Quarzrohr
Quarzplatte
Quarzstab
Optische Anwendungen
Halbleiterindustrie
Labor- und Chemieanwendungen
Quartz discs are thin, round slices of high-purity silicon dioxide. Their high-temperature resistance, low thermal expansion, and excellent optical and electrical properties make them essential in the semiconductor, optoelectronics, and precision instrument fields. These discs feature high purity, dimensional stability, and chemical stability, making them crucial for high-tech applications.
| Diameter | Thickness |
|---|---|
| 3mm | 1mm |
| 4mm | 1mm |
| 5 mm | 1mm |
| 6mm | 1mm |
| 7mm | 1mm |
| 8mm | 1mm |
| 8mm | 2mm |
| 9mm | 1mm |
| 10mm | 0,5 mm |
| 10mm | 1mm |
| 10mm | 2mm |
| 11mm | 1mm |
| 12mm | 1mm |
| 15mm | 0,5 mm |
| 15mm | 1mm |
| 15mm | 2mm |
| 16mm | 1mm |
| 18mm | 1mm |
| 20mm | 0,5 mm |
| 20mm | 1mm |
| 20mm | 2mm |
| 20mm | 3mm |
| 22mm | 1mm |
| 25mm | 0,5 mm |
| 25mm | 1mm |
| 25mm | 2mm |
| 25mm | 3mm |
| 25mm | 5 mm |
| 25mm | 8mm |
| 30mm | 0,5 mm |
| 30mm | 1mm |
| 30mm | 2mm |
| 30mm | 3mm |
| 30mm | 4mm |
| 30mm | 5 mm |
| 35mm | 1mm |
| 35mm | 2mm |
| 35mm | 3mm |
| 35mm | 5 mm |
| 40mm | 0,5 mm |
| 40mm | 1mm |
| 40mm | 1,5 mm |
| 40mm | 2mm |
| 40mm | 3mm |
| 40mm | 4mm |
| 40mm | 5 mm |
| 45 mm | 1mm |
| 45 mm | 2mm |
| 45 mm | 3mm |
| 50mm | 0,5 mm |
| 50mm | 1mm |
| 50mm | 2mm |
| 50mm | 3mm |
| 50mm | 4mm |
| 50mm | 5 mm |
| 50mm | 8mm |
| 50mm | 10mm |
| 55mm | 1mm |
| 55mm | 3mm |
| 55mm | 5 mm |
| 60mm | 1mm |
| 60mm | 2mm |
| 60mm | 3mm |
| 60mm | 5 mm |
| 70mm | 2mm |
| 70mm | 3mm |
| 70mm | 5 mm |
| 80mm | 2mm |
| 80mm | 3mm |
| 80mm | 5 mm |
| 80mm | 10mm |
| 90mm | 2mm |
| 90mm | 3mm |
| 90mm | 5 mm |
| 100mm | 0,5 mm |
| 100mm | 1mm |
| 100mm | 2mm |
| 100mm | 3mm |
| 100mm | 5 mm |
| 100mm | 10mm |
| 150mm | 2mm |
| 150mm | 3mm |
| 150mm | 5 mm |
- ayment method: By wire transfer or advance payment, depending on the quantity of the order.
- Delivery time: According to the order quantity.
- Transportation method: Sea freight or air freight, depending on the customer.
Remarks:
To confirm the order, The following parameters need to be provided: ① Square: length, width, thickness ② Circle: diameter, thickness ③ Accuracy ④ Quantity
| Eigenschaft Inhalt | Immobilienwerte |
|---|---|
| SiO2 | 99.99% |
| Dichte | 2,2×10³ kg/cm³ |
| Härte | 5,5 - 6,5 Mohs'sche Skala 570 KHN 100 |
| Zugfestigkeit | 4,8×10⁷ Pa (N/mm2) (7000 psi) |
| Druckfestigkeit | >1,1×10⁹ Pa (160.000 psi) |
| Wärmeausdehnungskoeffizient | 5,5×10-⁷ cm/cm-°C (20°C-320°C) |
| Wärmeleitfähigkeit | 1,4 W/m-°C |
| Spezifische Wärme | 670 J/kg-°C |
| Erweichungspunkt | 1730°C (3146°F) |
| Glühpunkt | 1210°C (2210°F) |
| Dehnungspunkt | 1120°C (2048°F) |
| Arbeitstemperatur | 1200°C (2192°F) |
| Elektrischer spezifischer Widerstand | 7×10⁷ Ohm cm (350°C) |
| Größe | Kundenspezifisch |
| Logo | Kundenspezifisches Logo akzeptieren |
JGS1
Commonly known as UV-grade fused silica, this material exhibits exceptionally low dispersion and very high transmittance in the ultraviolet (UV) spectral range.
JGS2
Similar to JGS1, but may have variations in specific performance parameters such as transmittance and thermal expansion coefficient, depending on the manufacturer’s standards.
JGS3
Typically used in applications requiring higher purity or specialized performance characteristics. Specific performance parameters can vary based on the manufacturer.
High Heat Resistance
Quartz glass softens around 1730°C, can be used continuously at 1100°C, and briefly up to 1450°C.
Low Thermal Expansion
Quartz discs have a very low thermal expansion, resisting cracking from quick temperature changes.
Corrosion Resistance
Quartz glass resists most acids, except hydrofluoric acid, and has acid resistance 30 times greater than ceramics and 150 times greater than stainless steel.
Excellent Light Transmission
Quartz discs transmit light well across the UV to IR range, with over 93% visible light transmission and over 80% maximum UV transmission.
Anwendungsszenario
Optische Anwendungen
Quartz discs are used to manufacture optical components such as lenses and prisms, as well as mask materials on photomasks. In the fabrication of photomasks, quartz discs are favored for their low expansion rate and high deep-UV (DUV) transmittance.
Electronics Applications
Quartz discs are used to fabricate semiconductor devices, electric light sources, and semiconductor communication devices. The high light transmittance and high-temperature resistance of quartz discs make them ideal for these applications.
Thermal and Mechanical Applications
Due to their good thermal stability and high corrosion resistance, quartz discs are also used to manufacture high-temperature and corrosion-resistant chemical instruments, chemical equipment, and related components in the defense industry.
Chemical and Chemical Engineering
Used as high-temperature and corrosion-resistant reaction vessels or observation windows in chemical reactions and melting experiments.
A low thermal expansion coefficient means that quartz discs/wafers maintain dimensional stability under temperature changes, which is crucial for high-technology applications requiring precise control.
Quartz discs/wafers have good light transmission, especially in the ultraviolet to infrared spectral range, making them ideal materials for optical applications.
Quartz discs are excellent electrical insulators, which makes them very useful in the electronics and semiconductor industries
Häufig gestellte Fragen
Quarzglas ist ein hartes und sprödes Material mit ausgezeichneten physikalischen und chemischen Eigenschaften, extrem hoher mechanischer Härte, guter elektrischer Isolierung, hoher Temperatur- und Korrosionsbeständigkeit, geringer und stabiler Verzögerungsleistung, guter Lichtdurchlässigkeit usw. Es findet breite Anwendung in der Halbleiterindustrie, Optik, Elektrizität, Chemie, Luft- und Raumfahrt, Automobilindustrie und anderen Bereichen. Harte und spröde Werkstoffe sind schwer zu bearbeiten, und in vielen Bereichen werden dringend Schneidverfahren mit geringem Kanteneinbruch, geringem Materialverlust, geringer Querschnittsrauheit und einem großen Schnittdickenbereich benötigt. Das traditionelle Schneidverfahren für Quarzglas ist das mechanische Schneiden, d. h. das Scheibenschneiden. Zu den nicht-traditionellen Schneidverfahren gehören Wasserstrahlschneiden, elektrochemisches Drahterodieren, kontinuierliches Laserschneiden usw. Das mechanische Schneiden ist kostengünstig, aber der Kontakt zwischen der Scheibe und dem Material verursacht einen hohen Werkzeugverschleiß, und das Material wird leicht durch das Werkzeug verschmutzt. Quarzglas neigt zu Kanteneinbrüchen, Mikrorissen und Eigenspannungen, was die Festigkeit und Leistung des Materials beeinträchtigt! Das Schneiden von Kurven ist schwierig und erfordert Nachbearbeitungen wie Schleifen und Polieren. Das Laserschneiden kommt nicht direkt mit dem Material in Berührung, hat keine Kontaktspannungen und kann komplexe Kurvenschnitte durchführen. Der Pikosekundenlaser hat die Vorteile eines kleinen Punktdurchmessers, einer hohen Präzision, einer kurzen Einwirkungszeit auf das Material und eines kleinen Einwirkungsbereichs und eignet sich für die Bearbeitung von harten und spröden Materialien.
。
