Advancing in the decarbonized future of natural gas transmission networks through a CFD study

The injection of green hydrogen into the natural gas grid is a way to decarbonize the gas sector and build an economic transport route for the large-scale delivery of hydrogen. The suitability of the natural gas infrastructure for this purpose depends on the impact that hydrogen may have on the corr...

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Bibliographic Details
Published in:International journal of hydrogen energy 2022-04, Vol.47 (35), p.15832-15844
Main Authors: Villuendas, Teresa, Montañés, Carlos, Gómez, Antonio, Alarcón, Alberto Cerezo, Storch de Gracia, M. Dolores, Sánchez-Laínez, Javier
Format: Article
Language:English
Subjects:
CFD study
Grid decarbonization
Hydrogen injection
Low-carbon hydrogen
Natural gas grid retrofitting
Transmission gas grid modelling
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Summary:The injection of green hydrogen into the natural gas grid is a way to decarbonize the gas sector and build an economic transport route for the large-scale delivery of hydrogen. The suitability of the natural gas infrastructure for this purpose depends on the impact that hydrogen may have on the correct operation of its components and understanding the new flow conditions in the system is essential for this aim. Computational studies can anticipate the expected environment in the pipe system, assessing the readiness of the system. However, the experience on this topic is not extensive enough and deeper understanding is necessary. Here we show a CFD study to simulate the transport of H2/NG blends in a gas setup with the main characteristics of injection sites and gas pipelines representatives of the transmission gas network. This setup considers a blending station, the pumping and injection procedure, and different pipelines geometries to predict the behavior of various mixtures of H2/NG. It can be seen how (1) a good mixing is achieved in the blending station after a pipe length equivalent to 20–30 diameters is reached; (2) pumping gas by a piston type compressor shows pulsations in the flow regardless the composition of the blend that can be damped implementing mitigation measurements; and (3) asymmetries in the flow are found when the direction of the fluid changes after section reduction, but 20 diameters downstream of the reduction the flow is fully developed. [Display omitted] •Modelling the injection of hydrogen in the natural gas transmission grid.•CFD studies to anticipate the behavior of the new fluid.•Mixing quality and possible segregation in blending stations considered.•Flow pattern when DN 80 pipes expands to a DN 150 or a DN 250 pipes.•Simulation of pumping of H2 and CH4 by a piston type compressor.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2022.03.055