Knowde Enhanced TDS
Identification & Functionality
- Additives Included
- Polymer Name
- Plastics & Elastomers Functions
- Technologies
Features & Benefits
- Materials Features
- Ultem Resin Attributes for Eyewear Frames
- Super tough
- Meets JIS B7285, includes 20,000 cycles blending repetitions
- Long life cycle
- UV stabilized
- Light weight
- Excellent in chemical and hydrolytic resistance
- Excellent dimensional stability
- Thin wall molding down to 1.2 mm
- Long term heat resistance (RTI > 170°C)
- Available in custom colors
ULTEM resin delivers a broad range of desirable performance properties for eyeglass frames and is also potentially usable in safety and 3D eyewear frames.
Dimensional and Hydrolytic Stability
- Ensures the lenses are retained in the frame
- Extends the product life cycle
Temperature and Chemical Resistance
- Excellent stain and chemical resistance
- High heat deflection temperature protects the frames even when left on the car dashboard in direct sunlight
Design Freedom & Ease of Production
- Precision thin wall molding at 1.2 mm
- Capability for custom colors providing a wide range of esthetic effects
- Enhanced processing window vs. nylons
Density
- Intrinsically lightweight (up to 50% vs. metal)
Mechanical Properties
- Higher flexural modulus at 3510MPa
- Offers elasticity coupled with resistance to deformation, allowing the frame to bend easily yet return to its original shape
- ULTEM™ Resin Offers
- Lead times of approximately 4 weeks*
- Up to 55% higher stiffness
- Better dimensional stability vs. PSU
- Excellent property retention at elevated temps:
Tg - 217°C, HDT @ 1.80 MPa: 190°C
- Up to 17% lower CTE than PES/PPSU
- Chemical resistance
- Metal plating compatibility
- Compatibility with multiple sterilization methods
- Availability for stock shapes & films
- Product Highlight
The ULTEM™ family of amorphous thermoplastic polyetherimide (PEI) resins offer outstanding elevated thermal resistance, high strength and stiffness, and broad chemical resistance. ULTEM™ copolymers are also available for even higher heat, chemical and elasticity needs.
ULTEM™ resins uniquely balance both mechanical properties and processability, offering design engineers exceptional flexibility and freedom. ULTEM™ resins are also inherently flame retardant and possess excellent dielectric character. ULTEM™ resins are therefore an excellent candidate for your electric vehicle battery needs where high heat resistance is required.
With its appreciable flow and dimensional stability, coupled with excellent resistance to Li-ion electrolyte, ULTEM™ resins such as ULTEM™ CRS5011 resin are today being used for insulation of Li-ion cell terminals. Given its excellent dielectric character, ULTEM™ resin is also an ideal candidate for bus bar insulation. For other powertrain elements, such as DC power converters. ULTEM™ UTF120 dielectric film is already enabling high temperature film capacitors.
- Key Benefits
- Heat Resistance
- Dimensional Stability
- Dielectric Performance
- Miniaturization and Thin Wall
- Resilience
- Ultem™ Resin for Animal Cages
What makes Ultem™ resin the right material for animal cages
- Long term heat resistance (RTI>170°C)
- Long life cycle
- NSF & FDA compliant
- Excellent chemical and hydrolytic resistance
- More balanced stiffness/strength
- Ability to withstand sterilization methods like steam, Gamma radiation & Eto gas
- Green product -- WEEE & RoHS compliant
Advantages
Excellent Hydrolytic Performance
- More than 5 years cycle life (>250 cycle) under 134° C autoclave environment
- Better transparency after long-term use in comparison with other high heat animal cage materials
Chemical Resistance
- Better stain resistance than PSU/Nylon/PP/PC
- More exceptional chemical resistance to detergents/disinfectants than other high heat animal cage materials
Processability
- Outstanding processability with less molding defects
- Wider processing window than other high heat animal cage materials
Mechanical Property
- Higher glass transition temperature (Tg) than PSU/PC/PP/Nylon and other high heat animal cage materials
- Relative thermal index (RTI): 25° C higher than PSU
Applications & Uses
- Markets
- Applications
- Plastics & Elastomers End Uses
- Plastics & Elastomers Processing Methods
- Applications in Various Industries
- Mobilty
- Connectors
- Water
- Food Service
- Healthcare
- Aerospace
- 5G Antennas / Radomes
- Semiconductors
Properties
- Mechanical Properties
- Physical Properties
- Thermal Properties
- Electrical Properties
- Impact Properties
- Injection Molding
- Flame Characteristics
| Value | Units | Test Method / Conditions | |
| Tensile Stress (Yield, Type I, 5 mm/min) | 110 | MPa | ASTM D638 |
| Tensile Stress (Break, Type I, 5 mm/min) | 105 | MPa | ASTM D638 |
| Tensile Strain (Yield, Type I, 5 mm/min) | 7 | % | ASTM D638 |
| Tensile Strain (Break, Type I, 5 mm/min) | 60 | % | ASTM D638 |
| Tensile Modulus (at 5 mm/min) | 3590 | MPa | ASTM D638 |
| Flexural Stress (Yield, 1.3 mm/min, 50 mm span) | 167 | MPa | ASTM D790 |
| Flexural Stress (Yield, 2.6 mm/min, 100 mm span) | 165 | MPa | ASTM D790 |
| Flexural Modulus (at 1.3 mm/min, 50 mm span) | 3550 | MPa | ASTM D790 |
| Flexural Modulus (at 2.6 mm/min, 100 mm span) | 3520 | MPa | ASTM D790 |
| Hardness (Rockwell M) | 109 | — | ASTM D785 |
| Tensile Stress (Yield, 50 mm/min) | 105 | MPa | ISO 527 |
| Tensile Stress (Break, 50 mm/min) | 85 | MPa | ISO 527 |
| Tensile Strain (Yield, 50 mm/min) | 6 | % | ISO 527 |
| Tensile Strain (Break, 50 mm/min) | 60 | % | ISO 527 |
| Tensile Modulus (at 1 mm/min) | 3200 | MPa | ISO 527 |
| Flexural Stress (Yield, at 2 mm/min) | 160 | MPa | ISO 178 |
| Flexural Modulus (at 2 mm/min) | 3300 | MPa | ISO 178 |
| Ball Indentation Hardness (H358/30) | 140 | MPa | ISO 2039-1 |
| Taber Abrasion (CS-17, 1 kg) | 10 | mg/1000cy | ASTM D1044 |
| Value | Units | Test Method / Conditions | |
| Water Absorption (at 23°C, 24hrs) | 0.25 | % | ASTM D570 |
| Water Absorption (at 23°C, saturated) | 1.25 | % | ASTM D570 |
| Water Absorption (at 23°C, saturated) | 1.25 | % | ISO 62-1 |
| Mold Shrinkage (on Tensile Bar, flow) | 0.5 - 0.7 | % | SABIC method |
| Mold Shrinkage (flow, 3.2 mm) | 0.5 - 0.7 | % | SABIC method |
| Mold Shrinkage (xflow, 3.2 mm) | 0.5 - 0.7 | % | SABIC method |
| Melt Flow Rate (at 337°C, 6.6 kgf) | 17.8 | g/10 min | ASTM D1238 |
| Density | 1.27 | g/cm³ | ISO 1183 |
| Moisture Absorption (at 23°C, 50% RH) | 0.7 | % | ISO 62 |
| Melt Volume Rate (at 340°C, 5.0 kg) | 13 | cm³/10 min | ISO 1133 |
| Melt Volume Rate (at 360°C, 5.0 kg) | 25 | cm³/10 min | ISO 1133 |
| Specific Gravity | 1.27 | — | ASTM D792 |
| Value | Units | Test Method / Conditions | |
| Thermal Conductivity | 0.22 | W/m-°C | ASTM C177 |
| Thermal Conductivity | 0.21 | W/m-°C | ISO 8302 |
| Vicat Softening Temperature (Rate B/50) | 211 | °C | ISO 306 |
| Vicat Softening Temperature (Rate B/50) | 218 | °C | ASTM D1525 |
| Heat Deflection Temperature (at 0.45 MPa, 3.2 mm, Unannealed) | 205 | °C | ASTM D648 |
| Heat Deflection Temperature (at 1.82 MPa, 3.2mm, Unannealed) | 197 | °C | ASTM D648 |
| Heat Deflection Temperature (at 0.45 MPa, 6.4 mm, Unannealed) | 207 | °C | ASTM D648 |
| Heat Deflection Temperature (at 1.82 MPa, 6.4 mm, Unannealed) | 198 | °C | ASTM D648 |
| Coefficient of Thermal Expansion (at -40°C to 150°C, flow) | 0.000055 | 1/°C | ASTM E831 |
| Coefficient of Thermal Expansion (at -40°C to 150°C, xflow) | 0.000055 | 1/°C | ASTM E831 |
| Coefficient of Thermal Expansion (at 23°C to 150°C, flow) | 0.00005 | 1/°C | ISO 11359-2 |
| Coefficient of Thermal Expansion (at 23°C to 150°C, xflow) | 0.00005 | 1/°C | ISO 11359-2 |
| Ball Pressure Test (at 123°C to 127°C) | Pass | — | IEC 60695-10-2 |
| Vicat Softening Temperature (Rate A/50) | 215 | °C | ISO 306 |
| Vicat Softening Temperature (Rate B/120) | 212 | °C | ISO 306 |
| Heat Deflection Temperature/Be (at 0.45MPa, Edgew 120*10*4, sp=100mm) | 200 | °C | ISO 75/Be |
| Heat Deflection Temperature/Ae (at 1.8 Mpa, Edgew 120*10*4, sp=100mm) | 190 | °C | ISO 75/Ae |
| Heat Deflection Temperature/Af (at 1.8 Mpa, Flatw 80*10*4, sp=64mm) | 190 | °C | ISO 75/Af |
| Value | Units | Test Method / Conditions | |
| Comparative Tracking Index | 150 | V | IEC 60112 |
| Comparative Tracking Index (M) | 100 | V | IEC 60112 |
| Volume Resistivity | 1.00E+15 | Ω.cm | IEC 60093 |
| Volume Resistivity | 1.00E+17 | Ω.cm | ASTM D257 |
| Relative Permittivity (1 kHz) | 3.15 | — | ASTM D150 |
| Relative Permittivity (1 MHz) | 2.9 | — | IEC 60250 |
| Relative Permittivity (50/60 Hz) | 2.9 | — | IEC 60250 |
| Surface Resistivity (ROA) | min. 1.E+15 | Ω | IEC 60093 |
| Dielectric Strength (in air, at 1.6mm) | 32.6 | kV/mm | ASTM D149 |
| Dielectric Strength (in oil, at 1.6mm) | 25 | kV/mm | IEC 60243-1 |
| Dielectric Strength (in oil, at 1.6mm) | 27.9 | kV/mm | ASTM D149 |
| Dissipation Factor (at at 1 kHz) | 0.0013 | — | ASTM D150 |
| Dissipation Factor (at 2450 MHz) | 0.0025 | — | ASTM D150 |
| Dissipation Factor (at 2450 MHz) | 0.0025 | — | IEC 60250 |
| Dielectric Strength (in oil, at 0.8mm) | 33 | kV/mm | IEC 60243-1 |
| Dielectric Strength (in oil, at 3.2mm) | 16 | kV/mm | IEC 60243-1 |
| Dissipation Factor (at 50/60 Hz) | 0.0005 | — | IEC 60250 |
| Dissipation Factor (at at 1 MHz) | 0.006 | — | IEC 60250 |
| Value | Units | Test Method / Conditions | |
| Instrumented Dart Impact Total Energy (at 23°C) | 33 | J | ASTM D3763 |
| Izod Impact (Unnotched, at 23°C) | 1335 | J/m | ASTM D4812 |
| Izod Impact (Notched, at 23°C) | 32 | J/m | ASTM D256 |
| Izod Impact (Notched, at -30°C) | 35 | J/m | ASTM D256 |
| Izod Impact (Reverse Notched, 3.2 mm) | 1174 | J/m | ASTM D256 |
| Color (at 23°C) | 33 | J | SABIC method |
| Izod Impact (Unnotched, 80*10*4, at 23°C) | No break | kJ/m² | ISO 180/1U |
| Izod Impact (Unnotched, 80*10*4, at -30°C) | No break | kJ/m² | ISO 180/1U |
| Izod Impact (Notched, 80*10*4, at 23°C) | 5 | kJ/m² | ISO 180/1A |
| Izod Impact (Notched, 80*10*4, at -30°C) | 5 | kJ/m² | ISO 180/1A |
| Charpy Impact (at 23°C, V-notch Edgew 80*10*4 sp=62mm) | 3 | kJ/m² | ISO 179/1eA |
| Value | Units | Test Method / Conditions | |
| Back Pressure | 0.3 - 0.7 | MPa | — |
| Drying Temperature | 150 | °C | — |
| Drying Time | 4 - 6 | Hrs | — |
| Drying Time (Cumulative) | 24 | Hrs | — |
| Front - Zone 3 Temperature | 345 - 400 | °C | — |
| Maximum Moisture Content | 0.02 | % | — |
| Melt Temperature | 350 - 400 | °C | — |
| Middle - Zone 2 Temperature | 340 - 400 | °C | — |
| Mold Temperature | 135 - 165 | °C | — |
| Nozzle Temperature | 345 - 400 | °C | — |
| Rear - Zone 1 Temperature | 330 - 400 | °C | — |
| Screw Speed | 40 - 70 | rpm | — |
| Shot to Cylinder Size | 40 - 60 | % | — |
| Vent Depth | 0.025 - 0.076 | mm | — |
| Value | Units | Test Method / Conditions | |
| Oxygen Index (LOI) | 44 | % | ASTM D2863 |
| Oxygen Index (LOI) | 47 | % | ISO 4589 |
| Glow Wire Flammability Index (passes at 960°C) | 3.2 | mm | IEC 60695-2-12 |
Regulatory & Compliance
- Certifications & Compliance
- ULTEM™ Resin May Support
- Electrical: UL94 V0 & 5VA, UL94 F1, UL746B
- Telecom: Telcordia GR-326, TIA/EIA-604-10A
- Mobility: FMVSS, IATF 16949, ISO 14001
- Food Service: FDA, NSF, EFSA, JHOSPA
- Water: NSF, WRAS, KTW
- Semiconductors: FM
- Healthcare: ISO 10993, FDA, USP Class VI, compatible with multiple sterilization methods
- Aerospace: ABD 0031, BMS, FAR25.853, OSU 55/55 & NBS smoke density tests
Packaging & Availability
- Regional Availability
- Availability
ULTEM™ resin is available in transparent and opaque custom colors, and can be glass filled for added stiffness.