A Critical Overview of the State-of-the-Art Methods for Biogas Purification and Utilization Processes

Muhamed Rasit Atelge,Cigdem Eskicioglu,David Krisa,Sebahattin Unalan,Hamdi Muratçobanoğlu,Nuri Azbar,Slimane Kalloum,Mohammed Djaafri,Abdulaziz Atabani,Hilal Demir Kıvrak,Tulin Avci Hansu,Halil Senol

doi:10.3390/su132011515

Abstract

Biogas is one of the most attractive renewable resources due to its ability to convert waste into energy. Biogas is produced during an anaerobic digestion process from different organic waste resources with a combination of mainly CH4 (~50 mol/mol), CO2 (~15 mol/mol), and some trace gasses. The percentage of these trace gases is related to operating conditions and feedstocks. Due to the impurities of the trace gases, raw biogas has to be cleaned before use for many applications. Therefore, the cleaning, upgrading, and utilization of biogas has become an important topic that has been widely studied in recent years. In this review, raw biogas components are investigated in relation to feedstock resources. Then, using recent developments, it describes the cleaning methods that have been used to eliminate unwanted components in biogas. Additionally, the upgrading processes are systematically reviewed according to their technology, recovery range, and state of the art methods in this area, regarding obtaining biomethane from biogas. Furthermore, these upgrading methods have been comprehensively reviewed and compared with each other in terms of electricity consumption and methane losses. This comparison revealed that amine scrubbing is one the most promising methods in terms of methane losses and the energy demand of the system. In the section on biogas utilization, raw biogas and biomethane have been assessed with recently available data from the literature according to their usage areas and methods. It seems that biogas can be used as a biofuel to produce energy via CHP and fuel cells with high efficiency. Moreover, it is able to be utilized in an internal combustion engine which reduces exhaust emissions by using biofuels. Lastly, chemical production such as biomethanol, bioethanol, and higher alcohols are in the development stage for utilization of biogas and are discussed in depth. This review reveals that most biogas utilization approaches are in their early stages. The gaps that require further investigations in the field have been identified and highlighted for future research.

Highlights

The bioeconomy is a new approach economy model that produces energy, food, and materials from renewable biological resources [1]
This paper examines the main principles of various upgrade methods, the technical and scientific features/consequences for biomethanation efficiency, the challenges that need to be addressed for further improvement, and the applicability of upgrade concepts
MW, and single-cycle gas turbine efficiencies are between 20–45% and their efficiency incombustion, and the results revealed that electrical efficiency was 53% and combined heat and power (CHP) efficiency could reach 82% using exhausted gases for energy recovery with low NOx emissions which was around 2% of the volume of exhausted gases [152]

Summary

Introduction

The bioeconomy is a new approach economy model that produces energy, food, and materials from renewable biological resources [1]. Several authors have concluded that bioenergy has a significant role to play in the decarbonization of society. In this context, it is critical to widen and deepen investigations of bioenergy materials that could be employed to aid in the attainment of sustainability objectives [4]. Biomasses are suitable for use in local energy supply and consumption systems. This means that energy production from locally sourced biomass is far more sustainable than energy production from biomass sourced from other areas, sometimes even across national borders [1]

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