Polymer Bushings and Bearings
by Sara McCaslin, PhD Sara McCaslin, PhD No Comments

Plain Polymer Bearings: When Simple Is a Design Advantage, Not a Compromise

Polymer plain bearings are often eliminated early in a design because it is easy equate complexity with performance. But that isn’t always true. While rolling-element bearings are the standard for a reason, the humble plain bearing, specifically when high-performance engineering polymers are used, offers a surprisingly robust alternative. Sometimes, eliminating moving parts is actually the biggest upgrade that can be made. 

This blog post explores what polymer plain bearings are, what their benefits are, and what their limitations are. 

Plain Polymer Bearings

A plain bearing (also known as a plane bearing) is the simplest design of a bearing, primarily because it has no rolling elements. These bearings come in several different forms, including cylindrical sleeves (the simplest), flanged (which can support axial loads), and thrust washers. As simple as their design is, however, there are many instances where they can outperform their rolling-element bearing counterparts

Plain Polymer Bearings vs Rolling-Element Bearings

What follows are some of the key benefits of simple plain bearing designs as compared to their rolling-element bearing counterparts. 

Superior Load Capacity and Shock Resistance: Plain bearings have a much larger surface-contact area than rolling element bearings possess. Because of this, plain bearings distribute loads much more effectively. Under shock loads, rolling-element bearings concentrate force into point loads that can cause fatigue or brinnelling. Plain bearings, however, can absorb shock and safely spread these impacts.

Predictable, Non-Catastrophic Failure: When a ball bearing fails, it seizes and can shatter and send problematic metal shrapnel into the system, a form of catastrophic failure that does serious damage beyond just the bearing itself. Plain bearings, on the other hand, experience wear at an even, predictable rate. This non-catastrophic failure mode is critical for applications in industries such as food processing and pharmaceutical applications, where contamination is a serious event.

Weight, Space, and Cost Savings: A typical plain bearing weighs less than half of a comparable needle-roller bearing, especially when a polymer bearing is used to replace a metal rolling-element bearing  (sometimes up to 14 times less than a deep-groove ball bearing). Their single-piece design eliminates the need for components such as snap rings and complex machined shoulders. This, in turn, enables engineers to shrink housing sizes and significantly reduce manufacturing costs.

Vibration Damping and Silence: Because they have no internal moving parts to rattle or slop around, plain bearings run quietly, and they naturally absorb a significant portion of mechanical vibration. This feature makes them extremely quiet when compared to rolling-element bearings.

Self-Lubrication: Perhaps the biggest advantage of plain engineering polymer bearings, such as PTFE and PEEK, is their maintenance-free nature. Instead of requiring continuous oil or grease, they rely on material transfer lubrication. As the shaft makes its first few rotations, the polymer smears a microscopic transfer film onto the mating metal shaft. This transfer film fills the microscopic recesses on the mating shaft, creating a dry-running, low-friction surface that prevents the messy buildup of debris common with greased bearings. 

When Polymer Plain Bearings are Not the Solution

Are plain bearings always the solution? No, and here’s a quick summary of where rolling-element bearings remain the recommended choice. For example, plain bearings are generally optimized for single-speed applications, but rolling-element bearings can tolerate a wider speed range, making them more suitable for applications with variable-speed drives. Start-stop cycles can also be a problem for plain bearings because it takes time for their lubricating transfer film to form, but rolling-element bearings are more efficient in such environments. In addition, high-precision applications work best with rolling-element bearings because polymer plain bearings require a radial clearance. Polymer bearings cannot handle the same level of edge loading as their equivalent rolling-element bearings. Finally, polymer plain bearings have much stricter mating shaft surface requirements.

Conclusion

Switching to plain bearings is not a solution for every design challenge. If you need extreme precision or are dealing with high-speed variability, rolling elements remain the best option. That said, the benefits of going simple are hard to ignore. Removing the risk of catastrophic seizure and reducing maintenance, polymer bearings solve the issues traditional rolling element metal bearings create. It comes down to knowing exactly what your application can tolerate.

If you are trying to decide between plain and rolling-element bearings, Advanced EMC can help. Contact us today and talk to one of our experienced bearing engineers.

PTFE Spring Energized Seals
by Sara McCaslin, PhD Sara McCaslin, PhD No Comments

The PTFE Spring-Energized Seal as a Casualty: Why Hardware and Installation Are the Real Killers

A seal rarely fails in isolation, but this is often forgotten.  When leakage occurs, the immediate reaction is often to blame the seal itself. However, this approach frequently addresses the symptom rather than the disease. In many failure analyses, the seal is the casualty of a compromised environment. 

High-performance spring-energized seals do not function in an environment by themselves. Rather, they are dynamic elements within a complex mechanical system that continuously react to issues in hardware, surface finish, alignment, pressure, and thermal cycling. When these boundary conditions drift outside their engineering limits, even the most advanced spring-energized seal will inevitably fail.

To achieve genuine reliability, the conversation must shift from “seal failure” to “system integrity.”

The Tribological System

A spring-energized seal is more than a polymer ring with a metallic energizer: it is a critical component of a tribological system. As such, its performance can be directly linked to three factors:

  • Gland Design: Dimensions, geometric tolerances, and extrusion gaps
  • Counterface: Material hardness, coating integrity, and surface finish
  • Operational Physics: Thermal expansion coefficients (CTE), pressure-induced hardware deflection, and friction-generated heat

Each factor impacts the contact stress profile and wear mechanics, which means if one element is ignored, the seal attempts to compensate until the application’s physics overwhelm it.

Gland Geometry for Spring-Energized Seals

The gland design sets the boundary conditions for the spring-energized seal’s life.

Radial Squeeze & Contact Stress: A lack of compression can lead to the formation of spiral leakage pathways in dynamic applications, while excessive interference generates frictional heat and accelerates natural abrasive wear. For spring-energized designs, the incorrect squeeze distorts the energizer’s force-deflection curve, essentially voiding the design that went into the spring.

Groove Volumetrics: A groove that is too wide allows axial shuttling, where the shaft and seal move axially. This leads to a tilted seal and skewed loading profiles. In addition, a groove that violates fill percentage guidelines restricts thermal expansion, causing stress spikes.

Extrusion Gap Mechanics: Under high pressure, PTFE will exhibit cold flow behavior (which is a material property, not a defect). If the extrusion gap (E-gap) is excessive or expands due to hardware pressure breathing, the polymer will extrude into the clearance. In addition, hardware features like lead-in chamfers are critical. A sharp corner acts as a cutting tool during installation, shaving the seal before it ever sees service pressure.

Surface Finish: The Micro-Interface

Surface finish is far too often the silent killer in dynamic applications. It is not enough to specify smooth, but rather define the correct surface finish required for effective film transfer when using materials such as PTFE or PEEK. Keep in mind that PTFE seals rely on the deposition of a thin transfer film onto the mating hardware to stabilize friction. If the counterface is too rough, it abrades the seal lip. On the other hand, if the surface is a mirror polish, it will prevent lubricant retention or film adhesion, leading to serious issues related to high stick-slip friction. The shaft hardness must also support the load: a soft shaft can suffer from galling or scoring, while a delaminating coating means a jagged, abrasive interface that destroys the seal lip.

Thermal and Mechanical Instability

Polymers and metals behave differently thermally. For example, PTFE is going to expand significantly more than steel given the same temperature differential. If such a CTE mismatch is ignored, rising temperatures can cause the seal to overfill the gland, resulting in higher friction and torque. However, when the PTFE spring-energized seal is subject to cryogenic temperature, it may shrink away from the bore and lose contact stress unless the spring energizer is correctly sized to compensate for this dimensional change.

Mechanically, pressure is not static. Housings breathe, bores distort, and bolts stretch. In cyclic applications, the extrusion gap is a dynamic variable that opens and closes with every pressure spike. This forces the seal to fatigue as it continuously reshapes itself to bridge the changing gap.

Misalignment and Eccentricity

Runout and misalignment are simply unavoidable with a rotary shaft seal for several reasons. Eccentric forces on one side of the seal lead to high compression, while the opposite side of the seal lifts off, losing critical contact. This, in turn, results in localized wear patterns and half-moon extrusion failures. Often, the seal is expected to mask bearing slop or structural deflection, which is actually a band-aid for mechanical instability that should have been resolved at the design stage.

Installation of Spring-Energized Seals

Many seals are destroyed before the machine is even turned on. Installation is a violent event for a simple polymer ring. Forcing a seal to go over threads, sharp shoulders, or through undersized bores can slice the polymer jacket or permanently deform the spring energizer, neither of which is good. Installation can destroy a seal before it has had a chance to perform.

Conclusion

Leakage is not solely a material failure. This thought process ignores the complex interplay of gland geometry, surface finish, and thermal dynamics that dictate performance. Trueseal solution reliability requires moving beyond component replacement and embracing a holistic approach to system integrity.

At Advanced EMC, we engineer tribological solutions. If you need help navigating complex boundary conditions or recurring failures with your PTFE spring-energized seals, let our engineers help you analyze the total application. Contact us today to design a sealing system built for your specific operational situation.