posted on 2018-01-05, 00:00authored byDavid Grosspietsch, Philippe Thömmes, Bastien Girod, Volker H. Hoffmann
Self-sufficient decentralized systems
challenge the centralized
energy paradigm. Although scholars have assessed specific locations
and technological aspects, it remains unclear how, when, and where energy self-sufficiency
could become competitive. To address this gap, we develop a techno-economic
model for energy self-sufficient neighborhoods that integrates solar
photovoltaics (PV), conversion, and storage technologies. We assess
the cost of 100% self-sufficiency for both electricity and heat, comparing
different technical configurations for a stylized neighborhood in
Switzerland and juxtaposing these findings with projections on market
and technology development. We then broaden the scope and vary the
neighborhood’s composition (residential share) and geographic
position (along different latitudes). Regarding how to design self-sufficient neighborhoods, we find two promising technical
configurations. The “PV-battery-hydrogen” configuration
is projected to outperform a fossil-fueled and grid-connected reference
configuration when energy prices increase by 2.5%
annually and cost reductions in hydrogen-related technologies by a
factor of 2 are achieved. The “PV-battery” configuration
would allow achieving parity with the reference configuration sooner,
at 21% cost reduction. Additionally, more cost-efficient deployment
is found in neighborhoods where the end-use is small
commercial or mixed and in regions where seasonal
fluctuations are low and thus allow for reducing storage requirements.