O-ring seals are some of the most common seals used in machine design. They prevent the loss of fluid and gas and are incredibly inexpensive, easy to make, reliable, and have simple mounting requirements.
Although O-rings are designed to be seated in a groove and compressed between two or more parts, they vary drastically in cross-sectional shape, color, hardness (durometer), and curing method.
Every manufacturer designs its O-rings to solve a specific problem for a particular application, so you must select your O-rings based on their functionality and your requirements.
With so many brands, shapes, and sizes to choose from, it can be challenging to determine the best fit for you. Thankfully, C&B Equipment has the extensive knowledge and practical experience to ensure your O-rings are nothing short of… well, boring. Let’s face it. If your O-rings aren’t boring, then they are likely causing problems.
The following are common causes of O-ring failure. This troubleshooting guide will help you identify issues with your O-rings, explain what is causing those issues, and help you prevent similar problems in the future.
Compression set occurs when an O-ring becomes squashed into a flat-sided oval. It won’t recover after removing the stressor, and it has permanently “set” into the deformed shape. Compression set is one of the most common causes of O-ring failure.
The following are common causes of compression set.
Using an O-
ring material
with poor
compression set
properties
Embrittlement at
high temperatures
causes the O-ring to lose its elasticity and ability to return to its original shape
Volume swell
Contact with fluid incompatible with the O-
ring material
Improper gland design
Incomplete curing during production
Use an O-ring material with low compression set and high temperature resistance. Check the gland design to make sure the O-ring isn’t over-compressed. Reduce the system’s operational temperature if needed and alleviate excessive frictional heat build-up at the seal face.
Extrusion occurs when high stresses force the O-ring material into the clearance gap between the mating flanges. Pulses of high pressure cause the clearance gap to open and close, trapping the O-ring between the sharp edges. This causes physical damage called “nibbling.”
The edges of the O-ring on the low-pressure side will have a chipped, chewed, or frilly appearance. Extrusion and nibbling usually occur in dynamic applications like hydraulic rods and piston seals.
High pressure above system design and tolerances and excessive or irregular clearance gaps are common extrusion causes. The O-ring material may be too soft, or the O-ring installed too large.
Reduce machining tolerances to decrease clearance. Ensure installation of correctly sized O-rings and try a more rigid material if necessary. Use backup devices to reduce clearance gaps. In some cases of extrusion and nibbling, O-ring size and shape are the problems.
For sealing applications with unusual geometries, custom-made O-rings, such as those offered by Kalrez®, may be an appropriate solution.
Abrasion occurs when there is repetitive contact between the O-ring surface and the housing. The excessive friction wears down the sliding contact faces of the O-ring, resulting in wear lines or even deep scratches and breaks.
The surface may look dull or glazed, and one side of the O-ring will be worn flat. Abrasion is typical in dynamic applications that involve rotary, oscillating, or reciprocating motion.
Inadequate lubrication, improper surface finish on metalwork, abrasive particles in the system fluid, and excessive temperatures can cause abrasion.
Ensure adequate lubrication and the correct surface finish on metalwork. Check the system fluid for contaminants and install filters or wiper/scraper rings if needed. Consider swapping to internally lubricated O-rings or an O-ring material with higher abrasion resistance.
Explosive decompression, also referred to as gas expansion rupture, occurs when high-pressure gas becomes trapped within the internal structure of an elastomer seal.
When exposed to high-pressure gas at high temperatures for an extended time, the O-ring’s polymer compound may absorb the gas. When the system pressure drops, the trapped gas expands to match the external pressure, causing surface cracks and blisters as the gas escapes.
Small amounts of gas may have little effect on your seal’s integrity, as the blisters may recede after the pressure equalizes. However, excessive amounts of trapped gas may cause severe damage or even rupture the O-ring.
Increase time for decompression and reduce system temperature. Choose an O-ring material resistant to explosive decompression or use an O-ring with a smaller cross-sectional size.
Many chemicals will react to certain O-ring materials. Degradation occurs when the O-ring material is unable to withstand the effects of a particular chemical. Elevated temperatures, excessive stretch or compression, and mechanical stresses can accelerate chemical attacks.
A degraded O-ring may show discoloration, blistering, cracking, or a change in shape or hardness. The specific indications vary by chemical reaction.
Choosing a suitable O-ring material is key to preventing chemical degradation. For the best chemical resistance in high temperatures, the gold standard is perfluoroelastomer (FFKM) material. Kalrez® FFKM O-rings resist attack from more than 1,800 chemicals, solvents, and plasmas while offering high temperature stability.
Chemically induced swelling occurs when there is an incompatibility between an O-ring’s material and its environment. The seal absorbs the media, growing in volume to the point of malfunction. The swelling may occur across the entire O-ring or only in the places exposed to the chemical. The swollen O-ring may extrude out of the seal grooves.
The only way to prevent this problem is to use an O-ring material chemically compatible with the system environment. Consult chemical compatibility charts, and don’t hesitate to consult a sealing material expert.
Kalrez® O-rings resist extreme volume swell when exposed to steam, sodium hydroxide, concentrated nitric acid, ethylenediamine, and many other chemicals and solvents.
The leading heat-related causes of seal failure, hardening, and embrittlement occur when the application temperature exceeds the maximum temperature rating of the seal material. It can also occur due to excessive temperature cycling. The seal material hardens, and oxidation causes the seal to crack.
The surface of a heat-degraded O-ring may appear pitted or cracked, especially on the areas with the most exposure. This problem often occurs in conjunction with compression set due to a loss of elasticity, so the ring may appear flat.
Use an elastomer O-ring with high temperature resistance. Kalrez® FFKM o-rings deliver outstanding high temperature stability. Even after long-term exposure to temperatures up to 327°C, Kalrez® FFKM o-rings retain elasticity and recovery properties better than other high-temperature elastomers.
C&B Equipment is proud to be a licensed distributor of Kalrez parts®. The superior performance of these seals helps you increase your uptime. Our goal is to eliminate your business’s downtime through top-of-the-line products and services. That goal is what we refer to as Uptime Solutioneering™.
Rubber o-rings are a common sealing device that hold a lot of responsibility. From automotive and hydraulics to aerospace and medical, o-rings serve as trusted sealing solutions for a variety of industries.
While these rubber devices play a crucial role in many important applications, they are not immune to failure. O-Rings can fail for many different reasons, but it’s usually caused by a combination of adverse effects and environmental factors. While unexpected failure can cause catastrophic damages to other parts and applications, there are preventative measures to be taken to lessen the chance of o-ring failure down the line. Here are the most common causes of o-ring failure and how to solve them.
Every o-ring seal has a specific amount of squeeze, or compression, that it can undergo before excessive deformation occurs. When an o-ring is exposed to high temperatures, swell, overly high compression or other major stresses, it can lose its elasticity and become unable to return to its original shape. This will cause the o-ring to develop flat surfaces on both sides of the cross-section, making it unable to properly seal.
Solution: Select an elastomer with a low compression set and reduce o-ring squeeze when possible. It’s also important to assure that the sealing material is compatible with the temperatures it’s exposed to and any other environmental conditions that may impact the sealing capabilities.
Abrasion is a common cause of o-ring failure that is typically seen in dynamic seals. When excessive friction between an o-ring and another surface is present, the o-ring will begin to wear down until eventually tearing. It’s common for metal surfaces to be too rough and act as an abrasive. Conversely, metal surfaces can also be too smooth, which leads to inadequate lubrication.
Lubrication plays a big role in sealing success. Lack of lubrication in the presence of friction can also lead to seal failure.
Solution: Always make sure there is enough lubrication present during any sealing application. During the o-ring design process, material selection is extremely important. Materials should be durable enough to handle any natural friction or the presence of abrasive materials in their application.
O-Rings act as a sponge that absorbs the surrounding fluid. However, when a sealing material is not compatible with the chemicals it absorbs or can’t handle the amount of humidity present, o-rings will begin to excessively swell. Chemical swell can lead to the loss of physical properties such as tensile, gland fill, extrusion and the complete loss of sealing strength.
Solution: During the material selection process, make sure that your sealing material is compatible with the chemicals it will be in contact with. Visit Apple Rubber’s Chemical Compatibility Guide to map out what each sealing material is compatible with.
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The Most Common Causes of O-Ring Failure and How to Solve Them
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