Giant gravel batteries could make renewable energy more reliable

Giant gravel batteries could make renewable energy more reliable

Wind and solar power are often criticised for being too intermittent, but Cambridge researchers could change that


Newly designed giant gravel batteries could be the solution to the on-off nature of wind turbines and solar panels. By storing energy when the wind stops blowing or the sun stops shining, it is hoped the new technology will boost to renewable energy and blunt a persistent criticism of the technology - that the power from it is intermittent.

Electricity cannot be stored easily, but a new technique may hold the answer, so that energy from renewables doesn't switch off when nature stops playing ball. A team of engineers from Cambridge think they have a potential solution: a giant battery that can store energy using gravel.

"If you bolt this to a wind farm, you could store the intermittent and relatively erratic energy and give it back in a reliable and controlled manner," says Jonathan Howe, founder of Isentropic and previously an engineer at the Civil Aviation Authority.

The Labour government committed to cutting the country's carbon emissions by 34% by 2020 and 80% by 2050, both relative to 1990 levels. To achieve this, ministers outlined plans to build thousands of wind turbines by 2020. The only economically viable way of storing large amounts of energy is through pumped hydro – where excess electricity is used to pump water up a hill. The water is held back by a dam until the energy is needed, when it is released down the hill, turning turbines and generating electricity on the way.

Isentopic claims its gravel-based battery would be able to store equivalent amounts of energy but use less space and be cheaper to set up....

Does Wind Need Storage?

The fact that “the wind doesn’t always blow” is often used to suggest the need for dedicated energy storage to handle fluctuations in the generation of wind power. Such viewpoints, however, ignore the realities of both grid operation and the performance of a large, spatially diverse wind-generation resource. Historically, all other variation (for example, that due to system loads, generation-commitment and dispatch changes, and network topology changes) has been handled systemically. This is because the diversity of need leads to much lower costs when variability is aggregated before being balanced.

Storage is almost never “coupled” with any single energy source—it is most economic when operated to maximize the economic benefit to an entire system. Storage is nearly always beneficial to the grid, but this benefit must be weighed against its cost. With more than 26 GW of wind power currently operating in the United States and more than 65 GW of wind energy operating in Europe (as of the date of this writing), no additional storage has been added to the systems to balance wind. Storage has value in a system without wind, which is the reason why about 20 GW of pumped hydro storage was built in the United States and 100 GW was built worldwide, decades before wind and solar energy were considered as viable electricity generation technologies. Additional wind could increase the value of energy storage in the grid as a whole, but storage would continue to provide its services to the grid—storing energy from a mix of sources and responding to variations in the net demand, not just wind.

As an example, consider Figure 7 below, which is based on a simplified example of a dispatch model that approximates the western United States. All numerical values are illustrative only, and the storage analysis is based on a hypothetical storage facility that is limited to 10% of the peak load and 168 hours of energy. The ability of the system to integrate large penetrations of wind depends heavily on the mix of other generation resources. Storage is an example of a flexible resource, and storage has economic value to the system even without any wind energy. As wind is added to the system in increasing amounts, the value of storage will increase. With no wind, storage has a value of more than US$1,000/kW, indicating that a storage device that costs less would provide economic value to the system. As wind penetration increases, so does the value of storage, eventually reaching approximately US$1,600/kW. In this example system, the generation mix is similar to what is found today in many parts of the United States. In such a system with high wind penetration, the value of storage is somewhat greater because the economic dispatch will result in putting low-variable-cost units (e.g., coal or nuclear) on the margin (and setting the market-clearing price) much more often than it would have without the wind. More frequent periods with lower prices offers a bigger price spread and more opportunities for arbitrage, increasing the value of storage.

In a system with less base load and more flexible generation, the value of storage is relatively insensitive to the wind penetration. Figure 8 shows that storage still has value with no wind on the system, but there is a very slight increase in the value of storage even at a wind-penetration rate of 40% (energy). An across-the-board decrease in market prices reduces the incentives for a unit with high fixed costs and low variable costs (e.g., coal or nuclear) to be built in the first place. This means that in a high-wind future, fewer low-variable-cost units will be built. This reduces the amount of time that low-variable-cost units are on the margin and also reduces the value of storage relative to the “near-term” value with the same amount of wind.

The question of whether wind needs storage ultimately comes down to economic costs and benefits. More than a dozen studies analyzing the costs of large-scale grid integration of wind come to varying conclusions, but the most significant is that integration costs are moderate, even with up to 20% wind-energy penetration, and that no additional storage is necessary to integrate up to 20% wind energy in large balancing areas. Overall, these studies imply that the added cost of integrating wind over the next decade is far less than the cost of dedicated energy storage, and that the cost can potentially be reduced by the use of advanced wind-forecasting techniques.

Well done Alok Jha you win the laziest journalist of the week award for a nice bit of product placement and lifting the contents of this webpage http://www.isentropic.co.uk/index.php?page=storage and other from Isentropic's website and passing them off as journalism.

John Loughhead, executive director of the UK Energy Research Centre, said that the novelty of the Isentropic system lay in using cheap materials as the heat store, thus making a normally expensive and mechanically complex process very simple. But he said demonstrators would need to be built to prove the idea actually functions. "The question is, does it work? From an engineering standpoint, the temperature differences they mention, +550C to -150C are initially credibility-stretching for a single-pass cycle, and the potential for gravel particles to pass through the engine and damage or clog the inevitable cooling and lubricating systems seems high."

...

The name "battery" was coined by http://en.wikipedia.org/wiki/Benjamin_Franklin">Benjamin Franklin for an arrangement of multiple http://en.wikipedia.org/wiki/Leyden_jar">Leyden jars (an early type of http://en.wikipedia.org/wiki/Capacitor">capacitor) after a http://en.wikipedia.org/wiki/Artillery_battery">battery of cannons.^{http://en.wikipedia.org/wiki/Battery_(electricity)#cite_note-2">3} Strictly, a battery is a collection of two or more cells, but in popular usage battery often refers to a single electrical cell.^{http://en.wikipedia.org/wiki/Battery_(electricity)#cite_note-3">4}

...

"If you take as an example, a perfect heat pump with a COP of say 4, that you want to supply heat at a temperature X. If you input one unit of electricity to the system then you end up with 4 units of heat at temperature X. If this was a perfectly reversible process then, when reversed, the heat engine cycle would have an efficiency of 25% ie it would take your 4 units of heat at this temperature X and generate 1 unit of energy. The COP is the inverse of the engine efficiency."

"In this example I have just given I could have a perfect heat engine with a Carnot efficiency of 25% (limited by temperature range) that as part of a storage cycle has a 100% charge/discharge efficiency. In the perfect machine it would not matter if the Carnot efficiency was 10% or 50% as the heat pump will simply be the inverse of this ie 10 or 2."

"I am hoping that this will have shown why the Carnot efficiency does not effect the charge/discharge efficiency of our storage system. The things that do effect it are the irreversible losses, such as, friction, electrical losses, pressure drops, heat transfer etc.. that occur during the cycle."

I love this Carnot obsession. The Carnot ratio is an availability ratio, not really an efficiency, ie, heat pump COP of an ideal engine is the inverse of its engine efficiency.
What is important here is that the engine cycle is reversible, not that it is a Carnot-equivalent cycle. A Brayton cycle, in its ideal form, is reversible (isentropic compression and expansion coupled with isobaric heat transfer) but not Carnot equivalent. This cycle in its purest form is actually the first Ericsson cycle and Ericsson did it well before Brayton or Joule.
The reason that we can show high reversibility is that isobaric heat transfer in the constant pressure stores can take place slowly under drifting flow conditions. Adiabatic compression and expansion takes place rapidly in very carefully designed cylinders. The transfer valves are also an example of extremely careful design with exceptionally low pressure losses. Parasitic heat transfer within the cylinders is also very carefully controlled resulting in very high thermodynamic reversibility, dead volume and its effects must also be minimised since it thermally pollutes the gas charge at the end of the stroke. Greater losses are actually electrical and mechanical.
Of course irreversinilities manifest themselves as waste heat, just not very much of it and we dump it in one limb of the circuit via heat exchange. This is a very non-critical part of the operation since we are creating a thermal split around a datum temperature. If this datum temperature is a bit above ambient (as it has to be to dump the heat of irreversibility) then it has an inconsequential effect on system performance.
This absolutely cannot work as a prime mover heat engine at 80% efficiency as James tried to explain (I thought very clearly). It is a thermodynamic battery in which the ONLY element of importance is process reversibility.
Jonathan Howes.
CTO Isentropic Ltd

Electricity would be used to heat and pressurise argon gas that is then fed into one of the silos. By the time the gas leaves the chamber, it has cooled to ambient temperature but the gravel itself is heated to 500C.