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PTFE (Polytetrafluoroethylene), also known by its trade name Teflon, is a polymer material commonly used in sealing applications that offers unparalleled stability and sealing characteristics across an extremely wide range of temperatures, from the extreme heat of a space shuttle engine to the cryogenically cold temperatures used to preserve

In this article, we will discuss how and why PTFE is one of the best materials to use for seals in a wide variety of applications.

Low Friction

PTFE has the highest melting point and lowest friction, and is the most inert of all the fluoropolymers. It has a continuous service temperature rating of 500 degrees Fahrenheit. Molding powders are excellent, fine cut granular resins, well suited for a variety of demanding chemical, mechanical, electrical and non-stick surface applications.

Such applications include:

• Cookware
• Outdoor Rain Gear
• Medical Devices
• And more!

Cryogenic Applications

Cryogenic seals are used with super-cooled media, like liquid hydrogen or compressed natural gas, at temperatures below -238°F and down to -460°F (absolute zero). Cold temperatures like this are rough on a seal because at these temperatures most materials begin to exhibit highly brittle behavior and lubricants typically cannot be used because they will freeze. PTFE seals, however, can handle temperatures all the way down to -450°F and are capable of dry running because of their extremely low friction. PTFE cryogenic seals are used in industries like oil & gas, pharmaceuticals, and aerospace.

High Temperature Applications

PTFE seals work well at the other end of the spectrum, too. They can continue to function in extreme temperatures up to 600°F, and continuous operating temperatures up to 600°F. Note that a filler may be required to enable the PTFE to dissipate heat more quickly. It’s not uncommon to see PTFE seals in petroleum or steam applications where temperatures greatly exceed 200°F.

PTFE is also non-flammable, making it ideal for use in applications such as jet propulsion engines. Where other materials would simply melt under the pressure of constant exposure to high temperature flames, PTFE is built to withstand even the hottest of environments.

The use of seals for high temperature applications include oil and gas industry and aerospace, to name a few.

Chemical Applications

The chemical resistance of PTFE is some of the best on the market. It is stable in most aggressive and corrosive media, including:

• Acetone
• Chloroform
• Citric Acid
• Hydrochloric Acid
• Sulfuric Acid
• Tallow
• Sodium Peroxide
• And more!

However, it should be pointed that that PTFE is not chemically resistive to liquid or dissolved alkali metals, fluorines and other extremely potent oxidizers, as well as fluorine gas and similar compounds. Outside of those, PTFE is an excellent choice for applications involving chemicals.

Oil and Gas Industry

Seals are critical for the safe and reliable operation of oil rigs across the globe. Not only do seals need to be able to withstand a wide variety of extreme temperatures, but they need to be able to handle extreme pressures as well. For well drilling, for example, seals need to handle pressures from 345 to 2070 bar (5000 to 30000 psi).

For those reasons, PTFE is an incredibly popular material to make oil and gas seals out of. Because of it’s resistance to heat, cold and high pressure, PTFE can withstand the rigors of oil and gas unlike any other material.

Spring-energized Seals

In order to retain sealing power under extreme temperatures, many engineers and designers go with spring-energized PTFE seals. The spring provides optimal sealing by forcing the lip of the seal against the mating surface and helps to account for dimensional changes as a result of temperature fluctuations.

A highly efficient seal is created as the system pressure increases enough to take over from the spring and engage the shaft or bore. The spring or energized seal assembly provides permanent resilience to the seal jacket and compensates for jacket wear, hardware misalignment and eccentricity. The jacket material is critical in design to assure proper seal performance.

Rotary Shaft Seals

Using PTFE in rotary shaft seals allows them to be able to run at higher pressures and velocities when compared to other materials. They are also able to have tighter sealing, often exceeding 35 BAR and can run at far more extreme temperatures ranging from -64 degrees Fahrenheit (-53 degrees Celsius) to 450 degrees Fahrenheit (232 degrees Celsius).

On top of that, they are:

• Inert to most chemicals
• Can withstand speeds up to 35 m/s
• Compatible with most lubricants
• Come in a wide range of sizes
• And more!

Conclusion

PTFE is an ideal sealing material for both extremely high temperature applications and demanding cryogenic applications. It retains its key sealing properties: stiffness, strength, dimensional stability (may require spring energizer), low friction, and chemical compatibility- even in the most aggressive operating conditions.

Need PTFE sealing solutions? Advanced EMC Technologies is the leading provider of PTFE spring energized and rotary shaft seals in the US. Contact us today!

FlexForce canted coil springs have special characteristics that make them useful in a variety of applications, ranging from locking components together in an orthopaedic implant to providing an energizer for mission critical aerospace applicants. In this blog post, we will introduce seven key facts about FlexForce canted coil springs that you need to know.

Are a Specific Design for Springs

Canted coil springs, also known as slant coil or cant coil springs, are springs that have the individual coils set at an angle to each other, rather than having them all parallel. This coil configuration significantly impacts the performance of these springs and makes them ideal for a wide range of uses.

What makes canted coil springs different from other types is the fact that they have a flat load curve when they are compressed. Because of this, canted coil springs generate predictable loads throughout their wide deflection range.

Can be Used as Mechanical Connectors

Canted coil springs are ideal for applications that involve latching, locking, or holding to connect two components (also known as detent mechanisms). Latching involves fastening two parts together so that they can still be disconnected when needed. Locking creates a permanent connection that can only be broken by damaging the sea. Holding, on the other hand, both retains and aligns parts and makes sliding possible via the controlled spring force. 

Canted coils are commonly used to connect two mating surfaces in a highly predictable, repeatable fashion thanks to the flat load curve. When canted coil springs are used, the insertion/removal force can be engineered to a high degree of accuracy.  And when used as a latching, locking, or holding connector, FlexForce canted coil springs provide a lightweight, high strength option that can be used for practically an infinite number of cycles.

Can Provide Exceptional EMI/RF Shielding

One of the common uses of canted coil springs is their ability to effectively provide EMI/RF shielding. Furthermore, the electrical properties of these springs can be customized to provide more optimal shielding against certain ranges of conductive and radiated interference.  

Add to this the fact that they can adapt to irregular and uneven shapes to provide consistent shielding, and it is easy to see why they are a common choice for applications that need to be protected from harmful electromagnetic and radio frequency crosstalk interference.

Can Act as a Multiple Point Electrical Conductor

Some designs depend on multiple electrical contact points, which a canted coil can provide. Using a canted coil spring for electrical connections results in a reliable connection that results in a cooler operation temperature. It allows engineers to manage more power in compact spaces and provides both conducting and grounding capabilities in both static and dynamic applications. In addition, canted coil springs as electrical conductors can perform in some of the harshest operating environments that may involve vibration and shock. It should come as no surprise that canted coil conductors are often used in medical applications inside the human body.

Can be Used with Spring Energized Seals

Canted coil springs work extremely well as the energizer in spring-energized seals. Because of the energizer, spring energized seals are able to maintain contact with the sealing surface, even if issues such as out of roundness, uneven mating surface, runout, hardware gaps, eccentricity, or seal lip wear are present. 

The flat load curve of these springs also means that friction stays fairly consistent in dynamic sealing applications. This makes them ideal for sealing situations that involve critical friction and torque specifications. In addition, canted coil springs are very unlikely to experience compression set. 

Available With a Range of Options

There are several options for canted coil springs. They are available in varying levels of spring force: light, medium, and heavy. And canted coil springs come in both standard and custom sizes. As to the spring wire itself, they are available in wire diameters between 0.25 mm (0.010 inches) and 1.50 mm (0.059 inches). As to the coil width, they come in sizes ranging from 1.5 mm (0.039 inches) and 15 mm (0.591 inches). However, designs can be highly customized if needed.

Finally, the three most common wire materials are Hastelloy, stainless steel (usually 300 series), and copper alloys. For use as a conductor or EMI/RF shielding, stainless steel is recommended. For applications that involve high heat and corrosive media, Hastelloy and Elgiloy may be recommended. Also keep in mind that these canted coil springs can be obtained with nickel, silver, or gold plating.

Used in a Wide Range of Industries and Applications

Canted coil springs are being used in a diverse group of industries and applications, including oil & gas, renewable energy, aerospace, defense, fluid power, transportation, semiconductor manufacturing, and medical devices. 

• As a mechanical connector, canted coil springs are often used to lock together frame assembly of a ventilator cart or to hold components together in wind turbines.
• As a multiple contact point conductor, canted coil spring assemblies are often used in active implantables such as pacemakers or neurotransmitters. 
• As EMI/RF shielding, canted coil springs can be found in electrical enclosures or used with data transmission cables.
• As a part of a spring energized seal, canted coil springs are used in critical aerospace applications and dangerous petrochemical environments involving extreme heat and corrosive materials.

Conclusion

FlexForce canted coil springs can be used as detent mechanisms, EMI/RF shields, multipoint electrical conductors, and energizing springs in seals. They are available in a number of options and can be fully customized to meet user needs. In addition, their reliable performance has already been proven in number industries and applications. If you are interested in FlexForce canted coil springs, contact us at Advanced EMC today.

Hytrel (property of the Dupont Company) is gaining in popularity as a material for seals, and there a number of reasons for this. In this blog post, we are going to talk about the general characteristics of Hytrel as well as the specific grades used for sealing applications.

What is Hytrel?

Hytrel is a TPC-ET thermoplastic polyester elastomer made by Dupont. Hytrel can be found in applications that seem to vary significantly in requirements and environmental challenges, such as off-road transportation equipment, oil and gas, hydraulic power, food handling, and medical devices. It is also used in electronics, automobiles, healthcare equipment, power tools, sporting goods, appliances, and cables.

Characteristics of Hytrel

Hytrel has a long list of excellent characteristics, including impact resistance, toughness, and resistance to chemical attack (including hydrocarbon solvents and fuels). In terms of sealing applicants, it offers:

• Flex fatigue resistance
• Spring-like properties
• Creep resistance
• Inherent flexibility
• The ability to flex in multiple directions
• Wide operating temperature range (cryogenic to +315°F)

In addition, Hytrel retains mechanical properties even at high temperatures and remains flexible at low temperatures. Hytrel also lends itself to a variety of manufacturing methods, including extrusion, blow molding, injection molding, and rotational molding. However, it is sensitive to water and phosphate fluids above 175°F.

Grades and Blends of Hytrel

Hytrel is available in various grades and blends, including seven specific grades that are well-adapted for seals. In addition to the grades discussed below, there are also renewable sourced options. Note that stabilizing additives can be combined with these grades to improve Hytrel’s resistance to heat aging and UV light.

Hytrel 4056

Hytrel 4056 is the most flexible grade, offering both toughness and strength over a considerably wide temperature range. It works extremely well for low-temperature applications because of its ability to retain flexibility. In addition, its low modulus allows it to be formed using extrusion and has a low melting point.

Hytrel 4068 and Hytrel 4069

Both Hytrel 4068 and 4069 provide flex-fatigue and creep resistance along with outstanding low-temperature properties. These grades can be formed using molding or extrusion and possess a higher melting point than Hytrel 4056 and a lower modulus. In addition, there is a food-grade available: Hytrel 4068FG.

Hytrel 4556

Hytrel 4556 is very similar to 4068 and 4069, with a low-to-medium modulus and can be manufactured using both extrusion and molding. This grade works extremely well for seals and gaskets.

Hytrel 5526 and Hytrel 5556

In terms of general properties, Hytrel 5526 provides a good balance. Its flow properties, however, primarily limit it to injection molding. Hytrel 5556 also offers a balance of properties with a medium modulus. It works well with extrusion but does not have the same high-flow properties available with Hytrel 5526. 

Hytrel 6356

Hytrel 6356 offers an excellent balance of properties such as toughness, flexibility strength, thermal resistance, and creep resistance. This high modulus grade is well adapted both to molding and extrusion processes.

Hytrel 4053FG NC010

When food contact grade seals are needed, Hytrel 4053FG NC010 may be an option. This is a low modulus extrusion grade whose properties include creep resistance, good low-temperature properties, and flex-fatigue resistance. 

Hytrel 5553FG NC010

This is a medium modulus molding and extrusion grade of Hytrel that provides a good balance of properties. It is intended for applications involving food contact.

Hytrel 6359FG NC010

Another good grade option of Hytrel, this material provides a good balance of properties including strength, toughness, flexibility, creep resistance, and thermal resistance. It is a medium to high modulus grade that works well with both molding and extrusion processes.

Benefits of Using Hytrel

When used in sealing applications, Hytrel offers a number of distinct benefits. For example, Hytrel can be used to replace multi-piece assemblies (including those composed of various materials) with a single component.

Because Hytrel has excellent creep and recovery properties, seals using Hytrel will be more resistant to dimensional changes and less likely to be permanently deformed. This is critical in many sealing applications, including those where there are extreme pressure and temperature changes. And because it can flex in multiple directions for far more cycles than a traditional elastomer such as rubber.

Unlike some seal materials, Hytrel grades vary according to modulus, which makes Hytrel a very versatile material choice. The differences in modulus are important: low modulus options can be used where little force should be needed to stretch the material, while high modulus grades work well for situations where significant force should be required to result in stretching. In addition, Hytrel is available in Shore D hardness ranging from 30 to 82.

As mentioned earlier, Hytrel has excellent properties when it comes to chemical compatibility and resistance to chemical attack. More specifically, it is resistant to mineral oils, greases, water-based hydraulic fluids, dilute acids, dilute bases, glycol, and hydrocarbon fuels. There are also grades of Hytrel that offer excellent resistance to the degrading effects of radiation. 

Hytrel is available in food grades that conform to both FDA and  European Food Contact regulations.  There are also grades in compliance with regulatory requirements that make them suitable for use in medical devices and other healthcare applications.

Conclusion

Hytrel combines the strength of engineering plastics with the flexibility of elastomers and the ease of processing provided by thermoplastics. Its combination of properties and flexibility in terms of manufacturing processes make it an excellent option for sealing applications

Today more and more countries are entering the space industry. According to the Space Foundation, the global market for space exploration was a whopping $383.5 billion worldwide in 2017, with a 100% increase in the total number of spacecrafts deployed. It is expected to grow to $1.1 trillion by 2040.

As the space market opens up, so does the need for technology that assists with cost, sustainability, efficiency and safety- such as seals.

In fact, polymer seals have been used in a variety of functions for spacecrafts such as:

• Propulsion
• Payload Systems
• Ground Support Equipment
• Regulators
• Main Fuel and Oxygen Valves
• Regulators
• And more!

In today’s blog post, we will explore the use of polymer seals in the space industry.

A Changing Landscape

Since the first expedition into space in 1961 by Russian cosmonaut Yuri Gagarin, there has been a surge in emerging countries and private sectors entering the space race.

In 2002 Elon Musk founded SpaceX, a private company whose goal is to manufacture and launch advanced rockets and spacecrafts with the goal of enabling commercial trips into space. In 2010 it became the first private company to return a spacecraft from low Earth orbit in 2010 and the first commercial spacecraft to deliver cargo to and from the International Space Station in 2012.

In India, the Indian Space Research Organization (or ISRO) has developed a massive and ambitious space program. In 2014 they launched their Mars orbiter, becoming the fourth space agency and the first in Asia to reach the red planet. In 2017, it launched 104 satellites in a single rocket, tripling Russia’s record.

With so many new players entering the scene, the space industry has never looked more exciting. This also requires an increase in demand for high quality parts, such as polymer seals.

Space is Cold and Engines are Hot

Polymer spring energized seals are commonly used in a variety of space applications because of their durability and ability to withstand extreme temperatures.

With temperatures in space reaching cryogenic (-238*F or -150*C) it is important that the seals used can withstand the extreme temperatures. The outer polymer lip of a spring energized seal for example allows the seal to be used in temperatures of -423*F (-253*C) to 302*F (150*C).

On top of having seals that can be used in the cold, dark vacuum of space, seals are also used in conjunction with things like thrusters, combustion chambers, and other parts of the shuttle where temperatures can reach a whopping 6,000*F (3,315*C).

Aggressive Chemicals

Many seals face frequent exposure to liquid oxygen and liquid hydrogen, the latter of which must be below 20K (-423*F or -253*C) in order to reach a liquid state. This puts an incredible amount of strain on the seal. One way around this is to make seals out of high-quality polymers such as PTFE, Torlon and more.

Increase of Pressure

In outer space, the pressure is 1.322 x 10^-11 Pa. For those keeping track at home, this is essentially zero. However, the act of leaving the Earth’s atmosphere causes such a huge fluctuation in pressure that there is a potential for metal and other hardware to open, which in tern could potentially impact the seal.

As such it is critical that seals used can hold up to the extreme fluctuation of pressure, and continue to run, to keep the shuttle and its crew safe.

Teflon, or PTFE, is a popular material used because of its ability to not only handle extreme temperatures, but extreme pressure fluctuations as well.

Cost Efficiency

As of 2012 it is estimated that the average launch cost of a NASA space shuttle is around $576 million. That cost does not factor in the price to build the craft, which values at a whopping $3.5 billion. As such, it behooves space programs to find ways to not only be cost efficient, but to be sustainable as well.

Luckily, with seals, making them out of polymer materials solves both problems!

Because of it’s ability to be produced at high volumes, making seals out of polymers can greatly reduce overhead cost. And because the plastic can be melted down and reused, they are highly sustainable as well!

In Conclusion

With more and more people interested in space exploration, it is becoming more and more critical to have high quality parts to perform critical functions.

Polymer seals are the best choice for companies looking to have a high quality, cost efficient, and sustainable part that will withstand the rigors of space travel.

For more information, or to learn how Advanced EMC Technologies can help your spaceship blast off, contact us today!

In cryogenic temperatures, most O-rings become brittle and fail. Many times cryogenic applications can also involve media that is not chemically compatible with traditional elastomeric materials. However, for axial sealing applications, there is an effective, dependable solution: encapsulated O-rings. 

What is an Encapsulated O-Ring?

In short, encapsulated o-rings combine the chemical resistance and extreme-temperature performance of FEP or PFA with the elasticity and resilience of silicone, FKM, or stainless steel energizers. Stainless steel springs or rugged elastomers are encapsulated within a durable, chemically resistant jacket made from FEP (fluorinated ethylene propylene) orPFA (perfluoro alkoxy copolymer). These o-rings are used with valve stems, flanges, joints, swivels, pumps, turbo expanders, and waterless fracking.

Materials Used With Encapsulated O-Rings

For the outside of the O-ring, the most popular materials currently in use are FEP, PFA, and PTFE. FEP is highly resistant to chemical attack, offers a low compression set, and has a low coefficient of friction. Its operating temperature range is -420°F through 400°F and is less expensive than PFA. In addition, FEP is available in FDA-approved grades. 

PFA is resistant to a wide range of corrosive chemicals, including naphtha, acid, aromatic solvents, petroleum, and alcohol. It has a wider operating temperature range than FEP, from -420°F through 500°F. It also possesses a low compression set and resistance to cracking and stress in addition to a higher overall mechanical strength when compared to FEP. It is also available in grades that have the following approvals: USP IV, FDA-compliant, EU Reg. 1935/2004, ADI-free, and 3-A Sanitary Standards.

The materials used for the interior energizer of encapsulated o-rings include 302 stainless steel for spring energized as well as silicone, FKM (trade name Viton), or EPDM. Whether its a spring-energized approach or a core of silicone, FKM, or EPDM, the interior of the encapsulated o-ring provides the additional resiliency that makes these o-rings so effective for cryogenic applications. Note that silicone and FKM ensure an even pretensioning at the sealing point.

Silicone provides a softer core than FKM and offers very good cold flexibility. Using FKM as the core material means that the o-ring will be able assume its original shape very quickly after installation/deformation due to its outstanding compression set characteristics. It is not, however, as temperature resistant as silicone. While EPDM can be used as a core material, it is not recommended because of how it reacts to the heat involved in manufacturing the encapsulated o-rings.

Solid-Core vs Hollow-Core Encapsulated O-Rings

The two basic types of encapsulated O-rings are solid core and hollow core. Solid core o-rings have an energizer made from either silicone or FKM (fluoroelastomer, trade name Viton). Both types of cores provide good elasticity and low compression set, but when used in cryogenic applications silicone is usually the better choice because it remains more flexible at lower temperatures. Hollow-core encapsulated o-rings, on the other hand, are used when there is a need for extreme elasticity or for fragile applications. 

Advantages of Encapsulated O-Rings

There are several advantages to using encapsulated O-ring, besides the fact that they  can outperform traditional seals in harsh environments that can include extreme temperatures and corrosive media. These o-rings are …

• Chemically resistant
• Available in non-contaminating and FDA-approved materials
• Low coefficient of friction that prevents issues with stick-slip behavior
• Low permeation
• Excellent corrosion resistance
• Low compression set
• Excellent service life
• Reliable sealing
• Cost effective

Encapsulated O-Rings for Cryogenic Operating Environments

For cryogenic environments, the best approach to encapsulated O-rings is the use of FEP or PFA exterior with a steel flat wound ribbon spring at the core. This configuration can handle cryogenic temperatures all the way down to -420°F and pressures up to 3000 psi as long as vented holes are placed in the FEP jacket to prevent dangerous blowouts. These encapsulated o-rings work best in static and slow dynamic applications and are ideal for applications that involve cryogenic media such as liquid oxygen, liquid nitrogen, hydrogen. These encapsulated o-rings are readily available in both metric and US cross-sections and a wide range of diameters.

Conclusion

For cryogenic applications where traditional o-rings have failed, encapsulated o-rings with an FEP/PFA exterior and a 302 stainless flat wound ribbon at the core is an excellent option. It has already been successfully used by NASA in not one but several successful rocket launches and has been incorporated into designs by Lockheed and Boeing.