Nov. 11, 2024
The following recommendations indicate the most suitable conditions for storing elastomeric items, whether as a single item or composite product.
Storage temperatures should not exceed 50°C. Low temperatures are not permanently harmful provided the rubber items are handled carefully and not distorted. When taken from low temperatures items should be raised to approximately 30°C before they are used.
Optimum humidity is about 65% in a draft-free atmosphere.
Protection from direct sunlight and strong artificial light with a high ultraviolet content is important. Unless packed in opaque containers, it is advisable to cover windows with red or orange screens or coatings.
Elastomeric items should be protected from circulating air wherever possible. As ozone is particularly harmful to rubber, storage rooms should be free from equipment that may give rise to electric sparks or discharge. Wrapping, storage in airtight containers or other suitable means should be used for vulcanised rubber items.
Where possible, rubber items should be stored in a relaxed position, free from tension or compression. Laying the item flat and avoiding suspension or crushing keeps it free from strain and minimises deformation.
Contact with liquids and semi-solid materials, particularly solvents, such as oils or greases should be avoided unless so packed by the manufacturer.
Metals such as manganese, iron and copper, or copper alloys can have a harmful effect on rubber. A layer of paper, polyethylene or cellophane will keep these separated.
Contact with other rubbers or creosotes should be avoided.
Elastomers should be stored for as short a period as possible, and strict stock rotation should be practised.
Organic solvents such as trichloroethylene, carbon tetrachloride and petroleum are the most harmful agents. Soap and water and methylated spirits are the least harmful, and all parts should be dried at room temperature before use.
The table shows the storage life of seal components made from the more common materials under ideal conditions. Storing under less than ideal conditions will reduce the life.
Base polymerCareful inspection of the following should be made before installation after storage:
a. Mechanical damage
b. Permanent distortion
c. Cracks or surface crazing
d. Tackiness or surface softening/hardening
Thin components (less than 1.6mm {1/16in}) tend to be more critically affected.
The appearance of ‘bloom’ is relatively unimportant, except in certain non-toxic applications.
The experts at Martin’s Rubber understand how difficult it can be to restore rubber, whether this is due to heavy usage, incorrect specification, or design for the application in question, or even the gradual degrading effect of weather, so PIF spoke to Martin’s Rubber about how to restore rubber products to extend their shelf-life.
“Rubber, like many organic materials, have a definite shelf-life that varies dependent on the type of rubber, and external factors that can speed up the deterioration process”, explains Claire Clarke of Martin’s Rubber. Over time rubber parts deteriorate, until this eventually leads to the total failure of the rubber part which can, in turn, lead to potentially catastrophic consequences.
“Depending on the environment, this could mean a minor inconvenience, or become a seriously catastrophic event”, claims Claire.
Martin’s Rubber recommends rubber restoring techniques that, when used in conjunction with proper maintenance, can bring your rubber products from the brink of failure and be restored to full functionality.
“You can’t do a good job without the right tools! When restoring rubber seals, you can often get very good results by using a combination of easy to find household items - alongside a few specialist products”, says Claire. She goes on to explain that dependent on the extent of the restoration, you will need some or all of these:
Claire from Martin’s Rubber explains a step-by-step process on how to restore your rubber products.
First things first, clear off any debris from the item you want to restore, including any paraffin wax that may have leached out of the rubber, using the rubber solvent.
Next, it’s a good idea to give the rubber seal a really good scrub to clean off excess dirt and prevent future wear and tear. For a lighter level of dirt, use warm water and mild soap. For heavier levels of dirt, mould or mildew, use the diluted bleach mix.
Using a different cloth to the one used earlier, rub the rubber conditioner thoroughly into the seal. Once it has been worked in and the rubber is completely saturated, wipe off the excess.
Removing too much of the rubber seal will render it completely useless! But if the rubber seal isn’t heavily damaged, with just a few scuffs and minimal damage, it would be beneficial to use a file or abrasive emery cloth to generally buff off the damaged areas of rubber. Once you’ve removed the damaged sections, reapply the rubber conditioner for additional protection.
“If you only need to restore smaller, lightly weathered rubber seals, boil some water in the saucepan, add a small amount of soap and submerge the seal”, suggests Claire. She goes on to explain, “remove the seal using tongs and test its flexibility and condition every 5 minutes or so.” Using this method, the time taken to restore rubber can vary depending on the item, but it can be just as effective and much less labour intensive than the previous method.
Martin’s Rubber are experts at rubber manufacture, maintenance and development. Their hands-on technical expertise and flexibility at all stages of development, testing and manufacture ensure that Martin’s Rubber can consistently meet and exceed customer expectations. For more information, head over to their website.
Perhaps the most famous O-ring failure in history is that of the Challenger space shuttle, which ended the lives of seven NASA astronauts in January 1986. In the shuttle’s right rocket booster, a seal failed at the aft field joint that led to the spacecraft exploding. It was later found that the O-ring didn’t have the capability to perform correctly at lower temperatures, so it failed to seal fully.
Investigators theorized that cold temperatures at launch time and frozen water within the rocket motor’s joints resulted in O-rings that didn’t return to their correct shapes before launch. This O-ring failure resulted in the joint along the right rocket booster failing as heated; combustible gases caused blow-by and erosion. The resulting domino effect led to the Challenger’s explosion 28 seconds after launch.
While O-ring failures don’t normally result in loss of life, their failure can often damage machinery and cause production delays. Knowing how to improve an O-ring seal will also make an application safer for everyone involved. For those dealing with machinery or equipment that relies on O-rings to operate properly, it’s important to understand what makes them seal so they won’t fail unexpectedly.
Before learning how to make an O-ring seal better, it’s important to understand why seals fail in the first place. Generally, seals stop working because they fail or wear out. Often preventative maintenance programs that utilize regular inspections will prevent failures by replacing old seals before they completely wear out and fail. However, sometimes seals fail for reasons other than natural wear and tear.
The primary culprit for seal failure is human error emanating from using the wrong seal for the application, as is what evidently happened to the Challenger space shuttle. This is especially true for seals used to join components. That’s why it’s always important to use seals intended for use with a specific component. However, many other things can cause seal failure. Understanding the symptoms and what to look for can help those tasked with correcting such problems.
The more common types of seal failure, along with ways to fix or prevent them, include:
Abrasion: Signs of abrasion include scrapes or loose particles on the surface of the seal. While this could result from high temperatures, poor surface finish, or a rough sealing surface, these also indicate abrasive particles. To fix or prevent:
Chemical degradation: When material becomes discolored, blisters or cracks prior to a seal failure, it’s likely due to chemicals degrading the material. The seal’s physical properties may also be seen to degrade. To fix or prevent:
Contamination: Foreign material on the seal’s surface cross-section indicates some type of contamination. This may result from conditions within the facility or degradation due to a chemical reaction. To fix or prevent:
Excess compression: Signs include a compressed seal occurring within a mated surface area, though alternatively, this could result from an improperly cured elastomer within the installed equipment or high temperatures. To fix or prevent:
Extrusion: When a seal’s edges become ragged or tattered along the low-pressure side, this is a warning of imminent failure. Though eroded gland edges, excessive clearances, high pressures, low modulus, too much elasticity, wrongly sized seal,s or other reasons could be the cause, it’s usually due to extrusion. To fix or prevent:
Heat degradation: When a seal shows radial cracks or its surface material becomes shiny and softens, the seal’s elastomers are likely not compatible with the system’s thermal requirements. To fix or prevent:
Improper installation: Damage occurring due to improperly installing a seal, or using the wrong type or size, can lead to seal failure. Indications like cuts, gashes or nicks on seal parts are indicative of this issue. To fix or prevent:
Over-compression: When the surface of a seal develops circumferential splits with compressed surfaces, or if it becomes completely flattened, it’s likely to fail. Though this could result from improper design, environmental chemicals, changes in thermal volume or the selected seal doesn’t have properties necessary to withstand the compression, the problem is likelier due to over-compression. To fix or prevent:
Now that we understand some common reasons why a seal might fail, let’s look at how to improve an O-ring seal.
O-rings are used in various industries, including aerospace, agriculture, plumbing, and transportation, to name but a few. These common ring-shaped seals fit into couplings, engines, pipes, pumps, shafts, and valves in various mechanical equipment. They’re used to prevent fuel, lubricants, oils, refrigerants, steam, water, and other liquids or gases from escaping. Understanding how to make an O-ring seal better starts with the installation process and, when done correctly, saves businesses time and money on maintenance and repair.
Many seal failures result from improper O-ring installation. To function properly, they must be free of foreign material and fitted correctly without forcing, while lubrication and added tape covering help extend the O-ring’s life. Correctly installed O-rings prevent leaks and lengthen the life of other components, whereas when poorly installed, they lead to damaged equipment and downtime, as well as additional maintenance and repair. To properly install an O-ring and ensure its proper functioning, a few guidelines should be followed.
Guidelines for how to make an O-ring seal better:
As per many of these guidelines, lubrication is particularly useful in improving O-rings seal.
To properly function, O-rings must be lubricated. Not only will lubrication help the seal last longer, but it will also prevent breakdowns of machinery, motors, engines, or other devices the seal is meant to protect should it fail. Applying oil or grease will protect the O-ring from damage when used. Lubricants also protect components by minimizing friction, providing water resistance, or preventing environmental degradation. Lubricating O-rings also reduces the chance of leaking seals in vacuum or pneumatic applications.
There are three main methods for lubricating an O-ring:
Various lubricants can be used when installing O-rings, with solvents, soap, water, polymers, petroleum distillates, and ester-based synthetic oils being the most commonly used. Some of these lubricants have led to concerns regarding safety and health, however, while certain lubricants can also damage rubber O-rings. Solvents contain volatile organic compounds (VOCs) that pose risks to human health while also posing a fire risk. Though soap and water are safer, their lubricating properties are inconsistent, and these solutions don’t work well in wet or damp environments. Meanwhile, any petroleum-based lubricants cause elastomeric rubbers to dry out or swell.
Since most O-rings and seals are made from synthetic rubber-like material such as ethylene propylene diene monomer (EPDM) rubber, neoprene, or nitrile, they’re best lubricated with other synthetic compounds. Ester-based and silicone-based lubricants top this list. Their properties include reducing friction, low volatility, stability in high temperatures and fluidity in lower temperatures, and waterproofing. Both synthetic lubricants are safe, posing neither risk of contamination nor health, and are also usable with products containing natural rubber.
As O-rings are used so widely, it’s important to be installed and maintained properly to function as designed. This includes ensuring they remain free of foreign substances and that they’re properly lubricated. By ensuring proper installation and maintenance, O-rings will continue to play a vital role in the operation and fabrication of appliances, aircraft, automobiles, engines, machinery, medical devices, motors, plumbing, pumps, and trucks, along with many other modern devices and equipment on which modern civilization depends.
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