<p>The aim of this study was to develop low-melting-point brazing filler metals for marine aluminum alloy AA5083. Six Zn–Al–Cualloys with varying aluminum contents were designed and systematically investigated. Among the examined alloys, Zn-4Al-3Cu exhibited the lowest liquidus temperature of 397.5&#xa0;°C, whereas Zn–14Al–3Cushowed a higher liquidus temperature of 435.5&#xa0;°C. The Zn–14Al–3Cualloy demonstrated the smallest equilibrium contact angle and the longest flow distance at a joint gap of 0.8&#xa0;mm. Calculations based on contact angle and surface tension data indicated that this alloy also possessed the highest capillary pressure. When the aluminum content was below 6 wt%, the microstructure consisted of <i>η</i>(Zn) dendrites and eutectic structures composed of layered <i>η</i>(Zn) and fine interlamellar eutectoid phases of <i>η</i>(Zn) and <i>α</i>(Al). With increasing aluminum content above 6 wt%, the microstructure evolved into dendritic eutectoid <i>η</i> + <i>α</i> structures together with lamellar eutectic phases. At the filler/base interface, zinc infiltration along the grain boundaries of the aluminum base metal was observed. The Zn–14Al–3Cualloy contained the fine eutectoid <i>η</i> + <i>α</i> structures, as well as the <i>ε</i>(CuZn<sub>4</sub>) intermetallic compounds which contributed to strengthening of the filler alloy. Consequently, Zn–14Al–3Cuexhibited the highest shear strength and average hardness among the investigated fillers.</p>

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Characteristics of zinc-based brazing fillers for AA5083 alloy

  • Hsuan-Han Lai,
  • Xian-Peng Yang,
  • Chi-Ming Lin,
  • Yun-Hsi Chao,
  • Weite Wu

摘要

The aim of this study was to develop low-melting-point brazing filler metals for marine aluminum alloy AA5083. Six Zn–Al–Cualloys with varying aluminum contents were designed and systematically investigated. Among the examined alloys, Zn-4Al-3Cu exhibited the lowest liquidus temperature of 397.5 °C, whereas Zn–14Al–3Cushowed a higher liquidus temperature of 435.5 °C. The Zn–14Al–3Cualloy demonstrated the smallest equilibrium contact angle and the longest flow distance at a joint gap of 0.8 mm. Calculations based on contact angle and surface tension data indicated that this alloy also possessed the highest capillary pressure. When the aluminum content was below 6 wt%, the microstructure consisted of η(Zn) dendrites and eutectic structures composed of layered η(Zn) and fine interlamellar eutectoid phases of η(Zn) and α(Al). With increasing aluminum content above 6 wt%, the microstructure evolved into dendritic eutectoid η + α structures together with lamellar eutectic phases. At the filler/base interface, zinc infiltration along the grain boundaries of the aluminum base metal was observed. The Zn–14Al–3Cualloy contained the fine eutectoid η + α structures, as well as the ε(CuZn4) intermetallic compounds which contributed to strengthening of the filler alloy. Consequently, Zn–14Al–3Cuexhibited the highest shear strength and average hardness among the investigated fillers.