Injection Molding an IC into a Connector or Consumable Item

Injection Molding an IC into a Connector or Consumable Item

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Injection molding is the method of choice to embed integrated circuits (ICs) in medical sensors and consumables. This application note discusses the special care required when selecting the plastic material. It explains that the processing temperature must be low enough not to soften or liquefy the solder that attaches the IC to a substrate. The article also discusses various plastic materials and shows how they are not all equally suited for the sterilization required by medical applications. Only few of the sterilization methods are compatible to both the plastic material and ICs. An example of an IC embedded into a consumable item is shown.


Integrated circuits (ICs) have been embedded in medical sensors and consumables or cables for quite some time. The concept and benefits of this technique are well understood.1 However, very few companies have acquired the expertise for both the manufacturing process and selecting suitable plastics for the application. This document describes the injection molding process in general, explains the critical temperatures, and gives an introduction to identifying suitable plastic materials.

What Is Injection Molding?

Injection molding is a process that forces molten plastic through a nozzle into a mold cavity. The mold cavity can initially be empty or contain an object to be encased by the plastic. Figure 1 shows a simplified drawing of an injection molding machine.2 The plastic is fed into the machine as granules. A screw-type plunger transports the granules through a heated barrel towards the nozzle. Along the barrel there are typically three heating zones called rear, center, and front. The front zone, next to the nozzle, is the hottest. On the way to the nozzle the plastic granules soften and become a homogenous mass, which is forced under high pressure into the mold cavity, where it quickly cools and hardens. The mold is then opened to remove the molded object and to prepare the mold for the next cycle. The processing conditions specification in the data sheet for the plastic material lists the appropriate temperatures of the zones and the mold.

Figure 1. The principle of an injection molding machine.

Figure 1. The principle of an injection molding machine.

The Critical Temperature

Besides pressure and filling speed, temperature is a critical parameter in the injection molding process. Temperature is also critical for the object to be encased. An IC by itself can handle up to 300°C for a short time without any harm. This temperature is permissible if the IC to be encased is wired-bonded to a substrate (circuit board) or if it is a plastic-packaged IC with crimped-on pins or in an SFN package3 with exposed contact areas. However, if the IC is soldered to a circuit board, the critical temperature for injection molding depends on whether the IC assembly is lead (Pb)-free or not. Lead-free ICs (plastic packaged or bumped die, also known as flip chip, UCSP, or WLP) require lead-free solder, which has a melting temperature of approximately 217°C. Traditional plastic-packaged ICs and RoHS-compliant bumped dies require standard solder (Sn/Pb 63/37), which has a melting temperature of approximately 183°C. The melting temperature must not be confused with the reflow oven temperature setting, which is 235°C for lead-free and 215°C for standard products.

Finding the Right Plastic

With roughly 30,000 different materials available for injection molding,4 finding the right plastic may appear like a serious challenge. The task becomes easier with some insight into the characteristics of various plastic materials.

There are thermosetting plastics, which can be heated and run through an injection molding machine just once. Epoxy, a plastic commonly used for IC packages, falls into this category. Once processed, the thermosetting plastic remains solid, regardless of the temperature. There are thermoplastics, which soften whenever they are heated. Thermoplastics can have an amorphous or semi-crystalline structure, which affects mechanical stability, chemical/wear resistance5, 6 and suitability to sterilization methods. Table 1 shows a selection of plastic materials for injection molding.

Table 1. Typical Plastics for Injection Molding.
Name Full Name Cost Structure Front ZoneTemp. (°C) Mold Temperature(°C) Sterilization Compatibility6, 7, 8, 9
ABS Acrylonitrile butadiene styrene Low Amorphous 210 to 232 63 to 85
49 to 85
HDPE High-density polyethylene Low Semi-crystalline 199 to 227
171 to 199
21 to 66
21 to 52
ETO CD (rad)
LDPE Low-density polyethylene Low Semi-crystalline 199 to 227 21 to 66 ETO CD (rad)
PA Nylon 6/6 Medium Semi-crystalline 282 to 293
249 to 271
66 to 107 AUT ETO CD VHP
PBT Polybutylene terephthalate Medium Semi-crystalline 243 to 257
216 to 232
66 to 121 AUT ETO RAD
PC Polycarbonate Medium Amorphous 293 to 310
216 to 232
82 to 121
66 to 121
AUT ETO (rad)
PET Polyethylene terephthalate Medium Semi-crystalline 238 to 260 135 to 163 AUT ETO RAD
PMMA Acrylic Low Amorphous 188 to 210
221 to 238
79 to 107
38 to 66
POM Acetal Medium Semi-crystalline 188 to 210
177 to 199
82 to 121 AUT ETO
PP Polypropylene Low Semi-crystalline 204 to 227
177 to 193
32 to 66 AUT ETO CD VHP
PS Polystyrene Low Amorphous 221 to 238
204 to 221
38 to 66 ETO CD VHP RAD
SAN Styrene acrylonitrile Low Amorphous 243 to 260
210 to 232
52 to 82
38 to 79
AUT: material is well suited for autoclave sterilization.
ETO: material is well suited for etylene oxide sterilization.
CD: material is well suited for chlorine dioxide sterilization.
VHP: material is well suited for vaporized hydrogen peroxide sterilization.
RAD: material is well suited for gamma ray or electron beam sterilization.
(rad): material may change its characteristics, e.g., discolor, when exposed to gamma rays or electron beams.

The temperature values above are compiled from data on the RTP Company10 website. Each plastic type usually has several variations with different processing and mold temperatures. Other vendors may offer the same plastic type with slightly different processing requirements. Additives such as reinforcement fibers, pigment, flammability reduction compounds, or conductivity enhancers can also impact the processing conditions. As a guideline, one should select the plastic based on the nozzle temperature or the front zone temperature as specified in the processing conditions for injection molding of plastics. For injection molding at 183°C, the choice of plastic is very limited. At 217°C, most of the materials in Table 1 are feasible. Materials such as nylon (PA) or polyethylene terephthalate (PET) can be used only if the IC is not soldered to a substrate. The plastic cools off rapidly inside the mold cavity. In summary, one should make sure that when the plastic enters the mold, it does not exceed the critical temperature.

Sterilization Compatibility

Products for medical applications typically undergo sterilization, at least once or even multiple times during their lifetime. Popular methods are autoclave steam sterilization, ethylene oxide (ETO) sterilization, chlorine dioxide (CD) sterilization, vaporized hydrogen peroxide (VHP) sterilization, hydrogen peroxide plasma sterilization, and irradiation with gamma rays or electron beams. The sterilization compatibility information in Table 1 is compiled from various publications. A report on hydrogen peroxide gas-plasma compatibility was not found. In any case, caution is advised since the test methods and details are not fully disclosed. For objects with an embedded IC the preferred sterilization methods are ETO and CD. Autoclave and VHP may also be acceptable, although the high temperature or vacuum required by these methods can affect embedded batteries or floating-gate memory cells. Hydrogen peroxide gas-plasma sterilization and irradiation (gamma ray or electron beam) are not recommended since they can damage ICs.

Exceeding the Critical Temperature

If the temperature of the plastic is too high when entering the mold, the solder that holds the IC in place softens or liquefies. As this hot plastic enters the mold cavity it can push the IC away from the pads on the substrate. Solder can protrude from the mold or short IC terminals, making the end product unusable or unreliable. Therefore, choosing the right temperature is a very critical step.

Nevertheless, there could be situations that require a plastic with a processing temperature above the solder melting point. In that case, one can consider two molding steps: first, use a plastic that stays below the critical temperature; second, use the plastic that requires the otherwise unacceptable temperature. Thus, with properly chosen dimensions and a well-timed temperature profile, the thermal inertia of the first layer protects the IC from the excess heat of the second molding step.

Electrostatic Charges

Mechanical contact of two different plastic materials causes triboelectric charging. The degree of charging depends on how different the electron affinity is between the two plastic materials. In some cases, plastics with different electron affinities can generate thousands of volts of electrostatic charging when rubbed together.

In the case of polyethylene (PE) and polyvinylchloride (PVC), these two plastics are very close together in the "triboelectric series." As a result, when PE contacts PVC there is little electrostatic charging produced on either material. However, acrylic (PMMA) and polyester plastics have a significant difference in electron affinity compared to PE or PVC.

If an acrylic or polyester plastic contacts PE or PVC, a relatively large electrostatic charge can be generated on both plastic materials. Acrylic or polyester would tend to give up electrons while PE or PVC would tend to attract electrons, causing the acrylic or polyester to become more positively charged while the PE or PVC would become more negatively charged.

The composition of the plastic used in T092 packages, for example, is different to some degree from either PE or PVC, but the extent of charging during overmolding would have to be determined experimentally for each overmolding process, since there are many variables involved in the amount of charge that could be generated on the materials used in the process. Generally, it is good manufacturing practice to provide ESD controls, such as installation of ionization fans, in an overmolding process.

Real-World Example

Application note 47021 features a DB9 connector with an embedded TO92-packaged 1-Wire® device. In this case, two of the DB9 pins are crimped to the IO and GND leads of the TO92 package. The NC (not connected) lead is cut off. This construction maximizes the choice of plastics since no solder is involved. Figure 2 shows the same connector before molding. The TO92 package is easily recognized.

Figure 2. DB9 connector with embedded TO92 1-Wire device before injection molding.

Figure 2. DB9 connector with embedded TO92 1-Wire device before injection molding.


Injection molding is the method of choice to embed ICs in medical sensors and consumables. Special care is required when selecting the plastic material since its processing temperature must be low enough not to soften or liquefy the solder that attaches the IC to a substrate. Plastic materials are not equally suited for the sterilization required by medical applications. Consequently, only few of the sterilization methods are compatible with both the plastic material and ICs.