At natural gas pressure reducing stations, gas first enters a water bath heater to boost its temperature slightly,
and after leaving the heater, it enters the throttle valve to reduce its pressure. This method has two major
drawbacks, which are the consumption of natural gas in the heater and the excessive loss of exergy in the throttle
valve. The pressure of natural gas can be reduced by using a vortex tube and converting it into hot and cold
currents, and then generating electricity by directing these currents to thermoelectric generators (TEGs).
Investigation of energy, exergy and environmental performance of the hybrid vortex tube-TEG system and
optimization of its performance for the working condition of Kermanshah pressure reducing station is the subject
of the present study. The cold mass fraction (CF) and efficiency of vortex tube are considered as decision variables.
Moreover, annual average first-law efficiency (ηI TEG), annual average second-law efficiency (ηII TEG) and
annual total electric power generated by the TEGs (Pout) are considered as optimization target functions. The
results of genetic algorithm based three-objective optimization revealed that the specifications of the optimal
system are: vortex tube efficiency = 0.36967, CF=0.95598, ηI TEG=0.03442, ηII TEG=0.04544, Pout=42770.58
kW and amount of CO2 mitigation per annum = 8.55 tons.