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Preparation and Microstructure Evolution of Continuous Unidirectional Solidification Tin Bronze Alloy at Different Continuous Casting Speed

Jihui Luo
Archives of Foundry Engineering | 2020 | vol. 20 | No 2 | 118-122 | DOI: 10.24425/afe.2020.131313
Keywords Continuous unidirectional solidification Tin bronze Microstructure evolution Continuous casting speed
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Abstract

The mold temperature of the downward continuous unidirectional solidification (CUS) cannot be controlled higher than the liquidus of alloys to be cast. Therefore, the continuous casting speed becomes the main parameter for controlling the growth of columnar crystal structure of the alloy. In this paper, the tin bronze alloy was prepared by the downward CUS process. The microstructure evolution of the CUS tin bronze alloy at different continuous casting speeds was analysed. In order to further explain the columnar crystal evolution, a relation between the growth rate of columnar crystal and the continuous casting speed during the CUS process was built. The results show that the CUS tin bronze alloy mainly consists of columnar crystals and equiaxed crystals when the casting speed is low. As the continuous casting speed increases, the equiaxed crystals begin to disappear. The diameter of the columnar crystal increases with the continuous casting speed increasing and the number of columnar crystal decreases. The growth rate of columnar crystal increases with increasing of the continuous casting speed during CUS tin bronze alloy process.

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Authors and Affiliations

Jihui Luo

Effect of Post Cast Heat Treatment on Cu20wt.%Sn on Microstructure and Mechanical Properties

S. Slamet S. Suyitno I. K. Indraswari Kusumaningtyas
Archives of Foundry Engineering | 2021 | vo. 21 | No 4 | 87-92 | DOI: 10.24425/afe.2021.138684
Keywords Tin bronze Sand casting heat treatment microstructure mechanical properties
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Abstract

Casting is one method of making metal components that are widely used in industry and up to date. The sand casting method is used due to its simplicity, ease of operation, and low cost. In addition, the casting method can produce cast products in various sizes and is well-suited for mass production. However, the disadvantage of casting, especially gravity casting, is that it has poor physical and mechanical properties.
Tin bronze Cu20%wt.Sn is melted in a furnace, then poured at a temperature of 1100°C into a sand mold. The cast product is a rod with 400 mm in length, 10 mm in thickness, and 10 mm in width. The heat treatment mechanism is carried out by reheating the cast specimen at a temperature of 650°C, holding it for 4 hours, and then rapid cooling. The specimens were observed microstructure, density, and mechanical properties include tensile strength and bending strength. The results showed that there was a phase change from α + δ to α + β phase, an increase in density as a result of a decrease in porosity and a coarse grain to a fine grain. In addition, the tensile strength and bending strength of the Cu20wt.%Sn alloy were increased and resulted in a more ductile alloy through post-cast heat treatment.
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Bibliography

[1] C.D. Association, (1992). Copper Development Association Equilibrium Diagrams the major types of phase transformation.
[2] He, Z., Jian, C.A.O. & Ji-cai, F. (2009). Microstructure and mechanical properties of Ti6Al4V / Cu-10Sn bronze diffusion-bonded joint. Transaction Nonferrous Metals Society of China. 19, 414-417.
[3] Chen, X., Wang, Z., Ding, D., Tang, H., Qiu, L., Luo, X. & Shi, G. (2015). Strengthening and toughening strategies for tin bronze alloy through fabricating in-situ nanostructured grains. Material and Design. 1-31. ISSN: 0261-3069.
[4] Kohler, F., Campanella, T., Nakanishi, S. & Rappaz, M. (2008). Application of single pan thermal analysis to Cu – Sn peritectic alloys. Acta Materialia. 56, 1519-1528.
[5] Taslicukur, Z., Altug, G.S., Polat, S., Atapek, Ş.H., Turedi E. (2012). A Microstructural study on CuSn10 bronze produced by sand and investment casting techniques. In 21st International Conference on Metallurgy and Materials METAL 2012, 23-25 May 2012 . Brno, Czech Republic, EU.
[6] Goodway M (1992). Metals of Music. Materials Characterization. 29, 177-184.
[7] Audy J, Audy K (2008). Analysis of bell materials: Tin bronzes. China Foundry. 5, 199-204.
[8] Debut, V., Carvalho, M., Figueiredo, E., Antunes, J. & Silva, R. (2016). The sound of bronze: Virtual resurrection of a broken medieval bell. Jurnal of Cultural Heritage. 19, 544-554.
[9] S.Slamet, Suyitno & Kusumaningtyas, I. (2019). Effect of composition and pouring temperature of Cu(20-24)wt.%Sn by sand casting on fluidity and mechanical properties, Journal of Mechanical Engineering and Science. 13(4), 6022-6035.
[10] S. Slamet, Suyitno and Kusumaningtyas, I. (2019). Effect of composition and pouring temperature of Cu-Sn alloys on the fluidity and microstructure by investment casting. IOP Conf. Series: Materials Science and Engineering. 547, 1-8.
[11] S. Slamet, Suyitno, Kusumaningtyas, I. & Miasa, I.M. (2021). Effect of high-tin bronze composition on physical, mechanical, and acoustic properties of gamelan materials. Archives of Foundry Engineering. 21(1), 137-145.
[12] Fletcher, N. (2012). Materials and musical instruments. Acoustics Australia. 40, 30-134.
[13] Sumarsam, (2002). Introduction to javanese gamelan (Javanese Gamelan-Beginners). Syllabus. 451, 1-28.
[14] Salonitis. K., Jolly. M. & Zeng, B. (2017). Simulation based energy and resource efficient casting process chain selection. A case study. Procedia Manufacturing. 8, 67-74.
[15] Sulaiman, S. & Hamouda, A.M.S. (2001). Modeling of the thermal history of the sand casting process. Journal of Materials Processing Technology. 113, 245-250.
[16] Kim, E., Cho, G., Oh, Y. & Junga, Y. (2016). Development of a high-temperature mold process for sand casting with a thin wall and complex shape. Thin Solid Films. 620, 70-75.
[17] S. Slamet, Suyitno, Kusumaningtyas, I. (2019). Forging process on gamelan bar tin bronze Cu-25 wt. % Sn post casting deformation to changes in microstructure, density, hardness, and acoustic properties. IOP Conf. Series: Materials Science and Engineering. 673, 1-9.
[18] S. Slamet, Suyitno, & Kusumaningtyas, I. (2020). Comparative study of bonang gamelan musical instrument between hot forging and Post Cast Heat Treatment / PCHT on microstructure and mechanical properties. IOP Conf. Series: Materials Science and Engineering. 1430, 1-9.
[19] Morando, C., Fornaro, O., Garbellini, O. & Palacio, H. (2015). Fluidity on metallic eutectic alloys. Procedia Materials Science. 8, 959-967.
[20] Pang, S., Wu, G., Liu, W., Sun, M., Zhang, Y., Liu, Z. & Ding, W. (2013). Effect of cooling rate on the microstructure and mechanical properties of sand-casting Mg-10Gd-3Y-0.5 Zr magnesium alloy. Materials Science Engineering A. 562, 152-160.
[21] Chuaiphan, W. & Srijaroenpramong, L. (2013). The Effect of Tin and heat treatment in brass on microstructure and mechanical properties for solving the cracking of nut and bolt. Applied Mechanics and Materials. 389, 237-244.
[22] Sláma, P., Dlouhý, J. & Kövér, M. (2014). Influence of heat treatment on the microstructure and mechanical properties of aluminium bronze. Materials and Technology. 48(4), 599-604.
[23] Hanson. D, Pell-Walpole, W.T. (1951). Chill-Cast Tin Bronzes. 1-368
[24] Sanchez, J.A.B.F., Bolarin, A.M. , Tello, A. & Hernandez, L.E. (2006). Diffusion at Cu / Sn interface during sintering process. Materials Science of Technology. 22, 590-596.
[25] Gupta, R., Srivastava, S., Kishor, N. & Panthi, S.K. (2016). High leaded tin bronze processing during multi-directional forging : Effect on microstructure and mechanical properties. Materials Science Engineering A. 654, 282-291.

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Authors and Affiliations

S. Slamet
1
S. Suyitno
2
I. K. Indraswari Kusumaningtyas
3
  1. Universitas Muria Kudus, Indonesia
  2. Universitas Tidar Magelang, Indonesia
  3. Universitas Gadjah Mada, Indonesia

Dry Sliding Friction and Wear Behaviour of Leaded Tin bronze for Bearing and Bushing Application

D. Dinesh A. Megalingam
Archives of Metallurgy and Materials | 2021 | vol. 66 | No 4 | 1095-1104 | DOI: 10.24425/amm.2021.136429
Keywords Wear coefficient of friction Microstructure leaded tin bronze grey relational analysis
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Abstract

Among different bearing materials, copper-based alloys are the most important source for bearing and bushing applications. In this work, the tribological behavior of a leaded tin bronze (Cu-22Pb-4Sn) against an EN31 Steel for various loads (20 N, 70 N, 120 N) and different sliding velocity (1 m/s, 3 m/s, 5 m/s) at 3000 m sliding distance is performed using a pin on disk tribometer. Irrespective of all loads and sliding velocity, a higher specific wear rate is observed at 1 m/s and 120 N that fails to facilitate the formation of lubricating film, whereas a lower specific wear rate is evident when the sliding velocity is increased to 5 m/s. This is attributed to the formation of a stable oxide layer that has been confirmed through the Energy dispersive X-ray spectroscopy analysis and Scanning electron microscopy. The coefficient of friction is observed in reducing trend from 0.69 to 0.48 for the increasing load (70 N, 120 N) and sliding velocity (3 m/s and 5 m/s) due to stable thin oxide film formation. Also, the increase in frictional force and loading the interacting surface temperature is increased to a maximum of 102°C. The Grey relational analysis indicates that the optimal parameters for the minimum specific wear rate and coefficient of friction is 120 N and 5 m/s that has been confirmed with experimental analysis.
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Bibliography

[1] R.F. Schmidt, D.G. Schmidt, (10Ed.), Selection and application of copper alloy castings: Metals Handbook, ASM International, USA (1993).
[2] H . Turhan, M. Aksoy, V. Kuzucu, M.M. Yildirim, J. Mater. Process. Technol. 114 (3), 207-211 (2001). DOI: https://doi.org/10.1016/S0924-0136(01)00569-6
[3] S . Equey, A. Houriet, S. Mischler, Wear. 273 (1), 9-16 (2011). DOI: https://doi.org/10.1016/j.wear.2011.03.030
[4] G .C. Pratt, Powder Metall. 12 (24), 356-385 (2014). DOI: https://doi.org/10.1179/pom.1969.12.24.007
[5] B.K. Prasad, Can. Metall. Q. 51 (2), 210-220 (2013). DOI: https://doi.org/10.1179/1879139511Y.0000000030
[6] B. Unlu, Bull. Mater. Sci. 32 (4), 451-457 (2009). DOI: https://doi.org/10.1007/s12034-009-0066-0
[7] V. Ruusila, T. Nyyssonen, M. Kallio, P. Vuorinen, A. Lehtovaara, K. Valtonen, V.T. Kuokkala, Proc. Inst. Mech. Eng., Part J: J. Eng. Tribol. 227 (8), 878-887 (2013). DOI: https://doi.org/10.1177/1350650113478706.
[8] J.P. Pathak, S.N. Tiwari, Wear 155 (1), 37-47 (1992). DOI: https://doi.org/10.1016/0043-1648(92)90107-J
[9] Jan Gerkema, Wear 102 (3), 241-252 (1985). DOI: https://doi.org/10.1016/0043-1648(85)90222-4
[10] B. Unlu, E. Atik, J. Alloys Compd. 489 (1), 262-268 (2010). DOI: https://doi.org/10.1016/j.jallcom.2009.09.068
[11] B.K. Prasad, A.K. Patwardhan, A.H. Yegneswaran, Mater. Sci. Technol. 12 (5), 427-435 (1996). DOI: https://doi.org/10.1179/026708396790165885
[12] J.P. Pandey, B.K. Prasad, Metall. Mater. Trans. A. 29 (4), 1245- 1255 (1998). DOI: https://doi.org/10.1007/s11661-998-0251-6
[13] S . Murphy, T. Savaskan, Wear 98, 151-161 (1984). DOI: https://doi.org/10.1016/0043-1648(84)90224-2
[14] B.K. Prasad, Metall. Mater. Trans. A. 28 (3), 1245-1255 (1997). DOI: https://doi.org/10.1007/s11661-997-0067-9
[15] M. Aksoy, V. Kuzucu, H. Turhan, J. Mater. Process. Technol. 124 (1-2), 113-119 (2002). DOI: https://doi.org/10.1016/S0924-0136(02)00137-1
[16] A.W.J. De Gee, G.H.G. Vaessen, A. Begelinger, ASLE Transactions. 12 (1), 44-54 (2008). DOI: https://doi.org/10.1080/05698196908972245
[17] M. Nursoy, C. Oner, I. Can, Mater. Des. 29 (10), 2047-2051(2008). DOI: https://doi.org/10.1016/j.matdes.2008.04.020
[18] G . Cui, M. Niu, S. Zhu, J. Yang, Q. Bi, Tribol. Lett. 48 (2), 111- 122 (2012). DOI: https://doi.org/10.1007/s11249-012-0007-8
[19] B.K. Prasad, J. Mater. Eng. Perform, 21 (10), 2155-2164 (2012). DOI: https://doi.org/10.1007/s11665-012-0139-x
[20] B. Juszczyk, J. Kulasa, S. Malara, M. Czepelak, W. Malec, B. Cwolek, L. Wierzbicki, Arch. Metall. Mater. 59 (2), 615-620 (2014). DOI: https://doi.org/10.2478/amm-2014-0101
[21] F . Summer, F. Grun, M. Offenbecher, S. Taylor, Tribol. Int. 131, 238- 250 (2019). DOI: https://doi.org/10.1016/j.triboint.2018.10.042
[22] M. Kestursatya, J.K. Jim, P.K. Rohatgi, Mater. Sci. Eng., A. 339 (1-2), 150-158 (2003). DOI: https://doi.org/10.1016/S0921-5093(02)00114-4
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Authors and Affiliations

D. Dinesh
1
ORCID: ORCID
A. Megalingam
1
ORCID: ORCID
  1. Bannari Amman Institute of Technology, Department of Mechanical Engineering, Sathyamangalam, Erode-638401, Tamil Nadu, India

Effect of High-tin Bronze Composition on Physical, Mechanical, and Acoustic Properties of Gamelan Materials

S. Slamet S. Suyitnoa I. Kusumaningtyasa I.M. Miasaa
Archives of Foundry Engineering | 2021 | vo. 21 | No 1 | 137-145 | DOI: 10.24425/afe.2021.136090
Keywords Tin bronzes Mechanical properties Acoustic properties Gamelan Sand casting
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Abstract

High tin bronze alloy (Cu>17wt.%Sn) is commonly as raw material to fabricate musical instruments. Gamelan musical instruments in Indonesia are produced using tin bronze alloy raw materials. The tin bronze alloy used by each gamelan craftsman has a different tin composition, generally in the range of Cu(20-24) wt.% Sn. This study aims to investigate the effect of microstructure, density, and mechanical properties of Cu(20-24)wt.%Sn against the acoustic properties processed by the sand casting method. The material is melted in a crucible furnace until it reaches a pouring temperature of 1100ºC by the sand casting method. The specimens were subjected to microstructure observations, density and porosity as well as mechanical properties testing including tensile strength, bending strength, hardness, and modulus of elasticity. Mechanical properties data then used to calculate several parameters of acoustic properties including speed of sound (c), impedance (z) and radiation coefficient (R). Processes simulation using Finite Element Analysis (FEA) and Experiment Method Analysis (EMA) were carried out to determine acoustic properties including sound intensity, natural frequency and damping capacity.
The experimental result shows that the increase in tin composition in Cu(20-24) wt.% Sn changed the microstructure of coarse grains into dendrite-columned fine grains. Physical properties of density decrease, while porosity increases. Mechanical properties including tensile strength, modulus of elasticity, and bending strength decreased, while the hardness of the alloy increases. The calculation of acoustic parameters such as the speed of sound (c), impedance (z) and radiation coefficient (R) has decreased. Moreover, sound intensity (dB), natural frequency (Hz) and damping capacity also decrease with increasing tin composition. Hence, tin bronze alloy Cu20wt.%Sn is the recommended raw material for the manufacture of gamelan instruments through the sand casting method.
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Bibliography

[1] Sumarsam. (2002). Introduction to Javanese gamelan (Javanese gamelan-beginners). Wesleyan University. Middletown.
[2] Sutton, R.A. (2007). Gamelan: The Traditional Sounds of Indonesia (review). Asian Music. 38(1), 142-144.
[3] Suyanto, Tjokronegoro H.A, Merthayasa I.G.N. & Supanggah R. (2015). Acoustic parameter for javanese gamelan performance in pendopo mangkunegaran Surakarta. Procedia – Social and Behavioral Sciences. 184. 322-327.
[4] Goodway, M. (1992). Metals of music. Materials Characterization. 29. 177-184.
[5] Audy, J. & Audy, K. (2008). Analysis of bell materials: Tin bronzes. China Foundry. 5(3). 199-204.
[6] Debut, V. Carvalho, M. Figueiredo, E. Antunes, J. & Silva, R. (2016). The sound of bronze: Virtual resurrection of a broken medieval bell. Journal of Cultural Heritage. 19. 544-554.
[7] Sugita, I.K.G. Soekrisno, R. Miasa, I.M. & Suyitno. (2011). Mechanical and damping properties of silicon bronze alloys for music applications. International Journal of Engineering &. Technology. 11(6). 81-85.
[8] Sugita, I.K.G. Soekrisno, R. & Miasa, I.M. (2011). The effect of annealing temperature on damping capacity of the bronze 20 % Sn alloy. International Journal of Mechanical & Mechatronics Engineering. IJMME-IJENS. 11(4).1-5.
[9] Slamet, S. Suyitno, & Kusumaningtyas, I. (2019). Effect of composition and pouring temperature of Cu (20-24) wt.% Sn by sand casting on fluidity and Mechanical Properties, Journal of Mechanical Engineering and Science. 13(4). 6022-6035.
[10] Sugita, I.K.G. & Miasa, I.M. (2013). Feasibility Study On The Use Of Silicon-Bronze Alloys As An Alternative Material For Balinese Musical Instruments. 20th International Congress on Sound & Vibration; 7-11 July 2013.1-5. Bangkok, Thailand
[11] Prayoga, B.T. Suyitno, Dharmastiti, R. & Akbar, F. (2018). Microstructural characterization, defect, and hardness of titanium femoral knee joint produced using vertical centrifugal investment casting. Journal of Mechanical Science and Technology.32(1).149-156.
[12] Salonitis, K. Jolly, M. & Zeng, B. (2017). Simulation-based energy and resource-efficient casting process chain selection : A case study. Procedia Manufacturing. 8. 67-74.
[13] Wegst, U.G. (2006). Wood For Sound. American Journal of Botany. 93.1439-1448.
[14] Adams, R. D. & Fox, M.A.O. (1973). Correlation of the damping capacity of cast iron with its mechanical properties and microstructure. Journal of Mechanical Engineering Science. 15(2). 81-94.
[15] Grafov, B.M. (1994). The archimedes law and electrocapillarity. Electrochimica Acta. 39. 467-469.
[16] ASTM. (2015). Standard test methods for bend testing of material for ductility.1.1-10.
[17] Sutiyoko & Suyitno. (2012). Effect of pouring temperature and casting thickness on fluidity, porosity and surface roughness in lost foam casting of gray cast iron. Procedia Engineering. 50. 88-94.
[18] Halvaee, A. & Talebi, A. (2001). Effect of process variables on microstructure and segregation in the centrifugal casting of C92200 alloy. Journal of Materials Processing Technology. 118, 123-127.
[19] Sutiyoko. Suyitno. & Mahardika. M. (2016). Effect of gating system on porosity and surface roughness of femoral stem in centrifugal casting. Adv. Sci. Technol. Soc. AIP Conference Proceedings. 1755, 1-6.
[20] Sulaiman, S. & Hamouda, A.M.S. (2004). Modeling and experimental investigation of the solidification process in sand casting. Journal of Materials Processing Technology. 156, 1723-1726.
[21] Nadolski, M. (2017). The Evaluation of Mechanical Properties of High-tin Bronzes. Archives of Foundry Engineering. 17(1), 127-130.
[22] Nimbulkar, S.L. & Dalu. R.S. (2016). Design optimization of gating and feeding system through simulation technique for sand casting of wear plate. Perspectives in Science. 8.39-42.
[23] Singh, R. & Singh, S. (2013). Effect of process parameters on surface hardness, dimensional accuracy, and surface roughness of investment cast components; Journal of Mechanical Science and Technology. 27(1), 191-197.
[24] Bartocha, D. & Baron, C. (2016). Influence of tin-bronze melting and pouring parameters on its properties and bells ’ tone. Archives of Foundry Engineering. 16(4), 17-22.

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Authors and Affiliations

S. Slamet
1 2
S. Suyitnoa
1
I. Kusumaningtyasa
1
I.M. Miasaa
1
  1. Universitas Gadjah Mada, Yogyakarta, Indonesia
  2. Universitas Muria Kudus, Kudus, Indonesia

Effect of Process Parameters on Exudation Thickness in Continuous Unidirectional Solidification Tin Bronze Alloy

Jihui Luo Fang He
Archives of Foundry Engineering | 2019 | vol. 19 | No 2 | 97-100 | DOI: 10.24425/afe.2019.127123
Keywords Continuous unidirectional solidification Tin bronze alloy Orthogonal experiment Exudation
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Abstract

The exudation layer seriously affects the properties and the surface finish of the tin bronze alloy. The effective control of the exudation thickness is important measure for improving the properties of the alloy. In order to study the influence of process parameters on the thickness of exudate layer, the tin bronze alloy was prepared by continuous unidirectional solidification technology at different process parameters. The microstructure of the continuous unidirectional solidification tin bronze alloy was analyzed. The effect of process parameters on microstructure and chemical compositions was studied by orthogonal experiment. The results show that there exists an exudation layer on the surface of the continuous unidirectional solidification tin bronze alloy, and the exudation is mainly composed of a tin-rich precipitated phase. It indicates that the continuous casting speed is the main factor affecting the thickness of exudation layer, followed by mold temperature, melt temperature, cooling water temperature and cooling distance.

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Authors and Affiliations

Jihui Luo
Fang He

Assessment of the Change in the Tin Concentration in Bronzes to the Basic Components of the Sound of Bells

D. Cekus M. Nadolski
Archives of Metallurgy and Materials | 2021 | vol. 66 | No 2 | 531-535 | DOI: 10.24425/amm.2021.135889
Keywords high-tin bronze components of the sound of bell frequency analysis mechanical properties velocity of sound
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Abstract

The subject of the study was to determine the impact of changes in mechanical properties of high-tin bronzes on the basic components of the sound of a bell. Change in the tin concentration in the range of about 7.5 to 20 parts wt. in a casting alloy significantly affects the mechanical properties of the alloy such as Young’s modulus or hardness. The free vibrations of bells were obtained with the help of the finite element method. In the numerical analyses the mechanical properties of standard alloys were adopted. The obtained natural frequencies of the bell made of a bronze with different tin concentration in copper were compared with the acoustic properties of a real bell casted on the basis of the same ribs. A significant effect of the increase in the alloying share of tin on the obtained results was stated. In addition, the acoustic analysis of aluminum bronze C95500 have been performed. Based on the obtained results, authors stated that this material can replace the commonly used high tin bronze C91300 for the unit production of bells.
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Authors and Affiliations

D. Cekus
1
ORCID: ORCID
M. Nadolski
2
ORCID: ORCID
  1. Czestochowa University of Technology, Department of Mechanics and Machine Design Fundamentals, 73 Dąbrowskiego S tr., 42-201 Czestochowa, Poland
  2. Czestochowa University of Technology, Faculty of Production Engineering and Materials Technology, 19 Armii Krajowej Av., 42-200 Czestochowa, Poland

Analysis of a Castings Quality and Metalworking Technology. Treasure of the Bronze Age Axes

P. Długosz A. Garbacz-Klempka Z. Kwak Ł. Karczmarek J. Kozana M. Piękoś M. Perek-Nowak
Archives of Foundry Engineering | 2018 | vol.18 | No 3 | 179-185
Keywords non-destructive testing archeometallurgy Tin bronze X-ray spectroscopy Castings Defects
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Abstract

Cast axes are one of the most numerous categories of bronze products from earlier phases of the Bronze Age found in Poland. They had multiple applications since they were not only used objects such as tools or weapons but also played the prestigious and cult roles.

Investigations of the selected axes from the bronze products treasure of the Bronze Age, found in the territory of Poland, are presented

in the hereby paper. The holder of these findings is the State Archaeological Museum in Warsaw. Metallurgical investigations of axes with bushing were performed in respect of the casting technology and quality of obtained castings. Macroscopic observations allowed to document the remains of the gating system and to assess the range and kind of casting defects. Light microscopy revealed the microstructure character of these relicts. The chemical composition was determined by means of the X-ray fluorescence method with energy dispersion (ED-XRF) and by the scanning electron microscopy with X-ray energy dispersion analysis in micro-areas (SEM-EDS). The shape and dimensions of cores, reproducing inner parts of axes were identified on the basis of the X-ray tomography images. Studies reconstructed production technology of the mould with gating system, determined chemical composition of the applied alloys and casting structures as well as revealed the casting defects being the result of construction and usage of moulds and cores.

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Authors and Affiliations

P. Długosz
A. Garbacz-Klempka
Z. Kwak
Ł. Karczmarek
J. Kozana
M. Piękoś
M. Perek-Nowak

Assessment of Impact of Nickel Additions on Tin Bronzes

M. Perek-Nowak J. Kozana M. Piękoś A. Garbacz-Klempka E. Czekaj
Archives of Foundry Engineering | 2018 | vol.18 | No 1
Keywords Wear resistant alloys Tin bronze Microstructure Alloy additives Cu–Sn–Ni
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Abstract

High prices of tin and its limited resources, as well as several valuable properties characterising Cu-Sn alloys, cause searching for materials of similar or better properties at lower production costs. The influence of various nickel additions to CuSn10 casting bronze and to CuSn8 bronze of a decreased tin content was tested. Investigations comprised melting processes and casting of tin bronzes containing various nickel additions (up to 5%). The applied variable conditions of solidification and cooling of castings (metal and ceramic moulds) allowed to assess these alloys sensitivity in forming macro and microstructures. In order to determine the direction of changes in the analysed Cu-Sn-Ni alloys, the metallographic and strength tests were performed. In addition, the solidification character was analysed on the basis of the thermal analysis tests. The obtained results indicated the influence of nickel in the solidification and cooling ways of the analysed alloys (significantly increased temperatures of the solidification beginning along with increased nickel fractions in Cu-Sn alloys) as well as in the microstructure pattern (clearly visible grain size changes). The hardness and tensile strength values were also changed. It was found, that decreasing of the tin content in the analysed bronzes to which approximately 3% of nickel was added, was possible, while maintaining the same ultimate tensile strength (UTS) and hardness (HB) and improved plasticity (A5).

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Authors and Affiliations

M. Perek-Nowak
J. Kozana
M. Piękoś
A. Garbacz-Klempka
E. Czekaj

Reconstruction of the Casting Technology in the Bronze Age on the Basis of Investigations and Visualisation of Casting Moulds

A. Garbacz-Klempka Z. Kwak T. Stolarczyk M. Szucki P.L. Żak D. Ścibior K. Nowak
Archives of Foundry Engineering | 2017 | vol. 17 | No 3 | DOI: 10.1515/afe-2017-0113
Keywords Application of information technology to the foundry industry Archaeometallurgy Casting moulds Tin bronze XRF
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Abstract

During excavation of the cremation cemetery of urnfield culture in Legnica at Spokojna Street (Lower Silesia, Poland), dated to 1100-700

BC, the largest - so far in Poland – a collection of casting moulds from the Bronze Age was discovered: three moulds for axes casting

made out of stone and five moulds for casting sickles, razors, spearhead and chisels, made out of clay. This archaeological find constituted

fittings of foundrymen’s graves. In order to perform the complete analysis of moulds in respect of their application in the Bronze Age

casting technology analytical methods, as well as, computer aided methods of technological processes were used. Macroscopic

investigations were performed and the X-ray fluorescence spectrometry method was used to analyse the chemical composition and metal

elements content in mould cavities. Moulds were subjected to three-dimensional scanning and due to the reverse engineering the geometry

of castings produced in these moulds were obtained.

The gathered data was used to perform design and research works by means of the MAGMA5

software. Various variants of the pouring

process and alloys solidification in these archaeological moulds were simulated. The obtained results were utilised in the interpretation of

the Bronze Age casting production in stone and clay moulds, with regard to their quality and possibility of casting defects occurrence

being the result of these moulds construction.

The reverse engineering, modelling and computer simulation allowed the analysis of moulds and castings. Investigations of casting moulds

together with their digitalisation and reconstruction of casting technology, confirm the high advancement degree of production processes

in the Bronze Age.

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Authors and Affiliations

A. Garbacz-Klempka
Z. Kwak
T. Stolarczyk
M. Szucki
P.L. Żak
D. Ścibior
K. Nowak

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