ACP34
Material description
Material ID: ACP34
Material type: Aluminium composite panel with a core consisting of polyethylene (PE) and fire retardants.
Polymer: Polyethylene (32%)
Additives (fire retardants, fillers or traces of inorganic elements): Magnesium Hydroxide (56%), Calcium Carbonate (7%), Silicon Oxide (5%), Sodium (1%), traces of other elements (<1%)
Core thickness: 2.91mm
Thickness of single metal skin: 0.5mm
Table 1. Estimated mass concentration of compounds.
| Compound | Mass Concentration (%) |
|---|---|
| Polyethylene (PE) | 32 |
| Magnesium Hydroxide (Mg(OH)2) | 56 |
| Calcium Carbonate (CaCO3) | 7 |
| Silicon Oxide (SiO2) | 5 |
| Sodium (Na) | 1 |
| Traces of iron (Fe) | <1 |
| Traces of potassium (K) | <1 |
| Traces of aluminium (Al) | <1 |
A. Material composition identification
A.1 Attenuated total reflection – Fourier transform infrared spectroscopy (ATR-FTIR)
Table 2. FTIR compound identification.| Identified Compounds |
|---|
| Polyethylene (PE) |
| Magnesium Hydroxide (Mg(OH)2) |
| Calcium Carbonate (CaCO3) |
| Silicon Oxide (SiO2) |
Figure 1 . FTIR spectra: Absorbance percentage versus wavenumber from the sample.
Figure 2. FTIR spectra: Absorbance percentage versus wavenumber from the sample and the identified compounds.
A.2 Energy Dispersive X-Ray Fluorescence (EDXRF)
Table 2. Inorganic elements and their mass concentration identified with EDXRF.
| Element | Mass Concentration (%) |
|---|---|
| Mg | 20 |
| Ca | 5 |
| Si | 3 |
| Fe | 1 |
| Na | 1 |
| K | <1 |
| Al | <1 |
| Al | <1 |
Figure 3. EDXRF spectra. Counts vs energy. Identified elements are shown as vertical lines.
B. Thermogravimetric analysis
Table 3. Mass fraction of residue after thermal decomposition.
| Condition | Fraction of mass residue at 800°C |
|---|---|
| Non-oxidative (nitrogen) | 0.41 |
| Oxidative (air) | 0.40 |
Table 4. Temperature and amplitude of main peaks in non-oxidative conditions.
| Peak ID | Temperature peak (°C) | Amplitude of peak (°C-1) |
|---|---|---|
| Peak 1 | 391 | 1.82 x 10-3 |
| Peak 2 | 485 | 1.114 x 10-2 |
| Peak 3 | 693 | 5.7 x 10-4 |
Table 5. Temperature and amplitude of main peaks in oxidative conditions.
| Peak ID | Temperature peak (°C) | Amplitude of peak (°C-1) |
|---|---|---|
| Peak 1 | 405 | 3.12 x 10-3 |
| Peak 2 | 472 | 9.36 x 10-3 |
| Peak 3 | 690 | 5.9 x 10-4 |
Figure 4. Normalised mass (solid line) and derivative of the normalised mass (dashed line) in 150 ml min-1 of nitrogen and a heating rate of 20°C min-1.
Figure 5. Normalised mass (solid line) and derivative of the normalised mass (dashed line) in 150 ml min-1 of air and a heating rate of 20°C min-1 .
C. Gross Heat of Combustion
Table 7. Gross Heat of Combustion individual results for sample.| Trial | ΔHc [kJ g-1] |
|---|---|
| Trial 1 | 18.05 |
| Trial 2 | 18.13 |
| Trial 3 | 18.09 |
| Average | 18.09 |
| Std dev | 0.04 |
D. Ignition parameters
Table 8. Summary of ignition parameters for sample.| Critical heat flux for ignition | Ignition temperature | Total heat transfer coefficient of losses | Apparent thermal inertia |
|---|---|---|---|
| q̇″cr [kW m−2] | Tig [°C] | hr [W m-2 K-1] | kρc [kW2 m-4 K-2 s] |
| 16.40 | 388 | 40 | 1.526 |
Figure 6. Time-to-ignition vs incident radiant heat flux for samples.
E. Burning behaviour
Table 9. Summary of key burning behaviour metrics.
| Heat flux | Test | Time to ignition | Fraction of mass residue | Peak heat release rate | Total energy released |
|---|---|---|---|---|---|
| q̇″inc [kW m-2] | tig [s] | mres [-] | q̇″p [kW m-2] | Qt [MJ m-2] | |
| 35 kW m-2 | |||||
| Test 1 | 127 | 0.49 | 134.87 | 73.85 | |
| Test 2 | 138 | 0.47 | 140.82 | 85.59 | |
| Avg | 132 | 0.48 | 137.84 | 79.72 | |
| 50 kW m-2 | |||||
| Test 1 | 84 | 0.45 | 141.18 | 70.72 | |
| Test 2 | 74 | 0.46 | 196.31 | 78.93 | |
| Avg | 79 | 0.46 | 168.75 | 74.83 | |
| 60 kW m-2 | |||||
| Test 1 | 60 | 0.41 | 222.74 | 86.03 | |
| Test 2 | 61 | 0.45 | 226.74 | 81.66 | |
| Avg | 60 | 0.43 | 224.74 | 83.85 | |
| 80 kW m-2 | |||||
| Test 1 | - | - | - | - | |
| Test 2 | - | - | - | - | |
| Avg | - | - | - | - |
Figure 7. Normalised mass loss over time for samples tested with 35, 50, 60 and 80 kW m-2.
Figure 8. Heat release rate per unit area over time for samples tested with 35, 50, 60 and 80 kW m-2.
| Test | ΔHc [kJ g-1] |
|---|---|
| 35 kW m-2 (Test 1) | 34.37 |
| 35 kW m-2 (Test 2) | 36.82 |
| 50 kW m-2 (Test 1) | 29.51 |
| 50 kW m-2 (Test 2) | 34.13 |
| 60 kW m-2 (Test 1) | 33.81 |
| 60 kW m-2 (Test 2) | 34.25 |
| 80 kW m-2 (Test 1) | - |
| 80 kW m-2 (Test 2) | - |
| Average | 33.82 |
| Std dev | 2.37 |
F. Flame Spread
Table 11. Minimum heat flux for flame spread rate and minimum flame spread rate for sample.| Orientation | q̇″min.spread [kW m-2] | Vf.min [mm s-1] |
|---|---|---|
| Horizontal | 10.60 | - |
| Vertical | 11.10 | - |
Figure 9. Lateral flame spread rate versus heat flux.
Figure 10. Vertical flame spread rate versus heat flux.
Figure 11. Vf-1/2 as function of q̇″ext in horizontal configuration.
Figure 12. Vf-1/2 as function of q̇″ext in vertical configuration.
Table 12. Flame spread parameter results for sample.
| Orientation | Trial | (kρcp⁄Φh2)1⁄2 [m3⁄2 s1⁄2 kW-1] | Φ [kW2 m-3] |
|---|---|---|---|
| Horizontal | 1 | 13.68 | 5.19 |
| Horizontal | 2 | 13.429 | 5.39 |
| Vertical | 1 | 6.271 | 24.71 |
| Vertical | 2 | 7.444 | 17.54 |