What is environmental assessment of energy storage systems?

Environmental assessment of energy storage systems - Energy & Environmental Science (RSC Publishing) Power-to-What? – Environmental assessment of energy storage systems † A large variety of energy storage systems are currently investigated for using surplus power from intermittent renewable energy sources.

What is shared electrical energy storage (SES) & shared thermal energy storage?

To mend the research gap, two CHP-SES system modes and design procedures, namely shared electrical energy storage (SEES), and shared thermal energy storage (STES), are proposed. These systems store distributed green power curtailments during the charging process and convert them to available power or heat during the discharging process.

Can shared electrical energy storage and shared thermal energy storage be used in CHP-SES?

Therefore, this paper proposes two CHP-SES design modes involving shared electrical energy storage and shared thermal energy storage, including three system configurations to store distributed green power curtailments during charging processes and convert them to available power or heat during discharging processes.

What are the environmental benefits of energy storage systems?

Environmental benefits are also obtained if surplus power is used to produce hydrogen but the benefits are lower. Our environmental assessment of energy storage systems is complemented by determination of CO 2 mitigation costs. The lowest CO 2 mitigation costs are achieved by electrical energy storage systems.

What are energy storage technologies?

Energy storage technologies are considered essential to future renewable energy systems, but they often have high resource requirements and potentially significant environmental and social impacts that need to be appropriately managed in order to realise a sustainable energy system. concentrated solar power with thermal energy storage (CSP TES).

How efficient is shared energy storage?

Shared energy storages involving shared electrical and thermal modes are proposed. Exergy and economic models are developed to reveal thermo-economic feasibility. Design procedures considering energy flow and capacity constraints are determined. Round-trip exergy efficiencies of proposed modes are 78.98 %, 54.34 %, and 43.36 %.