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D3000IEU6-XH
FOREVER
Product Description | |||
Polycarbonate (PC) is a versatile and widely used thermoplastic material known for its excellent mechanical properties and high impact strength. It is highly transparent and has a high heat resistance, making it suitable for various applications in industries such as automotive, aerospace, electronics, and construction. One of the notable properties of PC is its antistatic nature. This means that it does not easily accumulate static charges, making it ideal for applications where static electricity can pose a risk, such as in manufacturing processes or electronic components. Another important characteristic of PC is its resistance to hydraulic aging. Hydraulic aging refers to the degradation of a material when exposed to hydraulic fluids over extended periods of time. PC exhibits excellent resistance to this aging process, allowing it to maintain its properties and performance even in environments where contact with hydraulic fluids is common. In addition, PC has good surface resistivity, meaning it has the ability to prevent the flow of electric current on its surface. This property makes it useful for applications involving electrical equipment or devices, as it helps to prevent the buildup of static charges and potential electrical hazards. Furthermore, PC is known for its exceptional impact strength. It has the ability to withstand high impact loads without breaking or shattering, making it a popular choice for applications that require durability and toughness, such as safety glasses, bulletproof windows, and protective shieldings. Overall, Polycarbonate (PC) is a highly desirable material due to its combination of antistatic properties, resistance to hydraulic aging, good surface resistivity, and excellent impact strength. Its versatility and reliability make it a preferred choice for a wide range of applications in various industries. | |||
General | |||
Form |
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Low Temperature Impact Good Surface Appearance Thin Wall | |||
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Physical | Nominal Value | Test Method | |
Density / Specific Gravity 1.16 g/cm³ 1.16 | ISO 1183 ASTM D792 | ||
Moisture Absorption | ISO 62-4 | ||
23 °C;50% RH/24hrs | 0.15 % | ||
23 °C;50% RH/Equilibrium | 0.3 % | ||
Water Absorption 24 hrs;23 °C 23 °C;saturated 24 hrs;23 °C 23°C/Saturated | 0.7 % 3.5 % 0.7 % 3.5 % | ISO 62-1 ISO 62-1 ASTM D570 ASTM D570 | |
Melt Volume Rate, MVR | ISO 1133 | ||
2.16 kg;MVR at 250 °C | 5 cm³/10 min | ||
5 kg;MVR at 250 °C | 15 cm³/10 min | ||
5 kg;MVR at 260 °C | 23 cm³/10 min | ||
Melt Flow Rate[MFR](250 °C;5 kgf) 15 g/10min ASTM D1238 | |||
Mechanical | Nominal Value | Test Method |
Izod Impact, Notched 80*10*4;23 °C 80*10*4;-30 °C 23 °C -30 °C | 60 kJ/m² 60 kJ/m² 850 J/m 750 J/m | ISO 180/1A ISO 180/1A ASTM D256 ASTM D256 |
Notched Izod Impact Strength notched;80*10*3;23 °C 0 notched;80*10*3;-30 °C 0 | 65 kJ/m² 65 kJ/m² | ISO 180/1A |
Unnotched Izod Impact Strength unnotched;80*10*3;23 °C 0 unnotched;80*10*3;-30 °C 0 | NB kJ/m² NB kJ/m² | ISO 180/1U |
Izod Impact, Unnotched 80*10*4;23 °C 80*10*4;-30 °C 23 °C -30 °C | NB kJ/m² NB kJ/m² NB J/m NB J/m | ISO 180/1U ISO 180/1U ASTM D4812 ASTM D4812 |
Charpy Impact, V-Notched 23 °C;Edgew;80*10*4;sp=62 mm 0 -30 °C;Edgew;80*10*4;sp=62 mm 0 | 60 kJ/m² 60 kJ/m² | ISO 179 1eA |
Charpy Impact, Unnotched 23 °C;Edgew;80*10*4;sp=62 mm 0 -30 °C;Edgew;80*10*4;sp=62 mm 0 | NB kJ/m² NB kJ/m² | ISO 179 1eU |
Multi-Axial Instrumented Impact, Total Energy 23 °C -30 °C | 65 J 65 J | ISO 6603-2 |
Multi-Axial Instrumented Impact, Peak Energy 23 °C -30 °C | 55 J 55 J | ISO 6603-2 |
Instrumented Dart Impact, Total Energy 23 °C -30 °C | 40 J 40 J | ASTM D3763 |
Instrumented Dart Impact, Energy at Peak 23 °C -30 °C | 35 J 35 J | ASTM D3763 |
Instrumented Dart Impact, Peak force 23 °C -30 °C | 4000 N 4800 N | ASTM D3763 |
Tensile Modulus 1 mm/min 50 mm/min | 1750 MPa 1750 MPa | ISO 527 ASTM D638 |
Tensile Stress, Yield 50 mm/min 50 mm/min;Type I | 45 MPa 45 MPa | ISO 527 ASTM D638 |
Tensile Strain, Yield 50 mm/min 50 mm/min;Type I | 5.5 % 5.5 % | ISO 527 ASTM D638 |
Tensile Strain, Break 50 mm/min 50 mm/min;Type I | > 60 % > 60 % | ISO 527 ASTM D638 |
Tensile Nominal Strain, Break 50 mm/min 50 mm/min;Type I | > 60 % > 60 % | ISO 527 ASTM D638 |
Flexural Modulus 2 mm/min 1.3 mm/min;50 mm;span | 1825 MPa 1900 MPa | ISO 178 ASTM D790 |
Flexural Strength 2 mm/min 1.3 mm/min;50 mm;span | 70 MPa 70 MPa | ISO 178 ASTM D790 |
Ball Indentation Hardness(H358/30) | 78 MPa | ISO 2039-1 |
Thermal | Nominal Value | Test Method |
HDT/Af(1.8) | 105 °C | ISO 75/Af |
HDT/Bf(0.45) | 123 °C | ISO 75/Bf |
Vicat Softening Temperature | ||
Rate B/50 | 123 °C | ISO 306 |
Rate B/120 | 123 °C | ISO 306 |
Rate A/50 | 137 °C | ISO 306 |
Rate A/120 | 138 °C | ISO 306 |
Rate B/50 | 123 °C | ASTM D1525 |
Rate B/120 | 123 °C | ASTM D1525 |
CTE, Flow 23°C to 50°C 23°C to 50°C | 8.5E-05 1/°C 8.5E-05 1/°C | ISO 11359-2 ASTM E831 |
CTE, XFlow 23°C to 50°C 23°C to 50°C | 1.1E-04 1/°C 1.1E-04 1/°C | ISO 11359-2 ASTM E831 |
Heat Deflection Temperature[HDT], Unannealed 3.2 mm;1.82 MPa 0.45 MPa;3.2 mm | 105 °C 123 °C | ASTM D648 |
Ball Pressure Test(125°C +/- 2°C) | Pass | IEC 60695-10-2 |
Electrical | Nominal Value | Test Method |
Comparative Tracking Index | 175 V | IEC 60112 |
Surface Resistivity, ROA | 1.0E+09 - 1.0E+11 ohms | IEC 60093 |
Static Decay(5000V to <50V) | < 0.01 Seconds | FTMS101B |
Dielectric Constant(6.0e+10 - 9.0e+10 Hz) | 2.73 | |
Dissipation Factor(6.0e+10 - 9.0e+10 Hz) | 0.022 |
Surface Resistivity
1.0E+09 - 1.0E+11 ohms
ASTM D257
Product Description | |||
Polycarbonate (PC) is a versatile and widely used thermoplastic material known for its excellent mechanical properties and high impact strength. It is highly transparent and has a high heat resistance, making it suitable for various applications in industries such as automotive, aerospace, electronics, and construction. One of the notable properties of PC is its antistatic nature. This means that it does not easily accumulate static charges, making it ideal for applications where static electricity can pose a risk, such as in manufacturing processes or electronic components. Another important characteristic of PC is its resistance to hydraulic aging. Hydraulic aging refers to the degradation of a material when exposed to hydraulic fluids over extended periods of time. PC exhibits excellent resistance to this aging process, allowing it to maintain its properties and performance even in environments where contact with hydraulic fluids is common. In addition, PC has good surface resistivity, meaning it has the ability to prevent the flow of electric current on its surface. This property makes it useful for applications involving electrical equipment or devices, as it helps to prevent the buildup of static charges and potential electrical hazards. Furthermore, PC is known for its exceptional impact strength. It has the ability to withstand high impact loads without breaking or shattering, making it a popular choice for applications that require durability and toughness, such as safety glasses, bulletproof windows, and protective shieldings. Overall, Polycarbonate (PC) is a highly desirable material due to its combination of antistatic properties, resistance to hydraulic aging, good surface resistivity, and excellent impact strength. Its versatility and reliability make it a preferred choice for a wide range of applications in various industries. | |||
General | |||
Form |
| ||
|
|
| |
| |||
Low Temperature Impact Good Surface Appearance Thin Wall | |||
| |||
| |||
|
| ||
Physical | Nominal Value | Test Method | |
Density / Specific Gravity 1.16 g/cm³ 1.16 | ISO 1183 ASTM D792 | ||
Moisture Absorption | ISO 62-4 | ||
23 °C;50% RH/24hrs | 0.15 % | ||
23 °C;50% RH/Equilibrium | 0.3 % | ||
Water Absorption 24 hrs;23 °C 23 °C;saturated 24 hrs;23 °C 23°C/Saturated | 0.7 % 3.5 % 0.7 % 3.5 % | ISO 62-1 ISO 62-1 ASTM D570 ASTM D570 | |
Melt Volume Rate, MVR | ISO 1133 | ||
2.16 kg;MVR at 250 °C | 5 cm³/10 min | ||
5 kg;MVR at 250 °C | 15 cm³/10 min | ||
5 kg;MVR at 260 °C | 23 cm³/10 min | ||
Melt Flow Rate[MFR](250 °C;5 kgf) 15 g/10min ASTM D1238 | |||
Mechanical | Nominal Value | Test Method |
Izod Impact, Notched 80*10*4;23 °C 80*10*4;-30 °C 23 °C -30 °C | 60 kJ/m² 60 kJ/m² 850 J/m 750 J/m | ISO 180/1A ISO 180/1A ASTM D256 ASTM D256 |
Notched Izod Impact Strength notched;80*10*3;23 °C 0 notched;80*10*3;-30 °C 0 | 65 kJ/m² 65 kJ/m² | ISO 180/1A |
Unnotched Izod Impact Strength unnotched;80*10*3;23 °C 0 unnotched;80*10*3;-30 °C 0 | NB kJ/m² NB kJ/m² | ISO 180/1U |
Izod Impact, Unnotched 80*10*4;23 °C 80*10*4;-30 °C 23 °C -30 °C | NB kJ/m² NB kJ/m² NB J/m NB J/m | ISO 180/1U ISO 180/1U ASTM D4812 ASTM D4812 |
Charpy Impact, V-Notched 23 °C;Edgew;80*10*4;sp=62 mm 0 -30 °C;Edgew;80*10*4;sp=62 mm 0 | 60 kJ/m² 60 kJ/m² | ISO 179 1eA |
Charpy Impact, Unnotched 23 °C;Edgew;80*10*4;sp=62 mm 0 -30 °C;Edgew;80*10*4;sp=62 mm 0 | NB kJ/m² NB kJ/m² | ISO 179 1eU |
Multi-Axial Instrumented Impact, Total Energy 23 °C -30 °C | 65 J 65 J | ISO 6603-2 |
Multi-Axial Instrumented Impact, Peak Energy 23 °C -30 °C | 55 J 55 J | ISO 6603-2 |
Instrumented Dart Impact, Total Energy 23 °C -30 °C | 40 J 40 J | ASTM D3763 |
Instrumented Dart Impact, Energy at Peak 23 °C -30 °C | 35 J 35 J | ASTM D3763 |
Instrumented Dart Impact, Peak force 23 °C -30 °C | 4000 N 4800 N | ASTM D3763 |
Tensile Modulus 1 mm/min 50 mm/min | 1750 MPa 1750 MPa | ISO 527 ASTM D638 |
Tensile Stress, Yield 50 mm/min 50 mm/min;Type I | 45 MPa 45 MPa | ISO 527 ASTM D638 |
Tensile Strain, Yield 50 mm/min 50 mm/min;Type I | 5.5 % 5.5 % | ISO 527 ASTM D638 |
Tensile Strain, Break 50 mm/min 50 mm/min;Type I | > 60 % > 60 % | ISO 527 ASTM D638 |
Tensile Nominal Strain, Break 50 mm/min 50 mm/min;Type I | > 60 % > 60 % | ISO 527 ASTM D638 |
Flexural Modulus 2 mm/min 1.3 mm/min;50 mm;span | 1825 MPa 1900 MPa | ISO 178 ASTM D790 |
Flexural Strength 2 mm/min 1.3 mm/min;50 mm;span | 70 MPa 70 MPa | ISO 178 ASTM D790 |
Ball Indentation Hardness(H358/30) | 78 MPa | ISO 2039-1 |
Thermal | Nominal Value | Test Method |
HDT/Af(1.8) | 105 °C | ISO 75/Af |
HDT/Bf(0.45) | 123 °C | ISO 75/Bf |
Vicat Softening Temperature | ||
Rate B/50 | 123 °C | ISO 306 |
Rate B/120 | 123 °C | ISO 306 |
Rate A/50 | 137 °C | ISO 306 |
Rate A/120 | 138 °C | ISO 306 |
Rate B/50 | 123 °C | ASTM D1525 |
Rate B/120 | 123 °C | ASTM D1525 |
CTE, Flow 23°C to 50°C 23°C to 50°C | 8.5E-05 1/°C 8.5E-05 1/°C | ISO 11359-2 ASTM E831 |
CTE, XFlow 23°C to 50°C 23°C to 50°C | 1.1E-04 1/°C 1.1E-04 1/°C | ISO 11359-2 ASTM E831 |
Heat Deflection Temperature[HDT], Unannealed 3.2 mm;1.82 MPa 0.45 MPa;3.2 mm | 105 °C 123 °C | ASTM D648 |
Ball Pressure Test(125°C +/- 2°C) | Pass | IEC 60695-10-2 |
Electrical | Nominal Value | Test Method |
Comparative Tracking Index | 175 V | IEC 60112 |
Surface Resistivity, ROA | 1.0E+09 - 1.0E+11 ohms | IEC 60093 |
Static Decay(5000V to <50V) | < 0.01 Seconds | FTMS101B |
Dielectric Constant(6.0e+10 - 9.0e+10 Hz) | 2.73 | |
Dissipation Factor(6.0e+10 - 9.0e+10 Hz) | 0.022 |
Surface Resistivity
1.0E+09 - 1.0E+11 ohms
ASTM D257
