The present invention pertains to welding, brazing or soldering dissimilar metals, and, more particularly, it pertains to joining copper tubes to aluminum tubes.
It is known that various difficulties are encountered when it is desired to produce a metallurgical bond between copper and aluminum. One difficulty is that the melting point of aluminum is 933.5 K and the melting point of copper is 1356.6 K. Another difficulty is that the oxide layer on aluminum is difficult to remove, making it difficult to bring any brazing or soldering composition into direct metal to metal contact with the aluminum. The high thermal conductivity of both aluminum and copper makes it difficult to provide localized heat to the juncture between aluminum and copper.
A further difficulty is that an aluminum copper junction tends to form precipitated particles of intermetallaic aluminum-copper compounds. These intermetallics are brittle, and tend to produce a brittle joint. U.S. Pat. No. 4,224,499: Laser Welding Aluminum to Copper teaches an interesting approach to eliminating intermetallics. An aluminum conductor and a copper conductor are pressed together with a predetermined contact pressure. A brief laser pulse is directed at the juncture of the aluminum and copper. The laser causes melting of the aluminum and copper, and the pressure causes most of the molten material to be ejected. Intermetallic Al—Cu compounds are found in the ejected material, but the joint between aluminum and copper, although it is a fused connection, is generally free of intermetallics.
U.S. Pat. No. 5,549,335: Solderless Metallurgical Joint teaches joining an aluminum tube to a copper tube. An end portion of the copper tube is swaged and tapered to fit inside the end of the aluminum tube, and an end portion of the aluminum tube may be flared to receive the copper tube. Induction heating is applied to bring least one of the tubes to a temperature above the eutectic temperature of aluminum and copper. The two tubes are then forced together with a predetermined force. The result is a metallurgical bond comprising a layer of the aluminum-copper eutectic between the aluminum and the copper.
U.S. Pat. No. 5,338,072: Gastight Connection between Tubes of Small Diameter teaches joining an aluminum tube to a copper tube. In this case, the aluminum tube fits inside the copper tube. The steps of fluxing and soldering are used to obtain a metallurgical bond. This patent teaches the option of employing a sleeve of high melting point metal such as steel between the copper and the aluminum. This patent speaks of the difficulty of making such connections in the field. In particular, the difficulty of preventing an internal bead that would impede fluid flow is cited.
U.S. Pat. No. 6,149,049: Metallurgical Bonding of Dissimilar Metal Tubes teaches the use of a connecting member comprised of concentric metallurgically bonded tubes. In particular, it teaches a method for joining a copper tube to a titanium tube. A connecting member comprising metallurgically bonded concentric copper and titanium portions is placed between the two tubes. The titanium portion of the connecting member is welded to the titanium tube and the copper portion of the connecting member is soldered to the copper tube.
Various other patents describe explosive bonding of sheets of dissimilar metals. In particular, U.S. Pat. No. 4,925,084: Method of Explosion Welding of Alloy Aluminum teaches a method for bonding magnesium-alloyed aluminum sheets to sheets of high strength materials. The patent teaches limiting the pressures produced by the explosion to prevent magnesium in the aluminum from vaporizing.
Other patents teaching explosive bonding include U.S. Pat. No. 4,756,464, U.S. Pat. Nos. 4,747,350, and 3,137,937. Furthermore the teachings of the patents cited above are hereby incorporated into the present patent application by reference thereto.
The principal objective of the present invention is to provide for leak proof seals between tubing comprised of dissimilar metals.
It is a further objective of the present invention to provide a simple and reliable method for joining tubes of dissimilar metals “in the field” at the customer's site. Although, in the factory, such joints could have been made mechanically, brazed, soldered or explosively-bonded, in the field the repair procedure must be:
In particular, it is difficult to obtain a good metallurgical bond between aluminum and copper. Furthermore, a direct metallurgical bond between aluminum and copper is subject to deterioration with time because diffusion at the boundary between the aluminum and the copper may enable the creation of intermetallic compounds of aluminum and copper, which are brittle.
It is, accordingly, an objective of the present invention to provide a bimetallic coupler for joining a tube of a first metal to a tube of a second metal. A first portion of the coupler is comprised of or compatible with the first metal and a second portion of the coupler is comprised of or compatible with the second metal.
It is another objective of the present invention to provide a coupler for joining two metallurgically incompatible metals.
It is yet another objective of the present invention to provide a coupler which may be employed in the field to join tubing comprised of two metallurgically incompatible metals.
It is an additional objective of the present invention to provide a coupler for joining dissimilar metal tubes wherein the joining processes can be performed without inadvertently obstructing the tubes by brazing, soldering or welding materials.
A further objective of the present invention is to provide a coupler for joining a first tube comprised of a first metal to a second tube comprised of a second metal, the first metal and the second metal being metallurgically incompatible. The coupler has first and second portions for connection to the first and second tubes, respectively, and it has a third portion comprised of a third metal disposed between the first portion and the second portion, the third portion acting as a diffusion barrier between the first metal and the second metal.
In one aspect, the present invention is a method of joining a first tube comprised of a first metal to a second tube comprised of a second metal. The method includes metallurgically bonding a first plate or sheet comprised of the first metal or a metal metallurgically compatible with the first metal to a second plate or sheet comprised of the second metal or a metal metallurgically compatible with the second metal to make a laminated plate or sheet comprising a first layer of the first metal or a metal similar to the first metal metallurgically bonded to a second layer of the second metal or a metal similar to the second metal. The first layer is drilled to form a first clearance hole for the first tube, and the second layer is drilled to form a second clearance hole for the second tube, the second clearance hole being substantially coaxial with the first clearance hole, the second clearance hole communicating with the first clearance hole. The laminated plate or sheet is cut or milled to excise a coupler for joining the first tube to the second tube, the coupler including the first clearance hole and the second clearance hole. The first tube is then inserted into the first clearance hole, where it is soldered, brazed or welded, and the second tube is inserted into the second clearance hole, where it is soldered, brazed or welded.
In another aspect, the present invention is a method of joining a first tube comprised of a first metal to a second tube comprised of a second metal, the first metal and the second metal being metallurgically incompatible. The method includes obtaining a first plate or sheet comprised of the first metal or a metal metallurgically compatible with the first metal, obtaining a second plate or sheet comprised of the second metal or a metal metallurgically compatible with the second metal, and obtaining a third plate or sheet comprised of a third metal, the third metal being metallurgically compatible with the first metal and the third metal being metallurgically compatible with the second metal. The third plate or sheet is placed between the first plate or sheet and the second plate or sheet. The third plate or sheet is then metallurgically bonded to the first plate or sheet and to the second plate or sheet to make a laminated plate or sheet having a first layer comprised of the first metal or a metal similar to the first metal, a second layer comprised of the second metal or a metal similar to the second metal, and a third layer comprised of the third metal, the third layer being interposed between the first layer and the second layer. The method further includes drilling the first layer to form a first clearance hole for the first tube and drilling the second layer to form a second clearance hole for the second tube, the second clearance hole being substantially coaxial with the first clearance hole, the second clearance hole communicating with the first clearance hole. The method further includes cutting or milling the laminated plate or sheet to excise a coupler for joining the first tube to the second tube, the coupler including the first clearance hole and the second clearance hole. The first tube is then inserted into the first clearance hole and soldered, brazed or welded to the coupler, and the second tube is inserted into the second clearance hole and soldered, brazed or welded to the coupler.
In an additional aspect, the present invention is a coupler for joining a first tube of a first metal to a second tube of a second metal, the first metal being dissimilar to the second metal. The coupler includes a first coupler portion comprised of the first metal or a metal compatible with the first metal and a second coupler portion comprised of the second metal or a metal compatible with the second metal. The first coupler portion is metallurgically bonded to the second coupler portion. A first clearance hole for the first tube is disposed in the first coupler portion and a second clearance hole for the second tube is disposed in the second coupler portion, the second clearance hole communicating with the first clearance hole. The end user may then solder, braze or weld the first tube into the first clearance hole and solder, braze or weld the second tube into the second clearance hole, so that a leak proof connection is provided between the first tube and the second tube.
In yet another aspect, the present invention is a coupler for joining a first tube of a first metal to a second tube of a second metal, the first metal being metallurgically incompatible with the second metal. The coupler includes a first coupler portion comprised of the first metal or a metal similar to the first metal, a second coupler portion comprised of the second metal or a metal similar to the second metal, and a third coupler portion comprised of a third metal; the third metal being metallurgically compatible with the first metal and the third metal being metallurgically compatible with the second metal, the third coupler portion being interposed between the first coupler portion and the second coupler portion. The first coupler portion is metallurgically bonded to the third coupler portion and the second coupler portion is metallurgically bonded to the third coupler portion. A first clearance hole for the first tube is in the first coupler portion and a second clearance hole for the second tube is in the second coupler portion, the second clearance hole communicating with the first clearance hole through the third coupler portion. The end user may then solder, braze or weld the first tube into the first clearance hole and solder, braze or weld the second tube into the second clearance hole, so that a leak proof connection is provided between the first tube and the second tube.
Coupler 40, preferably, is excised out of the laminated plate or sheet 20 after the alignment hole 52, the first clearance hole 43 and the second clearance hole 48 are drilled. Coupler 40 may be then employed to facilitate or enable the joining of first tube 42 comprised of the first metal to the second tube 47 comprised of the second metal. In particular, coupler 40 may be employed in the field, i.e. at a customer's location. Preferably, coupler 40 is excised out of the laminated plate or sheet 20 by a hole saw or a trepanning tool.
In like manner, the diameter of second clearance hole 48 should be sufficiently great that the liquid solder or brazing material will be drawn into the space between second tube 47 and second clearance hole 48 by capillarity. Also, the diameter of clearance hole 48 should be small enough that the liquid solder or brazing material will not tend to form a bead inside of tube 47 or inside alignment hole 52; being held in the space between second tube 47 and second clearance hole 48 by capillarity.
In a presently preferred embodiment for this configuration, the first metal is aluminum or an aluminum alloy and the second metal is titanium or a titanium alloy.
Coupler 60, preferably, is excised out of the laminated plate or sheet 30 after the alignment hole 52, the first clearance hole 43 and the second clearance hole 48 are drilled. Coupler 60 may be then employed to facilitate or enable the joining of first tube 42 comprised of the first metal to the second tube 47 comprised of the second metal. In particular, coupler 60 may be employed in the field, i.e. at a customer's location. Preferably, coupler 60 is excised out of the laminated plate or sheet 20 by a hole saw or a trepanning tool.
In like manner, the diameter of second clearance hole 48 should be sufficiently great that the liquid solder or brazing material will be drawn into the space between second tube 47 and second clearance hole 48 by capillarity. Also, the diameter of second clearance hole 48 should be small enough that the liquid solder or brazing material will not tend to form a bead inside of tube 47 or inside alignment hole 52; being held in the space between second tube 42 and second clearance hole 48 by capillarity.
In the presently preferred embodiment for this configuration, the first tube is aluminum or an aluminum alloy, the second metal is copper or a copper alloy, and the third metal is titanium or a titanium alloy.
It is noted that the detailed description of the presently preferred embodiments of the invention presented above is to be considered as illustrative and not restrictive and that the invention may be otherwise embodied within the scope of the appended claims.