Semitron® ESd 420V PEI

1 of 12 products in this brand

Semitron® ESd 420V PEI Polyetherimide electro static dissipative shapes, a high-performance material designed for use in the semiconductor and electronics industries. With its unique combination of properties, this grade offers a range of benefits for device handling and test applications.

Features:

  • High strength and stiffness, making it suitable for extreme structural applications
  • Excellent resistivity in the 10E5 to 10E8 ohms per square range, ensuring reliable electrostatic dissipation
  • Heat deflection temperature of 419° F / 215° C, making it suitable for high temperature environments
  • Not subject to dimensional change as a result of exposure to moisture

Benefits:

  • Suitable for use in a range of applications within the semiconductor and electronics industries
  • Offers reliable performance in extreme conditions
  • Cost-effective alternative for applications that do not require the thermal performance of ultra-high performance materials

Applications:

  • Device handling and test applications within the semiconductor and electronics industries
  • Suitable for use in high temperature environments, including extreme structural applications.


Polymer Name: Polyether Imide (PEI)

Physical Form: Plates, Rods, Tube

Features: Dimensional Stability, ESD Protection, High Stiffness, High Strength, High Tolerance, Odorless, Static-Dissipative

Density: 1480.0 - 1480.0 kg/m³

Tensile Modulus: 5450.0 - 5450.0 MPa

Color: Black

Knowde Enhanced TDS

Identification & Functionality

Technologies

Features & Benefits

Labeling Claims
Product Features
  • High temperature resistance
  • ESD additives for static dissipation
  • Good dimensional stability

Applications & Uses

Properties

Color
Flame Rating
Physical Form
Mechanical Properties
ValueUnitsTest Method / Conditions
Tensile Strength70MPaISO 527-1/-2 (7)
Tensile Strain (Elongation) at Break1.5%ISO 527-1/-2 (7)
Tensile Modulus of Elasticity5450MPaISO 527-1/-2 (9)
Compressive Stress (1 / 2 / 5 % Nominal Strain)44/89/169MPaISO 604 (10)
Charpy Impact Strength (Unnotched)14kJ/m²ISO 179-1/1eU
Charpy Impact Strength (Notched)2kJ/m²ISO 179-1/1eA
Hardness (14)112Rockwell MISO 2039-2
Thermal Properties
ValueUnitsTest Method / Conditions
Glass Transition Temperature (DMA, Tan Delta)220°CDMA
Coefficient of Linear Thermal Expansion (23 - 60°C)30µm/(m.K)
Coefficient of Linear Thermal Expansion (23 - 100°C)30µm/(m.K)
Coefficient of Linear Thermal Expansion (min. 150°C)34µm/(m.K)
Heat Deflection Temperature (Method A: 1.8 MPa (264 PSI))215°CISO 75-1/-2
Continuous Allowable Service Temperature in Air (20.000 hrs) (3)170°C
Flammability (3 mm) (5)V-0UL 94
Electrical Properties
ValueUnitsTest Method / Conditions
Surface Resistivity10E5 - 10E8Ohm/sq.ANSI/ESD STM 11.11
Miscellaneous Properties
ValueUnitsTest Method / Conditions
Density1.48g/cm³ISO 1183-1
Water Absorption (At Saturation in Water of 23 °C)1.4%

Regulatory & Compliance

Certifications & Compliance
Chemical Inventories

Technical Details & Test Data

Engineering Notes

It is important to know how applied voltage affects the resistance of a material. Some materials exhibit high resistance at low voltages, but when subjected to harsher conditions, they can fall. This is due to dielectric breakdown and is irreversible. This chart illustrates the effect of sequential applications of 100 through 1,000 volts, then a return to 100 volts to determine the hysteresis. Since static electricity can be several thousand volts, consistent performance across the voltage range must be considered.

Some materials are very inconsistent and vary on the "grain" of machining. One pair of lines illustrate the typical variation from side to side (A to B) of the same sample. This example demonstrates the need for consistent behavior in service.

Semitron® ESd 420V PEI - Engineering Notes

Note
  • Thermal Properties -  The figures given for these properties are for the most part derived from raw material supplier data and other publications.
  • (2) Values for this property are only given here for amorphous materials and for materials that do not show a melting temperature (PBI, PAI & PI). DMA settings, oscillation amplitude of 0.20 mm; a frequency of 1 Hz; heating rate of 2°C/min
  • (3) Temperature resistance over a period of min. 20,000 hours. After this period of time, there is a decrease in tensile strength – measured at 23 °C – of about 50 % as compared with the original value. The temperature value given here is thus based on the thermal-oxidative degradation which takes place and causes a reduction in properties. Note, however, that the maximum allowable service temperature depends in many cases essentially on the duration and the magnitude of the mechanical stresses to which the material is subjected.
  • (4) Impact strength decreasing with decreasing temperature, the minimum allowable service temperature is practically mainly determined by the extent to which the material is subjected to impact. The value given here is based on unfavorable impact conditions and may consequently not be considered as being the absolute practical limit.
  • (5) These estimated ratings, derived from raw material supplier data and other publications, are not intended to reflect hazards presented by the material under actual fire conditions. There is no ‘UL File Number’ available for these stock shapes.
  • Mechanical Properties -  Most of the figures given for the mechanical properties are average values of tests run on dry test specimens machined out of rods 40-60 mm when available, else out of plate 10-20mm. All tests are done at room temperature (23° / 73°F)
  • (7) Test speed: either 5 mm/min or 50 mm/min [chosen acc. to ISO 10350-1 as a function of the ductile behavior of the material (tough or brittle)] using type 1B tensile bars
  • (8) Test speed: either 0.2"/min or 2"/min or [chosen as a function of the ductile behavior of the material (brittle or tough)] using Type 1 tensile bars
  • (9) Test speed: 1 mm/min, using type 1B tensile bars
  • (10) Test specimens: cylinders Ø 8 mm x 16 mm, test speed 1 mm/min
  • (11) Test specimens: cylinders Ø 0.5" x 1", or square 0.5" x 1", test speed 0.05"/min
  • (12) Test specimens: bars 4 mm (thickness) x 10 mm x 80 mm; test speed: 2 mm/min; span: 64 mm.
  • (13) Test specimens: bars 0.25" (thickness) x 0.5" x 5"; test speed: 0.11"/min; span: 4"
  • (14) Measured on 10 mm, 0.4" thick test specimens.
  • (15) Electrode configuration: Ø 25 / Ø 75 mm coaxial cylinders; in transformer oil according to IEC 60296 ; 1 mm thick test specimens.
  • (16) Measured on disks Ø 50 mm x 3 mm.
  • (17) Measured on 1/8" thick x 2" diameter or square
  • (18) Test procedure similar to Test Method A: “Pin-on-disk” as described in ISO 7148-2, Load 3MPa, sliding velocity= 0,33 m/s, mating plate steel Ra= 0.7-0.9 μm, tested at 23°C, 50%RH.
  • (19) Test using journal bearing system, 200 hrs, 118 ft/min, 42 PSI, steel shaft roughness 16±2 RMS micro inches with Hardness Brinell of 180-200
  • (20) Test using Plastic Thrust Washer rotating against steel, 20 ft/min and 250 PSI, Stationary steel washer roughness 16±2 RMS micro inches with Rockwell C 20-24
  • (21) Test using Plastic Thrust Washer rotating against steel, Step by step increase pressure, Test ends when plastic begins to deform or if temperature increases to 300°F.