Extrusion of polymers

Extrusion is a process of manufacturing long products of constant cross-section (rods, sheets, pipes, films, wire insulation coating) forcing soften polymer through a die with an opening.

Polymer material in form of pellets is fed into an extruder through a hopper. The material is then conveyed forward by a feeding screw and forced through a die, converting to continuous polymer product.

Heating elements, placed over the barrel, soften and melt the polymer. The temperature of the material is controlled by thermocouples.

The product going out of the die is cooled by blown air or in water bath.

Extrusion of polymers (in contrast to extrusion of metals) is continuous process lasting as long as raw pellets are supplied.

Extrusion is used mainly for Thermoplastics, but Elastomers and Thermosets are also may be extruded. In this case cross-linking forms during heating and melting of the material in the extruder.

The thermoplastic extruded products may be further formed by the Thermoforming method.

Six PTFE special ovens ordered by Belgian customers have been produced and ready for shipment.

The ovens have been produced and ready for delivery. Our company can produce various types of ovens and sintering furnaces such as high temperature oven, PTFE oven, natural gas sintering furnace, vacuum sintering furnace, stainless steel oven, PTFE rotary sintering furnace, trailer type sintering furnace and so on. Our oven has double safety system, program control, automatic temperature rise and cooling, can set 56 section temperature, with time control and ultra-high temperature double safety protection, good insulation performance, uniform furnace temperature, sintering curve, timing value and temperature can be set. value. The working temperature error in the furnace is ±1 °C, and there is no error within 1000 hours of operation. The inside of the hearth and the turntable made of stainless steel will not rust.

Two sets of sintering furnace ordered by customers in Southeast Asia have been shipped

Our company has customized two sets of PTFE sintering furnace for customers in Southeast Asia, which are used for sintering 1500mm*1500mm PTFE plates and rotary cutting bars. Wheels are installed at the bottom of the sintering furnace according to customer's requirements, which is convenient for moving.

Our company has advanced production equipment and rich experience. Our sintering furnace are exported to the United States, South Korea, India, the Philippines, Russia, Saudi Arabia, Indonesia and other countries... Our company can produce various types of ovens and sintering furnaces such as: high temperature oven, four Fluorine oven, natural gas sintering furnace, vacuum sintering furnace, stainless steel oven, PTFE rotary sintering furnace, trailer type sintering furnace, etc. Our sintering furnace has double safety system, program control, automatic temperature rise and cooling, can set 56 section temperature, time control and ultra-high temperature double safety protection, can customize the oven according to the user's needs, better meet the customer's needs.

Japanese customers order a PTFE paste extruder/polymer extruder customer in our company to accept the inspection last week.

Japanese customers ordered a PTFE paste extruder/polymer extruder in our company. Our company has finished production and the customer went to the site for acceptance. After careful inspection and acceptance by the customer, the machine is well-made without any quality problems. Satisfied, ready to package delivery. Our polymer extruderhttps://www.sukoptfe.com/other-machine can extrude PTFE tubing with high output, high precision and easy operation. Our company provides a full set of technical support, welcome new and old customers to consult.

Our engineers went to the Hebei customer factory to carry out on-site installation and commissioning of the equipment.

Hebei customers purchased a UHMWPE rod extruder and an UHMWPE polymer tube extruder. Our engineers went to the customer site to install and debug the equipment. The installation process was very smooth and the equipment production quality was good.

The commissioning process was smooth, and the equipment was running well during the trial run. Our company also provided customers with recycled raw materials for testing, which saved customers from unnecessary waste during trial operation. Our engineers also provide guidance and training to the technical staff of the customer. The customer is very satisfied with our service.

Our engineers went to the customer site to install the dry grinding and returning machine.

Our engineers went to the customer site to install the dry grinding and returning machine.

The customer ordered a dry grinding and returning equipment from our company to dry-recycle the ptfe waste. Our ptfe waste recycling equipment consists of three machines, namely 1. washing machine 2. dry mill 3. electric sieve mill, the output can reach 40KG per hour.

1. Washing machine: Wash the waste in the washing machine, wash it with detergent, forcibly stir it, wash it once in half an hour, and wash 100-120 kg at a time.

2. Dry mill: put the cleaned PTFE waste into the dry mill and produce 30-40 kg/hour.

3. Electric sifting machine: After the dry grinding, the powder is placed in the automatic sifting machine. There are different mesh sizes such as 100 mesh, 80 mesh and 40 mesh, which can meet different needs. The powder with large particle size after sieving can continue to be placed. Grinded in a dry mill.

Belgian customers order six sintering.furnaces from us

Belgian customers order six sintering.furnaces from us

After careful consideration by many parties, the customer finally selected our products. After the customer visited the factory, they fully affirmed the strength of our company. The customer recognized the quality and service of our equipment, and finally chose to order 6 sintering.furnaces in our company. Our company can produce all kinds of ovens and sintering.furnaces such as: high temperature sintering.furnaces, PTFE oven, natural gas sintering.furnaces, vacuum sintering.furnaces, stainless steel oven, PTFE rotary sintering.furnaces, trailer type sintering.furnaces, etc. Our sintering.furnaces has double safety system, program control, It can automatically heat and cool down, can set 56 section temperature, has time control and ultra-high temperature double safety protection, good insulation performance, uniform furnace temperature, can set sintering curve, timing value and temperature value. The working temperature error in the furnace is ±1 °C, and there is no error within 1000 hours of operation. The inside of the hearth and the turntable made of stainless steel will not rust.

Company website:www.sukoptfe.com

Preparation technology of PTFE fiber

Carrier spinning method
Wet spinning
Wet spinning of PTFE usually in viscose or polyvinyl alcohol (PVA) as the carrier, mix with PTFE powder or emulsion dispersion, and add a small amount of boric acid, make spinning solution , perform wet spinning, spinning head placed in sodium sulfate and ammonium sulfate coagulation bath, dope from the nozzle in the coagulation bath solidified into fiber, fiber after leaching roller soft water leaching, again after oil roller and drying roller respectively, in 380 ~ 400 ℃ high temperature sintering, remove PVA carrier carbide, stretch to make PTFE fiber under 350 ℃. This method of spinning spend process cumbersome, high processing cost and energy consumption and time-consuming. Guo Yu-hai and others invented a highly efficient rapid method of preparation of PTFE fiber. This method will first evenly mix low relative molecular mass of volatile organic solvent with water, in under the condition of stir with PVA, continue to stir until completely dissolved, mixture of PVA water solution. Then the PVA water solution and persulfate, PTFE dispersion mixing uniformity, dope. Then borate or boric acid dissolved in water, with alkaline pH adjustment as alkaline, mixture coagulation bath. Finally adopt the wet spinning equipment of conventional , the spinning fluid conveying to the nozzle, through metering pump metering, direct spinning in the coagulation bath, then drying, sintering and stretch, the PTFE fiber is made.

Dry spinning

This method is PTFE gel realized by dry spinning. PTFE is first concentrated dispersion and PVA blended, add gel regulator boric acid or Borate salts and alkalis adjust the pH to alkaline, whisking to a sudden increase in the viscosity and gel formation, are spinning solution. And then dry them using conventional spinning equipment, gas pressure or screw spinning liquid to the spinning head, measured in metering pumps, dry spinning, and then dried, prepared mixture of PTFE and PVA fiber. Finally using conventional sintering and stretching equipment, will be mixed sintering to remove PVA fiber, finally after stretching process stretching, PTFE fiber preparation.

Carrier spinning method is the most mature method of preparing PTFE fiber, and has been one of the few companies to realize industrialization. Among them, Japan toray company USES mass fraction 60%, the average particle size was 0. 3 microns of PTFE, and the mass fraction of 2% sodium alginic acid aqueous solution of the emulsoid mixed spinning, the fiber by coagulation, bath again after washing, drying, and under 380 ℃ hot stretching, removal of alginic acid sodium, gain PTFE fiber, its monofilament linear density of 0. 67 dtex and fracture strength of l. 25 cN/dtex, elongation at break of up to 59%, the method of spinning dope spinnability better than with viscose as carrier of PTFE dope spinnability. Showa industries, the use of the 114 mass fraction of 60% PT – 100 FE dispersed emulsion and cellulose of mass fraction of 8.9% viscose spinning solution spinning, after solidification of the nascent fibers by water, squeeze liquid, with 0. 05 mol/L Na0H processing, and the fiber heat treatment under 280 ℃ and hot stretching under 320 ℃, the final heat treatment 72 h under 320 ℃, the fiber’s breaking strength for 1. 16 cN/dtex elongation at break was 16.1%. In addition, Beijing demonstration plant will be 60% mass fraction of PTFE emulsion and 10% mass fraction of PVA solution in proportion of 1:1.5 the spinning solution spinning, after solidification of the fiber by acetal, washing, drying, sintering and stretch to PTFE fiber system.

Cutting film splitting method
Cutting film crack method in the early 1970 s by the Austrian Lenzing company development and industrialization, in the preparation of PTFE fiber, need to make PTFE powder sinter cylindrical PTFE parison, cutting it up with a certain thickness of the film, and then by serrated tool divided into silk, above the melting point (327 ℃) sintering, then through stretching and end up with PTFE fiber heat treatment. This method can get the fiber with microporous structure, and high strength. Multifilament can be used as the sealing filler material, short fibers, can be used in the needle felt.

In addition, the PTFE film or sheet can also be cut into tiny width, and then direct tensile narrow fabric made of high strength PTFE fibers. But it is difficult to maintain uniform obtained by cutting along the longitudinal direction through the narrow width of the fabric, and narrow fabric tends to end part of fibril, so much stretch in narrow fabric PTFE fibers easily broken or through partial cutting in the longitudinal direction of the film are filament PTFE membrane orientation. Along the membranes of the longitudinal direction and in the transverse direction of the film with a z shape or linear-convex shape embossed and cut, the resulting filament including individual fibrils partially broken rule the network structure. PTFE fibers produced this way the individual fibrils with small average size and uniform size.

Japan Asahi of into Corporation through cutting film crack legal into has high stretch strength, and resistance chemical performance excellent of PTFE yarn. will containing hole rate 48% of PTFE film tear into 222 dtex of fiber, again on its added twist to 750 twist/m, in 440 ℃ and 1 000 m/min Xia stretch, get of fiber line density for 55 dtex, and containing hole rate 1%, modulus up to 294 cN/dtex.

Paste extrusion spinning method
Paste extrusion spinning usually PTFE powder 16% ~ 25% with mass fraction of volatile lubricants mixes, tune into a paste, made of shaped prefabricated embryos, and under certain pressure through a spinneret with a strip of die extrusion spinning, and then by drying, sintering, high stretch under high temperature, non-uniform white yarn. In addition, can also squeeze film extrusion equipment or thin strips, then by a rolling process to remove additives, and longitudinal cutting, drawing and fluffy after processing, are PTFE fibers were made by paste extrusion of thin wall, small diameter and permeability of PTFE hollow fiber. PTFE powder in conditions below its melting point made of PTFE hollow fiber, and then fired 10 min at 350 ℃, 250 ℃ under 400%, was 0.76 mm inner diameter and wall thickness of 0.10 mm, diameter of less than 0.15 mm hollow fibers.

In 1997, M. Shimizu proposes a method for preparing high strength and PTFE fibers by paste extrusion. Added to the PTFE powder mass fraction 20% of lubricants, embryo, extrusion, gained single wire, heated treatment and then 350 ℃ 1.5h, and 387 ℃ to 50 mm/min of speed stretching 10 times, received strength as much as 1.56 ~ 2.82 GPa PTFE fibers.

The PTFE powder was mixed with a lubricant (isoparaffin oil Isopar-E) to form a paste, standing at 0 ℃ 180 h at 40 ℃ cure 30 h, make the mix full wetting and swelling, then press embryo and extrusion , handle 2 h under 340 ℃, and then to 0. 5 c/min speed down to room temperature, finally stretching to get in a 370 c PTFE fiber, 3.5 ~ 4.0 cN/dtex the fracture strength, elongation at break is 22%.

Melt spinning method

Melt spinning is PTFE content to 4% ~5% of perfluorinated ethylene copolymer of perfluoro-n-propyl ether mixed spinning melt, after spinning by screw extrusion machines pump quantitative pressure injection hole, making it into a fine stream into the air, and cooling in the spinning channel into the wire. PTFE fibers high strength of this method, but PTFE supermolecular structure changes after melting, leading to its ductility disappeared and molecular chain orientation stretch is blocked, together with PTFE high viscosity and apparent flexibility, PTFE melt fiber prepared by screw extruder for direct comparison difficult, difficult to achieve industrialization. Plunger extrusion method can overcome this difficulty. The plunger in the extrusion process, due to extremely low surface energy of PTFE and wall-slip phenomenon, reduce unnecessary shear in the flow process, so they can be on PTFE melt spinning. Li Min and other person in Donghua university, are prepared by the PTFE fibre with high molecular weight. Tervoort by high relative molecular mass such as PTFE and PTFE mixed with low relative molecular mass, melt processing, preparing PTFE filament. Properties of PTFE fibers produced this way worse than that of pure PTFE fiber with high molecular weight.

The Manufacturing Process of PTFE

Making the TFE

1 Manufacturers of PTFE begin by synthesizing TFE. The three ingredients of TFE, fluorspar, hydrofluoric acid, and chloroform are combined in a chemical reaction chamber heated to between 1094-1652°F (590-900°C). The resultant gas is then cooled, and distilled to remove any impurities.

Suspension Polymerization

2 The reaction chamber is filled with purified water and a reaction agent or initiator, a chemical that will set off the formation of the polymer. The liquid TFE is piped into the reaction chamber. As the TFE meets the initiator, it begins to polymerize. The resulting PTFE forms solid grains that float to the surface of the water. As this is happening, the reaction chamber is mechanically shaken. The chemical reaction inside the chamber gives off heat, so the chamber is cooled by the circulation of cold water or another coolant in a jacket around its outsides. Controls automatically shut off the supply of TFE after a certain weight inside the chamber is reached. The water is drained out of the chamber, leaving a mess of stringy PTFE which looks somewhat like grated coconut.

3 Next, the PTFE is dried and fed into a mill. The mill pulverizes the PTFE with rotating blades, producing a material with the consistency of wheat flour. This fine powder is difficult to mold. It has "poor flow," meaning it cannot be processed easily in automatic equipment. Like unsifted wheat flour, it might have both lumps and air pockets. So manufacturers convert this fine powder into larger granules by a process called agglomeration. This can be done in several ways. One method is to mix the PTFE powder with a solvent such as acetone and tumble it in a rotating drum. The PTFE grains stick together, forming small pellets. The pellets are then dried in an oven.

4 The PTFE pellets can be molded into parts using a variety of techniques. However, PTFE may be sold in bulk already pre-molded into so-called billets, which are solid cylinders of PTFE. The billets may be 5 ft (1.5 m) tall. These can be cut into sheets or smaller blocks, for further molding. To form the billet, PTFE pellets are poured into a cylindrical stainless steel mold. The mold is loaded onto a hydraulic press, which is something like a large cabinet equipped with weighted ram. The ram drops down into the mold and exerts force on the PTFE. After a certain time period, the mold is removed from the press and the PTFE is unmolded. It is allowed to rest, then placed in an oven for a final step called sintering.

5 The molded PTFE is heated in the sintering oven for several hours, until it gradually reaches a temperature of around 680°F (360°C). This is above the melting point of PTFE. The PTFE particles coalesce and the material becomes gel-like. Then the PTFE is gradually cooled. The finished billet can be shipped to customers, who will slice or shave it into smaller pieces, for further processing.

Dispersion polymerization

6 Polymerization of PTFE by the dispersion method leads to either fine powder or a paste-like substance, which is more useful for coatings and finishes. TFE is introduced into a water-filled reactor along with the initiating chemical. Instead of being vigorously shaken, as in the suspension process, the reaction chamber is only agitated gently. The PTFE forms into tiny beads. Some of the water is removed, by filtering or by adding chemicals which cause the PTFE beads to settle. The result is a milky substance called PTFE dispersion. It can be used as a liquid, especially in applications like fabric finishes. Or it may be dried into a fine powder used to coat metal

Belgian customers order six sintering.furnaces from us

After careful consideration by many parties, the customer finally selected our products. After the customer visited the factory, they fully affirmed the strength of our company. The customer recognized the quality and service of our equipment, and finally chose to order 6 sintering.furnaces in our company. Our company can produce all kinds of ovens and sintering.furnaces such as: high temperature sintering.furnaces, PTFE oven, natural gas sintering.furnaces, vacuum sintering.furnaces, stainless steel oven, PTFE rotary sintering.furnaces, trailer type sintering.furnaces, etc. Our sintering.furnaces has double safety system, program control, It can automatically heat and cool down, can set 56 section temperature, has time control and ultra-high temperature double safety protection, good insulation performance, uniform furnace temperature, can set sintering curve, timing value and temperature value. The working temperature error in the furnace is ±1 °C, and there is no error within 1000 hours of operation. The inside of the hearth and the turntable made of stainless steel will not rust.

Company website:www.sukoptfe.com

PTFE Shaft Seals

Where High-Speed Seals Are Found

High speed rotary shaft seals are found in many applications.  Examples would include cryogenic deflashing equipment, vacuum pumps, torpedo shaft seals, gas turbine engine starters, and submersible dredge pumps.  AC/DC motors often require high speed shaft seals, and can be found in items like CNC tool spindles and dental or surgical instruments.  

Smooth Operation

Another key issue with high speed seals is the need for smooth operation, which means avoiding problems like stick-slip.  PTFE is an ideal material for avoiding stick-slip, and supports smooth, quiet operation.

Friction

Friction can make or break a high-speed seal.  At high speeds, the effects of friction have a greater impact on seal performance.  Shaft seals need to have extremely low friction, and since some applications may prohibit the use of lubricants, there is a good chance that the ideal polymer material for a high-speed seal will be self-lubricating.  

PTFE is ideal for addressing this challenge because it has the lowest coefficient of friction of any material known to man, and is also self-lubricating.  

Elevated Temperatures

One of the main challenges in high speed shaft seals is controlling temperatures.  High speed leads to increased heat generation.  Heat generation leads to dimensional changes, which means that a high-speed seal needs to have a small coefficient of thermal expansion to ensure dimensional stability.  

Another goal is to conduct heat away from seal, which means that along with a small coefficient of thermal expansion the seal material needs to have a high coefficient of thermal conductivity.  Not all heat can be conducted away, however.  A high-speed seal needs to be made of a material that can handle higher temperatures.  

PTFE can perform well in temperatures up to 500°F.  It has good thermal conductivity which can be greatly improved using carbon fillers, and has a low coefficient of thermal expansion which can be enhanced through fillers such as glass and carbon.

Efficiency

As already mentioned, high speed shaft seals are often used with AC/DC motors.  These are often small and may be battery powered, making efficiency a very important factor.  If losses can be minimized, efficiency can be maximized and have a positive effect on battery life.  A low friction material that promotes smooth operation is vital for these types of applications, and PTFE certainly fits that bill.

Something about UHMW you may want to know

UHMW-PE stands for Ultra High Molecular Weight Polyethylene. It is the highest quality polyethylene (PE) available, engineered for tough jobs and a wide range of applications. It delivers savings in a number of difficult applications. Ultra High Molecular Weight is the secret of this polymer’s unique properties. Its high-density polyethylene resin has a molecular weight range of 3 to 6 million, compared to 300,000 to 500,000 for high molecular weight (HMW) resins. That difference is what ensures that this material is strong enough to withstand abrasion and impact better than lower level poly products. UHMW-PE’s high molecular weight means it will not melt or flow as a molten liquid. Processing methods are therefore derived from those of powder metal technology. UHMW-PE cannot be transformed and molded by conventional plastic processing techniques (injection molding, blow molding or thermoforming). Compression molding is the most common conversion process used with this resin because it produces a stronger, more consistent product.

UHMW is known for its high abrasion resistance, natural lubrication, high impact strength, chemical-, corrosion-, and moisture-resistance and acoustic impedance.

Due to its abrasion-, corrosion-, chemical- and moisture-resistant properties, UHMW is commonly used in applications where conditions may be too harsh for other materials. It is a cost-effective high performance polymer used to produce low cost, high quality parts.

UHMW is a self-lubricating material which exhibits excellent wear and abrasion properties as well as adding extremely high impact strength. A few of the markets which would utilize these attributes would be snowboard bottoms, package handling, packaging, food processing and automotive.

The high molecular weight is what gives UHMW-PE a unique combination of high impact strength efficient of friction and abrasion resistance that outwears carbon steel 10 to 1 making it more suitable for applications where lower molecular weight grades fail.

There are three tests you can perform:

1. Burn Test – light it with a match and smell the smoke. If it smells like candle wax – that indicates polyethylene. UHMW does not drip as readily as HDPE but it will drip.
2. Oven Test – place it in an aluminum dish in a 300 degree oven. Regular HDPE will slump or melt but UHMW will not change size or shape. However, it could warp or distort due to built in stresses.
3. Saw Test – When cut with a saw, regular HDPE gives sawdust or filings while UHMW gives strings or nothing.

Properties of PTFE

PTFE is ideal for performance due to unique properties. The molecular structure of PTFE is depicted in Fig. . The properties of PTFE widely spread in all the branches and being used for a variety of applications. Various properties of PTFE are represented in Fig. Reports on various properties of PTFE have been discussed in this topic.

Physical properties of PTFE

 Barrier properties

PTFE demonstrated superior hydrophobic nature due to the low surface energy. Wrinkled superhydrophobic surfaces, fabricated from two forms of PTFE exhibit the durable and excellent barrier properties as the roll-off angle of the surfaces tend to be very low. The contact angle for single-scale wrinkled PTFE and hierarchical wrinkled PTFE surface was measured at 163° and 172° that has been possessing higher magnitude. Surface modification of PTFE from hydrophobic to hydrophilic property was optimized by the addition of chemical agents amino (-NH₂), carboxyl (-COOH) and sulfonic acid (-SO₃H). On microfiltration analysis, membranes of PTFE adhered with hydrophilic agent’s shows good microfiltration property. The property of plasma modified PTFE is more effective in high-performance direct contact membrane distillation (DCMD). PTFE has been treated with a plasma to obtain pore on the surfaces. Surface morphology study reveals the appearance of parallel pore layers during plasma treatment. Plasma treatment deploys contact angle as a function of treatment time. The bipolar Argon plasma treatment of PTFE also supports the same as with plasma treatment there is an increase in surface free energy. Even though the low surface energy property of virgin PTFE is useful but somehow it is difficult to blend or grind with other polymers. In such a case, the modification of surface is achieved using high-energy irradiation which is in connection with degradation process. Further examination revealed that under irradiation, the PTFE compound has low molecular weight and lower hydrophobicity.

A work on extended PTFE tape demonstrated the increase in water contact angle in a feasible manner. PTFE was stretched using a mechanical device for different ratio of extension. It was portrayed that the increasing extension ratio significantly increases the water contact angle of the surface. The water-repellent property of the surface was mainly due to the decrease in the density of PTFE tape under stretching. More precisely the reason for higher contact angle was the alignment of PTFE microforms on the tape.

The composition of inorganic fullerene-like tungsten disulfide (IF-WS₂) nanoparticles and PTFE improved the hydrophobic property. The drastic change in surface roughness of IF-WS₂/PTFE was revealed by atomic force microscope (AFM) images. Such key factor was the reason for the increase in hydrophobicity. The different contact angles reported for PTFE and PTFE composites are graphically shown in Fig.

Tribological property of PTFE surface

Surface friction of PTFE

Extensive studies have been done on the friction property of PTFE because of interesting low friction coefficient. Friction occurs due to the relative motion of the surface. A virgin PTFE reveals the ultimate friction resistance property therefore optimized for different types of lubrication. As a function of glass fiber, carbon, and graphite loading, there has been a strong influence over friction properties. A wear mechanism was reported for metal precursor-based PTFE composites. Nano-sized PTFE particles were filled in nickel (Ni) and phosphorous (P) coatings. The work revealed the considerable change in friction coefficient (μ) of Ni-P/PTFE coatings when subjected to wear test. Comparatively, Ni-P/PTFE coating exhibited low wear resistance than Ni-P coating because of the presence of PTFE particles.

Surface wear of PTFE

Wear is the most important property of PTFE among surface properties. In general, wear is also associated with mechanical properties, the parameters of wear include weight load, velocity, temperature, contact area, and sliding distance. A familiar method known as Pin-on-Disc setup was used to analyze the wear behavior. This test showed that the friction coefficient for virgin PTFE decreased with the increase in loading of carbon and bronze, increased the wear resistance whereas the friction coefficient was affected slightly. PTFE with filler loadings was effectively have good wear resistance when bearing the weight load over the surface.

Surface lubrication of PTFE

The performance of PTFE as self-lubricant bearings was well known and often examined for its excellent sliding behavior. The mitigation of London dispersive forces in PTFE is due to the highly electronegative fluorine atoms. Furthermore, this property of PTFE was thoroughly examined to improve for high efficiency. In PTFE compound, the fluorine atoms are very close, forming a smooth and cylindrical surface so as the other molecules sliding over easily. In tribological view, PTFE is the topmost material preferred among all.

Abrasion property of PTFE

Abrasion property of PTFE interlinked with wear rate and friction coefficient. Pure PTFE compound are good in abrasion resistance but fixing it on the surface is the challenging task. Glass fiber (GF) and carbon fiber (CF) filled PTFE were tested for the abrasion resistance capacity. The abrasiveness and surface morphology of the worn surfaces of GF/PTFE and CF/PTFE was studied using scanning electron microscope (SEM). The wear volume was certainly lost in GF/PTFE than CF/PTFE. Under various weight loads, CF/PTFE poses better abrasion resistance because of the adhesion of carbon fibers with the PTFE matrix. Although PTFE possesses lower friction property than any other polymer, the addition of filler makes it suitable for interfacing with good friction resistance.

Mechanical properties of PTFE

Tensile, hardness, stress, and strain tests on PTFE

The mechanical property of PTFE deals with the study of tensile strength, stress and strain, ductility, hardness, and molding ability. PTFE is ductile in nature and obviously remains low in mechanical phase when compared to other polymers but PTFE has a good advantage in constructing mechanical device parts by loading filler components. Compression test on two grades of PTFE exhibited good mechanistic performance. Significantly the mechanical properties are affected by temperature hence the samples of PTFE were also tested with the load of 50% at a temperature varying from − 198 to 200 °C. During deformation, PTFE undergoes a structural change of approximately 30% in comparison with metals which are less than 10%. The rearrangement of molecules due to strain is temporary because of the viscoelastic nature of polymers and permanent damage when it reaches the physical aging.

Generally, the unfilled PTFE exhibits very poor flexural properties. An improvement over mechanical property has been studied in detail for the composite material Polyamide6 (PA6)/PTFE. Flexural and tensile properties test were conducted for different PA6 content. The samples were analyzed by keeping constant load for five specimens of different magnitudes and the morphology was observed using SEM. Under stress, the deformation of PTFE occurs and improves the flexural toughness due to the absorption of energy. Results showed that the 30% PA6-reinforced PTFE composites have a significant improvement in mechanical performance. The improved tensile strength of PTFE composites is depicted in Fig.

Improvement of mechanical property as a function of temperature

PTFE filled with expanded graphite nanoparticles (nano-EG) with reinforcement of nano-aluminum oxide_, nano-copper, nano-silicon dioxide were studied to explore its mechanical properties. Dynamic mechanical thermal analysis (DMTA) method was used to analyze the mechanical property. It is noteworthy that the composites reinforced with nano-materials have a remarkable improvement in strength and hardness in comparison with the pure PTFE. DMTA provided good results under testing of the composites and different types of reinforcement showed different distinct mechanical properties. Notably, the composite added with nano-Al₂O₃ showed higher tensile strength and the composite added with nano-SiO₂ showed high elastic modulus. Dynamic mechanical testing proved that the increase of hardness in PTFE/Nano-EG composites with an increase in stress relaxation time and limit.

Creep resistance properties of PTFE

Creep test is important for engineering polymers. Lower creep rate increases the ability of the material to withstand under harsh physical conditions. PTFE exhibits high creep and causes hindrance to utilize in applications. The improvement in creep properties of PTFE with the addition of micro and nanoscale fillers are an important case of study. Directional PTFE/nano-SiO₂ thin films were tested for the improved creep property. Epoxy based nano-SiO₂ mixed with powder PTFE before it is executed for sintering process. The addition of SiO₂nanoparticles increases the crystalline form of PTFE. Thermal mechanical analyzer (TMA) was used to analyze the mechanical properties of the composite. The tensile properties of PTFE and PTFE composites (nano-SiO₂) were measured and it shows the difference in modulus, tensile strength, and elongation at break at a different weight percent (wt.%) of PTFE/Nano-SiO₂. The results clearly indicate that the addition of nano-SiO₂ considerably improves the tensile strength and hardness and in particular, it reduces the creep strain and creeps rate. The reinforcement of short carbon fibers and short glass fibers significantly improved the tensile strength of 18 wt.% and 20 wt.% of the filler ratio to the PTFE which was reported by the authors.

Chemical properties of PTFE

The peculiar property of PTFE is chemical inertness. Naturally, PTFE is non-reactive and insoluble due to the strongly bonded carbon-fluorine atom. The high molecular weight is responsible for chemical inert behavior. PTFE is not affected by common reagents such as hydrofluoric, hydrochloric, and chlorosulfonic acids. Even above the transition temperature (327 °C), PTFE is insoluble in organic solvents like hydrocarbons, chlorinated hydrocarbons, or ester and phenol. This is due to the very fewer interaction forces between fluorocarbon and other molecules.

Solubility of PTFE

A detailed and comparative examination has been made on the solubility of PTFE under thermodynamic observations. The solvents chosen are oligomers, non-oligomeric perfluorocarbons, aromatic perfluorocarbons, and non-perfluorocarbons. The report was consolidated the different types of thermodynamic solubility influence on PTFE. The solubility of PTFE involves various factors such as temperature, pressure, solvent polarity and swelling in solvents.

There are many practical issues of PTFE in terms of solubility. Several methods were employed to understand the solubility of PTFE with commercial solvents such as perfluorocarbon and other halogenated fluids. Autogenous and superautogenous methods were involved in the solubility of PTFE under applied pressure. The report suggested that the entropy effects cause insolubility due to the less intermolecular forces. The molecular weight of the solvent can influence the solubility with the increase of lower critical solution temperature.

2.4 Thermal properties of PTFE

The performance in terms of thermal conductivity of PTFE over a wide range of temperature is excellent than other polymers. The thermal stability is due to the linear high crystalline arrangement of carbon-fluorine atoms that shows a high melting point of about 342 °C. For the measurement of crystallinity, different techniques can be preferred such as X-ray diffraction, density and dynamic mechanical analysis (DMA). The differential scanning calorimetry (DSC) technique was used to prepare the material from the melt with different crystallinity as a function of temperature. The sample was further tested with reference to one another. The thermal conductivity was measured using Lee’s disk apparatus clearly indicates the improvement in heat transport of aluminum flakes included PTFE. The increase in thermal conductivity at 232 °C was noted for different levels of crystallinity. A detailed study on the thermal behavior was carried out by incorporating ceramics (Sr₂ZnSi₂O₇) as a filler with PTFE. This work explains that how the filler fraction is responsible for the increase in thermal conductivity of the composites. It was measured that the thermal conductivity of Sr₂ZnSi₂O₇ is 16.5 W/mK which is large when compared with PTFE (0.283 W/mK). The increase in thermal conductivity depends upon the filler material’s shape, size, and thermal properties. The fillers generally provide the heat transfer path which was the reason for the increase in thermal conductivity.

2.4.1 Thermal transport property of PTFE composites

Thermal transport property of Al/PTFE nanocomposite with graphene and CNT were reported. Graphene and CNT are widely involving in numerous applications and significantly influence the material behavior which is added along with them. By introducing graphene into Al/PTFE, increasing thermal conductivity was observed. Al acts as a mediator for heat transportation throughout the composite. Thermal diffusivity analysis of Al/PTFE portrayed about how quickly the material responds to the heated environment. The addition of graphene in Al/PTFE increases thermal diffusivity in contrast to the addition of nano carbon (C) allotrope and CNT. The amorphous nature of nano C and CNT is due to the random arrangement of sp² and sp³carbons which results in low thermo-physical property.

2.5 Electrical properties of PTFE

2.5.1 Dielectric property of PTFE

PTFE would play a role of a dielectric medium or insulating medium in an electronic component was consumed potentially because of distinct electric properties. The dielectric constant (ɛ_r) and the dissipation factor (tanδ) are very important for a material operating as a dielectric medium in the charge storing devices. Recently, many works were explored the dielectric properties of PTFE-based composites. Depending upon the filler property, the ɛ_r and tanδ varied and demonstrated in many reports. The improved ɛ_r and tanδ for various PTFE-based composites are shown in Fig. . It shows the PTFE composites tested under different frequency ranges and their respective ɛ_r and tanδ values. It is obvious that depending upon the frequency, the polarization mechanism varies for different types of composites. For PTFE filled with SiO₂ (silicon dioxide), the values of ɛ_r and tanδ increased at 5GHZ of frequency when compared to Virgin-PTFE. The large surface area of the SiO₂ and their moisture absorbance and contaminants were taken into account for explaining the function of ɛ_r and tanδ. PTFE/AlN (aluminum nitrate) showing improved ɛ_r and tanδ as a function of filler loading. The values were obtained in the low frequency range from 100 Hz to 1 MHz which was suggested for electronic packaging. PTFE/TeO₂ showed excellent ɛ_r and tanδ stability tested under 1 MHz and 7 GHz of the frequency range. The increase in tanδ was observed due to the interfacial polarization of the ceramic TeO₂ particles at higher volume fraction in the PTFE matrix. The experimental results showed the improved dielectric constant of MgTiO₃ceramic filled PTFE. The results were good in agreement with the Maxwell-Garnett theoretical model which considers the occupation of ceramic particles in the host polymer system. The calcium copper titanate incorporated PTFE and its dielectric property was studied. The ɛ_rhere reported at low frequency (100 Hz) and attributed to interfacial polarization mechanism. The size of the particle present in the composites obviously changing the value of ɛ_r and tanδ which were demonstrated. Over different frequency ranges, PTFE is stable and possess low dielectric constant ɛ_r ∼ 2.1 and low loss tangent because of the neutralization of dipole moment exhibited by C-F bonds. A work was reported on the moisture absorbance of PTFE/Micron-rutile and PTFE/Nano-rutile composites. The moisture absorbing phenomena is important here because the water molecules are polar in nature having high ɛ_r ∼ 70 which can significantly affect the dielectric nature of the PTFE composition. It is to understand from the above notes that the filler compositions, the size of the particles, frequency, and property of the host polymer system are the important parameters for the dielectric properties.

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 Optical and spectral properties of PTFE

The inherent optical and spectral properties of PTFE greatly help in the instrumentation of efficient optical devices. The light reflectance and diffusion parameters of PTFE are extremely high; hence, the material has been inevitable in optical instrumentation. Reflectance factor is the measurement of the surface’s ability to reflect light which is equal to the ratio of reflected flux to the incident flux. PTFE exhibits good optical characteristics from a broad ultra-violet to near infra-red spectrum and good in performance when exposed to light or any other electromagnetic radiation. The reflectance angle measurements were studied using reflectometer which was used to measure the bidirectional reflectance of the PTFE pallet. The applications of PTFE as a light diffuser in radiometry were very attractive. The Lambertian surfaces (an ideal surface having high diffusive reflectance) are constructed with PTFE. Previous works considering that low density PTFE functions as a Lambertian diffuser. Measurement of bidirectional reflectance distribution function (BRDF), directional hemispherical reflectance (DHR) and directional hemispherical reflectance (DHT) were taken for two samples namely high density PTFE (HD PTFE) and low density PTFE (LD PTFE). To cover the entire wavelength of the spectrum, the aforesaid measurements were carefully done with the help of Fourier transform infrared Raman spectroscopy (FTIR) and LAMBDA 950 spectrophotometer. The results shown were in favor of LD PTFE because of the order of magnitude for DHR is less than HD PTFE.

The reflectance factor of PTFE is extreme to sustain at high intense electromagnetic radiation. For all optics-based instrumentation works, PTFE was suggested as a white light diffuser. A work was conducted to study the reflectance factor of pressed PTFE powder with a standard reflectance factor scale ratio (45°/0°). The sample was pressed and examined with 45°/0° reflectometer for wavelength varying from 380 to 770 nm. Analysis of samples was done by taking two variabilities: one is an operator (samples collected from 10 different laboratories) and another one is the material (various composition of PTFE). Final result evolved with the expanded uncertainty of 45°/0° reflectance factor due to material and operator variability.

Amorphous PTFE commercially known as Teflon®AF is having a glass-like transparency and possess good optical properties and highly preferred in optical devices. Teflon® AF is a copolymer of PDD and TFE. A detailed study was conducted to calculate the refractive index, extinction coefficient (k), the absorption coefficient (α) and optical absorbance (A) of three different grades of Teflon®AF. The purpose of this work was to compare all the three grades for their respective optical properties. The samples were analyzed using spectroscopic ellipsometer. Further results revealed that the optical characteristics varied for three different grades of Teflon®AF with respect to the TFE content.