new material
Thermal insulating glass is an advanced architectural material designed to improve energy efficiency by reducing heat transfer. Engineered with multiple layers, low-emissivity coatings, and gas-filled cavities, it significantly enhances indoor climate control, minimizes heat loss, and increases sustainability in residential, commercial, and industrial applications. This glass ensures optimal thermal insulation while maintaining optical clarity, making it essential for modern building designs, aerospace structures, and precision engineering solutions.
Product Overview
Thermal insulating glass is specially designed optical glass used to block the conduction of heat sources. It is widely used in devices and instruments that require effective thermal isolation. With its unique material structure and coating technology, thermal insulating glass provides excellent heat resistance, significantly reducing heat transfer and protecting equipment from high temperatures. It is commonly used in medical devices, projectors, and other temperature-sensitive instruments.
Key Features
- Excellent Thermal Insulation: Effectively prevents heat transfer, protecting devices from external heat sources.
- High Transparency: Despite its superior thermal insulation properties, the glass retains high transparency, ensuring the normal operation of devices.
- High-Temperature Resistance: Has excellent heat resistance, allowing it to operate stably in high-temperature environments.
- Durability: Offers strong impact resistance and abrasion resistance, making it suitable for various industrial applications.
- Customizable Sizes: Available in various sizes and shapes, customized to meet the specific needs of different devices.
Applications
- Medical Devices: Widely used in medical equipment such as high-temperature devices, laser therapy machines, UV sterilization equipment, etc., to protect sensitive components from thermal damage.
- Projection Equipment: Used in projectors and similar devices to effectively block heat and prevent overheating.
- Precision Instruments: Provides stable thermal conditions in devices requiring precise temperature control, such as electron microscopes and lasers.
- Industrial Equipment: Acts as a thermal protection material in industrial environments, ensuring equipment stability and safety in high-temperature working conditions.
- Optical Devices: Used in optical instruments in high-temperature environments to provide effective thermal isolation and maintain the optical performance of the equipment.
| Grade | Thickness (mm) | 420(nm) | 500(nm) | 600(nm) | 700(nm) | 800(nm) | 900(nm) | 1000(nm) | 1060(nm) | 2200(nm) |
| GRB1 | 3 | ≥85.0 | 45.0~70.0 | ≤4.0 | ||||||
| GRB2 | 2 | 365≥83.7 | ≥83.7 | ≥80.0 | ≤61.9 | ≤30.0 | ≤9.1 | ≤1.8 | ||
| GRB3 | 2 | 365≥81.9 | ≥81.0 | ≥76.4 | ≤50.6 | ≤12.9 | ≤2.8 | ≤0.1 | ≤0.9 |
| Grade | Thickness (mm) | A[2856k] | D65 | Chemical Stability | ND | α×10⁻⁷(/℃) | Tg(℃) | Ts(℃) | S | |||||
| x | y | Y | x | y | Y | DA | DW | |||||||
| GRB1 | 3 | 0.439 | 0.412 | 91.7 | 0.307 | 0.33 | 90.8 | 3 | 2 | 1.51 | 59 | 587 | 656 | 2.54 |
| GRB3 | 2 | 0.44 | 0.413 | 86.5 | 0.311 | 0.334 | 87.4 | 2 | 3 | 1.512 | 59 | 587 | 656 | 2.55 |
| Grade | Bubble | Stripe | Stress |
| GRB1 | C | 3C | 4 |
| GRB3 | D-C | 3C | 4 |
