Smart curtailment: the little-known battle between nature and efficient wind power
December 06, 2018
December 06, 2018
Working to save bats, energy, and money at the same time¡ªit¡¯s all about site-specific risk patterns
Wind turbines have become one of the most recognizable icons of renewable energy, with close to 60,000 turbines currently operating in the US and Canada. Thanks to recent technological improvements, these turbines are being built larger and becoming more efficient. This trend is enabling the industry to expand its footprint into areas with lower wind speeds¡ªareas that weren¡¯t as advantageous for power generation before.
It¡¯s good for our global energy future, but it also increases a concerning ecological impact uniquely associated with wind power. The problem? Unexpectedly high rates of bat fatality at wind farms. Many people are surprised that bats collide with turbines given their highly developed sense of echolocation. But an estimated half million bats die annually at wind farms in the US and Canada.
Why does this matter? For one thing, bats provide around $3.7 billion in agricultural pest control services in North America. Some species are also endangered, so the risk of bat fatality can raise regulatory hurdles and legal issues for our clients in the industry. Plus, bats are fascinating creatures¡ªwe should do what we can to protect them.
Two species of bats that are most relevant to this discussion are the Indiana bat and the Hoary bat:
It may come as no surprise, but bats are only at risk at night and when the turbines are spinning. Shutting the turbines down effectively avoids the risk to bat populations, but it also precludes our client¡¯s ability to generate power. So, how can we minimize the level of bat casualties while maximizing energy production?
The amount of energy produced from wind ultimately varies with wind speed. Most commercial wind turbines don¡¯t begin to produce electricity until the wind speed reaches about 3.5 metres per second (m/s)¡ªor about 7.8 miles per hour. Referred to as the ¡°cut-in speed¡± (indicated below by the blue dashed line), this is when a turbine¡¯s blades start spinning to generate power.
What does this have to do with bats? Even though bats are more active during periods with lower wind speed, quite a bit of bat activity occurs when wind speeds are above the cut-in speed, which increases exposure to risk. So, how can reduce bat fatality rates?
By changing the cut-in wind speed, we can manipulate and manage the amount of risk to bats. This is known as curtailment. The US Fish and Wildlife Service (USFWS) has determined that if we curtail operations below 6.9 m/s (indicated by the red line) at night during the time of year when bats are active, we can avoid risk to federally endangered bats. This approach is effective and substantially reduces risk, but it is also very costly in terms of energy loss.
Accordingly, the space between the red and blue lines is the difference between unacceptable risk and manageable risk to listed bat species in the eyes of the USFWS. But, it can also be the difference between the economic success or failure for a wind project.
Wind speed is only one of many variables affecting risk to bats. The aerosphere¡ªthe part of the atmosphere where bats interact with turbine blades¡ªis a complicated habitat where other factors such as temperature and precipitation can come into play at any given moment.
While the complexity of bat behavior in the aerosphere can be challenging, Â鶹´«Ã½ has tools to help understand how bat activity and risk relate to these factors.
Acoustic bat detectors monitor the ultrasonic echolocation pulses that bats use while flying. By mounting detectors on top of the turbines, we can characterize bat activity in the rotor zone. Next, we align time-stamped bat recordings to temperature, wind speed, and turbine rotor speed recorded at corresponding turbines to determine conditions when bats are active and whether that activity is exposed to risk.
With this information, we can visualize bat activity as a spectrum. Red indicates the highest activity and the highest risk while blue indicates conditions with very little bat activity and very little risk.
The heat map shows the distribution of 60,000 bats recorded over six years at two commercial wind projects. It highlights that risk is concentrated during calm wind speeds but also during warm temperatures. By overlaying the normal cut-in speed of a wind turbine, you can see that quite a bit of warm color (and therefore risk to bats)¡ªin this case 70% of activity¡ªoccurs to the right of the blue line. By raising the curtailment speed to 6.9 m/s, the risk is minimized with only 6% of bat passes now exposed to risk.
But, notice the large amount of blue (low risk) between the red and blue lines. This effectively represents wasted curtailment¡ªenergy loss during conditions when bats are rarely active. By redesigning curtailment to account for temperature as well as wind speed, we can safely operate turbines in a wider range of conditions and generate more renewable energy with a minimal increase in risk to bats.
At its core, smart curtailment recognizes that the value of curtailment is proportional to the amount of avoided risk. In our experience, incorporating temperature and wind speed¡ªas well as adjusting cut-in speeds monthly to reflect bat activity¡ªcan substantially reduce the cost of curtailment while continuing to minimize risk to bats.
If applied at a typical 50-turbine wind farm, this approach could save enough renewable energy to power over 500 homes for a year compared to blanket curtailment below 6.9 m/s. So, how do we convince the industry to adopt this approach on a broader scale?
Ultimately, we can boost awareness and acceptance of smart curtailment through:
At Â鶹´«Ã½, we are uniquely positioned to understand not only the biology of bats, but how it intersects with the business of running a wind farm. By tailoring curtailment to fit site-specific risk patterns, we are essentially designing something that integrates biology and business. We can offer our clients a potential solution to a difficult problem while helping them meet their goals for renewable energy production. And, if we do it right, we can simultaneously provide important information on minimizing impacts to an ecologically diverse and important group of species while meeting these goals.