Low Temperature Impact Tests in Austempered Ductile Iron and Other Spheroidal Graphite Cast Iron Structures.

Ratto, P.J.J.; Ansaldi, A.; Fierro, V. E.; Agüera, F.R.; Villar, H. N. Alvarez; Sikora, Jorge Antonio

doi:10.2355/isijinternational.41.372

Cited by 15 publications

(9 citation statements)

References 6 publications

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“…The main factors that influence the structure of ductile iron are chemical composition, cooling rate, liquid treatment, and heat treatment (Ref [1][2][3][4]. The cooling rate of a casting is primarily a function of its section size, pouring temperature, and the material mold ability to absorb the heat.…”

Section: Introductionmentioning

confidence: 99%

Effect of Cooling Rate on Microstructure and Mechanical Properties of Thin-Walled Ductile Iron Castings

Górny

Tyrała

2012

J. of Materi Eng and Perform

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This article addresses the effect of cooling rate on microstructure and mechanical properties as determined by changing molding media and section size. The research was conducted for thin-walled iron castings with 2-5-mm wall thickness and for the reference casting with 13-mm wall thickness, using different molding materials (silica sand and insulating sand ''LDASC'') to achieve various cooling rates. Thermal analysis was performed to determine the real cooling rate at the beginning of the graphite eutectic solidification. In general, it was found that the predictions based on theoretical analysis of the solidification process of ductile iron are in good agreement with the experimental outcomes. Finally, the present study provides insights into the effect of cooling rate on the graphite nodule count, the ferrite fraction and mechanical properties of thin-walled ductile iron castings. The study shows that the cooling rate of thin-walled castings varies in a wide range (80-15°C/s) when changing the wall thickness from 2 to 5 mm, accompanied by significantly changing the mechanical properties of ductile iron. The cooling rate can be effectively reduced by applying an insulating sand to obtain the desired properties of thin-walled castings practically in the whole range of ductile iron grades in accordance with the ASTM Standard.

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Section: Introductionmentioning

confidence: 99%

Effect of Cooling Rate on Microstructure and Mechanical Properties of Thin-Walled Ductile Iron Castings

Górny

Tyrała

2012

J. of Materi Eng and Perform

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“…Figure 10 shows that the microstructures of basic metal are ferrite, and Fig. 11 shows that the microstructure of the heat-affected zone is a mixture of ferrite and tempered pearlite, while the microstructure of According to several studies, pearlite is harder than ferrite, when pearlite appears in the molten zone, it changes the mechanical characteristics (tension-shear, elasticmoduli (E) and longitudinal modulus (C L )) of welding [26,27], and mechanical properties depend on the percentage of pearlite and ferrite content in the microstructure of welding [9], and increasing the percentage of p e a r l i t e l e a d s t o i n c r e a s i n g t h e h a r d n e s s o f microstructures.…”

Section: Experimental Settingmentioning

confidence: 99%

Evaluation of the physical properties of spot welding using ultrasonic testing

Moghanizadeh

2015

Int J Adv Manuf Technol

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Spot welding is an effective method of joining metal sheets. This method is extensively applied by automotive and similar industries. The quality of spot welding depends on the physical characteristics to a large extent. Therefore, determining the proper methods to ensure the physical characteristics is of utmost importance. This study used ultrasonic nondestructive testing to assess the physical characteristics of spot welding and its quality. The method employs different intensities of ultrasonic wave energy travelling through a test object, which is influenced by structural changes caused by heating during the welding process. As a result, it is possible to estimate such physical characteristics of welding as microhardness of the spot welding through attenuation coefficient of ultrasonic testing. In addition, the experimental results indicate the relationship between microhardness value and spot welding quality.

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“…After the specimens have reached the required temperature, they were quickly fractured within a 5 s time interval. According to standard EN 10045, the 5 s time interval is acceptable for the duration of the test, and no significant temperature loss can be expected (Ratto et al , 2001).…”

Section: Materials and Experimental Proceduresmentioning

confidence: 99%

“…In view of that, it is of great importance to know the behaviour of DI and ADI at low temperatures (Riabov et al , 2002; Batra et al , 2007). One very important criterion for materials selection, especially in low‐temperature applications, is the ductile to brittle transition temperature (Ratto et al , 2001; Fierro et al , 2002).…”

Section: Introductionmentioning

confidence: 99%

Transition temperature and fracture mode of as‐castand austempered ductile iron

Rajnović

Erić²,

Šidjanin

2008

Journal of Microscopy

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SummaryThe ductile to brittle transition temperature is a very important criterion that is used for selection of materials in some applications, especially in low-temperature conditions. For that reason, in this paper transition temperature of as-cast and austempered copper and copper-nickel alloyed ductile iron (DI) in the temperature interval from −196 to +150• C have been investigated. The microstructures of DIs and ADIs were examined by light microscope, whereas the fractured surfaces were observed by scanning electron microscope. The ADI materials have higher impact energies compared with DIs in an as−cast condition. In addition, the transition curves for ADIs are shifted towards lower temperatures. The fracture mode of Dls is influenced by a dominantly pearlitic matrix, exhibiting mostly brittle fracture through all temperatures of testing. By contrast, with decrease of temperature, the fracture mode for ADI materials changes gradually from fully ductile to fully brittle.

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Low Temperature Impact Tests in Austempered Ductile Iron and Other Spheroidal Graphite Cast Iron Structures.

Cited by 15 publications

References 6 publications

Effect of Cooling Rate on Microstructure and Mechanical Properties of Thin-Walled Ductile Iron Castings

Effect of Cooling Rate on Microstructure and Mechanical Properties of Thin-Walled Ductile Iron Castings

Evaluation of the physical properties of spot welding using ultrasonic testing

Transition temperature and fracture mode of as‐castand austempered ductile iron

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