Abstract
Carbon consumption of activated carbon varies with sulfur-containing products. In this work, differential thermogravimetric (DTG), electron paramagnetic resonance (ESR), X-ray photoelectron spectroscopy (XPS), and temperature programmed desorption (TPD) we re used to reveal the adsorption-regeneration process of H2S and the effect of adsorption products on carbon consumption. The results show that H2S reacts with the C=C bond to form the C-S bond as an intermediate state, followed by the formation of elemental sulfur. It directly sublimates at approximately 380 °C, about 30 °C higher than the decomposition temperature of H2SO4. In the thermal regeneration process, the elemental sulfur in the form of monoclinic sulfur (S8) first breaks into infinitely long chain molecules (S∞) and then into small molecules, finally into sulfur vapor. The desorption of elemental sulfur consumes less oxygen and carbon functional groups, reducing the chemical carbon consumption by 59.8% than H2SO4; moreover, the compressive strength reduces less due to its slight effect on the disordered graphitic structure. H2S also reacts with the C=O bond to form H2SO3 or H2SO4. The desorption of H2SO3 does not require carbon consumption. The decomposition of H2SO4 needs to react with the C=C bond to release SO2, CO2, and CO, and the compressive strength of activated carbon significantly decreases. The carbon consumption originates from two aspects; the one from the regeneration of sulfur-containing products is more than twice the other one from the decomposition of oxygen-containing functional groups.
Highlights
Due to the leakage of coke oven gas from the furnace wall, coke oven flue gas contains approximately 200 mg/m3 H2S in addition to 150 mg/m3 SO2, and this issue must be ameliorated by oxidation (Vinod and Tawfik, 2013)
To further illustrate the decomposition process of the sulfur products in activated carbon, in situ diffuse reflectance infrared Fourier transform (DRIFT) spectra are carried out with the results shown in Fig. 2 (c) and (d)
When the activated carbon is regenerated, the temperature rise first causes the S8 ring structure to break into infinitely long chain molecules (S∞)
Summary
Due to the leakage of coke oven gas from the furnace wall, coke oven flue gas contains approximately 200 mg/m3 H2S in addition to 150 mg/m3 SO2, and this issue must be ameliorated by oxidation (Vinod and Tawfik, 2013). Carbon consumption of activated carbon purification technology is obvious different under different industrial flue gas. For a long-term operation of activated carbon purification device, it is found that the carbon consumption in sintering flue gas purification is 1.15 ~ 1.2 times higher than that in coke oven flue gas purification. The both flue gas has a similar NO concentration about 300 ~ 400 ppm and total sulfur concentration about 200 ~ 300 ppm. There is little research on the effects of H2S on carbon consumption of activated carbon for flue gas purification
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
