High-strength aluminum alloy clad material for heat...

Details High-strength aluminum alloy clad material for heat... High-strength aluminum alloy clad material for heat...

2000-10-31

2002-03-26

Koehler, Robert R. (Department: 1775)

Stock material or miscellaneous articles

All metal or with adjacent metals

Composite; i.e., plural, adjacent, spatially distinct metal...

C165S180000, C428S686000, C428S933000

Reexamination Certificate

active

06361882

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relate s to a high-strength aluminum alloy clad material for heat exchangers exhibiting excellent corrosion resistance. In particular, the present invention relates to a high-strength aluminum alloy clad material for heat exchangers exhibiting excellent corrosion resistance which is used as a constituent material for a working fluid passage of a heat exchanger joined by brazing, such as an evaporator for an automotive air conditioner or a radiator, and has particularly excellent corrosion resistance and excellent formability before brazing, and high strength after brazing.
2. Description of Background Art
Heat exchangers made of an aluminum alloy have been widely used as radiators, oil coolers, inter-coolers, heaters, and evaporators for air conditioners for automobiles, and condensers and oil coolers for hydraulic devices or industrial machines. Various types of heat exchangers made of an aluminum alloy are known. Among these, a laminated heat exchanger (drawn-cup type heat exchanger) has attracted attention because of its light weight. Such a drawn-cup type heat exchanger is fabricated by forming working fluid passages by laminating formed aluminum alloy clad materials, combining corrugated fins made of an aluminum alloy between the working fluid passages, and integrally brazing these materials.
As shown in
FIGS. 1 and 2
, a drawn-cup type evaporator has press-formed core plates
11
and
12
made of aluminum alloy clad materials and a corrugated fin
13
made of an aluminum alloy laminated thereon. The core plates
11
and
12
and the fin
13
are brazed by melting a brazing material in the core plates
11
and
12
, thereby forming a passage
14
for a working fluid such as a refrigerant between the core plates
11
and
12
.
As the core plates
11
and
12
, aluminum alloy clad materials having a core material and a brazing material are used. The core material is formed of an aluminum alloy containing Mn such as an Al—Mn alloy, Al—Mn—Cu alloy, Al—Mn—Mg alloy, or Al—Mn—Cu—Mg alloy (JIS A3003 alloy, JIS A3005 alloy, etc.). The brazing material is formed of an Al—Si alloy such as an Al—Si alloy, Al—Si—Mg alloy, Al—Si—Mg—Bi alloy, Al—Si—Mg—Be alloy, Al—Si—Bi alloy, Al—Si—Be alloy, or Al—Si—Bi—Be alloy. Either one or both sides of the core material is clad with the brazing material.
An aluminum alloy containing an Al—Mn alloy to which Cu, Mg, Zn, Sn, In, and the like are added is used as the fin
13
. The fin
13
and the core plates
11
and
12
are usually brazed by vacuum brazing. Moreover, flux brazing using chloride flux or fluoride flux is also used.
In recent years, reduction of the weight and manufacturing cost of heat exchangers has been strongly demanded. To deal with this demand, it is necessary to further decrease the thickness of the constituent materials of heat exchangers, such as those for a working fluid passage. However, when the strength of aluminum alloy clad materials used to form a working fluid passage is increased in order to decrease the thickness, formability is impaired due to the decreased amount of elongation. Moreover, corrosion resistance decreases, thereby causing the fabricability and durability of the heat exchangers to decrease. Therefore, development of clad materials exhibiting improved elongation (formability), strength after brazing, and corrosion resistance has been demanded.
Aluminum alloy clad materials used as the core plates
11
and
12
of the drawn-cup type evaporator
10
have a core material made of an aluminum alloy containing Mn. Therefore, these materials exhibit inferior pitting-corrosion resistance. For example, when applied to a working fluid passage for a refrigerant, perforation leakage may occur due to pitting.
Pitting-corrosion resistance of working fluid passage materials may be improved by using materials for which the potential is lower than that of the working fluid passage materials, such as an Al—M—Zn alloy, Al—M—Sn alloy, or Al—M—In alloy as the fin
13
. The sacrificial anode effect of the fin
13
made of these materials provides the working fluid passage materials with corrosion resistance. However, occurrence of pitting-corrosion in the working fluid passage material can be prevented only in the area near the fin
13
. Occurrence of pitting-corrosion in the working fluid passage material is inevitable in the area apart from the fin
13
because the sacrificial anode effect of the fin
13
is not obtained.
The following materials are proposed as aluminum alloy clad materials for working fluid passages exhibiting improved corrosion resistance: (1) a clad material in which Cu, Ti, Cr, or Zr is added to the core material thereof (Japanese Patent Publication 41621/1994, Japanese Patent Application Laid-open No. 241133/1988, Japanese Patent Application Laid-open No. 83396/1989, and Japanese Patent Application Laid-open No. 258945/1990); (2) a clad material in which the content of Fe, which forms a compound functioning as a cathode and decreases corrosion resistance in the core material, is limited to 0.2% or less (Japanese Patent Application Laid-open No.83396/1989); and (3) a clad material exhibiting improved intergranular corrosion resistance in which the Fe content and the Si content in the core material are limited (Japanese Patent Publication 41621/1994 and Japanese Patent Application Laid-open No. 241133/1988). Although these aluminum alloy clad materials exhibit improved corrosion resistance, these materials cannot fully satisfy the demand for improved formability and strength after brazing.
In order to obtain an aluminum alloy clad material which can solve the above problems in conventional working fluid passage materials and satisfy the demand for reduced thickness, the present inventors have conducted extensive experiments and studies on the composition of the core material, the composition of the brazing material used to clad both sides of the core material, and the effects of the combination of these materials on formability, strength after brazing, brazability, and corrosion resistance. Accordingly, an object of the present invention is to provide a high-strength aluminum alloy clad material for heat exchangers which has excellent corrosion resistance and superior formability before brazing, is easily brazed, and has improved strength after brazing.
SUMMARY OF THE INVENTION
In order to achieve the above object, the present invention provides the following high-strength aluminum alloy clad materials for heat exchangers exhibiting excellent corrosion resistance.
(1) A high-strength aluminum alloy clad material for heat exchangers exhibiting excellent corrosion resistance comprising a core material and a brazing material, with either one or both sides of the core material clad with the brazing material, wherein the core material comprises an aluminum alloy comprising from 0.3% to less than 0.6% of Mn, from more than 0.6% to 1.0% of Cu, less than 0.1% of Si, 0.3% or less of Fe, and from 0.06% to 0.35% of Ti, with the remainder consisting of Al and impurities; and the brazing material used to clad either one or both sides of the core material comprises an Al—Si aluminum alloy in which the Ca content is limited to 0.006% or less.
(2) A high-strength aluminum alloy clad material for heat exchangers exhibiting excellent corrosion resistance comprising a core material and a brazing material, with either one or both sides of the core material clad with the brazing material, wherein the core material comprises an aluminum alloy comprising from 0.3% to less than 0.6% of Mn, from more than 0.7% to 1.0% of Cu, less than 0.1% of Si, 0.3% or less of Fe, and from 0.06% to 0.35% of Ti, with the remainder consisting of Al and impurities; and the brazing material used to clad either one or both sides of the core material comprises an Al—Si aluminum alloy in which the Ca content is limited to 0.006% or less.
(3) A high-strength aluminum alloy clad material for heat exchangers exhibiting excellent corrosion resistance comprising a core material

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