The Under-appreciated Renewable
I’ve been fascinated by geothermal energy for years, and the publication of the latest “International Market Overview” from the Geothermal Energy Association
(GEA) provides a good opportunity to examine how this
proven, low-emission energy technology is changing and expanding into
new opportunities.
Global geothermal power capacity grew by just under 5% in the 16 months since the group’s previous international survey.
That’s slower than the recent growth of wind and solar power, although
its worth recalling that global solar output only caught up with
geothermal in 2011 and still lags behind it in the US. Sufficient
projects are apparently now under development or construction
eventually to double global geothermal capacity to over 23 gigawatts
(GW).
International Growth and Technological Diversification
The report cites geothermal development in 70 countries, but growth
is focused in three main regions: Southeast Asia (Indonesia and
Philippines), North and Central America, and East Africa. The expansion
of geothermal energy in developing countries is particularly
encouraging, both as an alternative to cheaper but higher-emitting
electricity generation from coal, and as another option for reliable
generation to enable smaller grids to accommodate intermittent sources
like wind and solar.
Most new geothermal plants outside the US employ traditional
dry-steam or “flash” technologies. This is the kind of geothermal power
that people generally envision when they hear the term, involving wells
drilled into high-temperature underground hydrothermal reservoirs,
yielding steam to run turbines on the surface. The global distribution
of suitable resources for this technology goes a long way to explaining
why development is occurring in some countries but not others.
Yet while the US doesn’t lack
high-quality hydrothermal resources, particularly in the West, the GEA
reported that “since 2007 all but one of the new power plants that came
online in the United States was binary,” referring to a newer technology
in which wells producing hot water or brine provide the energy to vaporize
another fluid like butane or even liquefied CO2 to drive a turbine
generator. This technology generally results in higher capital costs but
greatly increases the available resource that can be tapped.
Geothermal Overlaps Oil & Gas
Low-temperature geothermal technology also creates opportunities for
“co-production” in conjunction with oil and gas, particularly in mature
oil fields in which the produced water sometimes exceeds oil volumes by a
factor of 20:1. It takes a lot of electricity to pump all that water
out of the ground, process it, and pump it back down. That power must
either be purchased or generated onsite. If co-production can just
provide enough power to cover an oil field’s operating power
requirements, it represents a savings in the cost per barrel of oil
produced, while net power generation offers a potential new revenue
source. GEA cites estimates of up to 3 GW of co-production potential
from US oil and gas fields.
Of course that’s not the only commonality between geothermal energy
and oil and gas production. Geothermal development involves many of the
same steps of resource identification, lease or concession negotiation,
exploratory drilling, and production drilling accompanied by the
construction of production facilities. Development risks, including the
risk of failing to find a commercial reservoir, are also similar, as is
the business model of an operating geothermal field, with its large
up-front investment and gradually declining output, boosted at later
stages by enhanced-recovery projects. This is all very different from
the way a wind farm or utility-scale solar plant is planned, built and
run.
The report highlights other areas in which geothermal technology is
advancing. Perhaps because of large installations like the Geysers in
California, I tend to think of geothermal–other than for home heat
pumps–as a utility-scale technology. However, geothermal innovators have
produced binary devices that can extract distributed-scale quantities
of power from hot water or brine, producing as little as 50kW, as
described in the report’s section on new technologies. It also mentions
the possibility of using binary geothermal plants to provide flexible
power to the grid.
In my view the most important advances discussed relate to EGS, or
enhanced geothermal systems (also referred to as engineered geothermal
systems) which use techniques similar to hydraulic fracturing to create
artificial hydrothermal reservoirs where only dry, hot rocks exist
underground. This opens up the potential for geothermal power to vast
areas that have good underground heat sources but lack a coincident
subsurface water source. GEA includes a good discussion of EGS and
mentions several milestone projects that came on-line in the last year
in Australia and the US.
Show Me the Money
With ample resources and suitable technology, the biggest challenge
that geothermal developers must overcome is financial. Because of its
long development cycle and capital costs–typically a multiple of
wind-turbine costs per megawatt–it’s a hard sector for start-ups to be
successful. This has been especially true since the financial crisis,
and we’ve seen at least one high-profile geothermal company file for bankruptcy.
Geothermal energy has benefited from various government incentives
intended to reduce these risks and make geothermal more attractive,
including tax credits, loan guarantees,
and the World Bank Global Geothermal Development Plan described in the
report, which as of 2012 was financing over $300 million of geothermal
projects in developing countries.
Conclusions
In 2006 MIT issued a detailed report on “The Future of Geothermal Energy“.
The authors estimated that the potential for unconventional geothermal
energy (mainly EGS) in the US alone was over 1,200 GW. Currently
operating geothermal facilities and those under construction or in the
planning stages barely scratch the surface of what this technology could
contribute in baseload, low-emission power generation. Achieving even a
fraction of this potential will require further improvements in
technology, but just as importantly it will take the involvement of
large corporations with the patience to work through long project
timelines and the financial flexibility to manage the associated risks.
http://www.energytrendsinsider.com/2013/09/18/global-geothermal-growth-highlights-evolving-technology/
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