UDK 669.131.8:620.17:620.18 ISSN 1318-0010 Izvirni znanstveni članek KZLTET 33(6)401(1999) B. BOŠNJAK, B. RADOVI]: EFFECT OF AUSTEMPERING TEMPERATURE ON MICROSTRUCTURE ... EFFECT OF AUSTEMPERING TEMPERATURE ON MICROSTRUCTURE AND MECHANICAL PROPERTIES OF UNALLOYED DUCTILE IRON VPLIV AUSTEMPERING TEMPERATURE NA MIKROSTRUKTURO IN MEHANSKE LASTNOSTI NELEGIRANE DUKTILNE SIVE LITINE Branka Bošnjak 1, Branko Radulovi} 2 1University of Montenegro, Cetinjski put bb. 81000 Podgorica, Yugoslavia 2Faculty of Metallurgy and Technology, University of Montenegro, Cetinjski put bb., 81000 Podgorica, Yugoslavia Prejem rokopisa - received: 1996-10-04; sprejem za objavo - accepted for publication: 1997-04-21 Austempered ductile cast iron (ADI) has emerged in the last several decades as a major engineering material. The heat-treating of the ductile cast iron produces austempered ductile iron (ADI) with an excellent combination of s trength, fracture toughness and wear resistance for a wide variety of applications in automotive, rail and heavy engineering in dustries. The austempering temperature is the most important parameter in determining both the structure and the mechanical properties of unalloyed austempered ductile irons. It is varied in the range of 250-450°C. The aim of this wor k was to optimize the microstructure, and consequently the properties of ductile cast iron of composition Fe-3.48C-2.7Si (in wt.%). The analysis of the microstructure was performed by light microscopy, scanning electron microscopy, and X-ray diffr action. Keywords: cast iron, austempered ductile iron, austempering, retained austenite. Austemprana duktilna siva litina (ADI) je postala v nekaj zadnjih letih pomemben inženirski materia l. To litino izdelamo s toplotno obdelavo duktilne sive litine in ima zelo dobro kombinacijo trdnosti, žilavosti loma in od pornosti proti obrabi. Zato je primerna za uporabo v avtomobilski, železniški in težkih strojnih industrijah. Austempering temperatura je temeljni parameter, ki določa mikrostrukturo in mehanske lastnosti aust emprane litine. Ta temperatura je v razponu od 250 do 450 °C. Cilj tega dela je bil optimiziranje mikrostrukture in la stnosti duktilne sive litine s sestavo Fe-3,48%C-2,75%Si (v ut.%). Mikrostruktura je bila analizirana z optično mikroskopijo, rast er elektronsko mikroskopijo in difrakcijo X žarkov. Ključne besede: austemprana duktilna siva litina, austempranje, zadržani austenit 1 INTRODUCTION Austempered ductile iron (ADI) is a heat-treated ductile cast iron. It has a unique acicular matrix micro -structure that consist of high-carbon austenite ( ?hc ) and bainite ( a) with graphite nodules dispersed in it. With this microstructure ADI displays remarcable mechanical and physical properties. ADI is also highly versatile respect to manufacturing. Furthermore, the manufact -uring cost of an ADI component is lower than that of plain carbon or low-alloy steels 3. Figure 1: Schematic diagram of the austempering heat-treatment process Slika 1: Shema austempering toplotne obdelave KOVINE, ZLITINE, TEHNOLOGIJE 33 (1999) 6 Austempering is an isothermal heat-treatment process whose features are shown schematically in Figure 1 . It consists of austenitizing the components at approximately 900°C, quenching to the appropriate temperature (250 to 500°C) and holding at this temperature for between ˝ and 3 hours. During the holding period, austenite transforms isothermally to give a predominantly bainitic microstructure with varying proportions of retained austenite. 2 EXPERIMENTAL The chemical composition of the material used in this investigation (in weight percents) is reported in Table 1 . Tensile test bars were machined from the bottom section of the cast keel blocks 300 x 150 x 25 mm of unalloyed cast iron to avoid segregation effects, porosity, and low nodule count in the upper section. All the specimens were initially austenitized at 900°C for 2h and then austempered in molten salt bath at different temperatures in the range of 250 to 450°C for 2h, and then finally air-cooled to room temperature. Five identical test specimens were tested from each condition and the average values are reported in Table 2 . 401 B. BOŠNJAK, B. RADOVI]: EFFECT OF AUSTEMPERING TEMPERATURE ON MICROSTRUCTURE ... Table 1: Chemical composition of the investigated unalloyed ADI Table 2: Mechanical properties of unalloyed ADI (wt. %) Tabela 1: Kemična sestava preiskane nelegirane ADI (ut.%) C Si S Mn P Cu Ni Cr 3.48 2.70 0.001 0.07 0.033 0.02 0.06 0.03 Tabela 2: Mehanske lastnosti nelegirane ADI Austempering temperature °C Yield Strength MPa Ultimate Tensile Strength MPa Elongation % Hardness HB 250 1242 1483 1.2 453 300 1165 1380 2.4 427 350 939 1082 5.1 362 400 806 1010 6.2 331 450 717 952 7.0 324 Figure 2: Microstructure of ADI; a) austempering temperature 250°C (LM x300 and SEM x1500), b) austempering temperature 350°C (LM x300 and SEM x1500), c) austempering temperature 450°C (LM x300 and SEM x1500) Slika 2: Mikrostruktura ADI; a) temperatura austempranja 250°C (OMx300, SEMx1500); b) temperatura austempranja 350°C (OMx300, SEMx1500); c) temperatura austempranja 450°C (OMx300, SEMx1500) 402 KOVINE, ZLITINE, TEHNOLOGIJE 33 (1999) 6 B. BOŠNJAK, B. RADOVI]: EFFECT OF AUSTEMPERING TEMPERATURE ON MICROSTRUCTURE ... Samples for microstructal analysis were taken from the tensile test specimens at positions far from the fractured area. Specimens for light and scanning microscopy were prepared by the stan dar d metallographic technique. In addition to a qualitative analysis, a quantitative analysis using a computer image analyser was used. The microstructures of these differently heat-treated materials are shown in Figure 2a to 2c , respectively. In these microstructures austenite appears as dark gray areas between adjacent bainitic platelets and graphite nodules. The volume fraction of not transformed austenite was determined with X-ray diffraction ( Figure 3). The values of the volume fraction of phases for the heat-treated specimens are reported in Table 3 . Table 3: Volume share of microstructural constituents Tabela 3: Volumski delež konstituent mikrostrukture Austempering temperature /°C/ Bainite % Austenite % Graphite % 250 75.3 10.5 14. 300 66.4 18.0 15.5 350 65,0 21.2 14.5 400 48.3 36.6 15. 450 45.4 39.2 15.3 Figure 3: X-ray diffraction pattern for unalloyed austempered ductile iron Slika 3: Difrakcijska slika X žarkov za austemprano nelegirano duktilno sivo litino KOVINE, ZLITINE, TEHNOLOGIJE 33 (1999) 6 Figure 4: Influence of the volume share of bainite on hardness, yield strength and ultimate tensile strength of unalloyed austempered ductile iron Slika 4: Vpliv volumskega deleža bainita na trdnost, mejo plastičnosti in natezno trdnost austemprane nelegirane duktilne sive litine 3 RESULTS AND DISCUSSION 3.1 Microstructure The graphite spheroidisation of all tested specimens was found to be more than 90%. The graphite nodules were uniform in size and distribution with a volume fraction of 14 to 16%. An average graphite nodule size of 17m to 35m and an average count of 150mm -2 to 300mm -2 were found by image analysis. The microstructure of ADI obtained by the austempering process strongly depends on the transformation temperature. By lower austempering temperature the undercooling of austenite is greater and the diffusion rate of carbon is slow (graphite nodules are source for carbon). This results in more bainite and less austenite formation in the matrix by austempering temperatures of 250, 300 and 350°C. Moreover, these bainite platelets are rather small in size. This is clearly visible in Fig. 2a-b. At the higher austempering temperature, the carbon diffusion rate is faster and, consequently, the growth rate of bainitic platelets is rather rapid. This results in a lower volume share of bainite and more austenite in the metal matrix, but bainitic platelets are rather coarse, as clearly visible in Figure 2c . 3.2 Mechanical properties Test results reported in Table 2 show that after austempering at a lower temperature (250°C) the maximal yield and tensile strength and hardness of ADI are obtained, while austempering at a higher temperature (450°C) produces the maximal ductility of unalloyed ADI. Ductility of the unalloyed ADI increases with the increase in the austempering temperature. In Figure 4 hardness, yield, and ultimate tensile strength of unalloyed ADI are plotted against the volume share of bainite. It is evident that as the volume share of 403 B. BOŠNJAK, B. RADOVI]: EFFECT OF AUSTEMPERING TEMPERATURE ON MICROSTRUCTURE ... bainite increases, hardness, yield, and ultimate tensile strength of ADI increase. Since the graphite content is more or less the same, the above test results indicate that hardness, yield, and ultimate tensile strength of ADI decrease as the volume fraction of austenite in the matrix increases, i.e., for higher hardness, yield, and ultimate tensile strength, ADI should have more bainite and less austenite in the matrix, and should be, therefore, austempered at a lower austempering temperature. On the other hand, for higher ductility, ADI should have more austenite in the matrix and should be treated at a higher austempering temperature. 4 CONCLUSIONS At lower austempering temperatures (250, 300 and 350°C) more bainite was nucleated while its growth rate was rather slow. It resulted in a larger volume fraction of bainite in the matrix in form of smaller bainitic platelets. At higher austempering temperatures (400 and 450°C) less bainite was nucleated, while, its growth rate was more rapid. As a result, the matrix consisted of a smaller volume share of bainite in form of significantly coarser platelets. Yield, tensile strength and hardness of unalloyed ADI increase with increase in volume share of bainite in the matrix, while, the ductility of ADI increases with the increase in volume fraction of austenite in the matrix. 5 REFERENCES 1 R.C.Voigh, Cast Metal, 2 ( 1989 ) 71-93. 2 P.A. Blackomore & R.A. Harding, Proc. 1 st International Confe -rence on ADI , Chicago, 1984 , 117-134. 3 Patatunda, S. & Singh, I., Journal of Testing and Evaluation, JETVA, 23 ( 1995 ) 5, 325-332. 40 KOVINE, ZLITINE, TEHNOLOGIJE 33 (1999) 6