Calculation of shrinkage compensation factors for rapid prototyping (FDM 1650)

被引:0
|
作者
Dao, Q
Frimodig, JC
Le, HN
Li, XZ
Putnam, SB
Golda, K
Foyos, J
Noorani, R
Fritz, B
机构
[1] Loyola Marymount Univ, Dept Mech Engn, Los Angeles, CA 90045 USA
[2] No Grumman Corp, Pico Rivera, CA 90660 USA
来源
COMPUTER APPLICATIONS IN ENGINEERING EDUCATION | 1999年 / 7卷 / 03期
关键词
rapid prototyping; shrinkage compensation factor; coordinate measurement machine;
D O I
10.1002/(SICI)1099-0542(1999)7:3<186::AID-CAE7>3.0.CO;2-Q
中图分类号
TP39 [计算机的应用];
学科分类号
081203 ; 0835 ;
摘要
Rapid prototyping turns a three-dimensional CAD drawing into an actual part that can be tested for form, fit, and function. Therefore, accuracy of the prototype is important. The goal of this research was to improve in-plane dimensional accuracy for the Stratasys FDM 1650 rapid prototyping machine. The CHRISTMAS-TREE(TM) test procedure developed by 3D Systems, Inc., was used to arrive at a new shrinkage compensation factor (SCF) for the Stratasys machine. It was found that an SCF of 1.010 will produce a 53% reduction in mean error of the dimensions. More test procedures could be implemented to further refine accuracy. (C) 1999 John Wiley & Sons, Inc.
引用
收藏
页码:186 / 195
页数:10
相关论文
共 50 条
  • [21] A study of the staircase effect induced by material shrinkage in rapid prototyping
    Hong, WB
    Lee, YT
    Gong, HQ
    RAPID PROTOTYPING JOURNAL, 2005, 11 (02) : 82 - 89
  • [22] New material options for FDM direct digital manufacturing and rapid prototyping machines
    不详
    AIRCRAFT ENGINEERING AND AEROSPACE TECHNOLOGY, 2009, 81 (01): : 90 - 90
  • [23] Thermal characteristics of a new metal/polymer material for FDM rapid prototyping process
    Masood, SH
    Song, WQ
    ASSEMBLY AUTOMATION, 2005, 25 (04) : 309 - 315
  • [24] Additive and subtractive rapid prototyping techniques: a comparative analysis of FDM & CNC processes
    Neuenfeldt-Junior, A.
    Cheiram, M.
    Eckhardt, M.
    Scheuer, C.
    Siluk, J.
    Francescatto, M.
    INTERNATIONAL JOURNAL OF INDUSTRIAL ENGINEERING AND MANAGEMENT, 2021, 12 (04): : 262 - 273
  • [25] Analyze the efficiency on FDM process of Rapid Prototyping Technology with the new filling method
    Ren, Chong
    Cao, Yiqing
    Fan, Lirong
    MECHATRONICS AND INTELLIGENT MATERIALS II, PTS 1-6, 2012, 490-495 : 2095 - +
  • [26] Major Factors in Rapid Prototyping of Mechanisms
    Chen, Yonghua
    Chen, Zhezheng
    ADVANCES IN MATERIALS PROCESSING IX, 2010, 443 : 516 - 521
  • [27] Anisotropic tensile failure model of rapid prototyping parts - Fused Deposition Modeling (FDM)
    Ahn, SH
    Baek, C
    Lee, S
    Ahn, IS
    INTERNATIONAL JOURNAL OF MODERN PHYSICS B, 2003, 17 (8-9): : 1510 - 1516
  • [28] Improvements bring finer feature detail and smoother surface finish to FDM rapid prototyping
    不详
    ASSEMBLY AUTOMATION, 2004, 24 (03) : 317 - 318
  • [29] Parametric error modeling and software error compensation for rapid prototyping
    Tong, K
    Lehtihet, EA
    Joshi, S
    RAPID PROTOTYPING JOURNAL, 2003, 9 (05) : 301 - 313
  • [30] Product Development and its Comparative Analysis by SLA, SLS and FDM Rapid Prototyping Processes
    Choudhari, C. M.
    Patil, V. D.
    INTERNATIONAL CONFERENCE ON ADVANCES IN MATERIALS AND MANUFACTURING APPLICATIONS (ICONAMMA-2016), 2016, 149
12345