August 4, 2021 By MDO Contributors Network

Don Bonitati, Minnesota Rubber & Plastics

Elastomer components image courtesy of Minnesota Rubber & Plastics

The long list of material properties impacting an elastomer component’s performance includes your prospective polymer’s end-use environment, chemical compatibility, hardness, compression set, tensile properties and manufacturability, to name a few. Although the selection process may appear daunting, understanding your application, your material options’ physical and mechanical properties, and the interaction with mating components will go a long way. These key attributes, in conjunction with understanding volume ramp schedules, will drive the proper manufacturing processes to ensure a successful product launch.

This article will walk you through some of the factors and trade-offs you’ll need to address when selecting a polymer for your medical component. It will also describe some of the capabilities that rubber and plastic specialists can provide you to enhance your product development.

Begin your material selection process by reviewing the product’s design intent, including clinical operation requirements. With any medical part, patient safety and cleanliness play a critical role in the material you choose. Assess where and how your part will be used, as well as any sterilization processes it may encounter. For instance, molded rubber seals have wide use in medical equipment, including implantable devices. Accordingly, you’ll need to know the following about your material:

Liquid silicone rubber (LSR) is often selected for medical device products. Still, in many applications, high consistency rubber (HCR) has been proven to be a better choice that can drive down overall part cost and reduce time to market.

Hardness is defined as the rubber’s resistance to indentation by a harder object and is an important consideration for critical medical components and seals. It’s possible to measure rubber hardness using a Shore durometer — according to ASTM D2240 — and the values are expressed in Shore hardness scale units. For example, the hardness of thermoset rubbers ranges from 20 Shore A to 90 Shore A, and harder thermoplastic elastomers are categorized as Shore D. However, the most common hardness range is 50 Shore A to 80 Shore A.

Your application needs will dictate your required material hardness. For example, sealing products typically use materials with a hardness of approximately 70 Shore A. If your parts have complex geometries or require deep undercuts, look for a material hardness between 30 Shore A and 80 Shore A.

When it comes to medical components, a gas or other medium’s ability to penetrate rubber is important in material selection. Components that endure sterilization are vulnerable to moisture incursion, so the material’s permeability must be as low as possible. In addition, a material’s molecular size and polarity, the filler material in your compound, your application’s temperature and other factors will determine permeability.

Material specialists like Minnesota Rubber and Plastics will analyze a rubber to see how it will behave under extension following ASTM D624 or ASTM D412 specifications. In a typical tensile strength test, gradually heavier loads are applied to a material sample, stretching the material to various lengths. This data is plotted graphically to create a stress-strain curve on an X-Y axis, with:

Y-axis = stress (MPa, force per unit area)

X-axis = deformation of the material (elongation length)

The material’s performance can be seen in different regions of the stress-strain curve:

If you require a stiff, rugged rubber, a steep curve will indicate a tough material that offers good resistance to deformation caused by elongation. A more gradual curve means the material deforms more easily.

Ultimate elongation is the percentage of the increased length to which the elastomer can be stretched (strained) to the break point. It is measured against the original length of the specimen. Tensile stress is usually measured and reported at predetermined strains — 50%, 100% and 300%— before the break occurs. The tensile values at different strains are reported as moduli.

Rubber deforms under compressive load and rarely returns completely to its original dimensions when the load is removed. The difference between the original and final dimensions, expressed as a percentage, is known as the compression set. Compression set measurements are usually performed following ASTM D 395 Method B (compression under constant deflection). This property is one of the most important aged properties, as it describes the ability of a molded article to maintain a seal under a compressive force. As many molded rubber articles are used in compression, it’s possible to define sealability by measuring compression set resistance.

In addition to matching your application’s criteria with a material’s physical and mechanical properties, manufacturing processes and their volumes will impact your choice of material and the unit price of your part. Manufacturing processes present cost trade-offs, and certain processes may not be ideal for some materials. The most common rubber manufacturing process options include:

In this process, uncured rubber is fed into vessels for heating. When the rubber reaches the desired temperature, the material is extruded into a mold cavity where it hardens and cures. Taking the geometric factors involved with tooling into consideration, injection molding is the most efficient manufacturing process. Its high precision also makes it suitable for custom projects or parts that have complex shapes. In addition, injection molding can effectively handle volumes as high as tens of millions of units, and it has the added benefit of generating little material waste.

Another popular method used with complex designs, transfer molding is well-suited for parts requiring multiple cavities. Here, the material is preheated and preformed for placement into a pot located between a closed mold system’s top plate and plunger. Then, the material is pushed out of the pot through sprues and into the mold cavity, where it is heated and pressurized. This process is typical for colored rubber parts.

Known for its simplicity, compression molding involves placing a preformed, uncured rubber compound directly into a heated mold cavity. Once in the cavity, the compound is compressed into its final shape by the mold closure. Compression molding is inexpensive and fast, and it can be used for most materials.

Each process involves trade-offs when it comes to achieving certain characteristics. Flash is one example. This condition can be defined as excess material that protrudes from a molded part’s surface at its parting lines. A combination of factors plays into whether the flash has a permissible thickness. Eliminating the extraneous rubber from a part will change the tooling geometry to achieve the desired precision. Because the tooling is more delicate, tooling life diminishes, and the cost of the reduced tooling life can influence your choice of manufacturing method.

In addition, certain materials are harder to process, which can lead to damaged parts. Due to this combination of material and process factors, consult with your rubber parts specialist to understand all the options involved with selecting the right rubber compound and manufacturing process to best achieve your goals.

Once you have determined all of your desired properties and characteristics, you can identify your potential material and manufacturing options with the help of your rubber expert and their information library. Our team will create a chart that allows you to cross-reference your criteria with the materials.

For example, suppose you require a silicone. In that case, your MRP material science partner will list the compound numbers that match your needs for biocompatibility, sterilization, insulin capability, temperatures or any other criteria you require.

Although there are many standard materials to choose from, no two applications are alike. Therefore, for applications with specific needs that a standard material may not be able to satisfy, it pays to choose a rubber specialist that has the capability and expertise to create a custom formulation that can best match your requirements.

To help determine whether a custom formulation is more suitable for the application than a standard material, Minnesota Rubber and Plastics applies many different test methods and devices to measure the material’s physical and mechanical properties. Using a process called compounding, we can enhance materials with additives to boost a property or make it more suitable for a specific manufacturing method. Still, compounding often creates more trade-offs. By enhancing one property, another may diminish. Your rubber specialist can walk you through the trade-offs to ensure you get the best performing material for the application.

Minnesota Rubber & Plastics has a proven history of helping medical OEMs design high-performance molded parts, and we also have the capability and expertise to develop the best-performing elastomeric for the application. From silicone molding, rubber to thermoplastic elastomer (TPE) conversion, cleanroom assembly or compounds that comply with ISO 10993, USP Class VI and FDA standards, we can solve your rubber parts design, development or manufacturing challenges no matter the volume. Application examples include insulin and glucose monitoring instruments for diabetes, POC diagnostics testing, delivery systems for transcatheter aortic valve replacement and other cardiovascular tools and surgical instruments.

Explore our design tools and resources at www.mnrubber.com.

Don Bonitati, medical market director for Minnesota Rubber & Plastics (based outside Minneapolis), leads the company’s global medical market strategy, including the company’s ongoing expansion efforts into emerging markets.

The opinions expressed in this blog post are the author’s only and do not necessarily reflect those of MedicalDesignandOutsourcing.com or its employees.

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