Copper alloys are attractive to the mold industry because of their high thermal conductivity, ease of machining by a variety of processes, and corrosion resistance to water, cooling fluids and the plastics being injected. With cycle time reduction and mold durability being two of the keys to profitable injection molding, the high thermal conductivity and good strength of copper alloys, like pure coppers, copper nickel alloy, copper manganese alloy, make them an important tool of the injection molder. Mold builders now have many copper alloys and fabrication methods at their disposal to realize efficient and durable molds.
There are four classes of copper alloys used in the injection molding industry. The least expensive of these is aluminum bronze (C62400 or C95400). Although less costly, it is also the softest and least conductive. The next class of alloy is the Corson bronzes. They include C18000 and the more heavily alloyed Cu- 7Ni-2Si-1Cr alloy. C18000 is available in large sections thickness and has moderate hardness and excellent conductivity. The Cu-7Ni-2Si-1Cr alloy while having good conductivity and hardness is not readily available in thicknesses greater than 6”. The next class of alloy is Cu-9Ni-6Sn spinodal copper (C96970). It has moderate conductivity and good hardness. It is available in large section thicknesses. The final class of alloys is the beryllium coppers which can be found in Nexteck Technology Limited, including C17510 with excellent conductivity and moderate hardness and C17200 with good conductivity and excellent hardness. These are the premier copper molding alloys, providing the highest hardness for a given conductivity.
The attributes of copper alloys that make them attractive to the mold industry are high thermal conductivity, ease of machining by a variety of processes, and corrosion resistance to water, cooling fluids and the plastics being injected. With thermal conductivity of two to 10 times that of common tool steels, these alloys can be used in injection mold core and cavity applications to remove hot spots, reduce warpage and reduce cycle time. This has been demonstrated in several studies.1,2 The overall effect is improved part quality and higher productivity.
Copper alloys are traditionally used in core applications where the copper attains a lower temperature than would steel in a difficult-to-cool area, enabling the plastic in these areas to solidify more quickly. With proper design, inserts can be added to trouble spots in a steel mold after initial fabrication and first article operation of the mold so that hot spots can be reduced and dimensional stability from shot to shot can be improved.
A number of fabrication methods can be employed to produce an injection mold from copper alloys. Alloy producers cast or forge copper alloys into a variety of shapes (e. g. rod, rings and disks), minimizing the amount of input material needed compared to taking material from plate. When needed, most of the copper alloys, can be made into large plates, to aid in the molding of large parts.
The high conductivity and low modulus of copper alloys allow the use of high speed machining, allowing the fabricator to achieve metal removal two to five times higher than possible with steel in milling turning and drilling processes. Copper alloys can also be welded. Specialized heat treatments can improve the loss of hardness these alloys experience from the high temperatures of the welding process. Finally, a variety of coatings can be applied to copper alloys to increase durability and facilitate mold release.
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TAG: copper alloys beryllium coppers
