Making Renewable Energy Work Better: "Swarm Power" Cogeneration
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There's a lot of talk about how renewable energy like solar and wind can't ramp up to meet our energy needs. What we need are creative solutions to that challenge, like distributed cogeneration. This image is a screen shot from a LichtBlic... However, most of these systems are designed to operate whenever there is a need for heat, with electricity either used locally or returned to the grid when it's produced. LichtBlick's "SchwarmStrom" or "Swarm Power" plan reverses that. According to Kampwirth, "It's easy to store heat and expensive to store electricity, so we run the CHP system when electricity is needed and store heat in water." Cogeneration for demand-response LitchBlick runs each unit for the number of hours needed to ensure the hot water storage system can provide 100% of heat and hot water needs. That's the way most building-scale CHP systems operate. What's different is that the LitchBlick central office uses wireless control to time each unit's operation for the hours when they anticipate the highest demand (and highest price) on the electricity market. The market price on the German electricity exchange varies every 15 minutes. Right now, LitchBlick interprets the pricing data from one day to assess when to operate each unit the next day, which works pretty well, although according to Kampwirth, they're already looking into systems that will allow more real-time control. Scaling cogeneration to the megawatt level It's this approach that makes LitchBlick's model a breakthrough for increasing the percentage of renewable energy in the grid: it makes for a scalable, distributed power supply that can provide for peak power needs and balance the irregularly generated power provided by renewable energy systems like solar and wind. This works much the same way that we hope the smart grid will eventually work with demand-response in the U.S. LitchBlick's goal is to ultimately install 100,000 units in Germany, which according to LitchBlick would produce 2,000 MW of electricity--what LitchBlick describes as the capacity of two nuclear power plants. Right now LitchBlick has 400 units installed, and is installing 10 more every week. Why not here? So why can't we get this in North America? In Germany, new renewable energy generators are encouraged. According to Kampwirth, electrical network providers are required to accept their electricity, and EcoBlue also gets a government subsidy for power produced. Also, the market price of electricity is generally higher than in the U.S., so this kind of innovation makes sense for an entrepreneurial green energy company like LitchBlick. I look forward to the day when we see more of this kind of creativity made in America. This is only likely to happen if we establish policies to encourage it. See this brief video on how the EcoBlue "Swarm Power" system works.