Over the past decade, soft-touch overmolding has radically changed the look, feel, and function of a broad range of consumer products. Abundant new color, texture, and tactile options are available in such products as toothbrushes, razors, power tools, cameras, kitchen items, hand-held electronics, and auto-interior parts.
Driving this change is the increasingly diverse range of thermoplastic elastomer (TPE) materials. In overmolding, a TPE is injection molded over or around a compatible substrate using either insert or multi-shot processes. The resulting hard-soft structures are quite effective in comfortable, non-slip, and abrasion-resistant handles, grips, and buttons.
A critical challenge for designers and producers of these parts is poor adhesion of TPE to substrate, which reveals itself in peeling, curling, fraying, or delamination of the material layers. Initially, this was a fairly straightforward issue since the most common approach was to combine an olefin-based TPE with a compatible rigid PP substrate.
In recent years, however, the range of materials used in overmolding has expanded significantly to include more TPE classes (e.g, TPU, TPV, SEBS) and a broader range of substrates (ABS, PC, and nylon). While the broader materials spectrum for overmolding expands opportunities for soft-touch design, it also adds new levels of complexity and poses new challenges in adhesion.
A toolbox of remedies
In insert molding, the rigid substrate is molded first and transferred to a second mold, where a TPE is shot around the insert to create the finished part. The process uses standard injection molding machines and relatively simple, low-cost tools. Insert molding is best suited to applications involving relatively low volumes and manufacturing locations where labor costs are low.
Multi-shot molding requires a special press with multiple barrels that allow several materials to be shot into the same mold. (Most often, such parts use two-shot molding, but some parts require three or four shots.) Benefits are reduced overall production time, superior part quality, and lower labor requirements. The approach is economically viable in programs of 250,000 parts/yr or more and regions where labor costs are high.
In both processes, strength and durability of adhesion between TPE and substrate require compatible hard and soft materials. The type of overmolding method used also affects adhesion performance: Multi-shot molding, by bringing together several melt fronts, generally offers superior adhesion. Adhesion performance is also affected by a number of additional factors:
1) Shut-off design: Design of the transition, or shut-off, area between the TPE and substrate is critical to adhesion. Designs should avoid “feathering,” or gradual thinning of the overmolded TPE. Thin layers cause inadequate bonding and can result in curling or fraying of the TPE layer at the tapered edges (see Fig. 1A).
The best antidote is a shut-off design that creates a sharp transition between TPE and substrate. Ideally, a uniform TPE layer thickness of around 0.04 in. is desirable for good adhesion, but that is not always feasible.
One solution is to incorporate a “step” in the substrate profile to create an abrupt transition between TPE and substrate (Fig. 1B). Alternatively, the substrate might include an indentation, with the shut-off designed to put the TPE flush against the substrate (Fig. 1C). Both approaches reduce feathering, neutralize curling, and eliminate tear points that might initiate fraying.
In a few cases (e.g., parts with exceptionally long flow paths or highly wear-prone areas), features are designed into the substrate to create a mechanical interlock after overmolding with TPE.
2) Vent design: Air entrapment in the cavity during TPE overmolding is also detrimental to adhesion and is best addressed by adequate venting in the tool. Insufficient venting can show up as poor adhesion at the end-of-flow points, scorching of the TPE, or even short shots. Typical vent depths are between 0.0005 and 0.001 in. The right vent depth for a given part depends partly on the flow properties of the TPE involved.
3) Substrate preparation: Proper preparation and handling of inserts is critical to adhesion performance. The cleaner the insert, the better the bond. The optimal production method is to overmold inserts directly after they are produced, since that minimizes chances of contaminants collecting on the insert surface. If storing inserts is unavoidable, they should be scrupulously protected against dust or dirt. Those who handle inserts should wear gloves, since skin oil can impair adhesion. Also, mold releases are best avoided since they seriously impair bond strength between TPE and substrate.
Preheating inserts prior to overmolding often improves adhesion strength. The extent of improvement depends on the degree of compatibility between insert material and TPE. The appropriate insert temperature depends on the substrate and TPE and is best determined through discussions with the materials suppliers.
4) TPE melt temperature: The relationship between temperature of the TPE melt and adhesion strength is reflected in the example of a 65 Shore A TPE overmolded on a PC substrate (Fig. 2). As the melt temperature increases from 370 F to 400 F, a notable improvement in adhesion strength is evident. But a further increase to 430 F actually reduces adhesion strength. In this instance, the optimum melt temperature is somewhat less than 400 F. Molders must balance desired adhesion strength against the possible adverse effects of elevated melt temperature, e.g., thermal degradation and ejection difficulty.
The best way to reach the optimal TPE melt temperature is to approach it gradually, not necessarily by increasing barrel temperature, but via higher screw rpm or injection speed. A problem in determining the actual melt temperature is that it is not always equivalent to injection nozzle temperature. A sensible approach is to use a pyrometer to measure melt temperature of a TPE air shot.
Selecting a target melt temperature for the TPE depends on the substrate and the adhesion level required. Most TPE suppliers provide a recommended range of melt temperatures for their products. For maximum adhesion, aim towards the upper end of the supplier’s recommended range.
5) “Feel” versus thickness: The tactile feel of an overmolded part is the sum of several factors, just one being the inherent softness (Shore A durometer) of the TPE. Part feel also depends on the TPE’s coefficient of friction, texture, and—most notably—wall thickness.
Where the TPE layer is less than 0.060 in. thick, the feel of a soft elastomer can easily be negated by the hardness of the underlying substrate. The degree of cushioning provided by a TPE layer is also greatly influenced by the substrate’s inherent hardness.
Moreover, thickness of the TPE layer also affects adhesion strength. Thin TPE layers tend to surrender heat rapidly in the cold cavity, and the drop in temperature tends to reduce bonding strength. The challenge for the designer is to strike a balance between the durometer and thickness of the TPE to achieve the cushioning level desired.
1) Predrying: Some TPE types—including TPU, TPV, and copolyesters—tend to be hygroscopic, or prone to moisture pick-up. If not appropriately dried prior to molding, absorbed moisture can turn to steam and harm adhesion at the interface of the two materials. Moisture also can hydrolyze some resins, harm surface properties, and increase ejection difficulty. Moisture at the time of molding generally should not exceed 0.05% by volume. Common practice is to dry TPEs in a desiccant dryer with a –40 F dewpoint.
2) Concentrate carrier compatibility: Overmolding with TPEs containing color concentrates can be tricky, one danger being conflict between the colorant carrier and the TPE. The workhorse carrier for TPEs has long been PP, but this carrier frequently performs poorly when bonding certain TPE families to nylon, PC/ABS, and other engineered substrates.
This is illustrated by adhesion data for a 55 Shore A TPE containing a color concentrate and overmolded on a PC/ABS substrate (Fig. 3). In this case, a PP concentrate carrier exhibits adverse effects on adhesion, apparently because of a conflict between the carrier and the TPE. In contrast, data show that with this particular TPE, EVA and TPU carriers provide superior adhesion.
3) Gate design: In parts that are subject to high wear during use, and consequently prone to layer delamination, gates should be positioned in the areas that will receive highest wear. That’s because TPEs are hotter (and thus generally adhere better) at the gate rather than at the end of flow. When appearance is a priority, as in cosmetics packaging, gating from the back of the substrate via a pin is preferred since it hides gate blemishes on the TPE.
To ensure that the TPE melt adequately fills the mold cavity, a key consideration is the ratio between flow length and part thickness. The minimum ratio should be around 150:1. Another proven approach is to locate the gate at the thickest area of the part and to keep flow length as short as possible.
In selecting a gating method, it is advisable to begin with a “steel-safe” design of the gates and to size them initially on the small side, enlarging them later as required. Certain TPEs (like SEBS) require a smaller gate to boost shear and ensure complete mold fill. Other TPEs (TPVs and TPUs) generally require larger-than-normal gates to compensate for their high melt viscosity.
More tips on tooling
Adhesion is not the only important consideration in overmolding, so here is some advice on aspects of tool design that will optimize other areas of performance:
1) Surface texture: Designers are sometimes tempted to underscore the texture and grip properties of a TPE by polishing the mold to add a smooth finish. Yet a smooth finish sometimes actually highlights flaws like knit lines and blemishes in the part. Conversely, texturing of part surfaces is often effective in hiding flaws and imparting a “grippy” or leather-like feel. Certain textures have the effect of imparting a harder or softer feel than might be anticipated in light of the TPE’s Shore A durometer. The goal is to balance the surface texture and durometer values of the TPE to get the intended product feel.
2) Ejection efficiency: Part ejection can be facilitated by designing 0.5° to 1° of draft into each side of the mold. With more ejection-resistant materials like TPUs, a 5° to 6° draft is sometimes required. Texturing the tool surface frequently improves ejection, whereas a more polished surface tends to impair it.
Ten Tips on Overmolding
Match compatibility of TPE and substrate.
Minimize peeling with sharp transitions in shut-off design.
Avoid trapping air in cavities via appropriate venting.
Balance TPE thickness with Shore A hardness for desired “feel.”
Maintain TPE melt temperature at the level that optimizes adhesion.
Dry moisture-sensitive materials.
Select color-concentrate carriers that are compatible with both the TPE and substrate.
Be aware of liabilities of smooth surface textures.
Keep the TPE flow-length/part- thickness ratio below 150:1.
Design gating with good adhesion in mind.
Tackling nylon adhesion
Nylon-based materials are an increasingly popular substrate in several high-growth overmolding markets—handles and grips for power and hand tools, appliances, and lawn/garden products. The downside is that nylons are often difficult to overmold with good adhesion. TPEs bond relatively well to unmodified and glass-filled nylons, but fall short when joined to versions that are highly formulated with additive packages.
Another problem is the broad array of available nylons, which differ by resin class (e.g., nylon 6, 66, and 12), reinforcement type and loading, and additives used. In the case of a first-generation TPE, test data show that a dramatic loss of adhesion strength occurs when it is bonded to impact-modified and heat-stabilized nylon 6 (Fig. 4). But progress is being made: Data show that a second-generation, improved-adhesion grade of the same TPE class yields significantly improved adhesion performance, even with heat-stabilized products.
Additional considerations also make nylon adhesion more difficult. One is their propensity for high moisture pick-up, which makes careful drying imperative. And the melt temperatures of nylons are higher than for most other substrates, so the TPE melt temperature has to be increased accordingly to ensure good bonding. Preheating of nylon inserts is also generally advised.
In addition, careful selection of color concentrate carriers is needed to ensure good TPE adhesion to nylons. In general, LDPE and EVA are preferred carriers with nylon substrates.
The overmolding process is utilized for many reasons that vary as per the characteristics of a particular project. Some common materials include toothbrushes, tool handgrips (e.g., cordless drills and screwdrivers), and personal care products (e.g., shaving razors and shampoo bottles).
Here are some examples of regular overmolding applications:
Rubber Over Plastic – A rigid plastic substrate is first molded. Afterward, soft rubber or TPE is molded onto or around the substrate. This is frequently utilized to give a soft grip area to a rigid part.
Plastic Over Plastic – Here, a rigid plastic substrate is first molded. Then different rigid plastic is molded onto or around the substrate. The plastics can vary in color and/or resin.
Plastic Over Metal – A metal substrate is here machined, formed, or cast. Then, the substrate is entered into an injection molding tool, and the plastic is molded around the metal. This is usually utilized to capture metal elements in a plastic part.
Rubber Over Metal – A metal substrate is a cast, formed, or machined. After then, the substrate is inserted into an injection molding tool, and the rubber or TPE is molded onto or around the metal. This is often used to provide a soft-grip surface.
There are many compatibility issues and limitations to note between different types of materials.
You aren’t limited to just two materials. we have made some products with three different types of materials on one part to accomplish color breaks and grip surfaces. Here is a simple instance with a product you’ll be intimately familiar with: scissors.
Manufacturers who want to add a soft-touch exterior to their products that enhance grip or “feel” and provide a stylish appearance attractive to consumers are prime candidates for overmolding. Overmolding also reduces shock and vibration, dampens sound, provides electrical insulation, and improves chemical/UV resistance, increasing product longevity. Overmolding also lowers production costs despite improving product viability and customer satisfaction. Below are the advantages of using overmolding.
Better Product Performance /Increased Shelf Appeal /Lower Production Cost
Injection molding is a common and cost-effective method for manufacturing parts. It’s widely used for everything from medical devices and children’s toys to household appliances and automobile parts, producing parts that are both strong and light, in many cases replacing machined or cast metal products.
Sometimes, however, injection-molded plastic parts need a little help. Low impact or vibration resistance, slippery surfaces, poor ergonomics, and cosmetic concerns are just a few of the reasons why a second molded part is often added as a grip, handle, cover, or sleeve.
Some manufacturers choose to assemble these two different molded components together with glue, screws, or an interference fit, but this takes time and costs money, and may lead to less-than-desirable results.
Hard-soft, overmold processes create integrated seals, acoustic-damping elements, and nonslip, impact and vibration-absorbing surfaces. These overmolded parts have broad potential in automobiles, material handling, plumbing, heating and air conditioning, power tools, and audio systems. Automotive applications range from sealed housings to easy-to-grip passenger compartment controls. Other potential end uses include paper transport rollers in office equipment, plumbing seals and gaskets, and soft grips on power tools.
Parts containing hard-soft combinations also overcome limitations of conventional assembly techniques. For example, fitting seals that prevent moisture from penetrating inside electronic components is getting more difficult as electronic packages continue shrinking. Molded hard-soft combinations may become an alternative to conventional seals and gaskets.
And there is more good reason for combining soft and hard plastics. For instance, directly molding soft elements onto hard-plastic substrates consolidates two or more components thus eliminating additional assembly costs. Injection molding also expands design flexibility making difficult-to-assemble parts, such as complex gaskets for hard-to-reach places, in a single step. Hard-soft molding may also eliminate undercuts and other features that hold conventional, mechanically assembled soft components in place. This reduces tooling cost and may remove specialized cams and sliding actions from the mold.
Cost savings reportedly exceed 25% over conventional assembly methods, because assembly is done by the molding machine. Thus labor and inspection costs drop, as does a range of ancillary manufacturing expenditures such as allocated floor space and parts inventory.
Hard-soft molding is most economical for big parts, but can be effective for large runs of small parts. With small parts, eliminating secondary assembly can more than balance out the tooling and equipment costs required for two-component molding.
In overmolding, a single part is created using a combination of two or more different materials. The first material (the substrate) is partially or fully covered by the subsequent (overmold) materials during the manufacturing process.
The hard plastic substrate provides structural support. The second material usually provides a soft texture. (For instance, screwdriver handles and toothbrushes are common hard-soft overmolded products.) Overmolding allows the use of two different materials without using additional adhesives or fasteners.
The substrate could be almost anything: a machined metal part, a molded plastic part, or an existing product (such as threaded inserts, screws or electrical connectors). The substrate is the basis for what will eventually become a single continuous part, made from chemically bonded (and often mechanically interlocked) materials of different types.
The overmold materials are often plastic-based and are typically in the form of pellets. These pellets are then mixed with colorants, foaming agents and other types of fillers. The pellets are melted down and the resulting liquid is injected into the mold tooling.
The overmold process is fairly straightforward:
The substrate material or part is placed into an injection molding tool
The overmold material is injected into, onto or around the substrate
The overmold material is allowed to cure or solidify
The end product: two materials joined together as a single part.
Typical over-mold combinations include:
Plastic Over Plastic – A rigid plastic substrate is molded first, followed by another rigid plastic overmold on or around the substrate. The two plastics often differ in color and/or resin.
Rubber Over Plastic – A rigid plastic substrate is molded first, followed by a soft rubber or TPE overmold. (TPE, or thermoplastic elastomer, is a mix of polymers, typically plastic and rubber.) This process is often used to create a rigid plastic part with a soft grip area.
Plastic Over Metal – A metal substrate is first machined, cast or formed. It is then inserted into an injection-molding tool, where the plastic is molded onto or around the substrate. This process is often used to capture metal components within a plastic part.
Rubber Over Metal – A metal substrate is first machined, cast or formed. It is then inserted into an injection molding tool and rubber or TPE is molded onto or around the metal. This process is used to create a rigid metal part with a soft grip surface.
In overmolding, a single part is created using a combination of two or more different materials. The first material (the substrate) is partially or fully covered by the subsequent (overmold) materials during the manufacturing process.
The hard plastic substrate provides structural support. The second material usually provides a soft texture. (For instance, screwdriver handles and toothbrushes are common hard-soft overmolded products.) Overmolding allows the use of two different materials without using additional adhesives or fasteners.
The substrate could be almost anything: a machined metal part, a molded plastic part, or an existing product (such as threaded inserts, screws or electrical connectors). The substrate is the basis for what will eventually become a single continuous part, made from chemically bonded (and often mechanically interlocked) materials of different types.
The overmold materials are often plastic-based and are typically in the form of pellets. These pellets are then mixed with colorants, foaming agents and other types of fillers. The pellets are melted down and the resulting liquid is injected into the mold tooling.
The overmold process is fairly straightforward:
The substrate material or part is placed into an injection molding tool
The overmold material is injected into, onto or around the substrate
The overmold material is allowed to cure or solidify
The end product: two materials joined together as a single part.
Typical over-mold combinations include:
Plastic Over Plastic – A rigid plastic substrate is molded first, followed by another rigid plastic overmold on or around the substrate. The two plastics often differ in color and/or resin.
Rubber Over Plastic – A rigid plastic substrate is molded first, followed by a soft rubber or TPE overmold. (TPE, or thermoplastic elastomer, is a mix of polymers, typically plastic and rubber.) This process is often used to create a rigid plastic part with a soft grip area.
Plastic Over Metal – A metal substrate is first machined, cast or formed. It is then inserted into an injection-molding tool, where the plastic is molded onto or around the substrate. This process is often used to capture metal components within a plastic part.
Rubber Over Metal – A metal substrate is first machined, cast or formed. It is then inserted into an injection molding tool and rubber or TPE is molded onto or around the metal. This process is used to create a rigid metal part with a soft grip surface.