Wednesday, October 9, 2013

Cheaper Grid Battery





We do not get a lot here, including the all-important energy density.  Otherwise it appears promising and deliverable so we will likely see more of this company.  I do like the lack of an acid solution for the system itself as that ends no end of operational difficulties.

Vanadium Redox has not gone away either, so the age of utility grade energy storage is fast approaching.  Flow batteries are the natural fix there.

This particular aspect of grid architecture is the low lying fruit of our grid system.  A storage option hugely increases grid capacity.

Startup Shows Off Its Cheaper Grid Battery

Sun Catalytix is making a new type of flow battery that could store hours’ worth of energy on the grid.
By Martin LaMonica on September 24, 2013


Startup Sun Catalytix is designing a flow battery for grid energy storage that uses custom materials derived from inexpensive commodity chemicals. It joins dozens of other companies seeking to make a device that can cheaply and reliably provide multiple hours of power to back up intermittent wind and solar power.

The MIT spinoff, which hopes to differentiate itself with a novel chemistry and inexpensive mechanical systems, is testing a small-scale five-kilowatt prototype. It projects that a full-scale system, which it expects to make in 2015 or 2016, will cost under $300 per kilowatt-hour, or less than half as much as the sodium-sulfur batteries now used for multihour grid storage.

Sun Catalytix CEO Mike Decelle says one advantage of the company’s technology is that it uses cheap ingredients. “We’re sourcing some this stuff really, really cheaply in ton quantities [from China] right now,” he says, standing in a doorway so the names of the chemicals are not readable to a visitor. “That’s where you’ve got to source and the kind of quantities you need.”

The active material in a typical flow battery is a metal, such as vanadium or zinc, dissolved in a liquid electrolyte. To create a current, the liquids are pumped from large tanks into a device where an electrochemical reaction occurs across a membrane. The electrolytes are pumped in the reverse direction to charge the battery. One big advantage of flow batteries is that the amount of energy they store can be increased by simply making the tanks larger.

Sun Catalytix’s electrolytes are made from metals combined with ligands, or molecules that bind to metal atoms. Using synthetic metal-ligand compounds as the active battery materials gave engineers more design flexibility in pursuing an inexpensive, safe battery that can last 15 years with daily charging, according to the company.

In one version of the battery being developed at its lab, two square plates made of carbon-plastic composite, each about as thick as a piece of paper, are stacked with a thin plastic membrane between them to form a cell. During charging and discharging, the two liquid electrolytes travel through grooves carved within each plate to trigger the chemical reaction across the membrane.

The prototype system, held in a glass enclosure, is made up of 50 cells in two horizontal rows, or “stacks.” The cells are not wired individually; instead, the current travels through the plates from one end of the stack to the other, which saves costs on wiring. Below the stacks are tanks of liquid electrolytes, pumps, valves, and tubes made of PVC plastic—all of which is off-the-shelf equipment. A full-scale system would use hundreds of cells, each roughly the size of a pizza box.

One way Sun Catalytix’s batteries are different from more conventional flow batteries, according to the company, is that the active materials are dissolved in a near-neutral aqueous solution that is safe in the case of a spill and not corrosive to pumps and valves. Most flow-battery electrolytes are strong acids, which could cause safety concerns if the technology is used in buildings and can require containment vessels that introduce more cost, says Venkat Srinivasan, head of the Energy Storage and Distributed Resources Lab at Lawrence Berkeley National Laboratory.

Sun Catalytix is also competing with companies making compressed-air storage machines and batteries with their own novel chemistries, such as a zinc-air battery from Eos Energy Storage and a liquid-metal battery from Ambri. (See “Cheap Batteries for Backup Renewable Energy” and “Ambri’s Better Battery.”) Decelle thinks Sun Catalytix’s battery will have an advantage over Ambri’s in terms of safety. A liquid-metal battery operates at several hundred degrees Celsius, which “might give some customers pause,” he says.


Sun Catalytix intends to pilot-test a full-scale battery in 2015. A one-megawatt system would fit into two 20-foot shipping containers, and the tanks of electrolytes would require more shipping containers, depending on how many hours of power are needed. The company, which has raised $16.5 million in investments, is now seeking more money from corporations and venture capitalists to build larger-scale prototypes. It intends to manufacture the cell stacks itself and rely on contract manufacturers or systems integrators to assemble the final product, Decelle says. 

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