Abstract
Solid particles have been shown to be an effective heat transmission as well as thermal storage medium for falling particle receiver based solar power systems at temperatures up to 1,000°C. The temperature distribution on the surface of the falling particle receiver is critical. High temperatures, thermal shocks, and temperature gradients produce substantial stresses on the receiver due to high, fluctuating, and non-homogeneous solar flux. To this effect, the optimum control of the heliostats’ aiming points is one of the obstacles that must be overcome. The flux distribution on the receiver surface must be carefully managed to avoid dangerous flux peaks or excessive temperature gradients which might result in local hot spots resulting in damage of the receiver’s internal components over time. To overcome this problem, specifying multiple aiming points on the receiver aperture may control the solar flux distribution. In this study both single and multi aiming points strategies are applied by assigning a group of heliostats to a specific aim point on the receiver, resulting in a uniform flux distribution over the receiver surface. Engineering software packages SolarPILOT, SOLTRACE and MATLAB are used in combination to get the optimal flux distribution. The results showed that the flux distribution is improved significantly after employing the multi aiming points strategy at the expense of greater spillage.
Highlights
By 2050, the global energy demand is projected to increase by more than 66% based on 2011 global energy demand (IEA, 2014)
The main issue here is that the flux distribution in the case of a single point aiming strategy is not balanced throughout the Particle Heating Receiver (PHR) panels
By allocating a set of heliostats to a specific aim point on the receiver, both single and multi aiming points techniques are used in this work, resulting in a uniform flux distribution over the receiver surface
Summary
By 2050, the global energy demand is projected to increase by more than 66% based on 2011 global energy demand (IEA, 2014). Several countries around the world have agreed to decrease carbon emissions to keep global average temperature rise well below 2°C, according to the Paris Agreement (United Nations, 2015). A reliable, sustainable, and cost-effective carbon-free energy production is required to meet tomorrow’s energy demands. In 2020, the share of renewable energy in global electricity generation reached 28.6% (IEA, 2021) and must reach 65% to meet the goal of reducing CO2 emissions to the limit as per ETP 2014 2°C Scenario (IEA, 2014). Under the Saudi Vision 2030, the goals for the Kingdom’s National Renewable Energy Program (NREP) were revised to generate 27.3 GW of renewable energy by 2024 and 58.7 GW by 2030 with a capacity of 2.7 GW from concentrated solar power (CSP) (Middle East Business Intelligence, MEED, 2019)
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