초록 ▼

A system for joining a pair of structural members having widely differing coefficients of thermal expansion is disclosed. A mechanically “thick” foil is made by dispersing a refractory metal powder, such as molybdenum, niobium, tantalum, or tungsten into a quantity of a liquid, high expansion metal

A system for joining a pair of structural members having widely differing coefficients of thermal expansion is disclosed. A mechanically “thick” foil is made by dispersing a refractory metal powder, such as molybdenum, niobium, tantalum, or tungsten into a quantity of a liquid, high expansion metal such as copper, silver, or gold, casting an ingot of the mixture, and then cutting sections of the ingot about 1 mm thick to provide the foil member. These foil members are shaped, and assembled between surfaces of structural members for joining, together with a layer of a braze alloy on either side of the foil member capable of wetting both the surfaces of the structural members and the foil. The assembled body is then heated to melt the braze alloy and join the assembled structure. The foil member subsequently absorbs the mechanical strain generated by the differential contraction of the cooling members that results from the difference in the coefficients of thermal expansion of the members.

대표청구항 ▼

1. A braze system for joining structural members having dissimilar coefficients of thermal expansion, comprising: a foil member disposed between opposing surfaces of said structural members, wherein said foil member consisting essentially of: tungsten uniformly distributed throughout a matrix of

1. A braze system for joining structural members having dissimilar coefficients of thermal expansion, comprising: a foil member disposed between opposing surfaces of said structural members, wherein said foil member consisting essentially of: tungsten uniformly distributed throughout a matrix of copper, said tungsten present in an amount equal to about 65% to about 95% by volume of said foil member;generally parallel surfaces, and;a thickness chosen to absorb a quantity of mechanical strain; and a quantity of braze material disposed between each of said surfaces of said foil member and said structural members. 2. The braze system of claim 1, wherein said copper is present in a weight fraction ranging between about 5% to about 10%.3. The braze system of claim 2, wherein said tungsten is uniformly distributed throughout said composite material as a plurality of particles having a size distribution of less than about 40 microns in diameter.4. The braze system of claim 1, wherein said foil member comprises a layer equal to about less than about 1 mm thick.5. An intermediate braze member for joining structures having dissimilar coefficients of thermal expansion, comprising: a foil member consisting essentially of tungsten uniformly distributed throughout a matrix of copper, wherein said tungsten is present in an amount equal to about 65% to about 95% by volume of said foil member, and wherein said foil member has a thickness chosen to absorb a quantity of mechanical strain. 6. The braze system of claim 5, wherein said copper is heated until it is a liquid, and wherein said tungsten is introduced into said liquid copper as a plurality of particles having a size distribution of less than about 40 microns in diameter and uniformly distributed throughout said liquid copper to form the foil member composite material.7. The intermediate braze member of claim 6, wherein said copper is present in a weight fraction ranging between about 5% to about 10%.8. The braze system of claim 5, wherein said foil member comprises a layer about to less than about 1 mm thick.9. A method for brazing structures having dissimilar coefficients of thermal expansion, comprising the steps of: providing a foil member consisting essentially of tungsten uniformly distributed throughout a matrix of copper, wherein said tungsten is present in an amount equal to about 65% to about 95% by volume of said foil member; providing at least first and second mechanical structures to be joined by brazing; providing a braze alloy capable of wetting surfaces of said foil member and said at least first and second structures; sandwiching said foil member between said structures to be brazed such that a portion of said braze alloy is sandwiched between each of said at least first and second structures and a facing surface of said foil member thereby forming a braze assembly; and heating said braze assembly to a first temperature to melt said braze alloy. 10. The method of claim 9, wherein said copper is present in a weight fraction ranging between about 5% to about 10%.11. The method of claim 10, wherein said copper is heated until it is a liquid, and wherein said tungsten is introduced into said liquid copper as a plurality of particles having a size distribution of less than about 40 microns in diameter and uniformly distributed throughout said liquid copper forming thereby the foil member composite material.