[0001] This application claims the benefit of U.S. Provisional Application No. 60/036,329,
filed January 31, 1997.
Field of the Invention
[0002] The present invention is directed to a method of improving the fracture toughness
in the short longitudinal direction in aluminum-lithium alloys and a product therefrom
and, in particular, to a method which controls the levels of copper, manganese, lithium,
and zirconium in the alloys to obtain the improved fracture toughness.
Background Art
[0003] It is well known that adding lithium as an alloying element to aluminum alloys results
in beneficial mechanical properties. Aluminum-lithium alloys exhibit improvements
in stiffness and strength while reducing density. Consequently, these types of alloys
have utility as structural materials in airplane and aerospace applications. Examples
of known aluminum-lithium alloys include AA2097 and AA2197. The chemical compositions
of these alloys are shown in Table 1 below.
[0004] Problems exist with aluminum-lithium alloys, particularly in thick plate of about(3
inches) 76.2 mm or greater, in terms of fracture toughness in the short longitudinal
(S-L) direction. Toughness values in this direction tend to be significantly lower
than toughness values in other directions such as the longitudinal (L-T) direction
or the long transverse (T-L) direction.
[0005] Metals & Alloys in the unified Numbering System, 7th Ed., Society of Automotive Engineers,
USA, 1996, p.30 discloses a composition for a wrought and heat treatable aluminum
alloy having 1.2 - 1.8 % lithium.
[0006] US-A-4 648 913 discloses a process for producing an aluminum alloy including the
processing steps of casting, homogenizing, hot working, solution heat treating, quenching,
optionally stretching and finally aging to obtain an improved fracture toughness alloy,
which contains 0.5 to 4 % Lithium, preferably 2.0 to 3.0 % lithium.
[0007] F. W. Gayle et al., Aluminum-Lithium, ed. by M. Peters and P.-J. Winkler, DGM, 1992,
p.203-208 discloses a production method for an aluminum alloy including 0.4 % silver
and 1 % lithium.
[0008] In view of the drawbacks in aluminum-lithium alloys with respect to fracture toughness,
a need has developed to provide a method of improving the short longitudinal (S-L)
direction fracture toughness for these types of alloys. In response to this need,
the present invention provides both a method and a product therefrom which significantly
increases the fracture toughness of aluminum-lithium alloys in the short longitudinal
(S-L) direction, thereby improving their suitability for more commercial applications.
Summary of the Invention
[0009] A first object of the invention is to improve the fracture toughness in the short
longitudinal (S-L) direction of aluminum-lithium alloys.
[0010] Another object of the invention is to provide a method of making an aluminum-lithium
alloy having improved short longitudinal direction fracture toughness.
[0011] A still further object of the present invention is to utilize an aluminum-lithium
alloy having controlled amounts of copper, lithium, manganese, zinc and zirconium
to achieve fracture toughness improvements.
[0012] Yet another object of the present invention is to provide an aluminum-lithium alloy
product having both improved fracture toughness in the short longitudinal (S-L) direction
and acceptable strength in the short transverse direction.
[0013] Other objects and advantages of the present invention will become apparent as a description
thereof proceeds.
[0014] In satisfaction of the foregoing objects and advantages, the present invention provides
a method for improving the fracture toughness in the short longitudinal (S-L) direction
in an aluminum-lithium alloy article comprising the steps of providing an aluminum
alloy consisting of, in weight percent all subsequent alloying levels are weight percent
unless otherwise indicated): 2.7 to 3.0% copper, 1.2% to less than 1.3% lithium, 0.30
to 0.32% manganese, 0.04 to 0.18% zirconium, with the balance aluminum and inevitable
impurities. The aluminum alloy can also include grain refining elements such as at
least one of boron, titanium, vanadium, manganese, hafnium, scandium and chromium.
Preferably, the aluminum alloy has only impurity levels of zinc so that it is essentially
zinc-free, e.g., less than 0.05 weight percent zinc, more preferably less than or
equal to 0.02%.
[0015] The lithium content is preferably controlled between about 1.2 to 1.28 weight percent
to provide a low density product with good fracture toughness in the short longitudinal
direction. Manganese is between 0.30 and 0.32 weight percent, with zirconium being
about 0.10 weight percent. It should be appreciated that the amounts of alloying elements,
other than the amounts of lithium and copper, can be within the ranges described in
the preceding paragraph.
[0016] This composition provides higher combined properties of fracture toughness and strength,
with slightly higher density. In this composition range, additional theta' precipitate
particles (Al
2Cu) would precipitate in addition to T
1 precipitate particles (Al
2CuLi) at the grain boundaries. This would increase the combined properties of strength
and fracture toughness in the short longitudinal direction.
[0017] Magnesium can be added if desired, in an amount up to 0.35% weight percent, preferably,
up to 0.25 weight percent. Small amounts of magnesium may be beneficial in terms of
strength and lowering of density. However, excessive amounts may create susceptibility
to stress corrosion cracking and do not provide further benefits in terms of strength
and density reduction.
[0018] The aluminum alloy is cast into an ingot and homogenized for a select period of time.
The homogenized ingot is then hot worked into a shape such as a plate and solution
heat treated for a select period of time. The solution heat treated shape is then
quenched, preferably in water, cold worked, preferably by stretching, and aged for
a select period of time. With this processing, the cold worked (stretched) and aged
shape exhibits equivalent strengths but higher fracture toughness in the short longitudinal
(S-L) direction than similar aluminum alloys having lithium contents greater than
1.3%.
[0019] The homogenization and solution heat treating temperatures can range between about
(900° and 1030°F) 482 to 554°C, preferably between about (930° F) 499°C and (1000°F)
538°C. More preferably, homogenization temperatures will range between about (940°F)
505°C to (975°F) 524°C , and solution heat treating temperatures will range between
about (975°F) 524°C to (1000°F) 538°C. The preferred temperature often depends on
the particular alloy composition as will be understood by one skilled in the art.
Homogenization times can be about 8 to 48 hours, preferably about 24 to about 36 hours.
Solution heat treating times can range from about 1 to 10 hours, preferably about
1 hour to 6 hours, more preferably about 2 hours, once the metal reaches a desired
temperature. The plate may be artificially aged without any cold work. However, it
is preferred to provide between about 4% and 8% cold work, preferably by stretching.
The plate is preferably artificially aged between about (300 and 350°F) 149 to 177°C
for between about 4 and about 48 hours, preferably between about 12 and about 36 hours,
with the aging .time being a function of the aging temperature.
[0020] Using the inventive processing, an aluminum-lithium alloy article is made having
vastly improved fracture toughness in the short longitudinal (S-L) direction. The
fracture toughness value in the short longitudinal (S-L) direction is at least about
68% of the fracture toughness in the long transverse (T-L) direction. While exhibiting
improved fracture toughness in the short longitudinal (S-L) direction, the inventive
aluminum-lithium alloy articles have tensile yield strengths exceeding about (54 KSI)
372.3 MPa.
Brief Description of the Drawings
[0021] Reference is now made to the drawings of the invention wherein:
Figure 1 compares the invention to the prior art in terms of tensile yield strength
in the short transverse direction and fracture toughness in the short longitudinal
(S-L) direction;
Figure 2 compares prior art alloy products and the invention alloy products with respect
to lithium content and fracture toughness in the short longitudinal (S-L) direction;
and
Figure 3 compares the prior art alloy products and the invention alloy products with
respect to copper content and fracture toughness in the short longitudinal (S-L) direction.
Description of the Preferred Embodiment
[0022] The present invention solves a significant problem in the field of aluminum-lithium
materials for structural applications such as those found in the aerospace and airplane
industry. That is, by controlling the compositional amounts of copper, lithium, manganese
and zirconium in these types of alloys, acceptable fracture toughness in the short
longitudinal (S-L) direction with acceptable strength in the short transverse (ST)
direction is obtained. This unexpected improvement in fracture toughness in the S-L
direction permits the use of these types of alloys in a wide variety of structural
applications requiring low weight, high strength and stiffness, and good fracture
toughness.
[0023] According to the present invention, the alloy elements of copper, lithium, manganese
and zirconium are controlled in the following ranges to achieve the improvements in
fracture toughness: 2.7 to 3.0 weight percent copper, 1.2 to less than 1.3 weight
percent lithium, 0.30 to 0.32 weight percent manganese, about 0.04 to 0.16 weight
percent zirconium, with the balance aluminum and inevitable impurities. One or more
grain refining elements can also be added to the aluminum-lithium composition described
above. The grain refining elements can be selected from the group consisting of titanium
in an amount up to 0.2 weight percent, boron in an amount of up to 0.2 weight percent,
vanadium in an amount of up to 0.2 weight percent, hafnium in an amount up to 0.2
weight percent, scandium in an amount up to 0.5 weight percent, and chromium in an
amount up to 0.3 weight percent. Preferably the aluminum is free of zinc. In other
words, zinc is present only as an impurity and at levels less than 0.05 weight percent.
It is believed that zinc in levels greater than such impurity level adversely affects
the mechanical properties of these types of aluminum-lithium alloys.
[0024] The manganese should be higher than 0.05 weight percent to control grain size and
homogenous slip behavior during plastic deformation processing.
[0025] The lithium content is controlled between 1.2 and less than 1.3 weight percent. The
manganese is between 0.3 and 0.32 weight percent with the copper level ranging between
about 2.7 and 3.0 weight percent.
[0026] Magnesium can be added if desired, in an amount preferably up to 0.35% weight percent,
preferably, up to 0.25 weight percent. Small amount of magnesium may be beneficial
in terms of strength and lowering of density. However, excessive amounts may create
susceptibility to stress corrosion cracking and do not provide further benefits in
terms of strength and density reduction.
[0027] In conjunction with specifying the alloy composition in the aluminum-lithium alloy
composition above, the alloy is processed by the steps of casting, homogenizing, hot
working (for instance, by rolling, forging, extruding and combinations thereof), solution
heat treating, quenching, cold working (for instance by stretching) and aging to form
an aluminum-lithium article having the improvements in fracture toughness in the S-L
direction.
[0028] As part of this processing, the aluminum-lithium alloy described above is cast into
an ingot, billet or other shape to provide suitable stock for the subsequent processing
operations. Once the shape is cast, it can be stress-relieved as is known in the art
prior to homogenization. The cast shape is then homogenized at temperatures in the
range of (930°F to 1,030°F) 499°C to 554.4°C, for a sufficient period of time to dissolve
the soluble elements and homogenize the internal structure of the metal. A preferred
homogenization residence time is in the range of 1 to 36 hours, while longer times
do not normally adversely affect the article. The homogenization can be conducted
at one temperature or in multiple steps utilizing several temperatures.
[0029] After homogenization, the cast shape is then hot worked to produce stock such as
sheet, plate, extrusions, or other stock material depending on the desired end use
of the aluminum-lithium alloy article. For example, an ingot having a rectangularly
shaped cross section could be hot worked into a plate form. Since this hot working
step is conventional in the art, a further description thereof is not deemed necessary
for understanding of the invention.
[0030] Following the hot working step, the hot worked shape is then solution heat treated
and quenched. Preferably, the hot worked shape is solution heat treated between (930°
to 1030°F) 499° to 554°C at a time from less than an hour to up to several hours.
This solution heat treated shape is preferably rapidly quenched, e.g. quenched in
ambient temperature water, to prevent or minimize uncontrolled precipitation of strengthening
phases in the alloy. The rapid quenching can also include a subsequent air cooling
step, if desired.
[0031] The quenched shape is then preferably stretched up to 8% and artificially aged in
the temperature range of (150° to 400°F) 66° to 204°C for sufficient time to further
increase the yield strength, e.g., up to 100 hours, depending on the temperature,
for instance, 24 hours at (300°F) 149°C. The stretched and aged shape is then ready
for use in any application, particularly an aerospace or airplane application. Alternatively,
prior to aging, the shape may be formed into an article and then aged.
[0032] In order to demonstrate the unexpected improvements associated with the present invention,
a comparison was made between properties of articles made from aluminum-lithium alloys
of the prior art and articles made from aluminum-lithium alloys according to the invention.
In this comparison, four prior art chemistries were selected along with four chemistries
according to the invention. An aluminum alloy melt was made from each of the eight
chemistries and processed by casting, homogenizing, solution heat treating, quenching,
stretching and aging to produce an aluminum-lithium alloy article or product. The
aluminum-lithium alloy articles were then subjected to tensile and fracture toughness
testing to compare the mechanical properties of the prior art chemistries to those
corresponding to the instant invention.
[0033] The following details the processing used and test methods to compare the mechanical
properties of the prior art and inventive aluminum-lithium alloy articles. In the
comparison, the prior art articles are designated as Examples 1-4, and the articles
of the invention are designated as Examples 5-8.
[0034] It should be understood that the processing variables and chemistries disclosed in
Examples 5-8 are embodiments of the invention.
Table 1
|
Si |
Fe |
Cu |
Mn |
Mg |
Zn |
Zr |
Ti |
Li |
AA2097 |
0.12 |
0.15 |
2.5-3.1 |
0.10-0.6 |
0.35 |
0.35 |
0.08-0.16 |
0.15 |
1.2-1.8 |
AA2197 |
0.10 |
0.10 |
2.5-3.1 |
0.10-0.5 |
0.25 |
0.05 |
0.08-0.15 |
0.12 |
1.3-1.7 |
Table 1 Notes
[0035] 1. Chemical compositions are expressed in a weight percent maximum unless shown as
a range.
[0036] 2. In addition to the listed elements, each alloy may contain other elements, with
the maximum amount of each other element not exceeding 0.05 wt. % and the total of
other elements not exceeding 0.15 wt. %.
Example 1
[0037] An aluminum alloy consisting of, in weight percent, 2.84 Cu-1.36 Li-.32 Mn.-.1 Zr,
the balance aluminum and impurities, was cast into an ingot with a cross section of
(16") 406.4 mm and (45") 1143 mm wide. The ingot was homogenized at (950°F) 510°C
for 36 hours, then hot worked to (4") 101.6 mm thick plate. The plate was then solution
heat treated in a heat treating furnace at a temperature of (990°F) 532°C for 2 hours
and then quenched in water. The plate was then stretched by 6% in the longitudinal
direction at room temperature. For artificial aging, the stretched samples were aged
in an oven at (320°F) 160°C for 24 hours. Tensile properties were determined at the
T/4 plane in accordance with ASTM B-557. Tensile tests in the longitudinal direction
and the long transverse direction used round tensile specimens with (.5") 12.7 mm.
diameter and (1") 25.4 mm gauge length. Tensile tests in the short transverse direction
were conducted with round tensile specimens with (.160") 4.1 mm diameter and (.5")
12.7 mm gauge length. Fracture toughness was determined at the T/4 plane by ASTM standard
practice E266 using W= (1.5") 38.1 mm Compact Tension specimens for the short longitudinal
direction and W= (2") 50.8 mm Compact Tension specimens for the L-T and T-L directions.
The results of these tests are listed in Table 2.
Example 2
[0038] An aluminum alloy consisting of, in weight percent, 2.71 Cu-1.37 Li-.32 Mn.-.1 Zr,
the balance aluminum and impurities, was cast into an ingot with a cross section of
(16") 406.4 mm and (45") 1143 mm wide. The ingot was homogenized at (950°F) 510°C
for 36 hours, then hot worked to (4") 101.6 mm thick plate. The plate was then solution
heat treated in a heat treating furnace at a temperature of (990°F) 532°C for 2 hours
and then quenched in water. The plate was then stretched by 6% in the longitudinal
direction at room temperature. For artificial aging, the stretched samples were aged
in an oven at (320°F) 160°C for 24 hours. Tensile properties were determined at the
T/4 plane in accordance with ASTM B-557. Tensile tests in the longitudinal direction
and long transverse direction used round tensile specimens with (.5") 12.7 mm diameter
and (1") 25.4 mm gauge length. Tensile tests in the short transverse direction were
conducted with round tensile specimens with (.160") 4.1 mm diameter and (.5") 12.7
mm gauge length. Fracture toughness was determined at the T/4 plane by ASTM standard
practice E266 using W= (1.5") 38.1 mm Compact Tension specimens for the short longitudinal
(S-L) direction and W= (2") 50.8 mm Compact Tension specimens for the L-T and T-L
directions. The results of these tests are listed in Table 3.
Example 3
[0039] An aluminum alloy consisting of, in weight percent, 2.77 Cu-1.33 Li-.32 Mn.-.11 Zr,
the balance aluminum and impurities, was cast into an ingot with a cross section of
(16") 406.4 mm and 45" 1143 mm. wide. The ingot was homogenized at (950°F) 510°C for
36 hours, then hot worked to (4") 101.6 mm thick plate. The plate was then solution
heat treated in a heat treating furnace at a temperature of (990°F) 532°C for 2 hours
and then quenched in water. The plate was then stretched by 6% in the longitudinal
direction at room temperature. For artificial aging, the stretched samples were aged
in an oven at (320°F) 160°C for 24 hours. Tensile properties were determined at the
T/4 plane in accordance with ASTM B-557. Tensile tests in the longitudinal direction
and the long transverse direction used round tensile specimens with .5" 12.7 mm diameter
and(1") 25.4 mm gauge length. Tensile tests in short transverse direction were conducted
with round tensile specimens with .160" 4.1 mm diameter and (.5") 12.7 mm gauge length.
Fracture toughness was determined at the T/4 plane by ASTM standard practice E266
using W= (1.5") 38.1 mm Compact Tension specimens for the short longitudinal direction
and W= (2") 50.8 mm Compact Tension specimens for the L-T and T-L directions. The
results of these tests are listed in Table 4.
Example 4
[0040] An aluminum alloy consisting of, in weight percent, 2.89 Cu-1.36 Li-.32 Mn.-0.1 Zr,
the balance aluminum and impurities, was cast into an ingot with a cross section of
(16") 406.4 mm and (45") 1143 mm wide. The ingot was homogenized at (950°F) 510°C
for 36 hours, then hot worked to (4") 101.6 mm thick plate. The plate was then solution
heat treated in a heat treating furnace at a temperature of (990°F) 532°C for 2 hours
and then quenched in water. The plate was then stretched by 6% in the longitudinal
direction at room temperature. For artificial aging, the stretched samples were aged
in an oven at (320°F) 160°C for 24 hours. Tensile properties were determined at the
T/4 plane in accordance with ASTM B-557. Tensile tests in the longitudinal direction
and the long transverse direction used round tensile specimens with (.5") 12.7 mm
diameter and (1") 25.4 mm gauge length. Tensile tests in the short transverse direction
were conducted with round tensile specimens with (.160") 4.1 mm diameter and (.5")
,12.7 mm gauge length. Fracture toughness was determined at the T/4 plane by ASTM
standard practice E266 using W=(1.5") 38.1 mm Compact Tension specimens for the short
longitudinal (S-L) direction and W=(2") 50.8 mm Compact Tension specimens for the
L-T and T-L directions. The results of these tests are listed in Table 5.
Example 5
[0041] An aluminum alloy consisting of, in weight percent, 2.78 Cu-1.21 Li-.31 Mn.-0.1 Zr,
the balance aluminum and impurities, was cast into an ingot with a cross section of
(16") 406.4 mm and 45" 1143 mm wide. The ingot was homogenized at (950°F) 510°C for
36 hours, then hot worked to (4") 101.6 mm thick plate. The plate was then solution
heat treated in a heat treating furnace at a temperature of 990°F 532°C for 2 hours
and then quenched in water. The plate was then stretched by 6% in the longitudinal
direction at room temperature. For artificial aging, the stretched samples were aged
in an oven at (320°F) 160°C for 24 hours. Tensile properties were determined at the
T/4 plane in accordance with ASTM B-557. Tensile tests in the longitudinal direction
and the long transverse direction used round tensile specimens with (.5") 12.7 mm
diameter and(1") 25.4 mm gauge length. Tensile tests in the short transverse direction
were conducted with round tensile specimens with (.160") 4.1 mm diameter and (.5")
12.7 mm gauge length. Fracture toughness was determined at the T/4 plane by ASTM standard
practice E266 using W=(1.5") .38.1 mm Compact Tension specimens for the short longitudinal
(S-L) direction and W=(2") 50.8 mm Compact Tension specimens for the L-T and T-L directions.
The results of these tests are listed in Table 6.
Example 6
[0042] An aluminum alloy consisting of, in weight percent, 2.86 Cu-1.28 Li-.3 Mn.-0.1 Zr,
the balance aluminum and impurities, was cast into an ingot with a cross section of
(16") 406.4 mm and (45") 1143 mm wide. The ingot was homogenized at (950°F) 510°C
for 36 hours, then hot worked to (4") 101.6 mm thick plate. The plate was then solution
heat treated in a heat treating furnace at a temperature of (990°F) .532°C for 2 hours
and then quenched in water. The plate was then stretched by 6% in the longitudinal
direction at room temperature. For artificial aging, the stretched samples were aged
in an oven at (320°F) 160°C for 24 hours. Tensile properties were determined at the
T/4 plane in accordance with ASTM B-557. Tensile tests in the longitudinal direction
and the long transverse direction used round tensile specimens with (.5") 12.7 mm
diameter and 1" 25.4 mm gauge length. Tensile tests in the short transverse direction
were conducted with round tensile specimens with (.160") 4.1 mm diameter and (.5")
12.7 mm gauge length. Fracture toughness was determined at THE T/4 plane by ASTM standard
practice E266 using W=(1.5") 38.1 mm. Compact Tension specimens for the short longitudinal
(S-L) direction and W=(2") 50.8 mm Compact Tension specimens for the L-T and the T-L
directions. The results of these tests are listed in Table 7.
Example 7
[0043] An aluminum alloy consisting of, in weight percent, 2.73 Cu-1.28 Li-.3 Mn.-0.1 Zr,
the balance aluminum and impurities, was cast into an ingot with a cross section of
(16") 406.4 mm and 45" 1143 mm wide. The ingot was homogenized at 950°F 510°C. for
36 hours, then hot worked to (4") 101.6 mm thick plate. The plate was then solution
heat treated in a heat treating furnace at a temperature of (990°F) 532°C for 2 hours
and then quenched in water. The plate was then stretched by 6% in the longitudinal
direction at room temperature. For artificial aging, the stretched samples were aged
in an oven at (320°F) 160°C for 24 hours. Tensile properties were determined at the
T/4 plane in accordance with ASTM B-557. Tensile tests in the longitudinal direction
and the long transverse direction used round tensile specimens with (.5") 12.7 mm
diameter and 1" 25.4 mm gauge length. Tensile tests in the short transverse direction
were conducted with round tensile specimens with .160" (4.1 mm) diameter and (.5")
12.7 mm gauge length. Fracture toughness was determined at the T/4 plane by ASTM standard
practice E266 using W=(1.5") 38.1 mm Compact Tension specimens for the short longitudinal
(s-L) direction and W=(2") 50.8 mm Compact Tension specimens for the L-T and the T-L
directions. The results of these tests are listed in Table 8.
Example 8
[0044] An aluminum alloy consisting of, in weight percent, 2.83 Cu-1.26 Li-.32 Mn.-0.11
Zr, the balance aluminum and impurities, was cast into an ingot with a cross section
of (16") 406.4 mm and (45") 1143 mm wide. The ingot was homogenized at (950°F) 510°C
for 36 hours, then hot worked to (4") 101.6 mm thick plate. The plate was then solution
heat treated in a heat treating furnace at a temperature of (990°F) 532°C for 2 hours
and then quenched in water. The plate was then stretched by 6% in the longitudinal
direction at room temperature. For artificial aging, the stretched samples were aged
in an oven at (320°F) 160°C for 24 hours. Tensile properties were determined at the
T/4 plane in accordance with ASTM B-557. Tensile tests in the longitudinal direction
and the long transverse direction used round tensile specimens with (.5") 12.7 mm
diameter and(1") .25.4 mm gauge length. Tensile tests in the short transverse direction
were conducted with round tensile specimens with (.160") 4.1 mm diameter and (.5")
12.7 mm gauge length. Fracture toughness was determined at the T/4 plane by ASTM standard
practice E266 using W=(1.5") 38.1 mm Compact Tension specimens for the short longitudinal
(S-L) direction and W=(2") .050.8 mm Compact Tension specimens for the L-T and the
T-L directions. The results of these tests are listed in Table 9.
[0045] The advantage of the present invention is shown in Figure 1 which correlates the
fracture toughness values in Tables 2-9 in the S-L direction with tensile yield strengths
in the S-T direction. As is evident from Figure 1, no compromise is made in the tensile
yield strengths between the prior art examples and the examples of the invention.
More specifically, the prior art tensile yield strength values range from just above
372.3 MPa. 54 KSI to almost 413.7 MPa (60 KSI). In comparison, the tensile yield strengths
of the examples according to the invention range from just below 55 KSI to just above
393 MPa. (57 KSI). Figure 1 demonstrates that the articles made of the present invention
provide significantly improved fracture toughness in the S-L direction while maintaining
acceptable strength levels in the S-T direction.
[0046] Figure 2 illustrates the unexpected improvements in fracture toughness in the S-L
direction over the prior art. The values depicted in Figure 2 demonstrate that the
fracture toughness in the S-L direction for Examples 5-8 is vastly superior to that
shown for Examples 1-4. This improvement, which relates to lithium content, is quite
unexpected in view of the prior art.
[0047] Figure 3 emphasizes the fact that the improvements in fracture toughness are related
to the lithium content of the alloys. Figure 3 demonstrates that the fracture toughness
does not vary widely with respect to copper content. For Examples 5-8, the fracture
toughness appears to remain relatively the same with increasing or decreasing amounts
of copper. Similarly, the fracture toughness of Examples 1-4 does not vary widely
with increasing or decreasing copper content.
[0048] Referring again to Figure 2, it is believed that the lithium content can be as low
as 0.8 weight percent while still giving improvements in fracture toughness and maintaining
the acceptable strength in the short transverse direction. It is further believed
that the same results are obtainable when practicing the inventive processing in accordance
with the broad processing variable ranges disclosed above.
[0049] Accordingly, an invention has been disclosed in terms of preferred embodiments thereof
which fulfill each and every one of the objects of the present invention as set forth
above and provides a new and improved method for improving the short longitudinal
direction fracture toughness of aluminum-lithium alloys.
1. An aluminum-lithium alloy article obtainable by
the process steps of casting, homogenizing, hot working, solution heat treating, quenching,
cold working and aging an aluminum alloy consisting of
1.2 to less than 1.3% by weight lithium,
2.7 - 3.0% by weight copper,
0.30 - 0.32% by weight manganese,
up to 0.35% by weight magnesium,
0.04 - 0.18% by weight zirconium,
below 0.05% zinc and
grain refiners selected from the group consisting of
up to 0.2% by weight titanium, up to 0.2% by weight boron, up to 0.2% by weight vanadium,
up to 0.2% weight hafnium, up to 0.5% by weight scandium, up to 0.3% by weight chromium,
the balance aluminum and inevitable impurities.
2. The aluminum alloy article according to claim 1, wherein the homogenization and solution
heat treating is performed at temperatures of 499°C to 554°C (930 to 1030°F).
3. The aluminum alloy article according to one of the preceding claims, wherein the cold
working is stretching between 4 and 8% and the aging temperature is 149°C to 177°C
(300 to 350°F).
4. The aluminum alloy article according to one of the preceding claims, wherein the fracture
toughness in the short longitudinal direction (S-L) is at least by 68.5% of the fracture
toughness in the long traverse direction (T-L).
5. The aluminum alloy article according to one of the preceding claims, wherein the magnesium
is up to 0.25% by weight.
6. The aluminum alloy article according to one of the preceding claims, wherein the fracture
toughness is at least 23.1 MPa
(21.0 KSI
) in the short longitudinal direction (S-L).
7. The aluminum alloy article according to claim 6, having a tensile yield strength of
at least 377.14 MPa (54.7 KSI).
8. A method for producing an aluminum-lithium alloy article comprising the steps of
casting, homogenizing, hot working, solution heat treating, quenching, cold working
and aging an aluminum alloy consisting of
1.2 to less than 1.3% by weight lithium,
2.7 - 3.0% by weight copper,
0.30-0.32% by weight manganese,
up to 0.35% by weight magnesium,
0.04 - 0.18% by weight zirconium,
below 0.05% zinc and
grain refiners selected from the group consisting of
up to 0.2% by weight titanium, up to 0.2% by weight boron, up to 0.2% by weight vanadium,
up to 0.2% weight hafnium, up to 0.5% by weight scandium, up to 0.3% by weight chromium,
the balance aluminum and inevitable impurities.
9. The method according to claim 8, wherein the homogenization and solution heat treating
is performed at temperatures of 499°C to 554°C (930 to 1030°F).
10. The method according to claim 8 or 9, wherein the cold working is stretching between
4 and 8% and the aging temperature is 149°C to 177°C (300 to 350°F).
11. The method according to claims 8 to 10, wherein the magnesium is up to 0.25% by weight.
1. Gegenstand aus Aluminium-Lithium-Legierung, erhältlich durch die Prozeßschritte des
Gießens, Homogenisierens, Warmbehandelns, Warmbehandelns in Lösung, Quenchens, Kaltbehandelns
und Altems einer Aluminium-Legierung, die aus
1.2 bis weniger als 1.3 Gew.% Lithium,
2.7 - 3.0 Gew.% Kupfer,
0.30-0.32 Gew.% Mangan,
bis zu 0.35 Gew.% Magnesium,
0.04 - 0.18 Gew.% Zirkon,
unterhalb 0.05 % Zink und
Kornverfeinerern, die aus der Gruppe bestehend aus
bis zu 0.2 Gew.% Titan , bis zu 0.2 Gew.% Bor, bis zu 0.2 Gew.% Vanadium, bis zu 0.2
Gew.% Hafnium, bis zu 0.5 Gew.% Scandium, bis zu 0.3 Gew.% Chrom besteht, ausgewählt
sind, besteht, wobei der Rest Aluminium und unvermeidbare Verunreinigungen sind.
2. Gegenstand aus Aluminium-Legierung nach Anspruch 1, bei dem die Homogenisierung und
die Warmbehandlung in Lösung bei Temperaturen von 499°C bis 554°C (930 bis 1030°F)
durchgeführt werden.
3. Gegenstand aus Aluminium-Legierung nach einem der vorangehenden Ansprüche, bei dem
die Kaltbehandlung Strecken zwischen 4 und 8 % ist und die Alterungstemperatur 149°C
bis 177°C (300 bis 350°F) beträgt.
4. Gegenstand aus Aluminium-Legierung nach einem der vorangehenden Ansprüche, bei dem
die Bruchfestigkeit in der kurzen Längsrichtung (S-L) wenigstens 68.5 % der Bruchfestigkeit
in der langen Querrichtung (T-L) ist.
5. Gegenstand aus Aluminium-Legierung nach einem der vorangehenden Ansprüche, bei dem
das Magnesium bis zu 0.25 Gew.% beträgt.
6. Gegenstand aus Aluminium-Legierung nach einem der vorangehenden Ansprüche, bei dem
die Bruchhärte in der kurzen Längsrichtung (S-L) wenigstens 23.1 MPa
(21.0 KSI
) beträgt.
7. Gegenstand aus Aluminium-Legierung nach Anspruch 6, mit einer Streckgrenze von wenigstens
377.14 MPa (54.7 KSI).
8. Verfahren zum Herstellen eines Gegenstandes aus Aluminium-Lithium-Legierung, mit den
Schritten des Gießens, Homogenisierens, Warmbehandelns, Warmbehandelns in Lösung,
Quenchens, Kaltbehandelns und Alterns einer Aluminium-Legierung, die aus
1.2. bis weniger als 1.3 Gew.% Lithium,
2.7 - 3.0 Gew.% Kupfer,
0.30 - 0.32 Gew.% Mangan,
bis zu 0.35 Gew.% Magnesium
0.04-0.18 Gew.-% Zirkon,
weniger als 0.05 Gew.% Zink und
Kornverfeinerern, die aus der Gruppe bestehend aus
bis zu 0.2 Gew.% Titan, bis zu 0.2 Gew.% Bor, bis zu 0.2 Gew.% Vanadium, bis zu 0.2
Gew.% Hafnium, bis zu 0.5 Gew.% Scandium, bis zu 0.3 Gew.% Chrom, ausgewählt sind,
besteht, wobei der Rest Aluminium und unvermeidbare Verunreinigungen sind.
9. Verfahren nach Anspruch 8, bei dem die Homogenisierung und die Wärmebehandlung in
Lösung bei Temperaturen von 499°C bis 554°C (930 bis 1030°F) durchgeführt werden.
10. Verfahren nach Anspruch 8 oder 9, bei dem die Kaltbehandlung Strecken zwischen 4 und
8 % ist und die Alterungstemperatur 149°C bis 177°C (300 bis 350°F) beträgt.
11. Verfahren nach den Ansprüchen 8 bis 10, bei dem das Magnesium bis zu 0.25 Gew.% beträgt.
1. Article en alliage d'aluminium-lithium pouvant être obtenu par
les étapes de traitement consistant à couler, homogénéiser, travailler à chaud,
traiter thermiquement en solution, tremper, travailler à froid et vieillir un alliage
d'aluminium constitué de
1,2 à moins de 1,3 % en poids de lithium,
2,7 à 3,0 % en poids de cuivre,
0,30 à 0,32 % en poids de manganèse,
jusqu'à 0,35 % en poids de magnésium,
0,04 à 0,18 % en poids de zirconium,
moins de 0,05 % de zinc et
des agents d'affinage de grain sélectionnés parmi le groupe constitué de
jusqu'à 0,2 % en poids de titane, jusqu'à 0,2 % en poids de bore, jusqu'à 0,2 %
en poids de vanadium, jusqu'à 0,2 % en poids de hafnium, jusqu'à 0,5 % en poids de
scandium, jusqu'à 0,3 % en poids de chrome, le reste étant de l'aluminium et des impuretés
inévitables.
2. Article en alliage d'aluminium selon la revendication 1, dans lequel l'homogénéisation
et le traitement thermique en solution sont effectués à des températures de 499°C
à 554°C (930 à 1030°F).
3. Article en alliage d'aluminium selon l'une quelconque des revendications précédentes,
dans lequel le travail à froid est un étirage entre 4 et 8 % et la température de
vieillissement est de 149°C à 177°C (300 à 350°F).
4. Article en alliage d'aluminium selon l'une quelconque des revendications précédentes,
dans lequel la ténacité à la rupture dans la direction longitudinale courte (S-L)
est égale à au moins 68,5 % de la ténacité à la rupture dans la direction transversale
longue (T-L).
5. Article en alliage d'aluminium selon l'une quelconque des revendications précédentes,
dans lequel le magnésium est présent jusqu'à 0,25 % en poids.
6. Article en alliage d'aluminium selon l'une quelconque des revendications précédentes,
dans lequel la ténacité à la rupture est d'au moins 23,1 MPa
(21,0 KSI
) dans la direction longitudinale courte (S-L).
7. Article en alliage d'aluminium selon la revendication 6, ayant une résistance à la
traction d'au moins 377,14 MPa (54,7 KSI).
8. Procédé pour produire un article en alliage d'aluminium-lithium, comportant les étapes
consistant à :
couler, homogénéiser, travailler à chaud, traiter thermiquement en solution, tremper,
travailler à froid et vieillir un alliage d'aluminium constitué de
1,2 à moins de 1,3 % en poids de lithium,
2,7 à 3,0 % en poids de cuivre
0,30 à 0,32 % en poids de manganèse,
jusqu'à 0,35 % en poids de magnésium,
0,04 à 0,18 % en poids de zirconium,
moins de 0,05 % de zinc et
des agents d'affinage de grain sélectionnés parmi le groupe constitué de
jusqu'à 0,2 % en poids de titane, jusqu'à 0,2 % en poids de bore, jusqu'à 0,2 %
en poids de vanadium, jusqu'à 0,2 % en poids de hafnium, jusqu'à 0,5 % en poids de
scandium, jusqu'à 0,3 % en poids de chrome, le reste étant de l'aluminium et des impuretés
inévitables.
9. Procédé selon la revendication 8, dans lequel l'homogénéisation et le traitement thermique
en solution sont effectués à des températures de 499°C à 554°C (930 à 1030°F).
10. Procédé selon la revendication 8 ou 9, dans lequel le travail à froid est un étirage
entre 4 et 8 % et la température de vieillissement est de 149°C à 177°C (300 à 350°F).
11. Procédé selon les revendications 8 à 10, dans lequel le magnésium est présent jusqu'à
0,25 % en poids.