Effects of In and Ga on Spreading Performance of Ag10CuZnSn Brazing Filler Metal and Mechanical Properties of the Brazed Joints

Ag-based brazing filler metals are preferred in many industries, but the high price of Ag restricts their wider application. Therefore, developing novel low-Ag brazing filler metals has aroused extensive interest. In this study, the effects of the In and Ga elements on the melting behavior and sprea...
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Autor*in:	Junqian Zhang [verfasserIn] Jiachen Xu [verfasserIn] Yucan Fu [verfasserIn] Songbai Xue [verfasserIn] Yuhai Zhang [verfasserIn]

Format:	E-Artikel
Sprache:	Englisch

Erschienen:	2023

Schlagwörter:	low-Ag filler metal melting temperature spreading performance microstructure mechanical properties

Übergeordnetes Werk:	In: Crystals - MDPI AG, 2011, 13(2023), 11, p 1597
Übergeordnetes Werk:	volume:13 ; year:2023 ; number:11, p 1597

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc

DOI / URN:	10.3390/cryst13111597

Katalog-ID:	DOAJ101257791

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language	English
source	In Crystals 13(2023), 11, p 1597 volume:13 year:2023 number:11, p 1597
sourceStr	In Crystals 13(2023), 11, p 1597 volume:13 year:2023 number:11, p 1597
format_phy_str_mv	Article
institution	findex.gbv.de
topic_facet	low-Ag filler metal melting temperature spreading performance microstructure mechanical properties Crystallography
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container_title	Crystals
authorswithroles_txt_mv	Junqian Zhang @@aut@@ Jiachen Xu @@aut@@ Yucan Fu @@aut@@ Songbai Xue @@aut@@ Yuhai Zhang @@aut@@
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callnumber-first	Q - Science
author	Junqian Zhang
spellingShingle	Junqian Zhang misc QD901-999 misc low-Ag filler metal misc melting temperature misc spreading performance misc microstructure misc mechanical properties misc Crystallography Effects of In and Ga on Spreading Performance of Ag10CuZnSn Brazing Filler Metal and Mechanical Properties of the Brazed Joints
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topic_title	QD901-999 Effects of In and Ga on Spreading Performance of Ag10CuZnSn Brazing Filler Metal and Mechanical Properties of the Brazed Joints low-Ag filler metal melting temperature spreading performance microstructure mechanical properties
topic	misc QD901-999 misc low-Ag filler metal misc melting temperature misc spreading performance misc microstructure misc mechanical properties misc Crystallography
topic_unstemmed	misc QD901-999 misc low-Ag filler metal misc melting temperature misc spreading performance misc microstructure misc mechanical properties misc Crystallography
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title	Effects of In and Ga on Spreading Performance of Ag10CuZnSn Brazing Filler Metal and Mechanical Properties of the Brazed Joints
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title_full	Effects of In and Ga on Spreading Performance of Ag10CuZnSn Brazing Filler Metal and Mechanical Properties of the Brazed Joints
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title_sort	effects of in and ga on spreading performance of ag10cuznsn brazing filler metal and mechanical properties of the brazed joints
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title_auth	Effects of In and Ga on Spreading Performance of Ag10CuZnSn Brazing Filler Metal and Mechanical Properties of the Brazed Joints
abstract	Ag-based brazing filler metals are preferred in many industries, but the high price of Ag restricts their wider application. Therefore, developing novel low-Ag brazing filler metals has aroused extensive interest. In this study, the effects of the In and Ga elements on the melting behavior and spreading property of Ag10CuZnSn filler metal and the microstructure and strength of the brazed joints were investigated. The results show that both In and Ga can significantly decrease the solidus and liquidus temperatures of the filler metal. The In element can dissolve into the liquid filler metal and the Ga element can decrease the surface tension of the melted filler metal, which, in turn, improves the spreading area. The In element prefers to dissolve into the Ag-rich phase, and the Ga element prefers to dissolve into the Cu-rich phase; both improve the strength of the filler metal through solid-solution strengthening. The shear strength of the 304 stainless-steel brazed joint reached a peak value of 396 MPa when the Ag10CuZnSn-1.5In-2Ga (wt%) filler metal was used. However, the excessive addition of In and Ga forms brittle intermetallic compounds (IMCs) in the brazing seam, which decreases the strength of the brazed joint.
abstractGer	Ag-based brazing filler metals are preferred in many industries, but the high price of Ag restricts their wider application. Therefore, developing novel low-Ag brazing filler metals has aroused extensive interest. In this study, the effects of the In and Ga elements on the melting behavior and spreading property of Ag10CuZnSn filler metal and the microstructure and strength of the brazed joints were investigated. The results show that both In and Ga can significantly decrease the solidus and liquidus temperatures of the filler metal. The In element can dissolve into the liquid filler metal and the Ga element can decrease the surface tension of the melted filler metal, which, in turn, improves the spreading area. The In element prefers to dissolve into the Ag-rich phase, and the Ga element prefers to dissolve into the Cu-rich phase; both improve the strength of the filler metal through solid-solution strengthening. The shear strength of the 304 stainless-steel brazed joint reached a peak value of 396 MPa when the Ag10CuZnSn-1.5In-2Ga (wt%) filler metal was used. However, the excessive addition of In and Ga forms brittle intermetallic compounds (IMCs) in the brazing seam, which decreases the strength of the brazed joint.
abstract_unstemmed	Ag-based brazing filler metals are preferred in many industries, but the high price of Ag restricts their wider application. Therefore, developing novel low-Ag brazing filler metals has aroused extensive interest. In this study, the effects of the In and Ga elements on the melting behavior and spreading property of Ag10CuZnSn filler metal and the microstructure and strength of the brazed joints were investigated. The results show that both In and Ga can significantly decrease the solidus and liquidus temperatures of the filler metal. The In element can dissolve into the liquid filler metal and the Ga element can decrease the surface tension of the melted filler metal, which, in turn, improves the spreading area. The In element prefers to dissolve into the Ag-rich phase, and the Ga element prefers to dissolve into the Cu-rich phase; both improve the strength of the filler metal through solid-solution strengthening. The shear strength of the 304 stainless-steel brazed joint reached a peak value of 396 MPa when the Ag10CuZnSn-1.5In-2Ga (wt%) filler metal was used. However, the excessive addition of In and Ga forms brittle intermetallic compounds (IMCs) in the brazing seam, which decreases the strength of the brazed joint.
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container_issue	11, p 1597
title_short	Effects of In and Ga on Spreading Performance of Ag10CuZnSn Brazing Filler Metal and Mechanical Properties of the Brazed Joints
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Effects of In and Ga on Spreading Performance of Ag10CuZnSn Brazing Filler Metal and Mechanical Properties of the Brazed Joints

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