Analysis of Pores Size and Distribution Effects On the Total Dimensional Specification of Pinion Gear, Head Stock And Drive Disc of Manganese Steel (46MNSi4) Casts using Control Chart And Ishikawa Diagram (Case at Akaki-Basic Metals Industry –Ethiopia)
|International Journal of Engineering Trends and Technology (IJETT)||
|© 2019 by IJETT Journal|
|Year of Publication : 2019|
|Authors : Asmamaw Tegegne, Netsanet Desalegn
|DOI : 10.14445/22315381/IJETT-V67I1P204|
MLA Style: Asmamaw Tegegne, Netsanet Desalegn "Analysis of Pores Size and Distribution Effects On the Total Dimensional Specification of Pinion Gear, Head Stock And Drive Disc of Manganese Steel (46MNSi4) Casts using Control Chart And Ishikawa Diagram (Case at Akaki-Basic Metals Industry –Ethiopia)" International Journal of Engineering Trends and Technology 67.1 (2019): 23-33.
APA Style:Asmamaw Tegegne, Netsanet Desalegn (2019). Analysis of Pores Size and Distribution Effects On the Total Dimensional Specification of Pinion Gear, Head Stock And Drive Disc of Manganese Steel (46MNSi4) Casts using Control Chart And Ishikawa Diagram (Case at Akaki-Basic Metals Industry –Ethiopia). International Journal of Engineering Trends and Technology, 67(1), 23-33.
Pores are formed on casts in different sizes and forms. Porosity, cavity and blow holes are grouped as pores are the main challenges in steel castings at one of the foundry Industry in Ethiopia. This research was carried out mainly on pores defect analysis of manganese steel (46MnSi4) castings. The casts affected by pores of various types were 4784kg of pinion gear, 900kg of drive disc and 4538 kg of headstock. Due to porosity on the surface of castings and other similar pores in the sub surface of castings secondary work of these components were carried out. Due to large amount of metal removal by secondary work, the casts lost their dimensional specifications and qualitythus rejected. To carry out this research mixed (exploratory and experimental) research method with quantitative and qualitative approaches was used. Instruments used for data collection were physical observations, photographic analysis and experimental analysis. Data was gathered from both primary and secondary sources. The result of the experiment was analyzed using control charts and Ishikawa (cause and effect) diagram. Based on the analysis results, the root causes of porosity were identified. Mold preparation problems, molding material property, pouring temperature and time, poor gating system design, inappropriate material composition and improper utilization of reclaimed sand were the main causes for porosity. Experimental analysis revealed that the maximum pore depths on the drive disc, pinion gear and headstock components were 24mm, 23mm and 24mm respectively. The sizes of pores were very large and many in number, distributed in wide areas of caststhat consequently need removal of excess metal from the surface for finishing.However, excess removal of metal cased the casts to be below the required specification. Because of low quality the casts were rejected. Rework was done and the cost for rework was high (USD34482.1025). Controlling the parameters of casting avoiding the factors may improve the quality of castings.
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Casting, Porosity, Dimension of casts, Defects, quality of casts