Computational and Experimental Studies into Concentration Limits of Associated Petroleum Gas Combustion

• Main Authors: Bachev N.L., Matyunin O.O., Bulbovich R.V., Betinskaya O.A., Shilova A.A.
• Format: Article
• Language: English
• Published: Academy of Sciences of Moldova 2019-08-01
• Series: Problems of the Regional Energetics
• Subjects: associated petroleum gases; a; flammability limits
• Online Access: http://journal.ie.asm.md/assets/files/04_02_43_2019.pdf

The issue of utilizing associated petroleum gas from low-yield fields in gas turbine power plants has become relevant recently. To develop universal power plants ensuring steady combustion of dissimilar in composition and highly ballast gases from different fields, reliable information on their combustion limits under real operating conditions is required. Composition analysis of as-sociated petroleum gases from various fields of the Russian Federation shows that the volume fraction of ballast components can be as high as 90 %, heavy hydrocarbons up to 10 %, hydro-gen sulfide-up to 6 %. This work is aimed to theoretical determination and experimental confir-mation of combustion concentration limits of associated petroleum gas. Another purpose is to work out recommendations for selection of the excess air ratio in the primary zone of the cham-ber at the design stage. This is achieved by theoretical determination of the air access coefficient on the upper and lower combustion limits using phlegmatization methods and experimental sub-stantiation of the computational results. The first experimental results were obtained in the pro-cess of burning petroleum gases collected directly in the fields with the volume fraction of bal-last components 26 % and 40 %. To clearly determine the presence of combustion in the cham-ber, a synchronous video recording of the process was conducted. Computational and experi-mental studies into concentration limits of associated alternated composition petroleum gas combustion resulted in some recommendations on organizing stable diffusion and homogeneous combustion in one-, two- or three-zone combustion chambers.