Principles for protecting solar energy
Solar panels and solar renewable energy plants use some of the more innovative and sustainable technologies that have been widely focused on in the last decades due to their key role in environmental protection and the reduction of dependence on fossil fuels. They convert the energy from the sun into clean, pollution-free electricity. With features including low production cost, high efficiency, and long life, these technologies are quite enticing when compared to conventional power plants. Flexibility in the deployment of solar power plants, especially in very remote areas, has granted them a vital role in the supply of sustainable energy and energy security. Distributing solar panels and plants across multiple locations provides several benefits, including reduced transmission losses, enhanced security, and a stronger grid system. More importantly, passive defense principles ensure the security and stability of the critical infrastructure of operating solar power plants. Key principles include selecting locations with low natural hazard risks, designing buildings and structures that withstand weather conditions and natural disasters, and distributing load across the grid to reduce dependence on a single area. Moreover, integrating solar power plants with intelligent grids and implementing backup systems, like accumulative systems, can enhance their efficiency and safety.
By Mehdi Jalilian
Guest contributor
The dispersion of solar power plants and passive defensive measures against attacks can only reduce their vulnerability and not completely avoid the shutdown of electricity production in wartime situations. Overall, this will not only increase the productivity of the plants but also reduce risks related to unexpected events and conflicts.
One of the most outstanding features of solar power plants is their flexibility in the supply of electricity to diverse regions. Their installation in disadvantaged and remote areas guarantees the availability of stable electricity to communities that have hitherto been deprived of such facilities. In addition, advanced storage technologies, like batteries, allow the use of electricity at times when there is low solar radiation.
Microgrid systems, being local in nature, further distribute any generated electricity in the locality itself, directly reducing dependency on main transmission lines. This prevents widespread power blackouts during disasters or acts of war and increases stability in the grid.
In view of the increasing importance of renewable energies worldwide, solar power plants are surely among the most rational and sustainable solutions to the supply of energy. Allowing for a reduction in dependence on fossil fuels and a decrease in environmental pollution, these plants will therefore increase energy security and help maintain key infrastructures. More specifically, the principles of passive defense and geographical dispersion protect solar plants against natural and human-induced threats.
One of the ways to answer present needs and ensure that the future will be brighter, safer, and more sustainable for generations to come is investment in the development of solar power plants and related technologies.