Quartz Tube
Quartz Plate
Quartz Rod
Optical Applications
Semiconductor Industry
Laboratory and Chemical ApplicationsA 45-degree angled quartz light guide rod is manufactured using specific angle cutting or forming processes, giving it a 45-degree angled surface. This design facilitates light transmission or redirection in a specific direction, accommodating particular optical system requirements.
| 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
| Property Content | Property Values |
|---|---|
| SiO2 | 99.99% |
| Density | 2.2×10³ kg/cm³ |
| Hardness | 5.5 - 6.5 Mohs' Scale 570 KHN 100 |
| Tensile Strength | 4.8×10⁷ Pa (N/mm2) (7000 psi) |
| Compression Strength | >1.1×10⁹ Pa (160,000 psi) |
| Coefficient of Thermal Expansion | 5.5×10⁻⁷ cm/cm·°C (20°C-320°C) |
| Thermal Conductivity | 1.4 W/m·°C |
| Specific Heat | 670 J/kg·°C |
| Softening Point | 1730°C (3146°F) |
| Annealing Point | 1210°C (2210°F) |
| Strain Point | 1120°C (2048°F) |
| Work Temperature | 1200°C (2192°F) |
| Electrical Resistivity | 7×10⁷ ohm cm (350°C) |
| Size | Customized |
| Logo | Customized Logo Accept |
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.
45-Degree Angled Design
This light guide rod is manufactured with a specific angle cutting or forming process to create a 45-degree angled surface. This design facilitates specific directional light transmission or redirection to meet the needs of particular optical systems.
High Light Transmittance
Made from high-purity quartz material, this light guide rod exhibits excellent light transmission, ensuring high throughput of light signals during transmission and minimizing light loss.
High-Temperature and Corrosion Resistance
The quartz material provides outstanding resistance to both high temperatures and corrosion, enabling the light guide rod to maintain stable performance even in harsh environmental conditions.
High-Precision Machining
To ensure the accuracy and finish of the 45-degree angled surface, this light guide rod undergoes precision machining and polishing processes, meeting high-precision optical requirements.
Application Scenario
Optical Systems
45-degree angled quartz light guide rods are widely used in various optical systems, such as optical sensors, optical imaging systems, and lasers. They play a vital role in these systems for transmitting, redirecting, or focusing light signals.
Medical Equipment
In the medical equipment field, 45-degree angled quartz light guide rods are extensively used in laser surgical instruments and optical microscopes. They ensure precise transmission and imaging of light signals, thereby enhancing the performance and accuracy of medical devices.
Scientific Research
In scientific research, researchers use 45-degree angled quartz light guide rods to construct diverse optical experimental systems for studying optical phenomena and the properties of optical materials. The high precision and stability of these light guide rods ensure more reliable and accurate experimental results.
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Frequently asked questions
Quartz glass is a hard and brittle material with excellent physical and chemical properties, extremely high mechanical hardness, good electrical insulation, high temperature and corrosion resistance, low and stable delay performance, good light transmittance, etc. It is widely used in semiconductors, optics, electricity, chemistry, aerospace, automobiles and other fields. Hard and brittle materials are difficult to process, and many fields urgently need cutting processes with small edge collapse, less material loss, low cross-section roughness, and a wide cutting thickness range. The traditional cutting method of quartz glass is mechanical cutting, that is, wheel cutting. Non-traditional cutting methods include water jet cutting, electrochemical discharge wire cutting, continuous laser cutting, etc. Mechanical cutting has low cost, but the contact between the wheel and the material causes large tool wear, and the material is easily contaminated by the tool. Quartz glass is prone to edge collapse, microcracks, and residual stress, which affects the strength and performance of the material! It is difficult to achieve curve cutting and requires post-processing, such as grinding and polishing. Laser cutting does not directly contact the material, has no contact stress, and can perform complex curve cutting. Picosecond laser has the advantages of small spot diameter, high precision, short action time with the material, and small action area, and is suitable for the processing of hard and brittle materials.
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