Material Composition | Lab equipment requiring high-temperature stability | Industry Standard: Borosilicate Glass (Melting Point: 820°C, ASTM C1210) Our Base: Pure Quartz (1710°C▲) Our Advanced: Coated Quartz (1750°C▲▲) | Superior heat resistance for extreme lab processes Chemical inertness (resists acids/bases) | Higher cost vs standard glass Brittle compared to metal alternatives |
Thermal Performance | High-temperature sterilization chambers | Industry Standard: Up to 1000°C (ISO 9001) Our Base: 1100°C▲ Our Advanced: 1400°C▲▲ (ASTM C1210) | Enables use in ultra-high-temperature labs (e.g., material testing) Uniform heat distribution | Requires specialized power systems for Advanced versions |
Surface Finish | Precision lab tools needing smooth surfaces | Industry Standard: Matte Finish (Ra 1.6 μm) Our Base: Polished (Ra ≤0.8 μm▲) Our Advanced: Ultra-Polished (Ra ≤0.4 μm▲▲) | Minimizes sample contamination Enhances optical clarity for monitoring | Polishing adds production cost and fragility |
Chemical Resistance | Acidic/alkaline environment use | Industry Standard: Resists 10+ chemicals (ASTM D543) Our Base: 30+ chemicals▲ Our Advanced: 50+ chemicals▲▲ (ISO 750) | Safe for corrosive lab chemicals (e.g., hydrofluoric acid) No coating degradation | Not compatible with hydrofluoric acid (quartz limitation) |
Dimensional Stability | Precision instruments requiring rigidity | Industry Standard: Thermal Expansion 3.2×10⁻⁶/°C (ASTM E228) Our Base: 2.1×10⁻⁶/°C▲ Our Advanced: 1.5×10⁻⁶/°C▲▲ | Maintains shape under rapid temp changes (e.g., cryogenic testing) Reduces calibration needs | Limited flexibility for non-uniform heating setups |
Electrical Conductivity | Insulated heating systems | Industry Standard: Conductivity 1×10⁻⁵ S/m (IEC 60093) Our Base: 5×10⁻⁷ S/m▲ Our Advanced: 1×10⁻⁷ S/m▲▲ | Safer for electrically sensitive lab equipment Minimizes energy loss | Requires thicker insulation for Advanced versions |