Field feature detection and morphing-based process planning for fabrication of geometries and composition control for functionally graded materials

Abstract

The inherent limitation of most solid freeform fabrication (SFF) is deposition in the form of layers. The set-up rather than the geometry and the material composition of the part becomes more important in the process planning. For a functionally graded material (FGM), the desired composition variation is of infinitesimal order; however, the finite size of the deposition head and the molten pool allows for a quantized volume addition. Such artificial imposition of the process for the desired geometric morphology and the functional gradience of materials limit the accuracy of the part. The frequent variation in the material composition is yet another issue associated with the fabrication of FGMs. The suitability of a field can be attributed to the desired material distribution of a part. Different features of the field are identified and used as the input for process planning. The mathematical morphing of the material gradience allows a smooth variation of the material composition across the geometry of the part during deposition. The paper describes a framework for FGM representation using maxel, process planning, and implementation of the fabrication of geometries, and the control of the material composition. The experimental results for the suggested approach are described.

Keywords

solid freeform fabrication functionally graded material maxel isocomposition contours multimaterial solid

References

Miyamoto

Kaysser

Rabin

Kawasaki

Ford

R. G.

Functionally graded materials: Design, processing and applications, Materials Technology Series, 5 October 1999.

Ensz

Griffith

Critical issues for functionally graded material deposition by laser engineered net shaping LENS TM. In Proceedings of the 2002 MPIF Laser Metal Deposition Conference, San Antonio, Texas, 2002, pp. 455–460.

Griffith

M. L.

Harwell

L. D.

Romero

J. T.

Schlienger

Atwood

C. L.

Smugeresky

J. E.

Multi-material processing by LENSTM. In Proceedings of the 1997 Solid Freeform Fabrication Symposium, Austin, Texas, 1997, pp. 387–393.

Pegna

Sail

CAD modeling of multi-modal structures for freeform fabrication. In Proceedings of the 1998 Solid Freeform Fabrication Symposium, Austin, Texas 1998.

Kumar

Dutta

An approach to modeling multi-material objects. In Proceedings of the 1997 ACM Solid Modeling Conference, Atlanta, Georgia, 1997, pp. 336–345.

Jackson

T. R.

Liu

Patrikalakis

N. M.

Sachs

E.M.

Cima

M. J.

Modeling and designing functionally graded material components for fabrication with local composition control. Mater. Des., 1999, 20(2/3), 63–75.

Biswas

Shapiro

Tsukanov

Heterogeneous material modeling with distance fields. Computer Aided Geometric Des., 2004, 21 215–242.

Jackson

Analysis of functionally graded material object representation methods. PhD Thesis, Massachusetts Institute of Technology, Ocean Engineering Department, Cambridge, Massachusetts, 2000.

Sarma

An assessment of geometric methods in trajectory synthesis for shape creating manufacturing operations. J. Mfg Syst., 2000, (19), 59–72.

10.

Kumar

Dutta

An approach to modeling and representation of heterogeneous objects. J. Mech. Des., 1998, 120(12), 659–667.

11.

Bhashyam

Shin

K. H.

Dutta

An integrated CAD system for design of heterogeneous objects. Rapid Prototyping J., 2000, 6(2), 119–135.

12.

Shin

K. H.

Natu

Dutta

Mazumder

A method for the design and fabrication of heterogeneous objects. Mater. Desi., 2003, 24, 339–353.

13.

Siu

Y. K.

Tan

S. T.

Slicing and contours generation for fabricating heterogeneous objects. In Proceedings of the Geometric Modeling and Processing — Theory and Application, 2002, pp. 219–225.

14.

Zhou

M. Y.

J. T.

Yan

J. Q.

Modeling and processing of functionally graded materials for rapid prototyping. J. Mater. Processing Technol., 2004, 146, 396–402.

15.

Patil

Dutta

Bhatt

A. D.

Jurrens

Lyons

Pratt

M. J.

Sriram

R. D.

Representation of hetergeneous objects in ISO 10303 (STEP). In ASME International Mechanical Engineering Congress and Exposition, Orlando, Florida, 2000.

16.

Siu

Y. K.

Tan

S. T.

Source-based heterogeneous solid modeling. Computer Aided Des. 2002, 34(1), 41–55.

17.

Anping

Shaw

L. L.

Sff-oriented modeling and process planning of functionally graded materials using a novel equal distance offset approach. In The 15th Solid Freeform Fabrication Symposium, Austin, Texas, 2004, pp. 544–552.

18.

Liu

Patrikalakis

N. M.

Sachs

E. M.

Maekawa

Cho

Stratton

C. C.

A design and post-processing system for local composition control in solid freeform fabrication. In Proceedings of the 2004 NSF Design, Service and Manufacturing Grantees and Research Conference, Dallas, Texas, 2004.

19.

Kumar

Kulkarni

Dutta

Adaptive slicing of heterogeneous solid models for layered manufacturing. J. Mater. Processing and Mfg Sci. 7..

20.

Dwivedi

Jandric

Kovacevic

Torch path planning for solid freeform fabrication based on welding. In Transactions of the North American Manufacturing Research Institution of SME, Vol XXXI, McMaster University, Hamilton, Canada, 2003, pp. 419–426.

21.

Dwivedi

Kovacevic

Automated torch path planning using polygon subdivision for solid freeform fabrication based on welding. J. Mfg Syst., SME, 2004, 23(4), 278–291.

22.

Gonzalez

R. C.

Woods

R. E.

Digital image processing, 2nd edition, 2001 (Addison-Wesley Longman Publishing Co., Boston, USA).

23.

Dwivedi

Kovacevic

Morphing based approach for process planning for fabrication of geometries and the control of material composition. In the 15th Solid Freeform Fabrication Symposium, Austin, Texas, 2004, pp. 553–562.

24.

Ouyang

Mei

Valant

Kovacevic

Application of laser cladding technique to the rapid manufacturing of tools for friction stir welding. In the 13th Solid Freeform Fabrication Symposium, Austin, Texas, 2002.