A Study on the Fabrication Process and Melt Infiltration of Salt Core in Squeeze Casting Method

스퀴즈캐스팅용 Salt Core의 제조 및 용탕침투성에 관한 연구

  • Kim, Ki-Bae (Division of Metals, Korea Institute of Science and Technology) ;
  • Noh, Sang-Woo (Dept. Metal and Material Engineering Science, Hanyand Univ.) ;
  • Lee, Ho-In (Division of Metals, Korea Institute of Science and Technology) ;
  • Nam, Tae-Woon (Dept. Metal and Material Engineering Science, Hanyand Univ.)
  • 김기배 (한국과학기술연구원 금속부) ;
  • 노상우 (한양대학교 금속재료공학과) ;
  • 이호인 (한국과학기술연구원 금속부) ;
  • 남태운 (한양대학교 금속재료공학과)
  • Published : 1997.08.20

Abstract

Developing a salt core for squeeze casting process, two different salt cores(pure salt core and mixed salt core) were fabricated and investigated. Pure salt core was composed of 100% NaCl and mixed salt core was made by mixtures of NaCl with MgO(1%), $Na_2B_4O_7$(2%), and talc(1%) as a binder or a strengthening agent. Salt cores were compacted to various theoretical density, heat treated, and then squeeze-cast with molten Al alloy(AC8A). The compression strength of salt cores were measured and the squeeze-cast products were examined for shape retention, infiltration of molten metal into the cores, and microstructures. The shape of salt core compacted at above 75% of the theoretical density was maintained stably. The higher theoretical density of salt cores gave higher compression strength, and the compression strength of mixed salt core was higher than that of pure salt core. Namely at 90% theoretical density, the compression strength of mixed salt core was $6.3 kg/mm^2$, compared to $4.6 kgmm^2$ for pure salt core. At a squeeze casting pressure of $1000 kg/cm^2$, molten Al alloy was infiltrated into pure salt core of under 85% of the theoretical density. At squeeze casting pressure of $1000 kg/cm^2$, only mixed salt core above 90% of the theoretical density were valid, but the shape of the core was altered in the case of pure salt core at 90% of theoretical density. A key factor for developing a salt core for squeeze casting process was estimated as the ultimate compressive strength of salt core.

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