Weldability of high strength aluminium alloys
Olabode, Muyiwa (2015-12-01)
Väitöskirja
01.12.2015
Lappeenranta University of Technology
Acta Universitatis Lappeenrantaensis
Julkaisun pysyvä osoite on
https://urn.fi/URN:ISBN:978-952-265-866-1
https://urn.fi/URN:ISBN:978-952-265-866-1
Tiivistelmä
The need for reduced intrinsic weight of structures and vehicles in the transportation
industry has made aluminium research of interest. Aluminium has properties that are
favourable for structural engineering, including good strength-to-weight ratio, corrosion
resistance and machinability. It can be easily recycled saving energy used in smelting as
compared to steel. Its alloys can have ultimate tensile strength of up to 750 MPa, which
is comparable to steel. Aluminium alloys are generally weldable, however welding of
high strength alloys like the 7xxx series pose considerable challenges.
This paper presents research on the weldability of high strength aluminium alloys,
principally the 7xxx series. The weldability with various weld processes including MIG,
TIG, and FSW, is discussed in addition to consideration of joint types, weld defects and
recommendations for minimizing or preventing weld defects.
Experimental research was carried out on 7025-T6 and AW-7020 alloys. Samples were
welded, and weld cross sections utilized in weld metallurgy studies. Mechanical tests
were carried out including hardness tests and tensile tests. In addition, testing was done
for the presence of Al2O3 on exposed aluminium alloy.
It was observed that at constant weld heat input using a pulsed MIG system, the welding
speed had little or no effect on the weld hardness. However, the grain size increased as
the filler wire feed rate, welding current and welding speed increased. High heat input
resulted in lower hardness of the weld profile. Weld preheating was detrimental to AW-
7020 welds; however, artificial aging was beneficial. Acceptable welds were attained
with pulsed MIG without the removal of the Al2O3 layer prior to welding. The Al2O3
oxide layer was found to have different compositions in different aluminium alloys.
These findings contribute useful additional information to the knowledge base of
aluminium welding. The application of the findings of this study in welding will help
reduce weld cost and improve high strength aluminium structure productivity by
removing the need for pre-weld cleaning. Better understanding of aluminium weld
metallurgy equips weld engineers with information for better aluminium weld design.
industry has made aluminium research of interest. Aluminium has properties that are
favourable for structural engineering, including good strength-to-weight ratio, corrosion
resistance and machinability. It can be easily recycled saving energy used in smelting as
compared to steel. Its alloys can have ultimate tensile strength of up to 750 MPa, which
is comparable to steel. Aluminium alloys are generally weldable, however welding of
high strength alloys like the 7xxx series pose considerable challenges.
This paper presents research on the weldability of high strength aluminium alloys,
principally the 7xxx series. The weldability with various weld processes including MIG,
TIG, and FSW, is discussed in addition to consideration of joint types, weld defects and
recommendations for minimizing or preventing weld defects.
Experimental research was carried out on 7025-T6 and AW-7020 alloys. Samples were
welded, and weld cross sections utilized in weld metallurgy studies. Mechanical tests
were carried out including hardness tests and tensile tests. In addition, testing was done
for the presence of Al2O3 on exposed aluminium alloy.
It was observed that at constant weld heat input using a pulsed MIG system, the welding
speed had little or no effect on the weld hardness. However, the grain size increased as
the filler wire feed rate, welding current and welding speed increased. High heat input
resulted in lower hardness of the weld profile. Weld preheating was detrimental to AW-
7020 welds; however, artificial aging was beneficial. Acceptable welds were attained
with pulsed MIG without the removal of the Al2O3 layer prior to welding. The Al2O3
oxide layer was found to have different compositions in different aluminium alloys.
These findings contribute useful additional information to the knowledge base of
aluminium welding. The application of the findings of this study in welding will help
reduce weld cost and improve high strength aluminium structure productivity by
removing the need for pre-weld cleaning. Better understanding of aluminium weld
metallurgy equips weld engineers with information for better aluminium weld design.
Kokoelmat
- Väitöskirjat [1102]