CSP molten salt towers scaled up

csp molton salt tower

Molten Salts CSP Plant

Wide-scale deployment of CSP molten salt towers will start soon. The CSP industry says to be ready for a wide-scale rollout of molten salt tower plants between 2018 and 2020.

Molten nitrate and potassium salts are used for energy storage in many CSP tower plants, but the 110 MW Crescent Dunes plant in Nevada and 20 MW Gemasolar plant in southern Spain are the only commercial tower plants to use molten salt as a heat transfer fluid (HTF) as well as for storage.

These two plants won’t be alone for long, with the 150 MW Noor III project in Morocco to be built by June, and the 100 MW Shouhang Dunhuang project in China also on schedule for completion in 2018.

Two more molten salt tower plants, the 150 MW Aurora project in Australia and the 100 MW extension to the DEWA project in the UAE (which is part of a 700 MW extension that also includes parabolic trough technology) are in development with expected 2020 completion.

Beyond 2020

Looking beyond 2020, many molten salt tower projects are in planning or development, including:

  • the 250 MW TuNur project in Tunisia
  • the 240 MW Copiapo hybrid CSP-PV project in Chile
  • the 100 MW Redstone project in South Africa
  • seven additional projects in China with a combined 535 MW capacity.

Ralf Wiesenberg, Managing Director of AF Aries Energy, said molten salt towers have the potential to become the most widely used CSP technology, but there must be at least five such plants in commercial operation for a wider rollout.

“The concept is proven, but for a wider acceptance and application of cost reduction potential we need more plants in operation,” he said.

Molton Salt Towers offer higher efficiencies

Molten salt towers have more potential for cost reduction than parabolic trough technology when certain conditions are met, Sergio Relloso and Yolanda Gutierrez explained in a recent paper on SENER’s involvement at Noor III. These conditions – namely high levels of DNI, low atmospheric attenuation, and necessity of storage – occur in countries like Chile, South Africa, Australia, and Morocco, they wrote.

Noor III is important

Noor III is important because it is bigger than the existing plants on every relevant metric and can therefore prove the viability of molten-salt tower plants on a larger scale.

  • Noor III will have 150 MW capacity
    1.3 times greater than Crescent Dunes, and 7.5 times greater than Gemasolar
  • Although it offers only 7 hours’ storage (compared to 10 hours for Crescent Dunes and 15 hours for Gemasolar), its storage tanks will be larger.
  • Each heliostat at Noor III will measure at 180m2, 50% larger than the 120m2 deployed at the other projects
  • Noor III’s solar field will have a greater number of heliostats than the other projects.
  • Its tower will rise to a height of 240m, greater than the 195m and 140m at Crescent Dunes and Gemasolar respectively.

The higher efficiencies that towers have will provide a competitive edge over troughs in locations with the right solar conditions. Until now, most CSP towers, including those at the 392 MW Ivanpah plant in California and the 50 MW Khi Solar One plant in South Africa, have used water as the heat-transfer fluid.

Learning from real-life projects

It is hoped that molten salt, a high-density material that transforms into a liquid state at high temperatures and has the ability to store an abundance of energy, will help give tower plants the levels of efficiency to compete with parabolic troughs in areas with high direct natural irradiance (DNI).

Molten salt plays two roles at Crescent Dunes and soon it will do the same at Noor III and Dunhuang:

  1. The molten salt is pumped up to the tower, where the heat exchanger heats the salt from around 550 Fahrenheit (290 Celcius) to 1,050 Fahrenheit (550 Celcius)
  2. Then it is a stored in a tank to be used for electricity generation during peak demand.

There is a lack of appropriate tools to conduct a proper simulation of molten salt tower plants, and simulators usually do not know the actual limitations and configuration of the receiver they are trying to represent, Relloso and Gutierrez wrote in their paper, published by the American Institute of Physics’ AIP Conference Proceedings.
This can lead to significant differences between simulated annual results and real operational plants, they added.

CSP Molton Salt Tower Plants

 

“There can be thousands of alternatives when the design ranges of solar field size, turbine power and storage capacity are combined, with each option resulting in a different levelized cost of electricity. It is then of the most importance having a simulation software capable of: accurately calculating annual plant performance; estimating project cost (for design purposes); and managing thousands of design alternatives in an iterative mode.

The experience of Gemasolar allowed SENER to fine-tune its SENSOL software in order to accurately simulate the receiver limitations and heliostat-aiming strategy.

For example, it was discovered at Gemasolar that the energy concentration ratio was so high (1,136:1) that if all heliostats in the field were pointed to the center of the receiver, incident flux would reach peak levels above 2000 kW/m2. In these conditions, receiver tubes would be permanently damaged in a few operation cycles.

As operations begin at Nour III and Dunhuang, and later at Aurora and DEWA, global molten salt tower capacity will increase 10-fold, and developers should be able to rely on enough real-world date to join the wide-scale rollout with confidence.

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