When understanding and examining energy storage for wide-scale, societal deployment that is scalable, affordable and reliable needs to include these factors: energy security, renewable power production and cyber security. At this time energy storage doesn’t meet any of these criteria. The best example is Tesla’s seemingly successful deployment November 2017 in South Australia of a lithium-ion battery storage system. This was hailed a great success a month later by:

“Smoothing out at least two major energy outages, responding more quickly than coal-fired backups and Tesla’s battery (Hornsdale Power Reserve) last week (December 2017) kicked in, in just 0.14 seconds after one of Australia’s biggest plants, the Loy Yang facility suffered a sudden, unexplained drop in output.”

There is a major problem with this line of analysis in late 2017 and even today in Australia – if Tesla’s battery storage system is that effective – then why did the Financial Times exclaim in late August, “Energy is at the Roots of Australia’s Political Crisis.” Countries and states that deploy energy storage systems that aren’t scalable, affordable or flexible the way natural gas is at this time are doomed to higher rates like Australia, Germany and Denmark, energy blackouts and higher emissions through increased use of fossil fuels; particularly, coal-fired power plants. China, which says it is the leader in green energy, is fooling world leaders and environmentalists bent towards renewable energy and energy storage products that aren’t ready for mass market.

China is building coal-fired power plants at a rapid pace while Australia – who signed the Paris Climate Agreement – exports billions a year in coal to Asia. If energy storage worked then renewable energy would work as well, since each technology complements the other. Renewables are intermittent and need energy storage capacity and/or fossil fuel backup. And at this time only fossil fuels works. The technology isn’t available now or in the near future for 24/7; 365 on-demand energy storage.

Other examples of failed renewable energy deployment are Germany and the state of Minnesota. Bloomberg reported in mid-August about Merkel’s climate goals have failed by stating:

“Germany, the nation that did more than any other to unleash the modern renewable-energy industry, is likely to fall short of its goals for reducing harmful carbon-dioxide emissions even after spending over $500 billion euros by 2025 to overhaul its energy system.” Germany is one of the top economies in the world, its engineering prowess for over a century is legendary and they have political consensus for green energy, but still they can’t blend renewable energy into emissions goals. The reason why is the intermittent nature of renewables and there isn’t an adequate energy storage system available. Even in technologically advanced Germany, which is attempting to shut down nuclear plants after the 2011 Fukushima Daiichi meltdown in Japan here’s the issues:

“Shutting down nuclear plants is leaving Germany short of generation plants that can work on the breezeless dark days in winter when wind farms and solar plants won’t provide much to the grid-and demand is at its peak.”

Additional problems occur for German renewable users and grid operators without adequate energy storage is, “the grid is so flooded with power that prices in the wholesale market sometimes drop below zero.” What’s further flexes German, EU, Chinese policymakers and the industrialized world is that Germany’s economy is more service-oriented and that uses less energy and emits fewer CO2 unlike China and increasingly the US that is heavier towards manufacturing and factories for larger shares of their respective GDP’s. The reductions will be more difficult to attain using renewable energy without scalable, affordable and reliable energy storage systems.

The United States (US) has its own example where prices have risen without adequate energy storage that doesn’t include California, which is usually the example given for high wholesale and retail prices since energy storage isn’t available in that state. However, Minnesota is a better example since historically Minnesota had rates 18.2% less than the national (US) average. Since 2009 Minnesota spent $10 billion on wind farms, upgraded transmission lines and the State’s renewable energy portfolio-standard, “requires utilities to generate 25-30% of electricity from renewable sources, mostly wind.” All of this was suppose to be achieved without an energy storage system in place. The results: Minnesota’s rates beginning in February 2017 are now above the national average, and they have not reduced greenhouse emissions relative to the US average, or cut pollution.

If Minnesota had not added renewable energy without energy storage in place and – instead stayed with their traditional energy mix – from 1990 to 2017 that state’s ratepayers would have saved $4.4 billion. Energy storage is the key besides the failure of intermittent renewables in each of these real-world examples.

But advocates for battery storage, smart grids and renewable energy will content that the technology is available, scalable, affordable and offers the flexibility that natural gas offers. However, “Commercial large-scale batteries available today are rated to deliver stored electricity for only two hours or ten hours duration.” Energy storage technology – in the near or long-term future isn’t feasible – and no one can say if or when it will be available though citizenry, governments and private industry keep insisting on renewable energy and a carbon-free society.

The US Department of Energy’s (DOE) Quadrennial Energy Review (QER) Part 1 (2015) that was completed under the Obama administration and definitively states what energy storage needs moving forward:

“Establish a framework and strategy for storage and flexibility: Energy storage is a key functionality that can provide flexibility, but there is little information on benefits and costs of storage deployment at the state and regional levels, and there is no broadly accepted framework for evaluation of benefits below the bulk system level.”

Any type of local, county, state, nation-state or international approach to energy storage systems will require a strategy and technology that includes flexibility, commonly accepted planning methods, on-demand consumer use, national and international connected transmission lines and be able to handle the variable, intermittent nature of renewable generation. Part 2 of the DOE’s, QER in 2017 also factored in that energy storage systems will need to handle increased cyber-security concerns and grid modernization for energy storage to be a factor in renewable energy and carbon-free society becoming a reality.