui
    Tang, Jinyao
    Feng, Shien-Ping
    Kim, Ji Tae
    [J]. ADVANCED FUNCTIONAL MATERIALS, 2023, 33 (15)
  • [9] Interactive Molecular Model Assembly with 3D Printing
    Fazelpour, Elham
    Fennell, Christopher J.
    [J]. JOVE-JOURNAL OF VISUALIZED EXPERIMENTS, 2020, (162): : 1 - 5
  • [10] Reconstruction of 3D volumetric defects in conductors of arbitrary shapes
    Rubinacci, G
    Tamburrino, A
    Ventre, S
    Villone, F
    [J]. ELECTROMAGNETIC NONDESTRUCTIVE EVALUATION (VIII), 2004, 24 : 77 - 84
12345