Things You Need To Know About Rubber Shrinkage

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One of the key factors in successful equipment design is the calculation of O ring squeeze. The amount the O ring will be squeezed by the surrounding hardware can have a bearing on the material selection, design and other key characteristics.

What exactly is O ring squeeze?

O ring squeeze is the amount that the ring will deform when pressure is applied. O rings only work as seals because of deformation, as they ‘flow’ to fill the gland, blocking any leakage from the assembly.

Virtually every gland has a tiny gap between the two mating surfaces, called a diametrical gap. This means that the O ring needs to be larger, in terms of cross sectional height, than the height of the gland. When the O ring is squeezed, it expands into the gap and forms a complete seal.

How much squeeze is enough?

To get the right amount of squeeze for the best seal, consideration has to be given to both the size of the O ring itself and the type of application being used. In a dynamic application, a lower squeeze is preferred as it will reduce friction and therefore wear on the seal.

With little or no squeeze applied, the natural elastometric characteristics of the O ring will prevent liquids from passing through. However, in situations where gasses need to be confined, a greater amount of squeeze is required to prevent passage through the hardware.

Increasing squeeze will tighten the seal, but should you always specify a high level of squeeze?

Is more better?

Some might say that the more an O ring is squeezed, the tighter the resultant seal will be. The greater the squeeze, the greater the force between the O ring and the mating hardware. This increase in force will do an even better job of preventing liquids, gasses and powders from escaping the seal. Or will it?

While a strong squeeze is desirable for a good seal, it’s not always a case of more is better. The more forcefully an O ring needs to be squeezed at installation, the higher the risk of creating a pinch, and therefore a pathway for leaks. Squeezing forces rise exponentially, so an increase in squeeze on the O ring could, in fact, lead to excessive stresses on the hardware and, potentially, to damage.

Higher squeeze also comes with a risk of greater friction and therefore faster wear. In short, squeeze is not something to be maximised, rather something that needs to be optimised.

Conclusion

There’s no hard and fast rule for the amount of squeeze you need in our O ring. In very general terms, a squeeze percentage of 13 – 27% is typical for hydraulic operations, and 10 – 24% for pneumatic.

However, these figures can change based on the materials in use and other factors such as temperature and environmental influences. If you’re unsure, the best option is to seek expert advice. Our team are always on hand to help; just get in touch to find out more.

MQ, VMQ, PMQ, FVMQ… What Does It All Mean?

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The world of silicone rubber is full of confusing acronyms. To an outsider, the names of some compounds can seem like a foreign language, potentially leading to confusion and misinterpretation. However, there are standardised names for the materials we use, as defined by the ISO. As such, it’s key that you’re familiar with these names and the properties of such materials in order to use the right variant for the job.

What types of silicone are there?

Silicone is widely used in a variety of industries, from food and medical to aerospace and more. It has amazing flexibility, low toxicity and excellent resistance to UV, oxygen, ozone and microbial growth.

For O ring materials, silicone has one of the greatest ranges of operating temperatures available. Standard silicone O rings are capable of handling temperatures from -60°C to 230°C, whereas specialist compounds can be made to reach as low as -100°C and as high as +300°C.

We’re going to look at four of these compounds in more detail today. Specifically, we’ll consider MQ, VMQ, PMQ and FVMQ to see what they are and what benefits they can bring to components.

MQ silicone

To give it its full name, this is methyl silicone, and is the simplest form of silicone compound . At a molecular level, it contains repeating units of oxygen, which gives it excellent resistance to ozone, as well as UV and general damage from weathering.

We don’t often use this type of silicone in this format, as it doesn’t have the best elastomeric properties. However, it is sometimes used as a base and them processed to improve performance.

VMQ silicone

This silicone is vinyl methyl silicone. It is produced by processing MQ silicone into a format where the methyl groups of molecules are replaced with vinyl ones. The resulting material has an impressive temperature range and better compression set than MQ. However, its poor tensile strength means it’s not suitable for some O ring fabrication.

PVMQ silicone

Also known as PVMQ, this is phenyl methyl silicone. With this compound, the methyl groups are replaced with phenyl groups, which dramatically improves the low operating temperatures of the material. In fact, PMQ silicones have almost a 100°C lower operating temperature than the equivalent MQ silicone, with a working temperature of -100°C.

FVMQ silicone

The final type has a more easily understood name: fluorosilicone. As with other fluorinated elastomers (FKM, FFKM etc.), adding fluorine at the molecular level results in stronger bonds. Stronger bonds mean fewer chemical reactions can take place, leaving us with a silicone with vastly better chemical resistance. Other properties of FVMQ silicone are similar to those seen in VMQ, although its hot air resistance is lower.

Clear as mud?

If you still feel confused about the types of silicone available for use, we’re here to help. Our friendly team are just a phone call away and can give you bespoke advice on the right material selection for your needs. Get in touch to find out more.

Choose Silicone: Five Situations Where This Is Your Perfect Material

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Silicone is one of the best multipurpose polymers out there. Its widespread use, not just in the sealing industry, is testament to the amazing properties of this material. The molecular make up of silicone, with a backbone of alternating silicone and oxygen atoms, gives it some unique characteristics that make it a top choice for certain applications.

Here are just five examples of situations where silicone is a top choice of material for you.

  1. If you’re using it outdoors

Silicone is amazingly resistant to ozone, UV and weather, all key considerations if your assembly is going to be open to the elements. Although exposure to these factors can be mitigated to some degree in a lab, out in the open, there’s not much you can do.

Outdoor seals andgaskets which are exposed to sunlight can reach internal temperatures of as high as 60°C. At the opposite end of the spectrum, they can also experience freezing temperatures in the winter. In addition to this, UV and ozone can cause cracking and degradation in materials susceptible to them.

The high energy siloxane bonds in silicone means it maintains integrity in a range of challenging conditions. It’s one of the most weather resistant polymers available, and a great choice for use outdoors.

  1. If it’s going to get very, very hot

Silicone has one of the widest temperature ranges of any material, making it a top choice for applications involving extremes of heat. Normal silicone’s operating temperature can go as high as +230°C. However, specialist types of silicone can be manufactured to withstand even higher temperatures, as much as +300°C.

  1. If it’s going to get very, very cold

Standard silicone maintains integrity down to temperatures as low as -84°C. However, specialist compounds such as phenyl methyl silicone (PMQ) have been developed to perform even better. PMQ has a working temperature range which goes as low as -100°C although, again, prolonged exposure is not recommended.

  1. Where cost is a consideration

Although not the cheapest material out there, silicone is far from being an expensive choice. What you get in terms of heat resistance and other characteristics offers excellent value for money in comparison with other, similar performing compounds.

  1. In static applications

When we’re considering what silicone is good for, it’s a good idea to think about what it’s not good for too. Silicone, by its nature, has poor resistance to tears and abrasions. It also has weaker tensile strength, which means it sill suit some applications better than others.

Notably, it is more suited to static applications, rather than dynamic ones, where there are no moving parts and it won’t need to stretch or compress to extremes.

There are, of course, many other places where silicone is a great choice of elastomer. It’s odourless, tasteless nature and resistance to microbial growth make it a popular material for use in the pharma and food industries, to name just a few.

If you’d like to find out more about silicone and whether it’s right for your project, talk to NES for expert advice.

5 Tips From The Pros For Perfect Installation of Seals

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Having a precision manufactured seal produced for your application is the first step to getting a reliable, competent part. However, faults which occur in the fitting of such seals could lead to failure, regardless of the quality of the seal itself.

For perfect installation of your seals every time, here are five tips from our experts to help you get it right.

  1. Clean the seal and installation tools

Working in a clean environment can help you give your seal the best chance of a reliable, long life. Dust and particulate that becomes trapped in the joint at the time of installation will affect performance massively. Ensure the seal itself is clean and clear of debris, using a lint free cloth to clean it. Ensure all tools being used in the installation and cleaned thoroughly too.

  1. Protect it from sharp edges

Being damaged during installation could lead to seal failure, so check the assembly for any sharp edges or imperfections. Remove any grease and grime from the surface too, again using a lint free cloth to do the job.

  1. Lubricate the seal and the sealing path

The majority of seals need to be fully lubricated prior to installation. There are a range of lubricants available, from petroleum based products to fluorocarbon fluid. The right lubricant for your seal will depend on the elastomer used for the seal itself. Talk to your expert at NES if you’re unsure what to use.

  1. Warm up the seal

Heating the seal slightly will improve elasticity and make installation much easier. This can be done by soaking the seal in warm lubricant but be sure to stay within the temperature tolerances for that material. Never put a seal in a microwave to warm it; just a few seconds can overheat an elastomer. Don’t heat it in a stretched state, as this could cause crosslinking and misshape the seal permanently. Once warm, don’t overstretch the seal while you are installing it.

  1. Use the right tools

Attempting to install a precision seal with the wrong tools can cause dents and damage to the seal itself. Any imperfections in the seal at this stage will be exacerbated once it’s under pressure, increasingly the risk of early seal failure. Use the appropriate tools for the job and take your time over installation to protect the seal’s integrity.

For more help on seal installation, as well as advice on custom made seals for your business, talk to the experts here at NES.

Chemical Degradation: What You Need To Know

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Rubber seals such as O rings are developed and manufactured to last. We can select materials for optimal performance for the environment they’re going to be in, such as heat resistance or chemical compatibility. However, as all polymers are unique in their make up and structure, using the right material for the application is crucial.

Understanding what can cause chemical degradation, and how different materials react to certain chemicals, can avoid costly failures later down the line. Here’s what you need to know about chemicals and their effects on your rubber components and seals.

What causes chemical degradation?

Some chemicals will react with certain elastomers, if those materials are not resistant enough to the chemicals they are exposed to. This can cause a range of problems, from an increase in cross link density, leading to a hard, brittle seal, to chain scission, resulting in reduced strength.

In some situations, the chemical or elements of it can actually ingress into the seal itself. This is often caused by the chemical being too similar to the material used in the elastomer, effectively allowing the media to be soaked up by the seal.

Having the wrong type of seal for the job increases the risk of a chemical attack, and it’s not just a failed seal you may have to deal with. Seal failure and associated chemical ingress into other parts of the assembly, may lead to direct loss or damage to expensive machinery, not to mention process downtime within the operation.

How to know if your O ring has suffered a chemical attack

The first way to identify chemical degradation in O rings is to take a visual appraisal of the component. There are several tell tale symptoms of a chemical attack, including:

  • Cracking and / or blistering
  • A change in hardness
  • Discolouration
  • Swelling, either localised or across the whole seal

Some of these symptoms can be caused by other issues, so it’s important to eliminate these or confirm chemical presence as soon as possible.

How to prevent a chemical attack

Choosing the right elastomer for the job is key to preventing any further chemical attack. Switch to an elastomer with proven resistance against the chemicals you know to be present in the environment.

Chemical attack is accelerated in elevated temperatures and when the seal is stressed, for example when its been stretched or squeezed excessively. This means that a material which, at first, seemed compatible suddenly becomes incompatible due to the forces it is placed under.

The best way to prevent chemical attack is to consult with an expert when making your material choice. To be sure that you’re getting the right elastomer for the job, chemical compatibility testing can be undertaken to help with your selection process.

Which elastomers offer the best chemical resistance?

The resistance of elastomers depends on the type of chemicals they will be coming into contact with. For example, if you’re using acetaldehyde in your operations, silicone and EPDM offer excellent resistance, whereas fluorocarbon, FFKM and polyurethane will fail. Nitrile and fluorocarbon would be a good choice for calcium bisulfide, whereas EPDM and natural rubber would not.

For help selecting the right type of material for your application, talk to our team.

What is Viton? A Guide To Viton O Rings

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Used in some of the harshest environments, where temperature extremes and chemical interactions are common, Viton™ rubber is one of the most hard wearing fluoroelastomers in the world. It’s high performance and excellent durability make it a top choice for many specialist applications.

If you’re looking for an impressively versatile material for difficult applications, you might be wondering ‘what is Viton™ and how can it help my business?’. We’re pleased to enlighten you with our complete guide.

What is Viton™?

Viton™ is a fluoropolymer elastomer and synthetic rubber compound, trademarked by DuPont under this brand name. It’s a fluorinated hydrocarbon rubber product with amazing capabilities, developed to withstand even the most challenging of environments.

In much the same way as Hoover has become synonymous with vacuum cleaners, so Viton™ has become the standard name for this type of material. However, there are differences within the Viton™ family which will affect their suitability for your application.

The standard grade for Viton™ is A grade, which has 66 percent fluorine content and is most commonly used in o rings and seals. Viton™ B offers better fluid resistance and Viton™ F is particularly good for resistance to fuel permeation. High performance grades are also available but do discuss with us if you’re not sure what you need.

Why use Viton™?

A Viton™ o ring will tend to be significantly more expensive than the equivalent nitrile component. This is because it simply does the job where other products cannot. In comparison to nitrile, Viton™ has a larger operating temperature range, better resistance to degradation from exposure to weather and ozone and is more chemically resistant too.

Choosing a Viton™ o ring for the toughest jobs means it will last longer. This means that you can enjoy extended service intervals, reducing maintenance costs and providing a more reliable seal. There is far less likelihood of unscheduled down time due to o ring failure, so your investment in a Viton™ product will pay back through better operational efficiency.

https://www.pinterest.co.uk/pin/290552613455600432/

What is Viton™ good for?

Viton™ seals are an ideal choice in any environment where there are challenging factors to contend with. For example:

  • High temperatures: A Viton™ o ring will withstand temperatures from -20°C up to 210°C
  • Chemicals: Viton™ can withstand a range of chemicals, including oils, acids, silicone fluids and gasses as well as halogenated and aromatic hydrocarbons
  • Environmental challenges: Viton™ can maintain a seal even in the presence of oxidation, UV exposure, weather, ozone, fungus and mould

So, what is Viton™ good for? Well, Viton™ is frequently used in appliance processing, automotive and chemical industries. We also supply Viton™ products to aerospace companies, oil and gas exploration industries and petroleum refining and transportation businesses.

Viton is often used in automotive industries    https://www.pinterest.co.uk/pin/290552613455600446

Is Fluoroelastomer the same as Viton™?

When you’re thinking about what is Viton™ exactly, you can classify it as one of the many fluoroelastomers out there. It’s a trade name for a fluoroelastomers produced by DuPont, so yes, it is the same thing. Other brand names for fluoroelastomers include FKM and FPM.

What is the difference between Viton™ and EPDM?

The main difference between Viton™ and EPDM is the chemical resistance they exhibit. EPDM is a good product for use in steam environments and has a relatively good chemical resistance, but nowhere near as good as Viton™. EPDM should never be used with solvents or petroleum agents.

What is Viton™ seal?

A Viton™ seal is simply a seal manufactured from Viton™. These seals or gaskets are commonly used to seal leaks, valves, pumps and similar. Viton™ o rings are the most common type of seal, which we provide here at NES in a variety of sizes and profiles.

For more advice on Viton™ or any of our other products, get in touch with the experts at NES today.

What Are The Uses of Teflon?

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Anyone who has grown up in the modern age has probably heard of Teflon™. Used in a variety of situations, from cooking to clothing, manufacturing to manicures, the amazing substance that we know as Teflon™ has proven itself to be an incredible addition to our modern lifestyles.

But have you ever considered what are the uses of Teflon™, and why is it such an incredible discovery? Let’s investigate.

What is Teflon?

Discovered by Roy. J. Plunkett in 1938, Teflon™ was identified almost by accident. While researching new refrigerants, Plunkett discovered an unusual by product which was exceedingly slippery and immune to many of the usual degrading factors.

Upon isolating this substance, Plunkett was attributed as the discoverer of Teflon™, a product used widely in numerous modern applications. What he had actually discovered was polytetrafluoroethylene, or PTFE, which is marketed by DuPont under the trade name Teflon™.

What are the uses of Teflon™?

So, you probably know of Teflon™ as a non-stick covering. It’s certainly put to good use in cookware, providing a non-stick surface for pans and pots worldwide. However, there are undoubtedly plenty of other places where you’ve come into contact with Teflon™, perhaps without even knowing it. For example:

  • Nail polish: Teflon™ provides a smooth, crack free surface in many nail polishes
  • Hair styling: Straighteners and curling irons are often coated in Teflon™
  • Carpet protection: Is your carpet ‘stain resistant’? It’s probably infused with Teflon™
  • Waterproof jackets: Do you own a Gore-Tex jacket? If so, you’re wearing Teflon™
  • Paint and metal finishing: That nice shiny finish on your car paint? It’s probably Teflon™
  • Solar panels: If your solar panels are classed as ‘self-cleaning’, that’s probably because they are coated in Teflon™ to let the rain wash the dirt away

Of course, there are many more examples of Teflon™ in practice, from door locking parts to drills, machinery and much more. Anywhere where you need to ensure a non-abrasive connection between two parts can benefit highly from the application of Teflon™.

Uses of Teflon™ coating

The most versatile element of Teflon™ is the fact it can be used to coat pretty much anything, without damaging the integrity or shape of the item it is being used to coat. When we’re thinking about what the uses of Teflon™ are, it’s important to realise that Teflon™ can be used as a coating on any other material you can imagine.

For example, Teflon™ can be used to coat dental fillings, to prevent them from sticking to adjacent teeth. It can also be used as a coating for pipes, to stop the metal from reacting to corrosive chemicals passing through them. It also makes an amazing lubricant where having wet oil present is just not practical.

It would be impossible to list all the places where you’ll come across this product, so when you’re considering what are the uses of Teflon™, it’s almost easier to think of where it is not used!

From food processing to automotive manufacturing, from your kitchen to your clothing, we rely on Teflon™ in so many ways it’s almost the unsung hero of our modern age.

How Do I Measure O Rings?

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In mechanical engineering, o-rings are a staple of a safe, functional assembly. In environments where high pressures or temperature extremes are common, they are the simplest and most effective way to create a reliable seal. Understanding how o rings are measured is a key skill for anyone who is responsible for the purchase or reordering of replacement gaskets for their facility.

You may have an o ring measuring tool or o-ring measuring gauge about your business, which is great. However, you still need to acquire the knowledge of how are o rings measured in order to accurately use these tools. Here’s what you need to know about getting the measurements of your o-ring right first time, every time.

Why do o-rings require accurate sizing?

Our o-rings are often used in sensitive environments, where pressures are extremely high or low, where temperatures are very high or low, or where chemicals or other dangerous liquids are in use. Failing to measure an o-ring correctly could result in a poor seal being made, risking failure and leaks within the system.

If you’re assembling an apparatus or machine for the first time, having the correct size and material of o-ring is crucial. Over time, your o-ring may start to wear or degrade, requiring replacement which, again, means knowing how are o rings measured in order to obtain the correct part. Having a poor fitting o-ring will decrease the lifespan of your seal and risks it failing unexpectedly.

How are o rings measured?

Here in the UK, o-rings are manufactured to specific sizes as specified by a British Standard (BS). Many rings will have a related BS number, which relates to the inside diameter, outside diameter and the thickness of the ring. These measurements can be taken in either inches or millimetres, although inches are the more common method used by o ring measuring tool products.

To measure your o-ring, follow these simple steps:

  • Using a ruler, measure the distance between the outer edges, which will give you the outside diameter (OD)
  • Using the ruler again, measure the distance across the inside of the ring, which will give you the inside diameter (ID)
  • If you have a Vernier calliper, you can use this to measure the thickness of your o-ring. Place the gasket between the jaws of the calliper to take this measurement, but be careful not to compress the material at all otherwise you’ll get an inaccurate result

If the o-ring has been cut or damaged, or is not a solid ring, you can calculate the inside diameter using the thickness of the cross section (CS) measurement and the length (L) of the ring as follows:

  • ID = circumference – CS
  • Circumference = L / 3.142
  • OD = ID + 2CS

Using these formulae, you should be able to find all the measurements you require in order to procure the correct replacement o-ring for your needs.

Using an o ring measuring tool

There are a number of tools out there to help you measure an o ring correctly. The two main types are the o-ring measuring gauge and the cone type o ring measuring tool. Here’s how to use them:

  • The o-ring measuring gauge

This is a sliding tool with silhouettes of o-rings down its length. For smaller o-ring sizes, you simply match them up to one of the silhouettes on the body of the gauge. For o-rings of larger sizes, you can simply place them around the spindles at the top of the gauge and then extend the slider until the ring is taut. These measuring gauges can be found in both BS and AS (American Standard) configurations, and with both metric and imperial scales.

  • The o-ring cone

These measuring cones have two measuring functions which aim to determine the thickness (CS) and the internal diameter. Around the bottom of the cone, slots will help you determine the CS of your o-ring by checking which one it fits in best. Once you’ve done that, you place the o-ring on the cone and see where it settles to determine the size.

Both of these products are relatively expensive for what they do and are probably an unnecessary investment unless you’re in the habit of measuring o-rings regularly. A Vernier calliper can be bought for a fraction of the cost and is useful in other elements of mechanical engineering too, for example when measuring the thickness of sheet metal, or the finer details of products.

If you are still not confident as to how an o-ring is measured, we’re here to help. You are welcome to send in your o-ring for measurement by our experts, or to contact us for help and advice on any of our products and their specifications. Getting the size of your o-ring right is crucially important, so don’t leave it to chance.

NES suggest that only o rings that have not being fitted into application are measured this way due to compressive force, temperature and groove dimensions. For further help on measuring o rings, please contact our technical team today.

Where and Why Are O Rings Used?

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You’ve probably come across numerous o-rings in your lifetime, whether you knew it or not. From cars to cameras, these little doughnut shaped parts are instantly forgettable but endlessly useful. They are probably one of the biggest revolutions in mechanical engineering to date, allowing us to develop new machinery, better products and safer working environments. So, what are o rings used for, and why are they so popular? Let’s find out.

Why are o rings used?

O rings have some amazing properties which makes them a crucial component of many precision engineered devices. Their natural propensity to return to their original shape when the cross section has pressure exerted on it means they are one of the most economical and reliable methods of making a strong seal possible.

The other reason o rings are so commonly used is down to the wide range of materials they can be made from. The majority of o rings are made from elastomers, which are a type of elastic polymer, but there are a huge variety of these elastomers available, each with different strengths, weaknesses and tolerances. The application that the o ring is destined for will determine which type of material is most suitable, for example:

  • High and low temperatures: Silicone and fluorosilicone can cope with temperatures as low as -100°C. Cryogenic operations will require a seal that can cope with low temperatures such as the NES Astra Seal®. For very high temperatures, FFKM works at up to 316°C
  • Chemical compatibility: Viton™, also known as FKM/FPM, o rings are resistant to many chemicals and work at high temperatures too
  • Hot water and steam: Ethylene propylene o rings (EPDM) are resistant to steam and hot water, as well as to alcohol, strong alkalis and fluids found in automotive applications
  • Grease and hydraulic fluids: Buna-N o rings, also known as nitrile o rings, are best to use where there is a lot of grease or hydraulic fluid around

As you can see, for pretty much any application you can think of, there will be an o ring which can handle that environment. This means they are useful in a huge range of applications, from appliances found around the home to gigantic machines used in manufacturing and even in the space shuttle!

What are o rings used for?

O rings are used to block a path which may otherwise allow a liquid or a gas to escape. The o ring is placed into a groove to secure them in place, and then compressed between two surfaces. By squeezing the o ring, there is no more clearance for it to move and it blocks the pathway of the liquid or gas you are trying to seal in place.

When the system comes under pressure, the o ring is squeezed against the opposite wall of the groove, maintaining a perfect seal even under very high or low pressures. The materials that o rings are made from (elastomers) are naturally springy and have a desire to return to their original shape, so when the pressure ceases, they spring back to their original position, maintaining a seal and readiness for the next cycle.

In a nutshell and to answer the question of what are o rings used for, they are used to seal in a liquid or gas and are the most effective way of ensuring a robust, reliable seal.

Where might you find o rings?

Because o rings are so good at keeping liquids and gasses from moving freely around, you’ll often find them in mechanical parts and processes, particularly where extremes of temperature or pressure are at work. Some applications that are almost certainly springing to mind already could include engines, boilers, refrigerators and compressors. But o rings are also found in some rather surprising places; for example:

  • Scuba gear: O rings in scuba gear are a life saving component of the breathing apparatus. Before every dive, the diver will check the o ring in the neck of their air tank to ensure it’s going to provide a good seal and deliver air to their regulators, not sea water.
  • Dental implants: In dental implants, liquid needs to be kept out of the implant to avoid the patient suffering with pain or infection. To do this, they use a biomedical silicone o ring, which forms a perfect seal and keeps the new tooth safe.
  • Paintballing: Paintball guns use compressed air to shoot globs of paint at unsuspecting enemies. To keep the air sealed in and ensure a powerful shot, o rings are used throughout the gun.
  • Your beer: If you enjoy a pint at the pub on the way home from work (don’t we all), o rings are contributing to your enjoyment and relaxation. Without an o ring, it would not be possible to transport the beer from the casket to the tap, or to carbonate it for that lovely bubbly refreshment.

Next time you’re down the pub, you can delight your friends with stories of what are o rings used for, and all the surprising places they might come across one.

For advice on o ring uses and materials, talk to our team of experts about our range of products including encapsulated seals, hot vulcanised o rings and moulded o rings.

Viton vs Nitrile O Rings

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As two of the most commonly used elastomers, both Viton™ and nitrile o rings have some fantastic properties. Both offer excellent compression set and have a wide range of uses in industrial and domestic applications. However, not everything is equal between these two popular materials, and it’s important to know which is better for particular applications. Here, we’ll look at Viton™ vs nitrile o rings to see where each should be used, and why.

Nitrile o-rings

Also called NBR or Buna-N, nitrile o rings are probably the most economical and widely used elastomer out there. This material has a desirable set of properties including low compression set, high resistance to abrasion and good tensile strength.

  • Temperature range: Effective from -40°C to 120°C
  • Suitability: General purpose, particularly in areas where the seal will be exposed to hydrocarbons, oils, petrol, water and hydraulic fluids
  • Benefits: Excellent abrasion and tear resistance, cost effective
  • Limitations: Nitrile is not good at resisting degradation by ozone or weather

You’ll find nitrile o rings used in many applications, including where oil resistance is needed or where low temperature functionality is required. These include automotive, aircraft fuel systems, marine applications and more.

Viton™ o rings

The name Viton is a trademark, a bit like Hoover or Sellotape, and refers to fluorocarbon o rings, or FKM/FPM for short. This material has an excellent tolerance for high temperatures, resistance to oils, fuels and hydraulic fluids as well as aromatics and solvents.

Various types of FKM/FPM/Viton™ o rings are available, with varying amounts of fluorine additions which increase performance in specific situations.

  • Temperature range: From -40°C up to 250°C
  • Suitability: Good for use in high temperature situations or where chemicals are being used. As well as resisting oils, petrol and hydrocarbons, Viton™ is resistant to mineral acids, halogenated hydrocarbons and more.
  • Benefits: Resistant to the majority of chemicals, as well as to degradation by UV, weather, ozone and mould.
  • Limitations: Less tolerant of low temperatures

You’ll find FKM/FPM o rings in a huge variety of applications from aircraft engines to vehicle components, particularly where resistance to corrosive liquids and fuels is required. This material has low compression set characteristics, making it ideal for use in high temperature environments, as well as resistance to all sorts of chemicals.

Viton™ vs nitrile o rings – which is the right choice?

Viewing these two o ring materials at a glance, it’s easy to see some occasions where the decision of Viton™ vs nitrile o rings will be clear to see. For example, if you know your assembly works at more than 100°C, nitrile will not be suitable. If your assembly is likely to be exposed to the weather, to UV or to ozone, nitrile will likely degrade and risk failure.

Viton™ /FKM/FPM is superior to nitrile in almost all situations, excluding operation at sub zero temperatures.

If you’re not sure which you need in the case of Viton™ vs nitrile o rings, we’re here to help. We’ve worked alongside customers from all sorts of diverse industries to help match them up with the right o ring for their needs and can help you too. We want to make sure you get all the functionality you need, without spending more than is necessary. Talk to our experienced team today for advice and support.