Abstract
A viable hydrogen infrastructure is one of the main challenges for fuel cells in mobile applications. Several studies have investigated the most cost-efficient hydrogen supply chain structure, with a focus on hydrogen transportation. However, supply chain models based on hydrogen produced by electrolysis require additional seasonal hydrogen storage capacity to close the gap between fluctuation in renewable generation from surplus electricity and fuelling station demand. To address this issue, we developed a model that draws on and extends approaches in the literature with respect to long-term storage. Thus, we analyse Liquid Organic Hydrogen Carriers (LOHC) and show their potential impact on future hydrogen mobility. We demonstrate that LOHC-based pathways are highly promising especially for smaller-scale hydrogen demand and if storage in salt caverns remains uncompetitive, but emit more greenhouse gases (GHG) than other gaseous or hydrogen ones. Liquid hydrogen as a seasonal storage medium offers no advantage compared to LOHC or cavern storage since lower electricity prices for flexible operation cannot balance the investment costs of liquefaction plants. A well-to-wheel analysis indicates that all investigated pathways have less than 30% GHG-emissions compared to conventional fossil fuel pathways within a European framework.
Highlights
The transition to renewable energy is a centrepiece of global environmental policies
A well-to-wheel analysis determines the ecological impact and efficiency of fuel cell electric vehicles (FCEV) compared to conventional fuel technologies and integrates our results with the 2014 well-to-wheel analysis from the Joint Research Centre, EUCAR and CONCAWE (JEC) [44]
The results show that underground storage solutions and liquid organic hydrogen carrier (LOHC) offer an economic solution to the storage of large amounts of hydrogen at low charge cycles
Summary
The transition to renewable energy is a centrepiece of global environmental policies. The targets set out by the German government foresee a reduction of GHGs in the energy system of 80% by 2050 against 1990 levels [3]. These targets fundamentally depend on the penetration of renewable energy technologies like wind and solar power across all energy sectors. In 2014, 1581 GWh of renewable power was curtailed due to grid congestion, resulting in compensation payments by the EEG levy of 82 million Euro [4].
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