PCTFE Ball Valve Seats for Low Permeation Applications
by Sara McCaslin, PhD Sara McCaslin, PhD No Comments

PCTFE Ball Valve Seats for Low Permeation Applications

Ball valve seats that show signs of swelling, blistering, or “popcorning” have been permeated at a molecular level. Needless to say, this can cause some serious issues such as leaks and catastrophic failure. The solution is to find a ball valve seat material that is highly resistant to permeation and an excellent choice would be PCTFE. In this week’s blog post, we will talk about PCTFE Ball Valve Seats and how they are used in Low Permeation Applications.

Introduction

Certain types of media may permeate the ball valve seat, leading to swelling, blistering, and leakage. Applications such as chemical processing and petrochemical transport may require a seat material that is resistant to permeation but still exhibits key properties such as low friction, compressive strength, and resistance to deformation is still needed.

How Permeation Works

Permeation refers to the molecular level penetration of gases, vapors, and liquids through a solid material via diffusion. In diffusion, molecules pass from an area of high concentration to an area of low concentration. This can be extremely problematic when a ball valve is being used because of the potential distortion and leaking of the ball valve seat.

Keep in mind that permeation can take place through a surprising variety of materials, including metals and polymers. In addition, some materials are only semipermeable, which means that only ions or molecules with certain properties can pass through the material. 

The rate of permeation is directly related to crystal structure and porosity, which is why factors such as density and molecular structure are important when selecting materials for applications where low permeation is important. 

Why Permeation is a Problem for Ball Valve Seats

Gas permeation can not only compromise gas stream purity but also result in dimensional changes of the ball valve seat. One form of these dimensional changes is swelling, which can occur if the permeating media becomes a part of the molecular structure of the material. In reinforced polymers, such as glass-reinforced PTFE, swelling can cause separation between the glass fibers and the PTFE matrix. 

Another common manifestation of permeation is referred to as “popcorning” or “popcorn polymerization” which occurs due to a polymeric chemical reaction. And among the most notorious source of problems with popcorning and swelling are monomers with extremely small molecular sizes such as Butadiene and Styrene.

Both popcorning and swelling will lead to leakage, and over time popcorning will completely destroy the ball valve seat. This makes the choice of ball valve seat materials extremely important for applications where this is a problem.

PCTFE for Low Permeability Ball Valve Seat Applications

One of the best materials for a ball valve seat application where permeability is a problem would be PCTFE (Polychlorotrifluoroethylene), a thermoplastic chlorofluoropolymer. PCTFE is sometimes referred to as Modified PTFE or PCTFE, as well as by trade names Kel-F, Voltalef, and Neoflon. PCTFE is often thought of as a second-generation PTFE material that maintains the chemical and thermal resistance of PTFE along with its low friction. It is also similar to other fluoropolymers such as PFA or FEP.

One of the defining characteristics of PCTFE is that it has a much more dense molecular structure and a low void and micro-porosity content when compared to similar ball valve seat materials. This gives it a very low permeability coefficient, which means that the likelihood of it swelling or popcorning is far lower than other materials. For example, its permeability for O2, N2, CO2, and H2 are 1.5 x 10-10, 0.18 x 10-10, 2.9 x 10-10, and 56.4 x 10-10 darcy, respectively.

PCTFE also provides improved toughness and strength along with good deformation recovery and excellent creep and cold-flow resistance. In addition, it has a wide operating temperature range of -100°F to 500°F. In fact, it performs extremely well at cryogenic temperatures. Because of its low friction, it also results in a very low ball valve operating torque. PCTFE also exhibits zero moisture absorption and is non-wetting. 

PCTFE works well in operating environments where other polymers may fail. For example, it is well adapted to nuclear service that may involve high radiation exposure, is non-flammable (D 635), and is resistant to attack by the vast majority of chemicals and oxidizing agents. The only chemicals that might lead to slight swelling are ethers, esters, aromatic solvents, and halocarbon compounds.

In addition to its use in applications requiring low permeability, PCTFE is also considered an excellent choice for applications that need a low-outgassing material and is commonly used in semiconductor applications. Also note that there are PCTFE grades that are FDA approved, such as Fluorolon PCTFE 2800. 

Conclusion

Fuel processing and transport, chemical processing, petrochemical systems, and emissions control are just a few of the applications where low permeation materials may be necessary. For such applications, PCTFE is an excellent option for ball valve seat materials because it combines the basic properties necessary for a seat with an extremely low rate of permeation.

If you need a solution to blistering, swelling, or popcorning of a ball valve seat, contact the experts at Advanced EMC. Our sealing team will work with you to find the right ball valve seat material for your application.

Thermoplastics for Medical Devices | Advanced EMC Technologies
by Jackie Johnson Jackie Johnson No Comments

Thermoplastics for Medical Devices

Thermoplastics for medical devices are becoming increasingly common. New materials are often the necessary building blocks for product development and technology breakthroughs in the medical device industry. With novel procedures and treatments emerging rapidly, the equipment and devices required to enhance such advances are frequently limited only by their materials of construction.

A wide variety of thermoplastic resins are used in the medical industry. Most applications have multiple requirements that must be met, which narrows the list of candidate materials considerably. Some of the most common selection criteria include chemical resistance, temperature resistance, impact resistance, elongation or flexibility, strength, stiffness, clarity, dimensional stability, and biocompatibility, among others.

In this week’s blog post, we will discuss some of the most common thermoplastics used in the medical industry.

PTFE

PTFE (Polytetrafluoroethylene), also known by its brand name Teflon, is a fluoropolymer most famous for its non-stick qualities. PTFE is inert to most chemicals and has the lowest coefficient of friction of any thermoplastic. It also has very good UV resistance, hot water resistance and electrical insulation even at high temperatures.

These features make it suitable for a variety of medical applications. It is most commonly used in tubing, keeping devices such as ventilators running smoothly. PTFE coating is also popular for use in vascular medical devices, such as catheters.

PEEK

Like, PTFE, PEEK (Polyetheretherketone) is well suited for a wide variety of medical devices. In particular, PEEK Optima and Zeniva PEEK are suitable for long term implants and have a uniquely similar structure to that of human bone. PEEK is also radiolucent which makes it well suited for dental implants and use in various medical instruments. Not only that, but PEEK is also able to be used continuously to 480°F (250°C) and in hot water or steam without permanent loss in physical properties.

For more hostile environments, PEEK is a high strength alternative to fluoropolymers. Because of this, PEEK is an increasingly popular FDA approved replacement for metal in the medical industry due to its lightweight nature, mechanical strength, radiolucent properties, creep and fatigue resistance, as well as its ease in processing.

UHMW-PE

UHMW-PE (Ultra-High Molecular Weight Polyethylene) is a low-pressure polyethylene resin that has a much higher abrasion resistance and impact strength compared to most plastics. Due to its self-lubricating, non-stick surface, it has a low coefficient of friction that makes it desirable in the medical industry. UHMW-PE’s biocompatibility has made it a popular biomaterial for joint replacements such as hips, knees and shoulders, for decades, as early as the 1960s.

Recently, the resin has been refined in such a way to serve the needs of surgeons doing minimally invasive surgical implants such as cardiovascular surgery. Because of its ability to be shaped into a range of textile constructions, UHMW-PE is suitable for enhancing the design of various implantable cardiovascular devices, including complicated stent grafts and covered stents.

TORLON-PAI

TORLON PAI (Polyamideimide) is one of the highest performing thermoplastics built from the TORLON resin. Its compressive strength is double that of PEEK when unfilled, and about 30% higher than ULTEM PEI. As a medical grade thermoplastic, Torlon offers high modulus, radiolucency, sterilization-compatibility and high wear resistance, making it ideal for components inside high performance and peristaltic pumps. Torlon’s extremely low coefficient of linear thermal expansion and high creep resistance deliver excellent dimensional stability over its entire service range.

In Conclusion

While we only went over a mere handful of thermoplastics, there are many more that are used in the medical device industry. Whether you need tubing for a pump, replacement for a bone, or more, there is a high-quality thermoplastic perfect for the task.

To learn more about polymers and their use in medical devices, check out this blog post HERE.

Need FDA approved seals for your medical device? Contact us today!