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Int J Adv Manuf Technol (2006) 30: 10491075 DOI 10.1007/s00170-005-0152-4 ORIGINAL ARTICLE Regina M. Gouker . Satyandra K. Gupta . Hugh A. Bruck . Tobias Holzschuh Manufacturing of multi-material compliant mechanisms using multi-material molding Received: 12 January 2005 / Accepted: 22 April 2005 / Published online: 22 February 2006 # Springer-Verlag London Limited 2006 Abstract Multi-material compliant mechanisms enable many new design possibilities. Significant progress has been made in the area of design and analysis of multi- material compliant mechanisms. What is now needed is a methodtomass-producesuchmechanismseconomically.A feasibleandpracticalwayofproducingsuchmechanismsis through multi-material molding. Devices based on compli- ant mechanisms usually consist of compliant joints. Com- pliant joints in turn are created by carefully engineering interfaces between a compliant and a rigid material. This paper presents an overview of multi-material molding technologyanddescribesfeasiblemolddesignsforcreating different types of compliant joints found in multi-material compliant mechanisms. It also describes guidelines essen- tialtosuccessfullyutilizingthemulti-material moldingpro- cess for creating compliant mechanisms. Finally, practical applications for the use of multi-material molding to create compliant mechanisms are demonstrated. Keywords Compliant mechanisms . Compliant joints . Multi-material molding . Mold design 1 Introduction Synthetic and natural structures have several distinct differences. Perhaps the greatest difference between these two types of structures is the use of compliance. Compli- ance, in relation to structures and mechanisms, is the ability or process of elastically deforming in response to changes in force without disruption of structure or function. It has been well recognized that man-made objects are primarily made up of relatively rigid materials, while natural objects are made with soft compliant materials, using rigid materials such as bones and teeth only in select places 19. It has been suggested that this distinct difference occurs from the assembly and production methods for each of the products. The fundamental requirement for natural structures is the absence of assembly. The entire system must be grown from a source or cell as a single entity 1. An example of the type of unique performance that can be achieved through the use of compliance in natural structures is the flapping of bird wings to achieve flight (Fig. 1). It has been shown that birds are designed with an integrated flexibility topromote draftand lift,causedbythe air, to rotate the wings throughout the cyclic process 19. This enables the bird to achieve much higher cyclic flapping rates at lower energy consumption. A common misconception is that an object has to be rigid to be strong 19. However, nature shows us that objects can be strong and compliant. Throughout human existence, nature has proven to be a fertile source for inspiration. Until recent years, many of these ideas could never be fully understood and reconstructed. With an improved understanding of the structure-property-function relationship in biological materials and systems and the invention of new materials and manufacturing techniques, bio-inspired designs are rapidly increasing in popularity 6. In a step towards bio-inspired design, the behavior of compliant mechanismshas beenstudied inorder to develop design rules for realizing actual mechanisms. A compliant mechanism is a flexible structure that elastically deforms to produce desired force or displacement. Similar to rigid mechanisms, compliant mechanisms will still transfer or transform motion, force, or energy, but they will also store strain energy in the flexible members as well 9. Com- pliant mechanisms mainly consist of rigid objects or features with added compliant or soft materials at strategic locations. There are several different types of compliant mechanisms currently being researched and developed. Some of the mechanisms developed include bistable mechanisms, orthoplanar flat spring, centrifugal clutches, overrunning pawl clutches, near-constant-force compres- sion mechanisms, near-constant-force electrical connec- R. M. Gouker . S. K. Gupta (*) . H. A. Bruck . T. Holzschuh Mechanical Engineering Department, University of Maryland, College Park, MD 20742, USA e-mail: skguptaeng.umd.edu tors, bicycle brakes, bicycle derailleur, compliant grippers, and microelectromechanical systems 9. Compliant designs have many advantages over tradi- tional designs that employ articulated joints. Included in these advantages is the reduction of wear between joint members, reduction in backlash, and high potential energy stored in deflected members 10. In addition, absence of assembly in production methods, reduction of weight, and part count found in compliant mechanisms all lead to the reduction of cost to manufacture the product. Several studies have indicated that assembly costs make up 40 50% of the manufacturing costs to produce a product 1. Part reduction reduces the assembly labor, purchasing, in- specting, warehousing, capitol requirements, and piece part costs of a product 17. Therefore any decrease in part count and manufacturing cost, no matter how minimal, will have a drastic effect on the total cost of the product. The use of multiple different materials in compliant mechanisms opens up the design space considerably. Until recently, a method did not exist to mass-produce multi- material compliant mechanisms. In the past, layered pro- cesses, such as stereolithography, selective laser sintering, shape deposition modeling, and 3D printing were utilized for making multi-material compliant mechanisms 2, 3, 11. While these processes can create intricate and complex geometries as well as material distributions, they are not suitable for mass production in most cases. A more suitable technique that has emerged for the manufacturing of multi- material compliant mechanisms is multi-material molding. Multi-material molding creates a part with one or more materials via a multi-stage mold. Multi-materialcompliantmechanismsareabletoachieve the same performance as homogeneous mechanisms with complex geometries because they employ compliant joints. The compliant joints are created by carefully engineering interfaces between two materials: one that is compliant and onethatisrigid.Thispaperdescribesseveraldifferenttypes ofinterfacesthatcanexistincompliantjoints.Furthermore, this paper presents results from experimental characteriza- tion of these interfaces to show that these interfaces are viable for creating compliant joints with the adequate mo- tion ranges. A detailed description for designing several different compliant joints that can provide from 1 to 3 degrees of freedom motions in mechanisms is outlined. For each joint design, we discuss possible mold design options and present a feasible mold design to realize the joint. Finally, we present two examples of devices consisting of compliant joints. The material presented in this paper will assist readers in designing and experimentally analyzing molded multi- material compliant mechanisms. Furthermore, it will help them in designing molds for manufacturing compliant mechanisms. Weexpectthatthisinturnwillresultinamore widespread use of multi-material compliant mechanisms. 2 Multi-material molding 2.1 Process overview Multi-material molding (MMM) involves molding multi- material assemblies from various polymers including ther- mosets, thermoplastics, and polyurethanes 8, 1315. The general molding process entails introducing the liquid material into a cavity shaped like the desired object, then allowing the liquid to solidify through cooling or chemical reactions. The hardened object can then be removed from the mold, where it may require finishing operations before it is complete. The multi-material molding process is very similar to the standard molding process, except the multi- material process makes use of more than one cavity con- figuration. Examples of some products molded with MMM techniques are shown in Fig. 2. There are many different types of design options for cavity change. Out of these, we have determined that the following three are most relevant for making compliant mechanisms: cavity transfer, removable core, and sliding core methods. The cavity transfer method involves trans- ferring the first stage part into another mold cavity (Fig. 3). This method simplifies mold design and many complex interfaces can easily be created. It also requires the most manipulation between stages. In the removable core method, all that is needed to transfer from one stage to the next is to remove the core (Fig. 4). This type of approach requires little to no manipulation between mold stages but is also very limited in the type of interfaces that can be created. In the sliding core method the total cavity of the part is extracted from the initial mold volume and sliding cores are strategically placed within the mold to restrict or enable flows into certain sections (Fig. 5). This method requires minimal manipulation between mold stages, since the part remains in the same mold cavity throughout the process. It also enables more complex in- terface options, but is more difficult to design because of the need to accommodate the motion of the sliding cores. Multi-material (MM) products possess several benefi- cial qualities over traditionally molded products including: (1) multicolor appearance, (2) skin/core configurations, (3) in-mold assembly, (4) selective compliance, and (5) soft- touch portions. Additionally, it could cost less to produce a Fig. 1 Bird flapping its wings in flight 1050 MM product compared to a similar assembly of multiple components. There are two broad manufacturing technologies com- monly used to make MM objects: injection molding and room temperature molding.Injection molding iscommonly used for large-scale production processes, while room temperature molding is primarily used for small production runs. Injection molding involves injecting molten plastic into a mold where it rapidly solidifies and is then ejected as the desired object 12. Injection molding is ideal for many applications because it is amenable to a variety of poly- meric materials, has a wide range of mold capabilities including complex structuresand is extremely control- lable. Additionally, the parts produced by injection mold- ing have a very low cycle time. Fundamentally, there are three different types of MM injection molding processes. Multi-component molding is the simplest and most com- mon form of MM injection molding. It involves the simultaneous (or sometimes sequential) injection of two different materials through either the same or different gate locations in a single mold. Multi-shot molding (MSM) is the most complex and versatile MM injection molding process. It involves injecting the different materials into the mold in a specified sequence, where the mold cavity geometry may partially or completely change between se- quences. Overmolding and insert molding simply involve molding a resin around a preformed part, either metal (as in insert molding) or a previously made injection molded plastic part (as in overmolding). Each of the three classes of MM injection molding processes is unique and can be distinguished using the taxonomy shown in Fig. 6. Room temperature molding utilizes polymers that are liquids at room temperature. Instead of injecting a hot liquid into the mold and then allowing the plastic to cool into a solid, room temperature molding utilizes reactive compounds that polymerize (i.e., cure) at ambient condi- tions. This involves mixing two compounds, a resin and a hardener, to activate the polymer, then pouring the mixture into the mold. The material then polymerizes in the shape of the cavity. The hardening time will be considerably longer than that of injection molded plastics. Because MM objects have geometric features consisting of differing materials, the molds must be filled in stages. This means that the molds are assembled in an initial configuration and the first material stage is poured. After a specified hard- Fig. 3 Cavity transfer molding method. a Mold for first stage. b Remove part from first stage and insert into second stage. c Pour second material into remaining cavity. d Resulting part Fig. 2 Various examples of compliant injection molded parts. (a) e-slimcase by ejector. (b) crest toothbrush 1051 Fig. 5 Sliding core molding method. a Core position for first stage. b Molded part first stage and core position for second stage. c Molded part for second stage and core position for third stage. d Resulting part Fig. 4 Removable core mold- ing method. (a) Mold with core inserted for first stage. (b) Resulting part from first stage. (c) Remove core and pour sec- ond stage. (d) Resulting part 1052 ening time, the molds are partially disassembled and some mold pieces are added, removed, or replaced with different ones. The second material stage can then be poured. This process is continued until all of the materials have been poured. There are several considerations when designing MM molds for room temperature molding. As mentioned pre- viously, they must be designed to incorporate several molding stages. Within each of these molding stages the molds must be easy and simple to manufacture, containing no undercuts in them. The absence of undercuts and the inclusion of draft angles ensures ease in demolding. Finally, since there will be no pressure exerted on the molds to hold them together the parting surfaces must be designed with pins or grooves so that proper alignment may be obtained. The absence of pressure when pouring the part also has a tendency to permit the existence of air bubbles and air pockets in the mold. The strategic location of air holes can effectively eliminate a majority of these problems. Thus, the biggest difference between MM injection molding and room temperature molding is the properties of the polymers that will be employed in each of the processes. This means that the specific MMM process that is chosen for a particular MM compliant mechanism will depend on the set of material properties that are desired. 2.2 Characteristics governing the MMM process This section discusses some of the characteristics that must be considered for MMM. Interfacial adhesion: The phenomenon of adhesion between two materials is complex, and consequently, it is difficult to predict the nature and exact quality of the resulting interface. In particular, the strength of inter- molecular bonding and mechanical interlocking will control the mechanical properties attributed to ad- hesion, such as interfacial strength and fracture toughness. Adhesion is a characteristic that can be en- gineered in the MMM process using three types of interfaces: Chemical interfaces: Chemical interfaces are formed as a result of the intermolecular bonding (i.e., cross-polymerization) alongthematingsurface between two compatible materials. The extent and strength of the chemical interface will be governed Fig. 7 Example of a chemical interface. a CAD model. b Molded part Fig. 8 Geometrically locked interface. a CAD model. b Molded part Multi-Material Molding Processes Multi-Component Molding Multi-Shot Molding Insert/Over Molding Bi-Injection Molding Skin/Core Molding Interval Molding Rotary Platen Index Plate Core Toggle Co-Injection Molding Sandwich Molding Fig. 6 Multi-material molding process tree 1053 Fig. 9 Two types of physical testing specimens (source: Multishot) Fig. 10 Test specimen geometry Fig. 11 Tensile test with multi- ple interface types 1054 by the curing time and the similarity of the solubility parameters for two polymers 18. Figure 7 shows an example of a typical molded chemical interface. Mechanical interfaces: Mechanical interfaces are formed by geometrically interlocking two incom- patible materials (e.g., polystyrene and polypropyl- ene) together. Additionally, interlocking interfaces can be used to selectively control the relative movement (i.e., degrees of freedom) between the materials. Figure 8 shows a schematic of a bar with a mechanical interface that does not permit any relative movement between the two materials. Combination interfaces: Using compatible materi- als at an interface with geometrically interlocking features allows components to be designed with combined interfaces that exhibit both chemical bonding and interlocking. Previous research shows that combination interfaces performed much better in tensile loading over flat bonded interfaces, which in turn performed much better than non-bonded interlocking interfaces 4. This suggests when interface strength is an important consideration combined interfaces should be used. Rheology: Fortunately, for multi-shot molding and overmolding processes, different materials flow from separate nozzles or into separate sections of the mold, meaning the actual flows never combine. In these cases, the only concern becomes whether the materials will meet along the desired interfaces and form the desired bonds or mechanical locking. This usually results in a series of equivalent standard single material injection molding flow problems that can be solved with any of the widely available mold flow simulators on the market. However, certain MMM process, such as co-injection and sandwich molding, utilize flows that are actually embedded inside of each other. In these cases, flows of multiple materials must be carefully understood in order to produce suitable MM objects. However, these processes are not suitable for making multi-material compliant mechanisms. Hence, from the rheological point of view we can treat MMM process as a sequence of single material flow problems and use established techniques from injection molding area to perform mold flow simulations. Fig. 12 Schematic diagram of the tensile test variables Fig. 13 Graph of 90A tensile test results 1055 3 Design and characterization of molded multi-material interfaces 3.1 Processing variables There are many variables that have an affect, either direct or indirect, on the MMM process. These parameters can be broken down into four main categories: temperature, pressure, time, and distance 5. A key parameter in MMM is the cooling time between molding stages, which affects the degree of cross-polymerization at an interface. Typically, for cross-polymerization to occur the second mold stage must be performed before the material has completely hardened from the first mold stage. However, the material from the first mold stage must be hardened enough so that it can be taken out from the mold. Therefore, the desire to maintain geometrically complex interfacial features directly contradicts the desire to maintain the best cross-polymerization. Due to the sensitivity of the material atthiscriticaltime,itisessentialtolimiteitherthemanualor robotic manipulations required between mold stages when engineering the interface. It is also necessary to design a molding schedule that balances the degree of cross- polymerization with the desire to maintain the geometrically complex interfacial features. 3.2 Interfacial strength characterization To determine the effects of processing variables on the engineered interface, it is necessary to characterize the strength and deformation response of the interface. The in- terfacial strength will determine the critical loads for MM compliant mechanisms. To characterize the interfacial strength, it is necessary to conduct experiments to determine the critical stresses at which the interface begins to debond. For example, a recent study explored the use of complex geometry to enhance interfacial tension strength by con- Fig. 15 Graph of multi-material 90A and 72DC tensile test results Fig. 14 Graph of 72DC tensile test results 1056 Fig. 16 Flat-end connection flexure test Fig. 17 Graph of m
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