Effect of Casting Design to Microstructure and Mechanical Properties of 5 mm TWDI Plate

Johny Wahyuadi Soedarsono; Bambang Suharno; Rianti Dewi Sulamet-Ariobimo

doi:10.4028/www.scientific.net/AMM.152-154.1607

Paper Titles

Research on the Roll Contour Configuration for Schedule Free Rolling in Hot Wide Strip Mills
p.1584

Marine Diesel Engine Speed Control System Based on Fuzzy-PID
p.1589

Design of Planetary Gear Reducer with Double Circular-Arc Helical Gear
p.1595

Semiquantitative SDG Graphical Modeling for Complex System Fault Diagnosis
p.1601

Effect of Casting Design to Microstructure and Mechanical Properties of 5 mm TWDI Plate
p.1607

Study on TBM Cutterhead Working Principle
p.1612

The Analysis of Overtaking of Whole Wheel Steering In-Phase of Multi-Axle Vehicle
p.1619

The Effect of Polyurethane Hardness on the New Die-Set of Sheet Hydroforming Process Parameters
p.1623

A Bearing Intelligent Fault Diagnosis Method Based on Cluster Analysis
p.1628

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 152-154Effect of Casting Design to Microstructure and...

Effect of Casting Design to Microstructure and Mechanical Properties of 5 mm TWDI Plate

Abstract:

In producing thin wall ductile iron (TWDI) cooling rate must be strictly maintained to prevent carbide formation. There are many ways to control cooling rate BUT the most independent one is by casting design. By choosing this parameter major changes in equipment and raw material used in the foundry can be avoided. This paper discusses the effect of gating system design on microstructure and mechanical properties of 5 mm TWDI plate. A casting design based on vertical gating system is made to produce 1, 2, 3, 4, and 5 mm TWDI plates. Plate with 5 mm thickness becomes an interesting subject due to its position as the thickest and furthest from ingate in casting design with a new concept. There are three designs coded as T1, T2, and T3. These three designs were also used in making 1 and 3 mm TWDI plates of which the result has been published. The plate with 5 mm thickness will be used for automotive components. Casting design simulation for filling flow and solidification were conducted with Z-Cast. Result of flow simulation shows that the filling flow happens in two kinds. Result of solidification shows that T3 has the highest solidification rate. In the experiment, the moulds used were furan sand. Experiment result shows that all the designs have microstructure consisting of nodule graphite in ferrite matrix, no trace of carbide and skin effect are formed. Skin effect length is various for all designs. The highest nodularity is only 72% and nodule count shows only 700 nodules/mm2. Brinell hardness number for all design is beyond standard given by JIG G5502. As for UTS and elongation none of the designs exceed the minimal standard. Experiment results confirms simulation result. Compared to the previous result nodularity and nodule count decrease and curve trends for every result are not similar.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 152-154)

Pages:

1607-1611

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.152-154.1607

Citation:

Cite this paper

Online since:

January 2012

Authors:

Johny Wahyuadi Soedarsono, Bambang Suharno, Rianti Dewi Sulamet-Ariobimo

Keywords:

5 mm Plate Thickness, Casting Design, TWDI

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] M. Caldera, M. Chapetti, J.M. Massone, and J.A. Sikora: Mater. Sci. Technol, Vol. 23 No. 8 (2007), p.1000.

Google Scholar

[2] R.A. Martinez, R.E. Boeri, and J. A. Sikora in: Proceeding of 2002 world conference on ADI, AFS, (2002).

Google Scholar

[3] D.M. Stefanescu, L.P. Dix, R.E. Ruxanda, C. Corbitt-Coburn, and T.S. Piwonka: AFS Trans, Vol. 110 (2002), p.1149.

Google Scholar

[4] J.W. Soedarsono and R. D Sulamet-Ariobimo: Adv. Mat. Res., (2011), in press.

Google Scholar

[5] A. Javaid, K. G. Davis, and M. Sahoo: Mod. Cast., 90(2000), p.39.

Google Scholar

[6] R. E. Showman, R. C. Aufderheiden and N. Yeomans: Mod. Cast., 96(2006), p.29.

Google Scholar

[7] K. M. Pedersen, N. S. Tiedjen: Mater. Charact., 09(2007).

Google Scholar

[8] L. P. Dix, R. Ruxanda, I. Torrance, M. Fukumoto, and D. M. Stefanescu: AFS Trans, Vol. 111 (2003), p.895.

Google Scholar

[9] K. K Schrems, J. A. Hawk, Ö. N. Dogan and A. P. Druschitz: SAE Tech. Paper Doc. No. 2003-01-0828 (2003).

Google Scholar

[10] C. Labreque, M. Gagné, A. Javaid and M. Sahoo: Int. J. Cast Metal Res., 16(2003), p.313.

Google Scholar

[11] C. Labreque, M. Gagné: AFS Trans, Vol. 108 (2000), p.31.

Google Scholar

[12] J.W. Soedarsono, B. Suharno and R. D Sulamet-Ariobimo: Adv. Mat. Res., (2011), in press.

Google Scholar

[13] B. Suharno, J. W. Soedarsono, T. P. Soemardi, and R. D. Sulamet-Ariobimo: Adv. Mat. Res., 277(2011), p.66.

DOI: 10.4028/www.scientific.net/amr.277.66

Google Scholar

[14] J.W. Woolley, D.M. Stefanescu: AFS Trans, Vol. 113 (2005), p.637.

Google Scholar