< face="Times New Roman">A simple electrochemical method and apparatus for the continues production of CO (carbon monoxide) from CO2 as chemical storage for electrical energy and a basic material for further organic products. < face="Times New Roman">Constant progress is made in solar and wind alternative energy production. Unfortunately, these systems are weather and time-dependent. Additionally, most of the geographic areas best suited for harvesting these resources are remote from population centers. Therefore the need for a reliable method to store and transport renewable energy is clear. < face="Times New Roman">CO can be easily converted into methanol, which is one of the major chemical raw materials and can by itself be used as fuel for diesel engines and the energy source for direct methanol fuel cells (DMFC). < face="Times New Roman">At present no reliable method of CO2 to CO reduction is available. Either using low temperatures which leads to low thermodynamic efficiency (<60%), Requires precious metals for electrodes and results in toxic byproducts, or using high temperatures which Requires pure CO2 input and Produces a mixture of CO2 and CO. < face="Times New Roman">The current technology describes an efficient, flexible, continues method for production of CO at high temperatures (900oC) without any byproducts or toxic materials.
- Production of CO from CO2
- Easy conversion into methanol
- No precious (Pt, Ag, Au, Pd) metals required
- No hazardous chemicals involved, no pollution
- Continuous operation is possible
- One can use flue gas as a source
- Capture of CO2 from air is possible
- The system is very compact>20 kW/m3
- Operation conditions are very flexible
- The process fits existing infrastructure
- CO can be easily converted into liquid fuel (CH3OH)
The outlined technology overcomes the basic problems of CO production by using molten Li2CO3 as the electrolyte, a Ti container (will not undergo corrosion), Ti cathode (does not catalyze decomposition of CO), and a graphite anode (no chemical reaction with Li2CO3). At 900°C and current density of 0.05-2 A/cm2, this unique system enables a thermodynamic efficiency close to 100%, continues production of CO – efficiently separating CO2 to CO and O2.