Tube en quartz
Plaque de quartz
Tige de quartz
Applications optiques
Industrie des semi-conducteurs
Applications en laboratoire et en chimieA quartz slotted rod, as a specialized machining tool, is primarily used for performing slotting operations on quartz materials, such as quartz glass and quartz crystals.
| diameter | length |
|---|---|
| 10mm | 300mm |
| 10mm | 600mm |
| 12mm | 300mm |
| 12mm | 600mm |
| 14mm | 300mm |
| 14mm | 600mm |
| 15mm | 300mm |
| 15mm | 600mm |
| 15mm | 1000mm |
| 16mm | 300mm |
| 16mm | 600mm |
| 16mm | 1000mm |
| 16mm | 1200mm |
| 18mm | 300mm |
| 18mm | 600mm |
| 18mm | 1000mm |
| 18mm | 1200mm |
| 20mm | 300mm |
| 20mm | 600mm |
| 20mm | 1000mm |
| 20mm | 1200mm |
| 22mm | 300mm |
| 22mm | 600mm |
| 22mm | 1000mm |
| 22mm | 1200mm |
| 25mm | 300mm |
| 25mm | 600mm |
| 25mm | 1000mm |
| 25mm | 1200mm |
| 28mm | 300mm |
| 28mm | 600mm |
| 28mm | 1000mm |
| 28mm | 1200mm |
| 30mm | 300mm |
| 30mm | 600mm |
| 30mm | 1000mm |
| 30mm | 1200mm |
| 32mm | 300mm |
| 32mm | 600mm |
| 32mm | 1000mm |
| 32mm | 1200mm |
| 35mm | 300mm |
| 35mm | 600mm |
| 35mm | 1000mm |
| 35mm | 1200mm |
- Payment method:
By T/T or prepayment,
It depends on the quantity of the order. - Delivery time:
According to the order quantity. - Shipping method:
By sea or by air,
It depends on the customer.
Remarks:
To confirm the order,
the following parameters are required:
① outer diameter ② length ③ quantity
| Contenu de la propriété | Valeurs immobilières |
|---|---|
| SiO2 | 99.99% |
| Densité | 2,2×10³ kg/cm³ |
| Dureté | 5,5 - 6,5 Échelle de Mohs 570 KHN 100 |
| Résistance à la traction | 4,8×10⁷ Pa (N/mm2) (7000 psi) |
| Résistance à la compression | >1,1×10⁹ Pa (160 000 psi) |
| Coefficient de dilatation thermique | 5,5×10-⁷ cm/cm-°C (20°C-320°C) |
| Conductivité thermique | 1,4 W/m-°C |
| Chaleur spécifique | 670 J/kg-°C |
| Point d'adoucissement | 1730°C (3146°F) |
| Point de recuit | 1210°C (2210°F) |
| Point de contrainte | 1120°C (2048°F) |
| Température de travail | 1200°C (2192°F) |
| Résistivité électrique | 7×10⁷ ohm cm (350°C) |
| Taille | Sur mesure |
| Logo | Acceptation de logos personnalisés |
There are two primary methods for producing quartz rods: the continuous method and the flame fusion method (also known as the gas fusion method).
Continuous Method: In this method, quartz sand is fed from the top into a furnace, which comprises a metallic quartz crucible surrounded by electric heating elements. The quartz sand melts at high temperatures. The molten material then passes through a shaping orifice at the bottom of the crucible, producing rods, tubes, sheets, or other various specified product forms.
Flame Fusion Method: This method involves using hydrogen and oxygen to melt colorless quartz crystal. The molten material is formed into quartz glass through the melting and congealing of crystalline particles in the flame. The quartz glass is then removed from the flame through different methods and processed into quartz rods of the desired shape.
Industrie des semi-conducteurs
In the semiconductor manufacturing process, quartz slotted rods are used for machining critical components such as wafers. They ensure the precision and quality of the products through precise slotting processes.
Optical Instrument Manufacturing
Quartz slotted rods are also widely used in the manufacturing of optical instruments, for applications like creating slots in lenses and prisms to meet the needs of high-precision optical systems.
Ceramics Industry
In the shaping and sintering of ceramics, quartz slotted rods are used for creating slots with specific shapes or structures, enhancing the quality and yield of ceramic products.
Autres applications industrielles
The structure of a quartz stirring rod generally includes the rod body, head, and connecting rod. Heads are designed in various shapes, such as disks or cones, to meet different stirring needs. Connecting rods are typically equipped with adjustment knobs for easy adjustment of the stirring rod length.
Scénario d'application
Industrie des semi-conducteurs
In the semiconductor manufacturing process, quartz slotted rods are used for machining critical components such as wafers. They ensure the precision and quality of the products through precise slotting processes.
Optical Instrument Manufacturing
Quartz slotted rods are also widely used in the manufacturing of optical instruments, for applications like creating slots in lenses and prisms to meet the needs of high-precision optical systems.
Ceramics Industry
In the shaping and sintering of ceramics, quartz slotted rods are used for creating slots with specific shapes or structures, enhancing the quality and yield of ceramic products.
Autres applications industrielles
Quartz slotted rods are used in various other industrial sectors such as glass processing and electronics manufacturing, fulfilling diverse and complex machining requirements.
The slotting process involves several steps: First, a quartz round rod is shaped into a square rod. Then, the ends of the square rod are cut, and the flatness, length, and perpendicularity of the square rod are inspected. Subsequently, the square rod is embedded into a graphite plate with an equal number of parallel “V”-shaped grooves on its upper surface. Liquid wax is then poured to secure the square rod to the “V”-shaped grooves. Finally, the liquid wax is cooled with water to solidify, completing the fixation of the square rod.
The slotting apparatus comprises a three-axis CNC machine tool with a graphite plate on its platform. The graphite plate features several parallel “V”-shaped grooves on its upper surface. This design helps improve the positioning and fixation of the quartz square rods, enhancing slotting precision.
Using quartz slotted rods offers multiple advantages, including improving the efficiency of slotting multiple square rods simultaneously, ensuring post-slotting precision, reducing damage to square rods during the slotting process, and facilitating easy removal of the slotted square rods.
quartz glass rod
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Quartz Light Guiding Rod
Quartz Angled Light Guiding Rod
Tige de mélange en quartz
Quartz Grooved Rod
Quartz Slotted V-Shaped Rod
CNC Precision Machining of Quartz Columns
Tige de mélange en quartz
Questions fréquemment posées
Le verre de quartz est un matériau dur et cassant doté d'excellentes propriétés physiques et chimiques, d'une dureté mécanique extrêmement élevée, d'une bonne isolation électrique, d'une résistance aux températures élevées et à la corrosion, d'un retard faible et stable, d'une bonne transmission de la lumière, etc. Il est largement utilisé dans les semi-conducteurs, l'optique, l'électricité, la chimie, l'aérospatiale, l'automobile et d'autres domaines. Les matériaux durs et cassants sont difficiles à traiter, et de nombreux domaines ont un besoin urgent de procédés de coupe avec un faible effondrement des arêtes, une perte de matériau réduite, une faible rugosité de la section transversale et une large gamme d'épaisseurs de coupe. La méthode traditionnelle de découpe du verre de quartz est la découpe mécanique, c'est-à-dire la découpe à la meule. Les méthodes de découpe non traditionnelles comprennent la découpe au jet d'eau, la découpe par fil à décharge électrochimique, la découpe au laser en continu, etc. La découpe mécanique est peu coûteuse, mais le contact entre la meule et le matériau entraîne une usure importante de l'outil, et le matériau est facilement contaminé par l'outil. Le verre de quartz est sujet à l'effondrement des arêtes, aux microfissures et aux contraintes résiduelles, ce qui affecte la résistance et les performances du matériau ! Il est difficile de réaliser une découpe en courbe et nécessite un post-traitement, tel que le meulage et le polissage. La découpe au laser n'entre pas directement en contact avec le matériau, n'a pas de contrainte de contact et peut réaliser des découpes de courbes complexes. Le laser picoseconde présente les avantages suivants : petit diamètre du spot, haute précision, temps d'action court avec le matériau et petite zone d'action. Il convient au traitement des matériaux durs et fragiles.
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