by Denise Sullivan Denise Sullivan No Comments

High Performance Electric Vehicle Seals

electric vehicle seals

 

There is a push for more people to drive electric vehicles. While they are more environmentally friendly, the motors differ significantly from traditional combustion engines. Electric vehicle seals must keep lubrication confined to the gearbox, dirt, and debris out of the motor while providing engine efficiency.

In this article, you will gain a basic understanding of

  • How electric vehicles and internal combustion engines differ
  • Design considerations for electric vehicle seals
  • Types of materials used in making seals for electric vehicles

Differences in Electric Vehicle and Internal Combustion Engines

If you are standing outside an electric vehicle looking at it, you may not notice many differences between it and a gas-powered automobile. The overall external design is the same, except the electric car has no exhaust pipe.

However, below the surface, the two engines are significantly different. Gas-powered have a gas tank, gas pump, motor, carburetor, alternator, smog controls, and hundreds of other moving parts. In addition, the engine requires seals to keep oil and other fluids from leaking out. 

An electric vehicle engine only has one main moving part: the motor. Despite the motor being in a dry environment, seals are still required to help keep dirt and dust out of the engine and the lubricants needed for the vehicle gearbox. 

Both electric vehicles and internal combustion engines require specialized seals to keep the motors/engines working efficiently.

Electric Vehicle Seal Design Considerations

Electric vehicle motors work more efficiently and require seals that can handle their unique needs. The seals used in electric vehicles often exceed the minimum requirements of seals found in internal combustion engines. In addition, many of them must work in dry environments.

Friction

Friction is one of the primary design considerations for electrical vehicle seals. While friction in any engine is not desired, electric vehicles need a lower friction seal than traditional gas-powered engines. Any friction created by seals causes efficiency loss in power output. 

If the engine isn’t efficient, the battery won’t be able to have the range that it should. A motor working harder to make up for the efficiency loss won’t be able to travel as far as it should. Lower friction is essential to gain better efficiency and long distance. 

Dry Running

Electric vehicles require both dynamic and static seals. The dynamic seals are often called rotary lip seals.  While they don’t require oil seals, electric motors need seals that work in a dry-running environment. 

The primary shaft uses a rotary seal to prevent dirt, dust, and water from entering the electric motor. If fluid and debris enter the motor, it can damage the engine and cause it to break down or damage some of the highly charged electrical components so that it won’t work efficiently.

In addition to running in a dry environment, the rotary seals must withstand the higher speeds electric motors run. The components spin up to 18,000 rpm, about three times faster than a traditional combustion engine. As a result, seals in these engines have to withstand high-speed running without lubrication.

Electric Vehicle Seal Materials

Not all materials common seal materials work well in electric vehicles. However, two of the more common types are PTFE and molded rubber. The materials are used for different applications but are necessary as part of the vehicle’s makeup.

PTFE Seals

Polytetrafluoroethylene (PTFE), more commonly known as Teflon, is a nonreactive material with a low coefficient of friction. Therefore, it is ideal for high-temperature environments found in an electric vehicle motor.

Seals made from PTFE are usually found on the e-axle and help to act as a barrier between the motor and gearbox. The engine is a dry environment, while the gearbox requires lubrication. The PTFE seal keeps lubricant from seeping into the motor. In addition, the seal’s dry side has a lip that keeps dust and dirt out of the engine.

In addition to keeping the lubricant in the gearbox and dirt out of the motor, the PTFE rotary seal can withstand the high speeds in the car’s engine. Additionally, it provides low friction to keep the motor running efficiently.

Molded Rubber

While PTFE is the ideal seal material for the e-axle, molded plastic is the perfect solution for valve housing. The valve housing needs a seal that will withstand high temperatures and pressure in the area. The T-junction area of the seal is the most problematic area known for failure. 

Molded rubber seals are push-in-place rubber gaskets that perform well under pulsating pressure. These gaskets can handle temperatures of up to 302°F (150°C) and 50 Bar pressure. In addition, it requires more gland space than seals used in a traditional combustion engine.

Conclusion

Electric vehicles are rising in popularity. However, due to the nature of their engines, they require different seals than a traditional combustion engine. These seals need to have lower friction and handle high-speed rotation.

Need seals for your electric vehicle manufacturing? Contact us today to find out how we can create custom seals for your project.

by Bill Vardeman Bill Vardeman No Comments

Understanding FEP Encapsulated Helical Springs

 

FEP encapsulated helical spring seals are approved for cryogenic and FDA use.

Fluorinated ethylene propylene (FEP) is one of the most popular jackets for encapsulated rings used in cryogenic, corrosive environments, and even FDA-approved food grades. It is well-known by many of the trade names Teflon FEP, Neoflon FEP, and Dyneon FEP. FEP encapsulated helical springs are one type of these seals.

Let’s take a closer look at what an FEP encapsulated helical spring is, the properties of these seals, and the benefits of using them.

What is an FEP Encapsulated Helical Spring

FEP Helical spring seals are created from helical springs. These are elastic coiled mechanical devices. Most consumers are used to seeing helical springs in equipment and devices that store and release energy.

A helical spring seal provides sealing solutions for industries operating in extreme conditions. These seals provide a gas-tight sealing system that meets environmental regulations and reduce fugitive emissions.

FEP encapsulated helical springs seals are housed within a durable, chemical jacket made from fluorinated ethylene propylene. The FEP jacket allows the spring seal to work in chemically corrosive environments or extreme temperatures. 

What are the Properties of FEP Encapsulated Springs

FEP encapsulated helical spring seals’ properties make them ideal for use in extreme conditions. A wide variety of industries can use these spring seals to meet their needs. 

Property Test Method Units Results
Encapsulation Max Service Temperature 8,000-hour aging tests °C / °F 204 / 400
Encapsulation Tear Strength ASTM D1004 (Initial) N / Kg 2.65 / 0.270
Encapsulation Tensile Strength ASTM D638
@ 24°C / 75°F		 PSI / Bar / MPa 3,400 / 234 / 23.0
Encapsulation Impact Strength ASTM D256
@ 24°C / 75°F		 J/m2 No Break
Encapsulation Hardness ASTM D2240 Shore 56
Encapsulation Specific Gravity ASTM D792 g/cm3 2.15
Encapsulation % Elongation @ Break ASTM D638
@ 24 °C / 75°F		 % 325
Encapsulation Flex Modulus ASTM D790 PSI / Bar / MPa 85,000/5,860 / 586
Encapsulation folding Endurance ASTM D 2176 Cycles 100,000
Encapsulation Ignition Temperature Vul045 °C / °F ≥530 / ≥986
Encapsulation Color Visual N/A Off Clear
Moisture Absorption Vul046a % <0.01

 

Advantages of FEP Encapsulated Spring Seals

FEP encapsulated spring seals have many advantages for industrial settings such as cryogenics, aerospace, and oil. It has some of the same advantages as using PFA encapsulated seals.

FEP encapsulated helical spring seals’ properties make them ideal for use in extreme conditions. A wide variety of industries can use these spring seals to meet their needs. 

The FEP jacket protects from corrosive chemicals. FEP has an excellent resistance rating for several chemicals, including the following.

  • Gasoline
  • Hydrochloric Acid (1-5, 20, and 30%)
  • Isobutyl Alcohol
  • Isopropyl Alcohol
  • Propane Gas
  • Sulfuric Acid ( 1-6, 20, 60, and 98%)
  • Sulfuric Hydroxide (1 and 50%)

FEP also has a wide operating range. It works in a temperature range of -420°F (-251°C) to 400°F (204°C). At cryogenic temperatures, FEP encapsulated helical springs remain flexible. This flexibility makes it preferable to O-rings in a cryogenic environment. 

The FEP encapsulated helical springs have low friction. It gives them a minimal stick-slip behavior. A low compression set allows the seal to return to its original shape after deformation.

Best FEP Encapsulated Helical Springs

FEP encapsulated helical seals have several advantages in cryogenic and corrosive environments. They withstand temperatures as low as -251°C (-420°F) and are flexible even at low temperatures. 

Advanced-EMC will work with you to find the encapsulated helical spring solution your application needs, from FDA-approved solutions for use with food processing equipment or a reliable, cryogenically compatible solution for a rocket. Contact us today to learn more.

FAQ

Is FEP silicone?

No, FEP stands for fluorinated ethylene propylene. A Teflon coating protects the seal from hazardous conditions such as extreme temperatures and chemical environments. FEP can encase silicone rings, but it is not silicone itself.

Is FEP the same as PTFE?

No, while both are Teflon substances, there are several key differences. FEP is better with gas and vapor permeability, while PTFE has a lower coefficient of friction.