Extreme performance--or processability? New TP polyimide offers both.Challenging applications in military and aerospace electronics, healthcare, and down-hole oil and gas applications have created the need for extreme-performance resins that combine very high heat and chemical resistance with good thermoplastic A polymer material that turns to liquid when heated and becomes solid when cooled. There are more than 40 types of thermoplastics, including acrylic, polypropylene, polycarbonate and polyethylene. melt processability. These market requirements prompted the development of Extem resin, a new amorphous, melt-processable thermoplastic polyimide Pronounced "poly-ih-mid." A type of plastic (a synthetic polymeric resin) originally developed by DuPont that is very durable, easy to machine and can handle very high temperatures. Polyimide is also highly insulative and does not contaminate its surroundings (does not outgas). (TPI (Tracks Per Inch) The measurement of the density of the storage channels on a disk or tape. Track density on magnetic disks has reached 125,000 tpi (125 Ktpi). See bpi, areal density and magnetic disk. ). Introduced by GE Plastics this past November, Extem resin is an offshoot of GE's 20-year experience in making Ultem polyetherimide resin. GE Plastics expects the new TPI to help narrow the performance-vs.-processability gap facing current high heat thermoplastic and thermoset A polymer-based liquid or powder that becomes solid when heated, placed under pressure, treated with a chemical or via radiation. The curing process creates a chemical bond that, unlike a thermoplastic, prevents the material from being remelted. See thermoplastic. materials (see Table 1). Extem resin boasts the highest glass transition (Tg) of any amorphous thermoplastic, at 311 C. Along with this extreme heat resistance, it offers high chemical resistance, high strength and stiffness, robust dimensional stability dimensional stability, n See stability, dimensional. , and high inherent flame resistance. At the same time, it provides the manufacturing productivity of melt processing by injection molding injection molding n. A manufacturing process for forming objects, as of plastic or metal, by heating the molding material to a fluid state and injecting it into a mold. , extrusion, blow molding, or thermoforming without requiring any post-cure or crystallization Crystallization The formation of a solid from a solution, melt, vapor, or a different solid phase. Crystallization from solution is an important industrial operation because of the large number of materials marketed as crystalline particles. steps to yield its maximum performance. Extem resins are the culmination of 14 years of R&D that included development of new monomers and a new manufacturing process. That process has been proven first at a pilot plant in the U.S., then at a just-launched semi-works plant in this country that can produce hundreds of tons annually. Additional commercial capacity for Extem resin is being scaled up at GE's new high-performance polymer plant due to open in Cartegena, Spain, in 2008. Target applications Extem resin's combination of processability and outstanding performance can help catapult the use of TPIs from exotic, low-volume applications to broader mainstream use. More than 30 customers are sampling and developing applications utilizing Extem resin. Extem resin's extreme heat, as well as improved chemical resistance to hydrocarbons and chlorinated chlorinated /chlo·ri·nat·ed/ (klor´i-nat?ed) treated or charged with chlorine. chlorinated charged with chlorine. chlorinated acids some, e.g. solvents, will position it for components in the down-hole oil and gas industry. Producers of aerospace and military connectors also can benefit from its high as-molded performance without additional postcure time or the long cycle times of nonmelting and thermoset imidized resins. Extem resin's potential lead-free solder solder (sŏd`ər), metal alloy used in the molten state as a metallic binder. The type of solder to be used is determined by the metals to be united. Soft solders are commonly composed of lead and tin and have low melting points. Hard solders (i. capability--along with its balance of strength, stiffness, and dimensional stability--makes it an excellent candidate for electrical, electronic, and semi-conductor applications. In automotive, Extem resin could offer opportunities for metal replacement. And in healthcare, Extem resins offer an interesting blend of properties that have shown significant benefits in hemo-compatible membranes. How it compares Demand for high-performance polymers (HPP HPP hyperkalemic periodic paralysis. ) is experiencing about 9% annual growth. The HPP market includes three major categories of polymers--amorphous thermoplastics, semi-crystalline thermoplastics, and non-melting and imidized materials (Fig. 1). Performance in the HPP world typically centers on chemical resistance and continuous-use temperature. Additionally, there are a variety of secondary considerations such as wear resistance and flammability flam·ma·ble adj. Easily ignited and capable of burning rapidly; inflammable. [From Latin flamm . [FIGURE 1 OMITTED] Amorphous thermoplastics such as PEI and polyethersulfone IPES IPES Improved Proposed Encryption Standard (cryptography) IPES Inverse Photoemission Spectroscopy IPES Information Processing Equipment and Software IPES Imus Pilot Elementary School IPES International Personnel Exchange System ) are typically characterized by relatively high Tg--217 C and 230 C, respectively. This leads to retention of strength, stiffness, and dimensional stability across a wide range of elevated temperatures. However, they are generally limited in their range of chemical resistance, particularly to highly alkaline materials, and are restricted to continuous-use temperatures below 200 C. Semi-crystalline polymers such as PEEK and PPS (Packets Per Second) The measurement of activity in a local area network (LAN). In LANs such as Ethernet, Token Ring and FDDI, as well as the Internet, data is broken up and transmitted in packets (frames), each with a source and destination address. offer high melting temperatures--334 C and 285 C, respectively--plus broad chemical resistance and high retention of properties under thermal aging. They are, however, susceptible to dimensional change and require glass fillers to maintain strength and stiffness above their relatively low Tg--85 C for PPS and 150 C for PEEK. Current imidized materials such as polyamide-imide (PAI PAI plasminogen activator inhibitor. PAI Plasminogen activator inhibitor, see there ) and thermoset polyimide (PI) offer a combination of amorphous and semi-crystalline attributes for extreme performance but fall short in productivity because of the need for long thermoset cure cycles, post-mold curing or crystallization, or milling parts from extruded stock shapes. For example, PAI can be injection molded as a thermoplastic but must be post-cured for up to 15 days in order to achieve its maximum physical properties. In its uncured state, PAI is a brittle, low-strength resin that must be handled very carefully in order to minimize part breakage. During the cure cycle, the imidization process is completed, which raises the strength, wear, and thermal characteristics. Once PAI parts are cured, the parts cannot be recycled or reused, as the material is now a thermoset. Components produced from thermoset polyimide can be molded with long cure cycles using compression molding Compression molding is a method of molding in which the molding material, generally preheated, is first placed in an open, heated mold cavity. The mold is closed with a top force or plug member, pressure is applied to force the material into contact with all mold areas, and heat or vacuum-bag/autoclave techniques. Or parts can be cut or milled from cured shapes such as film and slab stock. This limits the geometry of the final parts. There is, in addition, one other melt-processable TPI on the market, but it has a lower Tg and requires post-mold crystallization to achieve its maximum properties. Two resin families The Extem resin platform will initially offer two families of materials, Extem UH and Extem XH resins. The Extem UH family will offer the highest heat resistance, with a Tg up to 311 C, plus broad chemical resistance. The Extem XH family will offer a Tg up to 267 C along with higher melt flow. Additional attributes of Extem resins include exceptional dimensional stability; high strength, stiffness, and creep resistance at elevated temperatures; transparency; outstanding flame, smoke, and smoke-toxicity performance without additives, such as a high limiting oxygen index (LOI LOI Letter of Indemnity (international trade and carriage business) LOI Letter Of Intent LOI Loss On Ignition LOI Letter of Inquiry LOI Lack Of Information LOI Lack of Interest LOI Letter of Invitation LOI List Of Items ) of 45% to 47%. GE Plastics is investigating at least 75 potential products based on Extem resin, including various filled/reinforced compounds and blends with Ultem or other resins. Extem is also expected to join GE's LNP (Local Number Portability) The capability of keeping the same local telephone number when switching carriers. See NP and WLNP. portfolio of compounds designed for wear resistance, electrostatic Stationary electrical charges in which no current flows. For example, laser printers and copier machines place a positive charge of the image on a drum, and negatively charged toner is attracted onto the drum. The toner is then transferred to positively charged paper and fused to the paper by heat. dissipation (ESD (1) (Electronic Software Distribution) Distributing new software and upgrades via the network rather than individual installations on each machine. See ESL. ), and other properties. The UH family has a tailorable Tg from 260 to 311 C. The first commercial product from the UH family of resins will be a high-performance blend that allows melt processability on standard injection molding equipment. This product, as can be seen from the DMA (1) (Digital Media Adapter) See digital media hub. (2) (Document Management Alliance) A specification that provides a common interface for accessing and searching document databases. curve in Fig. 2, is a fully amorphous thermoplastic with a Tg as high as 280 C, the highest of any amorphous thermoplastic available today. This allows for retention of strength and creep resistance in unfilled, as-molded components up to very high temperatures, as signified by HDT HDT Heat Deflection Temperature (plastics) HDT High Dose Therapy HDT Heatpipe Direct Touch (Xigmatek) HDT Heat Distortion Temperature (plastics) HDT Henry David Thoreau as high as 265 C (Table 2). As indicated in Fig. 2, the primary drawback to other high-performance semi-crystalline resins is relatively low Tg, leading to losses in stiffness, strength, and creep resistance above that temperature. Extem UH resins also offer continuous-use temperatures as high as 230 C (preliminary). [FIGURE 2 OMITTED] Ultem resins have been used in applications with continuous-use temperatures as high as 200 C and UL Relative Thermal Index (RTI RTI - Return from interrupt ) ratings up to 180 C. However, Extem UH resins are expected to have continuous-use temperatures as high as 250 C and potentially achieve UL RTI ratings at or above 200 C, a level that no other melt-processable, amorphous thermoplastic can claim. Extem UH resins demonstrate outstanding thermal-oxidative stability at extreme temperatures as shown in Fig. 3. In addition to very high heat resistance, Extem UH resin also possesses superior chemical resistance. For example, GE's Ultem resin, though amorphous, has good resistance to chemicals such as organics and acids. Ultem CRS CRS Course CRS Certified Residential Specialist (real estate certification) CRS Central Reservation System CRS Can't Remember Stuff (polite form) CRS Cost Reduction Strategy CRS Consumer Relations Specialist 5001 resin currently offers the best chemical resistance in that family. But Extem UH resins radically outperform Ultem CRS5001 resin--for example, in resistance hydrocarbons such as toluene toluene (tōl`y  ēn') or methylbenzene (mĕth'əlbĕn`zēn), C7H8 and aggressive solvents like methyl ethyl ketone methyl ethyl ketonen. See butanone. methyl ethyl ketone See butanone. Noun 1. methyl ethyl ketone (MEK Noun 1. MEK - a terrorist organization formed in the 1960s by children of Iranian merchants; sought to counter the Shah of Iran's pro-western policies of modernization and opposition to communism; following a philosophy that mixes Marxism and Islam it now attacks the ) and chlorinated solvents such as methylene chloride Noun 1. methylene chloride - a nonflammable liquid used as a solvent and paint remover and refrigerant dichloromethane chloride - any compound containing a chlorine atom (Fig. 4). These new materials demonstrate chemical resistance comparable to cured PAI or PI. [FIGURE 4 OMITTED] Easier-flowing Extem XH The Extem XH family of resins is characterized by its extreme heat capability balanced with greater processability. While maintaining high creep resistance and strength at elevated temperatures, it can be injection molded to fill thin-wall, complex parts. Extem XH resin will offer a high-strength material for short-term heat resistance above 200 C. This offers the potential for use in lead-free soldering of electronics. At room temperature, many high performance amorphous and semicrystalline thermoplastics exhibit very high tensile strength tensile strength Ratio of the maximum load a material can support without fracture when being stretched to the original area of a cross section of the material. When stresses less than the tensile strength are removed, a material completely or partially returns to its (over 100 MPa). Extem XH resin, while not the strongest material at ambient ternperature, outperforms many others at temperatures up to 240 C by retaining more of its tensile strength and creep resistance. Figure 5 demonstrates the tensile strength of Extem XH resin vs. other high-performance resins at ambient temperature Outside temperature at any given altitude, preferably expressed in degrees centigrade. and 170 C. [FIGURE 5 OMITTED] Extem XH resins are transparent, dark amber, whereas most other extreme-performance resins are opaque. (Initial grades of Extem UH are not transparent.) Light transmission averages 35% over the visible spectrum from 400 to 700 nm. The average transmission in the visible range is governed most by the attenuation Loss of signal power in a transmission. Attenuation The reduction in level of a transmitted quantity as a function of a parameter, usually distance. It is applied mainly to acoustic or electromagnetic waves and is expressed as the ratio of power densities. below 500. This gives the XH material its dark amber hue. The yellowness index of Extem XH resin is in the range of 120 to 130 vs. 80 to 90 for Ultem resin. In the infrared region, the XH family has transmission of 80%. While all Extem resins are melt processable, the Extem XH family offers better flow properties. Extem XH resin exhibits about 20% greater flow than Ultem 1000 resin at process temperatures of 775 F (412 C) and 690 F (365 C), respectively (Fig. 6). [FIGURE 6 OMITTED] Extem XH resin can be used in complex, multi-cavity tools. Thin-wall injection molding of Extem XH has been demonstrated in parts with 0.010-in. wall thickness at flow lengths of over 0.250 in. Longer flows up to 4 in. for wall sections 0.030-in. thick have been achieved at injection pressures of 32,000 psi. Molding cycle times are comparable to those for Ultem resin--on the order of 35 sec for standard ASTM ASTM abbr. American Society for Testing and Materials test components. Minimal warpage is observed at high ejection ejection /ejec·tion/ (e-jek´shun) 1. the act of casting out or the state of being cast out, as of excretions, secretions, or other bodily fluids. 2. something cast out. 3. temperatures. Processing Extem resins Extem resin was developed with the processor in mind--i.e., to be fully melt-processable on high-temperature injection molding and extrusion equipment without the need for post-curing imidization steps. Extem resins must be dried to 0.2% moisture prior to injection molding. This can be accomplished in standard dryers at 150 to 175 C (302 to 347 F) with a dewpoint of-29 to -40 C (-20 to -40 F) for 4 to 6 hr. Injection molding equipment should be capable running melt temperatures of 390 to 420 C (734 to 788 F). Oil or electric-heated molds capable of operating in the range of 160 to 200 C (320 to 392 F) will handle the temperatures required to maximize flow length and minimize molded-in stress. Molds should be built of P20 or stronger steel to accommodate necessary thermal loads. Aluminum tools are not recommended for production but can be used for short prototype runs. Molds should also be designed to accommodate a stiffer overall flow, incorporating multiple gates and flow runners when challenged with a high flow-length/wall-thickness ratio. Generous gates, such as fan gates, should be employed when possible to minimize internal stresses. Sub-gates have also been successfully used to mold Extem resins. Grades containing mold release will be offered to minimize sticking and improve ejection efficiency. Mold designs should incorporate typical amorphous isotropic Refers to properties that do not differ no matter which direction is measured. For example, an isotropic antenna radiates almost the same power in all directions. In practice, antennas cannot be 100% isotropic. shrinkage rates of 0.5% to 0.7% for unfilled grades. Glass-filled materials will exhibit lower but anisotropic Refers to properties that differ based on the direction that is measured. For example, an anisotropic antenna is a directional antenna; the power level is not the same in all directions. Contrast with isotropic. shrinkage. In general, barrels and screws of conventional materials of construction are acceptable, though bimetallic bi·me·tal·lic adj. 1. Consisting of two metals, often bonded together and having different rates of thermal expansion. 2. Of, based on, or using the principles of bimetallism. screws are suggested. Nitrided metals are not recommended. Screw designs should have 16:1 to 24:1 L/D L/D Labor and Delivery L/D Lethal Dose L/D Lift/Drag (ratio) L/D Low Dynamic L/D Limiter/Discriminator L/D Loading / Discharging Rate (shipping) and low compression ratios of 1.5:1 to 3:1. Compression should be accomplished with a gradual and constant taper without sudden transitions in order to minimize excessive shear and material degradation. Barrels should be sized to accommodate 40% to 80% of the shot size to minimize residence time. Extem resin can meet international standards for recyclability. This is demonstrated by single-pass 100% regrind studies that indicate over 95% retention of tensile and elongation elongation, in astronomy, the angular distance between two points in the sky as measured from a third point. The elongation of a planet is usually measured as the angular distance from the sun to the planet as measured from the earth. properties. As always, the amount of regrind utilized will be governed by performance requirements of the application. Extrusion of stock shapes, profiles, and thin films is also achievable with Extem resin. Melt temperature will be from 370 to 405 C (700 to 760 F). Blow molding and thermoforming capability is also expected from Extem resin due to its fully amorphous nature and melt processability. NEED TO KNOW MORE? For more information on this company and its products, visit www.ptonline.com/suppliers: GE Plastics, Pittsfield, Mass. (800) 845-0600 * www.geplastics.com By Shawn Lee, Product Manager, GE Plastics Shawn Lee is the product manager for High Performance Polymers in the Americas at GE Plastics in Mount Vernon Mount Vernon, estate, United States Mount Vernon, NE Va., overlooking the Potomac River near Alexandria, S of Washington, D.C.; home of George Washington from 1747 until his death in 1799. , Ind. He has over 11 years of experience with GE and 3M in a variety of roles in technology, product development, and marketing. Prior to his current position, Lee was a regional application development specialist for GE's Ultem and Siltem resins.
TABLE 1--HIGH-PERFORMANCE POLYMER COMPARISONS
High-Performance
Polymer Common Types Advantages
Amorphous Polyetherimide (PEI) Strength, stiffness
Thermoplastics Polyethersulfone (PES) and isotropic
Polyphenylsulfone (PPSU) dimensional stability
across broad thermal
range.
Semi-Crystalline Polyphenylenesulfide (PPS) High melting
Thermoplastics Polyetheretherketone (PEEK) temperatures, broad
Polyphthalamide (PPA) chemical resistance
and wear properties.
Non-Melting or Polyamide-amide (PAI) High continuous-use
Thermoset Polyamide (PI) temperatures, broad
Imidized Resins chemical resistance,
and high compressive
strength.
High-Performance
Polymer Limitations
Amorphous Limited in chemical
Thermoplastics resistance and
continuous-use
temperatures.
Semi-Crystalline Poor dimensional
Thermoplastics stability and limited creep
resistance above Tg.
Low stiffness at high
temperatures in unfilled matrix.
Non-Melting or Requires imidization step
Thermoset via secondary cure or
Imidized Resins crystallization.
Limited conversion channels.
Limited reprocessability.
TABLE 2--EXTEM VS. ULTEM PROPERTIES
Property Ultem Ultem Extem Extem
1000 XH6050 XH UH
Physical
Density, g/cc 1.27 1.31 1.31 1.37
Water Abs., %
Equilib., 23 C 1.25 1.75 2.36 1.37
Moisture Abs., %
24 Hr, 50% RH, 23 C 0.25 0.6 0.6 --
MFR, g/10 min
337 C, 6.6 kgf 8 -- -- --
367 C, 6.6 kgf -- 12.5 7.1 --
Mechanical
Tensile Str., Yield, Mpa 114 95 90 120
Elongation, Yield, % -- -- -- 9
Flexural Strength, MPa -- -- -- 175
Flexural Modulus, MPa -- -- -- 3520
Tensile Modulus, MPa 3600 3500 3300 3800
Impact
Izod Impact, ft-lb/in.
Notched, 23 C 1 1.3 0.82 1.51
Reverse Notched, 23 C 24 35 27 33
Unnotched, 23C 34 35 37 --
Thermal
Glass Transition, C 217 247 267 280
Vicat Softening (B), C 209 242 260 --
HDT, C
0.45 MPa, 3.2 mm 206 232 249 263
1.82 MPa, 3.2 mm 191 216 235 240
CTE, 23 to 150 C,
Flow Dir., [10.sup.-5]
mm/mm-[degrees]C 5.40 5.30 5.00 4.50
Fig. 3--Heat-aging performance of Extem UH resin is expected to
achieve unprecedented UL RTI ratings for a melt-processable,
amorphous thermoplastic.
EXTEM UH TENSILE STRENGTH RETENTION AFTER 552 HR
Heat Aging
Temperature, C Percent Retention
250 84
260 74
270 85
280 99
290 56
Note: Table made from bar graph.
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