These
illustrations show how electric vehicles can help balance a city's power grid
as solar generation fluctuates during passing thunderstorms. Credit: Urban
Systems Engineering Lab
In tropical cities, afternoon
thunderstorms can plunge entire neighborhoods into brief moments of darkness.
When civil engineer Markus Schläpfer moved to Singapore a decade ago, he
recognized these thunderstorms as an emerging engineering challenge. For cities
that hope to run on solar energy, these short periods without strong sunlight
could destabilize urban power grids and undermine reliability.
In a paper, published in Nature Communications, Schläpfer and
collaborators explain how tropical cities, which will soon contain half of the
global population, can address this problem without expensive infrastructure
build-outs. For Schläpfer, the solution lies in connecting electric vehicles to
the grid.
"If you have a thunderstorm
moving over an area with solar energy, you can have your electric cars that are parked
serve as the energy source and balance out this lack of energy
generation," said Schläpfer, assistant professor of civil engineering and
engineering mechanics at Columbia Engineering. "When the thunderstorm
moves away, the cars are charged again by the photovoltaics."
The hidden cost of going solar
Solar photovoltaics (PV) have
become one of the cheapest sources of energy on the planet. PV energy is
inexpensive, carbon-free, and reliable—when the sun is shining.
When thunderstorms cut off power
generation in one neighborhood, electricity has to travel from neighboring
regions that are generating power. While that trip may only be a mile or two,
the amount of electricity flowing through power lines can easily overwhelm
the grid's capacity.
Traditionally, fixing a problem
like this would require new infrastructure, but that comes with significant
drawbacks. In dense cities, such projects can be staggeringly expensive.
Underground transmission lines in Singapore, for example, cost around 60 million
Singapore dollars per kilometer.
"Building new infrastructure
is extremely challenging and expensive in dense cities," Schläpfer said.
"This is a way to use the existing network in a more efficient way and
integrate more solar photovoltaics, which would otherwise need more
transmission line capacity."
Batteries already on the road
Researchers across the world are
exploring the possibility of using electric vehicles—namely their batteries—as
a substitute for new grid capacity. The idea is simple: since electric vehicles
have high-capacity batteries that connect to the grid through charging cables,
the grid should be able to use the energy stored in these batteries as a backup
during short-lived lulls in PV generation.
"Car batteries can feed in the
electricity stored in their batteries to the grid," Schläpfer explained.
"We do not need to import the electricity from nearby neighborhoods.
Therefore, we do not need to install a new cable."
When a thunderstorm cuts off solar
generation in a neighborhood, nearby parked cars discharge stored energy into
the local grid, absorbing the shortfall without requiring power to travel from
elsewhere. When the storm passes, the panels recharge the cars.
The right scale for the problem
Schläpfer's paper demonstrates the
importance of scale in developing a strategy for charging and discharging EV
batteries for this purpose. A conventional city-wide optimization strategy can
make things worse: by smoothing aggregate demand, it allows local imbalances to
accumulate, forcing the system to push large amounts of electricity across
longer distances. According to the team's research, loads traveling through
some transmission lines more than doubled during thunderstorms.
A better approach is managing charging neighborhood by neighborhood—in this case,
across Singapore's 55 urban planning areas—to reduce maximum line loads by
roughly 18% on storm days while also smoothing the broader daily demand curve.
"It's one of those things that
only seems intuitive once you see it," Schläpfer said. "This
potential hasn't really been explored before."
Where cars park matters
The method's effectiveness depends
on where cars are parked. Residential neighborhoods empty out during the day,
leaving fewer batteries available when solar generation peaks. Commercial
districts show the reverse. The researchers mapped these patterns using
anonymized, aggregated mobile phone data, which provided a level of detail that
allowed for more accurate models.
Crucially, the approach works even
where car ownership is low. Singapore has roughly one vehicle per eight
residents.
"This solution is really working in very car-light environments," Schläpfer said. "We need only a small number of cars, and it works."
Source: How electric cars could help tropical cities run on solar
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