The Next Step for Solar Collector: Developing Pumps for Higher Temperature Systems
The technology to exploit renewable energy sources is continuing to advance, improving efficiency and reducing costs. In concentrated solar power plants with central tower and molten salt, the sun’s energy is used to raise the temperature of molten salts, which are pumped into a steam generator that powers a turbine. The efficiency of this process can be improved if the working temperature is increased.
The technology to exploit renewable energy sources is continuing to advance, improving efficiency and reducing costs. In concentrated solar power plants with central tower and molten salt, the sun’s energy is used to raise the temperature of molten salts, which are pumped into a steam generator that powers a turbine. The efficiency of this process can be improved if the working temperature is increased. This knowledge has led to a large-scale project to develop corresponding pump technology that will be able to cope with temperatures above 700°C (1,300°F).
By Claude Mockels, Product Development Manager, Sulzer
High temperature salt pumps are primarily used in nuclear and solar power generation, as well as chemical and salt manufacturing. While these pumps are currently used at temperatures up to 600°C (1,100°F), designers are now looking to extend the current limitations by creating pumps that can be used in applications where higher temperatures can be beneficial.
Raising the Bar
In large-scale solar plants, mirrors focus the sun’s energy to a central tower where it is used to increase the temperature of the molten salts. Pumps are used to transfer molten salts from the ‘cold’ tank through the pipes to a hot salt tank and on to a steam generator. The steam powers a turbine, which turns a generator and produces electricity for the local grid.
For renewable solar energy plants, efficiency can be improved by increasing the temperature of the salt used to store the sun’s energy. Until recently, various salts have been used at temperatures around 600°C (1,100°F) and the pumping technology for this application is well- established. In order to improve efficiency, operators and manufacturers intend to increase the working temperature for new systems beyond 700°C (1,300°F).
At these temperatures, molten chloride salt has to be used. The use of this type of salt presents additional issues, such as its corrosive properties, that are not a problem with 600°C pumps, which operate with more benign salts. To address this, the existing second generation pumps have many proven design characteristics that now need to be extended.
Sectional drawing of Sulzer VEY Molten Salt Pump.
The Next Generation
For the next phase of more advanced solar plants, third generation pumps are in development, with projects being funded by the Department of Energy (DoE) in the United States and other organizations in Europe. Work is underway to establish the materials and components that need to be upgraded for this project to be successful.
Both designers and product developers are working together to develop new materials for wear components that will be used in this arduous environment. One group of high-toughness, ceramic-metal composite materials, known as cermets, will be used to manufacture strong, long-lasting components, such as bearings and sealing elements.
To overcome the challenges with this unique application, the materials need the correct mechanical properties as well as temperature and corrosion resistance. The mechanical properties of any material must also be sufficient to handle the energy required to drive these pumps; driveshafts must be capable of delivering the torque necessary to pressurize the system. The pump design must take account of the thermal expansion of the pump components to ensure clearances are maintained. This is an important consideration for mechanical parts such as present bushings, where clearances and axial elongation are important for reliable operation of the plant.
At the heart of any design for a pump that will operate in such a hostile environment is the computer model. Although parts that are in contact with the molten salt will be designed to handle the elevated temperatures, other parts need to be kept cool to ensure optimum performance.
The huge variations in temperature distribution have a significant effect on the mechanical design of the pump. Theoretical models help the engineers to understand this distribution and to develop both the materials and a physical design for the pump. Heat radiation must also be examined to ensure that the components that are not in contact with the molten salt, such as the electric motor and the top bearing, remain cool. Sophisticated thermal models can be used to examine the differences between the current designs and those required for the next generation. This has led to refinements of the cooling system which will be important in creating a reliable pump with a long service life. The numerical model will then be compared to the real-world results that are obtained from the pilot project.