PTFE and Graphite are popular materials used in valve and shaft packing, as well as similar applications. Both are usually found in a braided style, and both have a low coefficient of friction that allows them to be excellent sealants with longer shelf lives. They are both cost-effective, durable, and low maintenance.
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Despite all these similarities, PTFE and Graphite are very different types of sealants and often are used for different purposes. The main difference is the material each one is made from. Graphite is a naturally-occurring form of carbon white PTFE, or Polytetrafluoroethylene is a synthetic polymer. These origins cause them to have different properties and different applications.
PTFE Packing
PTFE is a white-colored synthetic polymer that can be lubricated and braided to form a flexible packing with excellent properties. This strong resin is highly resistant to aggressive substances, such as chemicals, acids, gasses, and many more caustic or abrasive substances. It protects shafts from wear and tear and is good insulation in electrical applications. Multi-yarn packings can also be made for increased strength and better lubrication capabilities.
PTFE is a widely-used braided sealant, as it is excellent for a wide range of systems dealing with fuel gasses, mineral and synthetic oils, steam water, effluents, strong chemicals, and many more. PTFE can be used in industrial plants that handle corrosive substances and oxidizers (except molten alkali metals). It’s also widely used in systems that handle other aggressive substances in pharmaceutical, food, aerospace, and electrical markets.
PTFE can also be combined with other materials to improve its properties and performance to meet specific application requirements. For example, multi-yarn PTFE packings can be designed to meet FDA requirements for edible products and pharmaceuticals. Overall, PTFE packing is a versatile and flexible sealant.
Graphite Packing
Graphite is a naturally occurring, inorganic form of pure carbon used to form a black-colored braided sealant. Graphite packings can also be blended with many other materials, including PTFE, for enhanced characteristics. They are good conductors of heat and are suitable for agitators, valves, and shafts that handle chemicals and acids.
Graphite packings are suited to high-pressure applications, faster shaft speeds, and high temperatures, such as steam turbines and high-temperature valves. They are a perfect alternative to asbestos packings, with simple installation and maintenance. Graphite packings offer even more benefits when treated with PTFE, such as preventing color contamination and improved system stability.
Part One
Last month, "carbon/graphite fiber" braided packings were shown to be effective solutions to many common sealing applications. But the questions remain: Are there packing materials that can more effectively seal at high temperatures? If so, do they require blocking agents?
The answer is yes, in the form of "flexible graphite" packings. Flexible graphite, also referred to as expanded graphite, begins with natural mineral flake graphite, found and mined in various parts of the world.
The "flakes" form a laminated or layered structure of completely crystalline graphite, which is essentially elemental carbon. This may be compared to a new deck of playing cards that has all its individual cards cemented together. In this unexpanded form, flake graphite is used for such products as dry powder lubricant, and the "lead" in pencils. It has excellent lubricity in this form, but poor sealing attributes.
However, when expanded and recompressed, it is transformed into a soft, flexible material (hence the term "flexible" graphite). It is resistant to strong chemicals and high heat, has a very low coefficient of friction, and has the wonderful advantage over braided carbon/graphite fiber packings of being an even superior conductor of heat - a real plus on rotating shaft/sleeves - with limited cooling water.
Flexible graphite has good corrosion resistance and will take the geometry of any vessel into which it is compressed, forming a homogeneous mass that makes it an excellent sealing material.
Expanding graphite flake is accomplished with the use of very strong oxidizing agents, such as sulfuric and nitric acids. After the acids weaken the bonds between the layers, the flakes are rinsed, dried, and exposed to high heat. The heat causes the layers to separate and form wormlike shapes.
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Imagine our previously mentioned deck of cards where all of the individual cards have been misshapen and then put back into the deck, giving the impression that the deck has expanded. When flake graphite goes through this process, it expands dramatically, now taking the appearance of wormlike shapes and giving cause to an often used description for expanded graphite: "vermiculated (worm-like) graphite."
Unfortunately, after compressing the worm-like graphite into flexible graphite it has very little tensile strength, so making it into yarns strong enough to be braided requires creativity. Since the flexible graphite is usually processed into sheets, typically a meter wide, some yarn manufacturers have simply embossed a variety of fibers into flexible graphite sheet for tensile reinforcement, and the sheet is then slit into braiding strands.
Another method is to knit Inconel wire netting around strands of flexible graphite and use them as braiding yarns (this braided product is typically used for valve applications, rather than high speed rotating equipment).
A third yarn-making method is to pultrude flexible graphite around a tiny bundle of carbon reinforcement yarns, which benefits from the properties of both carbon/graphite fiber and flexible graphite.
Since flexible graphite is an excellent sealing material, blocking agents are typically not required, depending on the ratio of flexible graphite to its reinforcement. Too much fiber reinforcement may defeat the optimum qualities of flexible graphite, and this may then require blocking agents to affect a seal.
In addition, too high a ratio of reinforcement to flexible graphite may inhibit the braided packings' ability to transfer heat on rotating applications. Some flexible packing manufacturers do add lubricant to their flexible graphite yarns in the braiding process to assist in the break-in period on high-speed rotating shaft/sleeves, but high quality flexible graphite, made into yarns and then braided, typically does not require added lubricants.
As we discussed last month, carbon/graphite fiber packings are limited to the maximum temperature of their blocking agents, such as PTFE. Flexible graphite packings without added lubricants can exceed these temperatures and are typically rated well over 1,000-deg F. Some high purity die-formed graphite rings can handle even higher temperatures in a non-oxidizing atmosphere.
Since flexible graphite can form a homogeneous mass without the need for blocking agents or added lubricants (which could be "washed out" by chemically corrosive media, or "cooked out" in extremely high temperature), it is a very effective material in sealing fugitive emissions of "volatile organic compounds" (VOCs).
VOCs have been targeted by a number of government environmental agencies as being responsible for air pollution. As such, braided flexible graphite has become an excellent sealing material for valves and flanges in the chemical process industries, limiting such fugitive emissions.
Braided flexible graphite packing is also finding greater acceptance in sealing rotating equipment (pumps, mixers, agitators, etc.) requiring near leak-free and flush-free service.
Flexible graphite may be susceptible to chemical attack in the presence of strong oxidizing fluids, including air at extremely high temperatures. These include liquids such as nitric acid, especially over 20 percent concentration, and sulfuric acid, especially over 98 percent concentration. Some compositions include oxidation inhibitors or are physically structured to extend temperature capability when exposed to oxidizing gases. Excessive shaft run-out in pumps and mixers also can adversely affect sealing performance of some flexible graphite packings just as they might with some fibrous packings. Because the material is not very abrasion resistant, pump applications with abrasive slurries or dissolved solids that can form abrasive precipitates also can cause sealing problems and may require a flush, reinforcement with fibers or foils, or corner yarns of a more abrasion resistant yarn.
As we learned last month, carbon/graphite fiber packings have proven to be effective solutions to many common sealing applications. This time, we have learned that flexible graphite packings appear to have become the packings of choice when sealing fugitive emissions, high heat media, and rotating equipment with limited cooling or flush available.
Which graphite packing is right for you? Consult your packing manufacturer for proper selection and installation assistance.
Next Month: What are the considerations in applying mechanical seals to abrasive slurry applications?
Pumps & Systems, August