Comparison of Water Scrubbing and Propylene ... - ACS Publications

May 13, 2013 - Table 3 indicates that the water scrubbing process was influenced significantly by H2S. After each experimental condition achieved stea...
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Comparison of Water Scrubbing and Propylene Carbonate Absorption for Biogas Upgrading Process Hong Nie,† Hao Jiang,† Daowen Chong,† Quangui Wu,‡ Chunming Xu,† and Hongjun Zhou*,† †

New Energy Research Institute, State Key Laboratory of Heavy Oil Processing, China University of Petroleum (Beijing), Beijing, China 102249 ‡ Unconventional Oil and Gas Technology Corporation Limited, Beijing, China 102200 ABSTRACT: Biogas upgrading using a physical absorbent is a simple and efficient technology with low energy requirements for regeneration. Owing to the good performance of carbon dioxide removal, propylene carbonate absorption is widely utilized in the purification of natural gas and synthesis gas. In this work, the feasibility of biogas upgrading with propylene carbonate as the absorbent was studied by the comparative tests of water scrubbing and propylene carbonate absorption. The influence factors of absorption gas/liquid ratio, air stripping gas/liquid ratio and hydrogen sulfide content in the feed gas were investigated. The capacity of biogas treated by propylene carbonate was 4−5 times of that by water. The propylene carbonate absorption showed better tolerance to the existence of hydrogen sulfide. When the concentration of hydrogen sulfide in the feed gas increased to 4000 ppm, the methane content in the product gas decreased by 5.09% with water as the absorbent, while it decreased only 1.68% in the propylene carbonate absorption test. The results showed that the propylene carbonate absorption had high efficiency and an obvious advantage of energy conservation when applied for biogas upgrading. The drawbacks of low methane recovery and high solvent loss could be avoided through flash evaporation and solvent recovery.

1. INTRODUCTION Renewable energy sources are of great potential to replace fossil fuels and to mitigate climate change.1 Biogas is an important source of renewable methane.2 It derives from anaerobic digestion of biomass such as industrial organic wastewater, municipal wastewater, agricultural and forestry wastes, municipal solid wastes, livestock manure, and so on.3−9 The composition of biogas is determined by the raw source and fermentation condition. Typically, biogas from anaerobic digestion is primarily composed of methane (CH4, 53−70 vol %) and carbon dioxide (CO2, 30−47 vol %) with trace compounds like hydrogen sulfide (H2S, 0−10000 ppm), ammonia (NH3, 97% CH4) and less CH4 loss (