Multi-material molding is a process in which two or more materials are added to a mold in order to produce multi-material objects; that is objects consisting of sections of differing material composition. Multi-material molding is becoming increasingly popular in the molding industry due to the functional and economical advantages of multi-material components over traditional single material components. For example, some advantages of multi-material molding include being able to produce components with a skin/core arrangement, and the ability to selectively control the relative motion between the differing material sections in molded components.

There are several individual manufacturing processes which can all be classified under the broad range of multi-material molding. These processes, such as co-injection, sandwich, and multi-shot molding all rely on different principles and produce different types of multi-material components. These processes can all be further sub-classified depending on the relation of the finished component to the mold or molds used to produce it. For example, co-injection components are all formed using a single mold, whereas multi-shot molding can use several different molds to produce a single component. The selection of an optimal process for a given component design is a complex function of part geometry, size, material selection, and other factors.

These new molding technologies require many new part and mold design considerations not applicable to traditional single material molding. An overview can be found in [Gup04], while [Li04] and [Kum02] outline algorithms for automated design and manufacture of such multi-material objects. To further aid this process, two independent yet complementary models for comparing traditional injection molding and assembly operations with bi-material rotary platen multi-shot injection molding can be utilized. The first model uses a cost-based metric for evaluation and comparison whereas the second model uses a set of relevant performance aspects as a basis for comparison. The models can account for every structural aspect of single-material (SM) and multi-material (MM) injection molding of several real-world products and their associated molds. An example of one such product is the Dewalt (Black & Decker) saw housing shown below in Figure 1.

Although multi-material molding was initially rare and mostly limited to the automotive industry, recently, multi-material molding technologies are expanding their applicability to consumer products, electrical devices, medical equipment, leisure items and packaging components. As the demand for multi-material components increases, these technologies will continue to expand and improve in order to more efficiently and economically meet this need.

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