You’re on page 5 of 32 material selection pages… Getting sleepy yet? Rather than continue staring at nearly identical rolls of material, sit back and relax as we discuss whether silicone is the right choice for your application.
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Silicone gaskets offer a wide range of heat-resistance and durability benefits, making them a popular choice for gasket manufacturing.
As a converter, Strouse regularly builds custom gaskets for our clients. We’re familiar with silicone’s material behavior compared to other gasketing materials, so today, we’ll explain its uses.
Read on to learn about the benefits and uses of silicone gaskets, plus what to consider when choosing a material for your gasket design.
If you’re looking for multi-temperature range, high-performance mechanical seals with high resilience and durability, you should consider using silicone gaskets.
Silicone gaskets can withstand high and low temperatures, making them a highly versatile material. Use them when you need a material with high-temperature resistance, a low compression set, and good electrical insulation.
The type of material in your gasket depends on its intended use. For example, if you’re dealing with a rigid object, you need a gasket that fits the set shape. Doors and moving structures need something more flexible.
Before you design a gasket, consider your needs, including temperature, pressure, corrosion resistance, availability, and cost.
Gaskets must be solid so they don’t allow materials to pass through, and some need to handle energy discharge. You can have many different types of gaskets, including:
And many different materials, including silicone, neoprene, EPDM, Teflon, Gore-Tex, and graphite gaskets.
Because of their versatility, silicone gaskets are used in many different industries.
Silicone gaskets resist extreme temperatures, UV light, ozone, and chemicals. Because they can handle extreme weather and temperatures without wearing down, they’re often the right fit for airplanes, space shuttles, and similar vehicles.
Silicone gaskets are stable and durable, maintaining their resilience and strength even in extreme conditions. Because they can handle unnecessary stress without issues, they are great for personal, commercial, or industrial vehicles. In addition, they reduce vibrations, provide high-quality radiator seals, and are otherwise used for mass transit systems like buses and trains.
In the construction industry, silicone gaskets seal HVAC systems and windows or doors. You can also use them in engine gaskets to vent ducts.
Other uses of silicone gaskets include sealing food processing machinery and industrial ovens in the food industry. The medical industry uses them for medical equipment like healthcare devices and pharmaceuticals.
Before we get into the different types of silicone gaskets, it’s worth considering the properties that differentiate them from other gasketing materials.
There are thousands of materials to make gaskets, but silicone stands out thanks to the benefits that allow it to be used in indoor and outdoor applications.
Silicone gaskets can withstand temperatures up to 392 degrees Fahrenheit continuously, which makes them great for many industrial applications. It can be exposed to high heat levels without degrading or wearing out.
Silicone seals can also withstand heat up to 428 degrees Fahrenheit intermittently and withstand extremely cold temperatures, remaining flexible at as low as -94 degrees Fahrenheit.
Silicone gaskets have conductive capabilities that make them excellent insulators of electricity. Blending silicone with nickel-graphite or silver-plated aluminum particles can shield electromagnetic interference (EMI).
Silicones are found in most high-voltage insulators and other electrical components. Different chemical reactions can cross-link them, making them non-reactive at high temperatures. The electrical industry relies on these non-reactive materials. Silicone can also be blended with semi-conductive carbon to prevent electromagnetic discharge.
Silicone gaskets are highly durable and resistant to UV light, ozone, and extreme weather conditions, making them ideal for outdoor gasketing.
Plus, silicone's tensile strength and durability make the gaskets highly economical, as it is a reliable and stable material. You can use these gaskets for a long time without them showing wear, and once installed, they don’t require much maintenance.
Because silicone gaskets are FDA-approved, they can be used in medical equipment, health care instruments, and food processing plants. They can also be mixed with other FDA-approved materials for high tear strength.
Unlike asbestos gaskets, silicone gaskets are also physiologically inert (not toxic or harmful to people). Their high tear strength and inertness make silicone gaskets useful for healthcare, food processing, medical diagnostic equipment, and pharmaceuticals.
Compression set reliance means that silicone gaskets function well under pressure by returning to their original thickness even after being compressed for long periods.
Silicone gaskets are a smart choice for a lower compression set. A compression of 100% means the material will never return to its original thickness. Lower compression set reliance materials ensure the material doesn’t get deformed in certain temperatures.
Matching the compression set reliance of your material to your intended use is essential. If the gasket material deforms, the seal will fail, leading to leaks and contaminations.
Silicone gaskets have low flammability levels, making them ideal for industries that generate excessive heat. They can also be used in telecommunications equipment and mass transit systems.
Silicone gaskets meet Underwriters Laboratories (UL) testing requirements for fire safety and flame resistance, meaning they can achieve UL94V0, UL94V1, and UL94HF1 flammability standards.
Silicone gasket material is water-repelling, repelling liquids, resisting moisture, and maintaining a watertight seal. This sealing ability is essential for industries dealing with moisture or water and is great for outdoor use in wet weather conditions.
Silicone gaskets can come in sheets or rolls of different thicknesses. Depending on your needs, you can also use solid, sponge, or foam silicones.
Solid silicone gaskets are not always soft but rather tightly packed and more rigid than sponge silicone. If you need a seal rating of IP67 or higher, you’ll want to choose solid silicones.
Solid silicones can offer exceptional sealing capabilities, but remember that they’re challenging to compress because of their hardness and require 15 to 20% compression.
Sponge silicone gaskets offer more cushioning and padding. They can be open-cell or closed-cell. Open-cell silicones contain pockets that allow water, air, and chemicals to pass unless the gasket is compressed.
Closed-cell silicones have pockets filled with nitrogen to prevent water, air, or other chemicals from passing through, even at low compression. They will need at least 50% compression. Sponge silicone gaskets have a higher temperature threshold of 500 degrees Fahrenheit.
Foam silicone gaskets can be soft, medium, firm, or extra-firm and offer different compression levels. Like sponge silicone gaskets, foam silicone gaskets need at least 50% compression. They can be open-cell, closed-cell, or a mixture of both, and their temperature threshold is 400 degrees Fahrenheit.
Die cut silicone gaskets are a common type of gasket, built using custom machine tools to create unique parts.
If you’re using your design with custom sizes and thicknesses, die cut silicone gaskets could be a good option. They’re often a more economical option for large volumes, because thousands of die cut gaskets can be produced per hour.
Molded silicone gaskets provide a higher-performance seal than die-cut silicone gaskets. However, this might come at a higher upfront cost, even though both are good for high-volume production.
Conductive silicone gaskets are made up of a mix of high-quality silicone and conductive particles. They are filled with conductive materials like nickel, carbon, and silver-plated nickel and are used for electronic equipment.
FDA-approved silicone gaskets are generally used in the food processing industry. They are odorless, tasteless, and fungus-resistant. They also can handle extreme cold and heat, making them ideal for places with food around, like dough or cake mixers.
Unfortunately, silicone isn’t ideal for oil or petroleum-based chemicals. Fluorosilicone, or fluorinated silicone rubber, is similar to silicone, except it can withstand extreme temperatures and resist fuels, oils, and other petroleum-based chemicals.
Choosing between a silicone and a rubber gasket will depend on your goals. Silicone gaskets can be more efficient and perform better than rubber gaskets, especially in extremely high temperatures.
Natural rubber can work well in temperatures from -58 degrees to 176 degrees Fahrenheit intermittently, whereas silicone can handle more extreme temperatures, from -94 degrees to 426 degrees intermittently. Natural rubber starts to wear down at 176 degrees and melts by 248 degrees.
The cost of rubber materials like SBR can make them more appealing than silicone in pricing. However, rubber is not used with ozone, strong acids, fats, oils, and grease. Silicone, on the other hand, can be used with these materials. You can use silicone gaskets in UV and extreme weather conditions for outdoor applications.
Ultimately, you’ll want to consider your design and application before finalizing your product material, which leads us to…
Now that you know more about silicone gaskets, you’re ready to pick out a gasket adhesive that suits your needs. Moreover, given the complexity of material behavior, you’ll want more to go off of than simply matching the numbers on a data sheet.
Before you finalize your design, you might want to test the material within your application. Requesting a design sample will allow you to see if silicone really is the best choice for your gasket design.
It’s one thing to build the perfect gasket once, but how can you consistently manufacture your part to reduce the chances of product failure?
We’re here to help you through your product development process. Reach out to ask questions or request a sample. Lastly, please visit our Learning Center for additional resources.
Originally published: February 24,
There are thousands of materials to choose from when building your custom gasket, each with different properties and tolerances to choose from.
Some of the most common categories of materials for making custom gaskets, and general guidelines for when they may be a fit are detailed below.
Contact us to discuss your requirements of Custom Silicone Gaskets. Our experienced sales team can help you identify the options that best suit your needs.
Please keep in mind that this article is meant to provide general guidance, and there are many materials with different properties and specifications to choose from within each category. Narrowing down to your final material is something best done with the help of an expert. This guide is designed to help you start the process of material selection, before diving into the nitty gritty details.
You can also use this table of contents to jump straight to the material you want to learn more about:
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Solids are often chosen based on a simple preference between solid and sponge materials. In general you can do most of the same things with solid and sponge materials but solid materials will give your gasket a longer life and more durability. Solids often extend the lifespan of the unit up to 2 times longer than a sponge material.
Additionally the compression force of a solid will always exceed that of a sponge. If your application has, or can handle strong compression forces, a solid material will be your best bet.
Solid materials can be formed into gaskets using die cutting, waterjet cutting, and CNC or digital cutting. In addition, solids materials can be molded into more three dimensional (rather than flat) gaskets if the situation calls for it.
Solid silicone is designed to be used in outdoor applications where physical properties are not critical but extreme temperature resistance is still needed. This may include situations where degradation may occur due to exposure to sunlight or ozone.
Fluorosilicone sheeting is designed to be used in similar conditions to silicone, with additional chemical resistance. Both extreme temperature resistance, and its resistance to chemicals such as oils and fuels makes it an ideal material for fuel delivery applications in the aerospace, automotive and defense industries. Because of the additional chemical resistance you will find that fluorosilicone costs slightly more than silicone.
Neoprene is a more cost effective option than either silicone or fluorosilicone. It is recommended for applications that require resistance to liquids such as water, oil, and other solvents. It is also resilient with a high degree of elasticity. With greater elongation and tear strength than silicones formulated for general purposes, this material is resistant to abrasion and fatigue.
Nitrile is a material specifically developed for commercial or industrial applications where environmental extremes and wear is an important factor. Nitrile exhibits resistance to chemicals like fuels and oils. It is a tough, long lasting material.
There are FDA approved versions of nitrile materials available, making it a common choice for agricultural or food handling applications.
Peroxide Cured EPDM (Ethylene-Propylene-Diene-Methylene) is used in a wide range of applications where a general-purpose rubber with excellent water, weather, UV and ozone resistance is required. The curing process of Peroxide Cured EPDM provides heat stability making it resistant to high temperatures and steam. This material may be less expensive than silicone in some applications. EPDM is not recommended for applications with exposure to oil.
The “higher end” choice for solid materials, Flouroelastomer is known for providing the best of everything. It provides resistance to extreme temperature ranges, shows strong resistance to chemicals and does well in most applications. As such, it is also the most expensive of all the solid materials. A common application where all of these properties are needed is in aerospace use cases.
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Butyl is a synthetic rubber that resists moisture and the passage of gasses well. In addition, it has strong resistance to oil and chemicals, making it a common choice for automotive and even medical applications.
Sponge materials are commonly chosen for applications when low compression forces are required. This may be the case if there is concern for warping or bowing of the housing during assembly, if plastic housing is required, or if there is concern for cracking at compression stops anywhere on the housing. In addition, sponge materials can make assembly much easier because there are far less compression forces needed.
In addition, sponge materials are sometimes selected over solids due to UL flame ratings. It is much easier to find silicone sponge materials with the UL94V-0 flame rating than it is for solid silicone.
Soft Density Closed Cell Silicone Sponge is an excellent material for gasketing and padding applications that require a soft, compressible material. It is resistant to extreme temperatures, making it ideal for outdoor applications, and offers a good compression set. Also, its non-interconnected closed cells prevent water absorption.
Silicone sponge has the longest life out of all the sponge material options. Typically, Silicone Sponge is available in Soft, Medium, Firm and Extra-Firm Densities.
A neoprene blend is an excellent choice for gasketing and sealing applications that require a soft and compliant material. It is considered a lower cost alternative to solid rubber and other sponge materials. It is commonly used in shock absorption applications, as a thermal barrier, for weather stripping, and as a common basic sealing solution for industrial applications.
Also, its non interconnected closed cells make it extremely impermeable to water absorption. This sponge rubber is typically available in five hardnesses: Soft, Medium, Medium-Firm, Firm and Extra-Firm.
EPDM Sponge material has most of the same qualities as the neoprene blend above, but exhibits greater resistance to ozone, making it useful in applications where a sponge material is best-fit but ozone exposure is a concern. As such, it is slightly more expensive than neoprene blend.
Similar to sponge materials, foam materials are used in applications where low compression force is required. In fact, they offer even lower compression forces than sponge materials. Additionally, foams are typically less expensive than either a solid or sponge.
In general, foams are used to provide a simple seal against primarily air and dust, but do not provide a true environmental seal. It is best fit if your application just needs a basic seal between two materials, and it is not fit for critical outdoor applications.
Cellular silicone foam features resistance to extreme temperatures and resilience required in many types of sealing, cushioning, insulation and vibration isolation applications. Typically silicone foam materials are available in six different varieties, ranging from ultra soft to extra firm.
Polyurethane foams offer a broad range of design solutions for gasketing, sealing, and energy absorption. They provide a balance of a lower cost option than silicone foams and have a very low compression set. Typically polyurethane foams can be formulated in a wide range of firmnesses and a variety of densities within each formulation.
Filter foams are designed almost exclusively to filter out dust. They allow breathing, or the in and out flow of air but keep dust out. As such they are commonly used in electronic applications where dust can cause problems.
Polyolefin is meant to be a low cost, or inexpensive material for making basic gaskets. For the most part, this material is selected when a space simply needs to be filled to ensure the two sides of a part aren’t touching each other.
Form in place (FIP) materials are best fit when you have a very small gasket that would be difficult to die cut and then assemble in your production facility. Very small and thin gaskets are flimsy and difficult to manage, increasing the effort and time that must go into assembly. This is more and more common due to the smaller form factors and space constraints in today’s electronic assemblies.
As such, FIP gaskets are usually selected in an effort to reduce the cost of assembly in these instances. Because the gasket is dispensed directly on the unit, then cured, before being sent back to your production facility, it saves a step (and money) on the assembly process.
In addition, when using custom gaskets for EMI applications, choosing FIP as the method for production can limit waste, thus reducing cost on more expensive materials. Because of their typical size, FIP materials are commonly used to create an effective seal for electronic devices.
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Typically, a one-component silicone sealant and adhesive that cures when exposed to ambient humidity at room temperature. This material has excellent sealing properties with superior weather, ozone and compression set, as well as electrical insulation properties typical of silicone.
The paste-like consistency of this compound allows for application on vertical and overhead surfaces in addition to horizontal surfaces, at certain viscosities. The uncured body of this material is also sufficient to adhere small objects during the curing process. Silicone used for FIP, exhibits both low temperature flexibility and high temperature performance.
Because it is readily available, and has such a wide range of properties, silicone is the most commonly used material for FIP gasket production.
UV materials are typically used when production or lead time is an important factor. These materials don’t require the same amount of curing time after dispensing that silicone does, and as such can be turned around much faster. UV materials are typically selected in instances where high volume and production throughput are the most important considerations.
Probably the most common type of FIP Gaskets utilized are those with EMI materials. These materials meet all the requirements for EMI applications, but are useful when a small and precise gasket is required. EMI materials have the ability to shield between the two sides of the gasket and are very commonly seen in applications across a wide spectrum including test equipment, communications, satellites, and aerospace.
EMI materials are used if shielding is required between two areas of a product or part.
Designers no longer need to choose between an environmental seal or EMI shielding gasket. Silicone extrusions merge both types of gaskets into a single product. This category of material features a thin electrically conductive shield co-extruded on a high performance silicone rubber base.
Silicone extrusions are typically selected when you have a groove you want to put a gasket into. In most cases you’ll be choosing between an extrusion or an FIP gasket, and your decision will be based on the size of the groove. If the groove is too small for an extrusion, FIP dispensing is likely the only option. In addition, extrusion provides a lower compression force, as it is a softer material than that used in FIP dispensing.
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Typically, silicone products made for EMI shielding are made conductive by putting a conductive filler in the material, often silver, aluminum, copper, or nickel. This type of material is highly flexible and can be made to fit a wide variety of sizes and designs. It usually doesn’t stand up to very harsh environmental conditions — like exposure to sunlight, caustic chemicals, fuels or oils — which can leave shielding and sealing capabilities impaired. As such, it is typically used primarily on print circuit boards (PCB) or as connector gaskets on ports in electronics.
Conductive fluorosilicone materials use a fluorinated silicone elastomer base instead, to prevent degrading with contact to the above-mentioned chemicals or environmental factors. Fluorosilicone products are also made conductive by putting a conductive filler in the material, often silver, aluminum, copper, or nickel. Gaskets made with fluorosilicone have a strong resistance to the hydrocarbons found in many of the harsher environmental conditions.
Like silicone above, this material is commonly used in PCB applications, and is selected when a more chemically resistant material is required. If you are concerned that the gasket material will come into contact with acetones or detergents that may erode the material, fluorosilicone is the right fit. As such, it is also typically more expensive than silicone.
This material is best fit in areas where very low compression forces are required. It is most commonly used for servers and in cabinets where electronics are slotted in layers on top of each other. It is generally less expensive than other EMI materials.
Dense rubber and foam based absorbers that are resistant to UV, ozone, extreme temperatures and flame. Typically these materials are thin, magnetically loaded sheet stock, having high loss at microwave frequencies, while maintaining the desirable characteristics of elastomeric binders. These materials are designed to help lower Q Factor in cavities and attenuate cavity oscillations.
These materials are technically not EMI materials themselves, but are often used in EMI applications. Instead, their job is to absorb frequencies emitted by electronic components, rather than “bouncing” them back like EMI materials.
Thermal interface materials are used to dissipate heat in a part. The type of material you need will be based on the amount of power being output over a specific timeframe. From there you can select the right conductivity of the material to dissipate the required heat. The more heat you need to dissipate, the more expensive the material, so you’ll be looking to find the material that dissipates just the amount you need, and no more, to avoid excess cost.
This group of materials is typically used for custom gasket production for chips or PCB applications. You’ll want to use it where pieces of the housing mate and you have a gap that needs to be filled. Silicone is generally selected when there is a large gap here. The idea is that the gasket will transfer the heat to your aluminum metal housing which will then dissipate the heat.
This class of materials offers the same benefits as Silicone gap fillers above, but has added properties that prevent outgassing. These acrylic pads have no siloxane VOC or oil bleeding, which are associated with silicone products and can often cause device failure. Silicone outgassing can cause contamination which may be a problem, particularly for hard drives in electronic applications. Acrylic Gap fillers would be best fit in these cases, as they don’t have any issues with outgassing.
Sil-Pad materials (named for silicone pads) are used in applications where you’d choose a silicone gap filler but the gap is very thin. The pads offer the ability to fit into much smaller gaps, but offer the same material benefits.
Thermal tapes are best fit when you need to create a structural bond with your custom gasket. If you have two sides of a part that need to be stuck together and you want to dissipate heat, thermal tape is the way to go. These materials are commonly used to bond a heatsink to circuit boards and in electronic commodity production.
Unlike pre-formed gap filling materials, Thermal Pastes or Gels offer infinite thickness options and eliminate the need for specific pad thicknesses or die-cut shapes for individual applications.
Thermal pastes can be used in the place of gap fillers when very low compression forces are required. They will create virtually zero stress on components during the assembly process. There is definitely a give and take with this class of materials as they are very messy. Your application must be able to tolerate this, and you have to be ready to immediately assemble the rest of the part before the paste dries. This material is typically used as a cost-effective option in high volume applications where precision isn’t overly important.
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