NO_x and SO_x removals for exhaust gas in glass melting furnace using a plasma and dry chemical hybrid process

Abstract

Laboratory-scale experiments were carried out on simultaneous removal of NO_x and SO_x from a glass melting furnace using a semi-dry plasma and chemical hybrid process (PCHP). The experimental apparatus is simulated to the aftertreatment system for a full-scale semi-dry glass bottle manufacturing system, and NO_x removal processes of plasma-induced ozone gas injection for the oxidation of NO followed by Na₂SO₃ solution reduction of NO₂ and a dry neutralization removal of NO₂ by NaHCO₃ or Na₂CO₃. First, NO removal experiments are carried out with water sprayed to form a localized cooling area by heat removal of vaporization in the reactor. As a result, the NO oxidation efficiencies of 76% (Liquid-to-gas ratio, L/G = 0.7 L/m³) and 98% (L/G = 2.0 L/m³) are achieved by the injecting ozone into the localized cooling area. Next, for experiments with a mixed simulated gas of NO and SO₂, when the mixed aqueous solution of Na₂SO₃ and NaOH is sprayed under the conditions of L/G = 0.7 L/m³ and 2.0 L/m³, NO_x removal efficiencies of 45% and 48% with NO oxidation efficiencies of 62% and 70% are obtained, respectively. Simultaneously, more than 75% of SO₂ is removed. Finally, the neutralization removal of NO₂ is investigated for the reaction with NaHCO₃ or Na₂CO₃ onto the filter in the reactor. It is clarified that Na₂CO₃ is more effective than NaHCO₃ for the removal of NO₂. The stable NO₂ removal is achieved at the dry type reactor. It was confirmed from the experimental results that PCHP combined with dry reduction chemicals method was promising for effective exhaust gas aftertreatment for a glass manufacturing system.