by Denise Sullivan Denise Sullivan No Comments

Selecting the Right Seals for Cold Temperature and Cryogenic Valves

Cold temperatures can cause materials to become brittle and lose elasticity, leading to seal failure. Additionally, thermal expansion and contraction can cause seals to break down over time. For these reasons, selecting the proper seals for cold temperature and cryogenic valves is crucial.

cryogenic valves

When selecting seals for cold temperature applications, it’s essential to consider the following factors:

  • Temperature range: The seal must withstand the extreme temperatures of cryogenic fluids.
  • Pressure range: The seal must withstand the pressure of the processed fluid.
  • Chemical compatibility: The seal material must be compatible with the processed fluid.
  • Wear resistance: The seal must withstand repeated valve cycling without breaking down.

 Factors to Consider When Selecting Cold Temperature Seals

When selecting the proper seal for your cold temperature application, there are several factors you need to consider:

Temperature Range

The first factor to consider is the temperature range your application will require. Cryogenic seals operate in temperatures ranging from -460°F (-273°C); you’ll want to choose a material specifically designed for these conditions. 

Pressure Range

You’ll also need to consider the pressure range your application will be operating under, as this will affect which type of seal you’ll need to use.

Chemical Compatibility

Another essential factor to consider is chemical compatibility with the fluid or gas your cryogenic valves system processes. Not all materials perform well with every substance they encounter over time.

Wear Resistance

Finally, wear resistance is an important consideration when selecting seal materials since repeated valve cycling and exposure to pressure can cause wear over time, eventually leading to breakdowns if not properly addressed beforehand.

Types of Cryogenic Valves Seals for Cold Temperature Applications

PTFE (Polytetrafluoroethylene), FEP (Fluorinated Ethylene Propylene), and UHMW (Ultra High Molecular Weight PE) are popular choices due to its exceptional chemical resistance and low coefficient of friction. It also has excellent thermal stability and can withstand temperatures as low as -460°F (-273°C). 

Another critical aspect of designing polymer seals for cryogenic applications is the seal geometry. The seal design must provide sufficient compression force to ensure proper sealing while compensating for any dimensional changes caused by temperature fluctuations or external forces. A common approach in these applications involves creating a labyrinth seal design where multiple grooves in the seal face interlock with corresponding ridges on the mating surface, creating various barriers between gasses while allowing relative movement between two mating surfaces.

Cryogenic valves’ sealing surfaces should be smooth and free of surface defects, as imperfections can compromise sealing integrity. Surface roughness is measured in Ra (arithmetic average deviation) or Rz (average peak to valley height). A typical Ra/Rz value for cryogenic seals should be less than 20/100 micro inch respectively.

Cryogenic applications often involve extreme pressure differentials, making it essential to select a polymer seal material that can handle high-pressure environments without extruding or deforming under load. In some cases, this requires designing the seal with an additional support element, such as a metal spring or an energizing lip that helps maintain proper compression force over time.

Proper installation procedures must be followed to ensure optimal performance and longevity of cryogenic seals, which includes ensuring that all mating surfaces are clean and free from debris or other contaminants that could compromise sealing integrity. The assembly process must also account for thermal expansion, which can cause dimensional changes in both components leading to reduced compression forces if not accounted for during installation.

Selecting the correct seals for cold temperature and cryogenic valves requires careful consideration based on multiple factors, including temperature range, pressure range, chemical compatibility, and wear resistance, among others discussed above. Choosing the proper seal can ensure that your valve system will function optimally and prevent leakages, which could be catastrophic in many processing applications. Be sure to work with a trusted supplier who can help you choose the proper seal for your needs and provide expert advice on installation and maintenance.

by Denise Sullivan Denise Sullivan No Comments

Advanced Properties and Applications of PTFE in Sealing Technology

PTFE has a unique combination of properties that make it ideal for use in sealing technology. One of its most notable characteristics is its ability to withstand extremely high and low temperatures. PTFE can operate in temperatures ranging from as low as -200°C to as high as 260°C, making it an excellent choice for applications where sealing performance needs to be maintained at extreme temperatures.

PTFE

Another significant advantage of PTFE is its chemical resistance. It is highly resistant to various chemicals, including acids, alkalis, and organic solvents. This makes it an excellent choice for use in chemical processing plants or other facilities where exposure to harsh chemicals is common.

PTFE also has excellent non-stick properties, which make it ideal for use in applications where adhesion could compromise the effectiveness of the seal. Its low coefficient of friction means that even under heavy loads or with repeated cycles of movement, PTFE will not experience significant wear or degradation.

In addition to these properties, it has outstanding electrical insulation characteristics and acts as a barrier against moisture and dust.

Manufacturing PFE Gaskets

Pure PTFE gaskets are produced by molding directly from suspended material or cutting (turning) from PTFE sheets (rods). Molding plates have uneven density and poor flexibility while turning plates have a relatively uniform density. Still, their material is curved due to the influence of the processing technology, which is not conducive to installation and use.

Modified PTFE gaskets add a certain proportion of functional materials, such as glass fiber or graphite powder, during production. The resulting gasket provides improved strength and durability compared with pure PTFE gaskets while maintaining this advanced material’s desirable properties.

Despite its many advantages, however, some limitations are associated with using PTFE in sealing applications. For example:

  • It can be difficult to achieve consistent compression when using pure PTFE gaskets due to their poor flexibility
  • PTFE can be prone to creep under sustained pressure, which can result in a loss of sealing performance over time
  • PTFE is unsuitable for high-pressure applications as it has low tensile strength and may deform or fail under high loads.

Applications for PTFE 

Despite these limitations, PTFE remains one of the most advanced materials available in sealing technology. Its unique combination of properties makes it ideal for use in various applications where reliable sealing is essential.

One potential application area where PTFE could increase use is the automotive industry. As electric vehicles become more prevalent, there will be an increased demand for seals that withstand harsh operating conditions. Its excellent temperature resistance, chemical resistance, and non-stick properties make it an ideal choice for use in battery enclosures and other critical components.

Another potential application area is within the food processing industry. Many food products are highly acidic or alkaline, which can cause traditional seals to degrade over time. PTFE’s chemical resistance makes it an excellent choice for acidic or alkaline foods. At the same time, its non-stick properties mean that any residue left on the seal after cleaning can easily be removed.

In conclusion, Polytetrafluoroethylene (PTFE) has many advanced properties that make it ideal for use in sealing technology. Its ability to withstand extreme temperatures while maintaining effective sealing performance sets it apart from other materials commonly used in this field. While some limitations are associated with using the material in certain applications, such as those involving high-pressure loads, its unique combination of properties means it remains one of the most important materials currently available. Over time, we may see even greater advances made with this remarkable material with continued research and development into new formulations and manufacturing techniques.