6 Warning Signs That You May Be On The Path To A Poor Gasket Design

You may be wondering what a gasket material supplier is doing writing about poor gasket design. Over the years we have seen our fair share of design flaws, and just before launch, everyone is scrambling to find a gasket material that will make up for the deficiencies in the design. We are here to tell you that it doesn’t have to be this way! Sometimes the best gasket design can come from choosing the right material in the first place.

More than a few times in our 20+ years of business, we have been called upon to suggest a material for an application before the design is finalized. With our line of metal reinforced composites, we can offer a solution that is going to seal most joints successfully. We are also on the front end of a lot of gasket designs as well. We are proud to partner with OEM’s and fabricators and provide design assistance, which helps avoid the scramble at the end when the design and material don’t play nicely together.

If you are currently designing a gasket, or may ever design a gasket, read on for some gasket design warning signs and how they can negatively affect how well your gasket will seal…

Some Common Problems & Their Potential Solutions

1. Temperatures are too hot, the material is burning up.

It may be aging with the heat exposure, requiring that a higher temp material be used.

2. Internal pressure is too high, gasket is leaking.

Designers should be sure that sufficient flange load is available to obtain an initial seal and then maintain it over the long term.

3. Material is crushing or splitting, gasket is leaking.

This may be a result of too much flange load, or the design of the flange itself. It may also be a result of material that is not correct for the application, or it might be too soft for the designed flange load.

4. Gasket is fracturing due to expansion/contraction, creating a leak path.

High temperatures can cause flanges to move with the heat expansion. Some materials will not tolerate this growth and contraction and tear apart. This can be rectified with a surface coating (anti-slip) or a different material altogether.

5. Gasket is not suitable for the fluid contained.

Compatibility should be verified so it does not degrade when exposed to fluid.

6. Gasket material may be swelling, indicating that degradation is present.

Some degree of swelling is typically acceptable. However, excessive swelling is an indicator of breakdown of the material and a suggestion that long-term performance may be questionable.

Now You Know

Even though there are technically advanced gasket materials out there, nothing beats a great design. As a design engineer, your #1 goal is to design something that will meet the requirements of your application. Getting your gasket material manufacturer involved before testing to ensure the design and the gasket material will work together is only going to help you achieve your goal.

Why not do everything you can to have confidence in your design from the beginning?

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7 Ways to Protect Against Gasket Blowouts

The fall guy…defined by the Urban Dictionary as “a person who is left with the blame for a crime, regardless of whether they were involved or not”. In our world, the fall guy is the lowly gasket. Too many times, gaskets tend to be an afterthought in the design process, BUT the gasket (or the material) is the first to be blamed if there are ever any problems in the application. If you are currently designing (or may ever design) an application that has gasketed joints, or are currently in the middle of troubleshooting (or may ever troubleshoot) because of a leak in a joint, this week’s post is for you!

Over the years, we have just about seen it all. We’ve been a part of varying stages of design projects….at times we’ve almost been a part of the design team, lending our expertise to help ensure success once the gasket is cut, and other times we come in at the tail end to suggest a material that will meet your exact specifications. We’ve also been the firefighters…driving in on our big red truck with hoses spraying (ok, not really…) to offer a gasket material solution when everything else you’ve tried isn’t working. Blame it on the design of the joint, blame it on the design of the gasket, blame it on the material, blame it on the rain….regardless, there are potential problems lurking everywhere and we’re here to help you navigate some of those issues. Everyone’s time (and money) is valuable and we want you to be educated and aware of what can be done to minimize your chances of a gasket blowout.

What You Need To Know

Protecting your product launch and the application from the damage a gasket blowout can cause is your #1 priority in design (or redesign). Nobody wants a gasket to be the reason a project can’t launch as planned. Like we mentioned above, your gasket may be the culprit, but the issue might also be something else entirely. Here are 7 things to consider to help protect your application from gasket blowouts.

  1. Material choice: Designers must use caution to select a material that is suited for the operating conditions, including temperature, pressure, fluid resistance, durability (for handling), durability (in service), aging characteristics, and other factors.
  2. Temperature: Consider the peak exposure, and choose material capable of withstanding that level of exposure.
  3. Pressure: Sealing joints that are holding back high pressure need to have a gasket with reinforcement to provide radial strength. Be sure to choose reinforced material for high pressure joints.
  4. Flange loading: Flanges are critical pieces of the bolted joint. Consideration must be given to: flange flatness, surface finish, stiffness, material (expansion), preparation, and others.
  5. Assembly: Joints must be assembled properly to recommended torque values and sequence. Often with compressible products, a second round of final torque once operating temperature has been achieved is also helpful to maintain load over long term service.
  6. Protection: Some gaskets exposed to extreme conditions can benefit by additional protection which shields the gasket body from destructive conditions. Heat flow, fluid erosion, and other “wear effects” can be protected against by flange rings, embossments, coatings, and other protective measures.
  7. Thickness: Generally speaking, the thinnest gasket you can use is the best choice. Thickness gets increased to compensate for flange conditions or other factors. Thinner gaskets have less chance for blowout than thick ones since the load is concentrated over less volume, providing higher shear strength to prevent blowout.

Go Forth

We love a good gasket blowout picture – send us yours and we just might feature it in an upcoming article.

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