Periodic Reporting for period 2 - PreFlexMS (Predictable Flexible Molten Salts Solar Power Plant)
Reporting period: 2016-12-01 to 2018-05-31
The following are specific objectives of the project
1. Improve state-of-art in molten salt CSP plant flexibility by designing and demonstrating the advantages of using a once-through-steam-generator compared to drum type steam generator
2. Extend reliable Direct Normal Irradiation (DNI) forecasting for the promising markets of the future like MENA, South Africa and South America. Refine and update models and methods used to provide such services and ensure high quality forecasting ability to ensure dispatch predictability. Provide the software architecture and capability to do so.
3. Design and demonstrate dispatch optimisation software that can utilise the developed forecasting, plant and machine learning models to maximise economic payback in various market scenarios by flexibly scheduling storage enabled CSP plants.
a. Evaluate techno-economic figures of merit like cost of electricity and net present value
b. Assess the data collection, transmission, management, computation and actuation related to the weather forecast and dispatch optimistation in an industrially relevant operational environment
c. Perform a life-cycle assessment including the benefits of all the novel components of the CSP plant
Due to bankruptcy of one of the partners providing the key piece of hardware equipment and decision of the coordinator to exit development activities in CSP, this project was terminated before reaching project outcomes.
Reference design of the full power block based on a once through steam generator is made for a full scale CSP plant. Important functional features for flexibility are calculated using high-resolution dynamic modelling. It is expected that the once-through steam generator would be quicker, more responsive and more economical to operate with respect to total cost-of-ownership compared to a drum type steam generator.
Weather forecasting infrastructure and digital interfaces with demonstration software architecture have been defined. Novel methods for DNI forecasting and impact of aerosols have been investigated and the validation sites relevant for different CSP use cases have been selected. A virtual power plant model for the CSP plant which incorporates modelling of the various components has been achieved. Progress was made on software architecture for collection, management, computation and actuation it. The models to be used for weather forecasting and their specifications for optimiser interface have been defined.
The main results were in terms of various weather forecasting improvements as described in the various publications, build up of engineering models and optimisation techniques, which could not be tested in an integrated manner to generate impactful results.
With respect to the demonstration hardware, the water steam skid and other auxiliary balance of plant equipment has been designed The various engineering studies to safely construct and operate the demonstration were performed. The engineering design of the water steam skid, interconnecting piping and OTSG pilot design is also completed.
A specialised life-cycle assessesment tool is used with extensive data collection to obtain important LCA measures.
The main deliverables on the hardware side will be the design experience, lessons learnt from actual operation, a reference design for the OTSG and associated control logic. On the software side the new models and evaluation methods to improve weather forecasting for CSP applications are expected to be available. Finally, the analysis of the project results will be used to update the economic value and competitive advantage of a CSP plant with the innovative features. Ultimately, this project will enable the consortium partners to offer the next generation of full scale CSP plants by reducing technology risk.
The expected socio-economic impacts can be summarised as follows.
Replicability: It is expected that the OTSG hardware engineering can be replicated by the relevant consortium partners and reduce market entry barriers to others.
Socio-economics: On one hand, European technology providers benefit from increased export markets, on the other hand, sunny developing countries gain new technological skills and higher low-carbon growth through large scale project construction.
Environment: Increased predictability and flexibility of CSP plants, allows them to compete effectively without any special considerations against fossil fired plants. The primary impact is to reduce carbon emissions from power generation while still maintaining grid integrity. This reduces the need for polluting fossil fired back up even in countries with high renewable penetration.
Market Transformation and Policy: This project would influence new policies that enable creation of remunerative markets for integrated storage with renewable electricity as well as set new standards to describe and overcome uncertainty of weather when investors compute the risk profile for a CSP project.