Both are removable-cover cores; the split is 550 °C. E-glass needle mat to 550, silica beyond to ~1000. Inzonex tiers covers on exactly this logic.
| E-glass needle mat | Silica needle mat / fabric | |
|---|---|---|
| Max service | 550 °C | 1000 °C |
| Density | 120–160 | 130–180 |
| Standards | needled E-glass per supplier datasheets (no binder — no smoke on first heat) | amorphous silica (≥94% SiO2) textiles per supplier datasheets |
| Forms | needled fibreglass mat — the standard CORE of removable insulation covers | needle mat and woven fabric — high-temperature removable covers, turbine and exhaust lagging |
| Duty | λ E-glass needle mat | λ Silica needle mat / fabric | E-glass needle mat thickness for EQUAL loss to 50 mm of Silica needle mat / fabric |
|---|---|---|---|
| 100 °C | 0.045 | 0.055 | 38 mm vs 50 mm |
| 250 °C | 0.050 | 0.055 | 43 mm vs 50 mm |
| 400 °C | 0.060 | 0.056 | 54 mm vs 50 mm |
Bisection on the cylindrical conduction equation; λ at mean temperature per each material's published curve. Full per-material tables: E-glass needle mat · Silica needle mat / fabric.
| Material | λ W/m·K | Loss W/m | Surface | Saving €/m·yr | t CO2/m·yr |
|---|---|---|---|---|---|
| Stone wool (mineral wool) | 0.041 | 31 | 25 °C | €125 | 0.5 |
| Glass wool | 0.038 | 29 | 24 °C | €126 | 0.5 |
| Ceramic fibre (RCF / AES blanket) | 0.060 | 44 | 27 °C | €119 | 0.4 |
| Aerogel blanket | 0.023 | 18 | 23 °C | €131 | 0.5 |
| Calcium silicate | 0.056 | 42 | 26 °C | €120 | 0.4 |
| Expanded perlite | 0.061 | 45 | 27 °C | €118 | 0.4 |
| Cellular glass | 0.047 | 35 | 25 °C | €123 | 0.4 |
| Microporous (fumed-silica) panels | 0.022 | 17 | 23 °C | €132 | 0.5 |
| Elastomeric foam (FEF) | 0.040 | 30 | 24 °C | €125 | 0.5 |
| PIR / PUR rigid foam | 0.028 | 21 | 23 °C | €130 | 0.5 |
| E-glass needle mat | 0.045 | 34 | 25 °C | €124 | 0.5 |
| Silica needle mat / fabric | 0.055 | 41 | 26 °C | €120 | 0.4 |
DN100 pipe at 100 °C, 50 mm insulation, per metre of pipe; bare loss 287 W/m. λ at mean temperature; € and CO2 per metre·year at €0.05/kWh, 8000 h, 82% efficiency. Method: ASTM C680 simplified (h=10).
