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Steam Methane Reforming CC¤

Introduction¤

In the Steam Methane Reforming (SMR) process, depicted in Figure 1a, natural gas is combined with high-pressure steam and introduced into reforming tubes containing catalysts conducive to the reforming reactions. These reactions are inherently endothermic, necessitating the integration of a furnace within the reforming section to provide the essential thermal energy. The fuel for this furnace is sourced from natural gas and the purge stream from the Pressure Swing Adsorption (PSA) unit.

Simplified block diagrams of hydrogen production technologies: (a) SMR natural gas reforming source:(1)
Simplified block diagrams of hydrogen production technologies: (a) SMR natural gas reforming source:(1)

For systems equipped with carbon capture technology, an additional CO2 removal unit is imperative to isolate and liquefy the CO2 present in the flue gas stream emanating from the furnace.[^1]

ES Model Parameters¤

All the parameters concerning the Steam Methane Reforming CC are listed in the table below.

entry_key value unit sets source_reference
CO2_C (layer) 0.236 kg_CO2 CAN Slaymaker, Amara, (2021): "Demographic and Geographic Region Definition in Energy System Modelling. A Case Study of Canada's Path to Net Zero Greenhouse Gas Emissions by 2050 and the Role of Hydrogen"
CO2_E (layer) 0.026 kg_CO2 CAN Slaymaker, Amara, (2021): "Demographic and Geographic Region Definition in Energy System Modelling. A Case Study of Canada's Path to Net Zero Greenhouse Gas Emissions by 2050 and the Role of Hydrogen"
H2_HP (layer) 1 kWh CAN Slaymaker, Amara, (2021): "Demographic and Geographic Region Definition in Energy System Modelling. A Case Study of Canada's Path to Net Zero Greenhouse Gas Emissions by 2050 and the Role of Hydrogen"
HEAT_HIGH_T (layer) -1.183 kWh CAN Slaymaker, Amara, (2021): "Demographic and Geographic Region Definition in Energy System Modelling. A Case Study of Canada's Path to Net Zero Greenhouse Gas Emissions by 2050 and the Role of Hydrogen"
NG_HP (layer) -0.983 kWh CAN Slaymaker, Amara, (2021): "Demographic and Geographic Region Definition in Energy System Modelling. A Case Study of Canada's Path to Net Zero Greenhouse Gas Emissions by 2050 and the Role of Hydrogen"
c_inv 1405.87 CAD/kW CAN Slaymaker, Amara, (2021): "Demographic and Geographic Region Definition in Energy System Modelling. A Case Study of Canada's Path to Net Zero Greenhouse Gas Emissions by 2050 and the Role of Hydrogen"
c_maint 70.29 CAD/kW/y CAN Slaymaker, Amara, (2021): "Demographic and Geographic Region Definition in Energy System Modelling. A Case Study of Canada's Path to Net Zero Greenhouse Gas Emissions by 2050 and the Role of Hydrogen"
c_p 0.85 - CAN Slaymaker, Amara, (2021): "Demographic and Geographic Region Definition in Energy System Modelling. A Case Study of Canada's Path to Net Zero Greenhouse Gas Emissions by 2050 and the Role of Hydrogen"
lifetime 30 y CAN Slaymaker, Amara, (2021): "Demographic and Geographic Region Definition in Energy System Modelling. A Case Study of Canada's Path to Net Zero Greenhouse Gas Emissions by 2050 and the Role of Hydrogen"

References¤

Data Sources
Slaymaker, Amara. (2021). "Demographic and Geographic Region Definition in Energy System Modelling. A Case Study of Canada's Path to Net Zero Greenhouse Gas Emissions by 2050 and the Role of Hydrogen"

[^1] Khojasteh Salkuyeh, Yaser, et al. “Techno-economic analysis and life cycle assessment of hydrogen production from natural gas using current and emerging technologies.” Int. J. Hydrogen Energy, vol. 42, no. 30, 27 July 2017, pp. 18894-909, www.sciencedirect.com/science/article/pii/S0360319917322036 ⧉.