| Open Condition | Incineration | Pilot | Other | 2071 | 7.4 second | At flame; Natural Gas Port; 40 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |
| Open Condition | Incineration | Pilot | Other | 1100 | 5 second | Port 4; 40 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |
| Open Condition | Incineration | Pilot | Other | 950 | 4.2 second | Port 8; 40 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |
| Open Condition | Incineration | Pilot | Other | 900 | 3.6 second | Port 10; 40 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |
| Open Condition | Incineration | Pilot | Other | 875 | 3.3 second | Port 11; 40 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |
| Open Condition | Incineration | Pilot | Other | 825 | 3 second | Port 12; 40 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |
| Open Condition | Incineration | Pilot | Other | 2071 | 7.4 second | At flame; Natural Gas Port; 45 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |
| Open Condition | Incineration | Pilot | Other | 2071 | 7.4 second | At flame; Natural Gas Port; 64 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |
| Open Condition | Incineration | Pilot | Other | 1300 | 5 second | Port 4; 45 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |
| Open Condition | Incineration | Pilot | Other | 1080 | 5 second | Port 6; 45 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |
| Open Condition | Incineration | Pilot | Other | 1050 | 4.2 second | Port 8; 45 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |
| Open Condition | Incineration | Pilot | Other | 930 | 3.6 second | Port 10; 45 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |
| Open Condition | Incineration | Pilot | Other | 850 | 3 second | Port 12; 45 kW loading experiment; The model assumes initial adiabatic flame temperature (2071 °C) and a linear temperature decay to Port 1. PFAS introduced with the natural gas or combustion air (t=0 sec) experience the full temperature profile (Figure 3) and flame chemistry before being analyzed by FTIR at Port 18 (t~7.4 sec). However, PFAS introduced at Ports 4‐12 experienced reduced temperatures, residence times, and exposure to flame chemistry. |