Blog Post

Measuring the True Costs and Benefits of Energy Storage – Part Two

See the original post in its entirety in North American Clean Energy.

In last month’s issue, Part One of this series began covering how checking a few simple performance metrics can help you calculate the true costs and benefits of competing energy storage systems. Additionally calculating this levelized cost of energy (LCOE) can help distinguish between what might look like a good price up front from what’s actually a better buy in the long run.

How to Calculate the Levelized Cost of Energy (LCOE)
To calculate the Cost of Electricity in Kilowatt Hours (kWh) over time:

Step One: Gather the Facts

  • Size of Battery in Rated Amp Hours – Ah
  • Voltage of Battery – V
  • Depth of Discharge – %
  • Number of Batteries – Qty
  • The battery rating is based on the manufacturer’s stated capacity in watt hours at specific discharge rates.

Step Two: Calculate Watt Hours (Wh)

  • Wh = Qty x Ah x V x %

Step Three: Calculate Lifetime Watt Hours (LW)

  • LW = Wh x Cycle Life
  • Cycle Life is the number of full (not partial) charge and discharge cycles expected over a battery’s lifetime while it has at least 80% of its original published capacity. It is based on manufacturer’s estimate using specific depth and rates of discharge and operating temperatures.

Step Four: Factor in Costs

  • Price (per battery)
  • Calculate Total Battery Cost (Qty x Price)
  • Add Ancillary Costs including Cabling, Racking, Containment, Venting, Cooling, Installation, Transportation, Maintenance, etc…
  • Calculate Actual System Cost = Total Battery Cost + Ancillary Costs

Step Five: Calculate Cost per Wh

  • Cost per Wh = System Cost / LW

Step Six: Calculate LCOE in kWh

  • LCOE = LW x 1000

In part one, covered the various components of the LCOE equation. These include, but are not limited to, whether a battery system needs HVAC equipment and extra space to regulate temperature regulation, maintenance and the manpower required to conduct it, use of other chemicals or resources, limitations on usages, operation locations or transport methods because of temperature issues or thermal runaway risks posed by using cobalt oxide.

Battery chemistries that contain cobalt include Lithium Cobalt Oxide (LiCoO2 or LCO), Lithium Nickel Manganese Cobalt Oxide (LiNiMnCoO2 or NMC), Lithium Nickel Cobalt Aluminum Oxide (LiNiCoAlO2 or NCA). This grouping of LI batteries can be referred to as LI with cobalt. Chemistries without cobalt oxide include Lithium Ferrous Phosphate (LiFePO4 or LFP) and Lithium Titanate (Li4Ti5O12 or LTO), although LTO is rarely used in large format energy storage. For more on this topic, please see Part One.

Cycle Life

The LFP chemistry offers a significantly longer cycle life, meaning the number of times the battery can be fully charged and discharged, than LI with cobalt. It also allows a deeper discharge depth and a faster charge/discharge rate.

Based on published studies, utilizing an 80 percent depth of discharge (DOD), Li batteries with cobalt offer a cycle life of 500 to 700 cycles, whereas the LFP batteries offer 2,500 to 4,000+ cycles. Therefore, if an Li battery with cobalt is discharged by 80 percent, once a day for a year, it would offer a cycle life of about two years (700/365 = 1.9 years). If the individual battery is discharged at a shallower depth, it could last longer. But that would result in less useable kWh per pound, square foot and human or mechanical resources required to install, house and `maintain the system. A shallower depth of discharge per battery (to extend cycle life) would also require more batteries, installation costs, space and maintenance to provide the same amount of power, raising the cost of energy over time.

By contrast, an LFP battery that is discharged by 80 percent once a day for a year will provide the same amount of power for 6.8 years to 10.9 years (2,500/365 = 6.8 and 4,000/365 = 10.9). That’s more than three to five times as long. Therefore the true cost of LFP battery storage over time is far lower given its longer cycle life, compact footprint and more efficient utilization of resources, even though its up-front price-point might be higher than batteries with
other chemistries such as Li with cobalt, lead acid, Lithium Nickel Manganese Cobalt, flow, zinc bromide or salt-water-based batteries.

Additionally, independent tests reported in scientific papers (Journal of Power Sources Vol. 257, 2014) studying the cycle life of LFP battery cell chemistry demonstrate that cycle life in excess of 8,000 cycles is practical and can be maintained when the depth of discharge is limited to a range of 60 percent. Therefore, if LFP batteries are integrated into a small or large power storage format in which the monitoring and control software platform maintains a recommended depth of discharge, the batteries could provide as many as 21 years of useful life (8,000/365 days = 21.9 years). This extended cycle life for the LFP chemistry can also be enhanced by a conservative rate of charge and discharge.

One other point to consider is that so-called “long duration, large format” batteries, such as aqueous salt water and some flow batteries, require an unusually slow optimal discharge rate. These battery chemistries can require discharge rates, as long as up to 20 hours, to protect capacity (useable kWhs) and cycle life. This significantly adds to the size, weight and LCOE per kWh. Meanwhile, the rate of charge and discharge for Li with cobalt batteries must be heavily regulated to control the buildup of heat and to prevent thermal runaway.

When considering an energy storage solution, be sure to calculate the LCOE and any other impact in order to assess the true costs and benefits of the system. We at SimpliPhi Power have strived to maximize LCOE through years of beta testing and analysis, both in the lab and in the field, selecting the optimum combination of characteristics across chemistries, proprietary BMS and battery architecture. The result is the most energy dense, efficient, long-lasting, environmentally benign and safe power storage available. We are looking down field, past the current drop in energy prices, to assess what kind of power solutions will work best and be healthiest for businesses, homes and individuals, as well as humanitarian, military and emergency uses. We encourage those considering energy storage to evaluate the options carefully and with the above criteria in mind to determine what solution create the more secure and sustainable future we all seek.

Catherine Von Burg has been the CEO of SimpliPhi Power since 2010. Before her work in energy storage, she spearheaded national program, policy and business-driven initiatives with organizations such as Pew Charitable Trusts, Rockefeller Institute, Columbia University, NY March of Dimes Foundation, John’s Hopkins School of Biomedical Engineering, Wilderness Education Association and First 5 Commission of California. She graduated from Columbia University in New York and holds a Master’s degree from University of Pennsylvania, School of Social Policy.
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