Renewable Energy Systems
We help renewable energy developers, investors, and project teams make confident, evidence-based decisions on solar, wind, and hybrid energy systems. From early-stage screening through to detailed feasibility and operational design.
Our work combines time-series system modelling with techno-economic and lifecycle analysis, translating engineering performance into clear investment metrics and sustainability indicators. Every engagement is grounded in peer-reviewed methods developed through European-funded research and validated against real project data.
We work across the full project lifecycle, so whether you are screening a new site, sizing a hybrid PV–wind–battery configuration, or assessing the lifecycle impact of a portfolio, you work with one team that connects engineering, economics, and sustainability in a single framework.
Techno-economic assessment & feasibility studies
Quantifying technical performance and project economics, from site screening to detailed feasibility analysis.
Resource and site assessment
Solar irradiance, wind speed, and hybrid resource analysis using satellite-derived datasets and existing measurement records, with explicit treatment of resource uncertainty in downstream yield and economic estimates.
Pre-feasibility and feasibility studies
Structured evaluation of technical, economic, regulatory, and grid-connection dimensions, supporting go/no-go and technology-selection decisions across the project lifecycle.
Techno-economic modelling
CAPEX and OPEX build-up, Levelised Cost of Energy (LCOE), NPV, IRR, and payback analysis, with full financial sensitivity to resource variability, market prices, and policy scenarios.
Sensitivity, scenario, and risk analysis
Three complementary perspectives on uncertainty: sensitivity analysis to identify the inputs that drive project economics most strongly; scenario analysis to test performance under defined market, policy, and resource cases; and Monte Carlo risk analysis to quantify probabilistic outcomes.
Life Cycle Assessment (LCA) and Costing (LCC)
Environmental and economic performance across the full project lifetime, aligned with ISO 14040/14044.
Environmental life cycle assessment
Cradle-to-grave assessment of carbon footprint, embodied energy, and broader impact categories for renewable energy assets, following ISO 14040/14044.
Life cycle costing
Total cost of ownership across capital, operational, replacement, and decommissioning phases, integrated with LCA outputs to produce environmentally adjusted economic indicators.
Comparative technology assessment
Side-by-side LCA and LCC of competing technologies, supporting technology selection on both environmental and economic grounds.
System modelling
From hourly performance simulation to optimal system sizing and operational strategy.
Time-series performance simulation
Hourly simulation of renewable generation, demand, and system behaviour using validated component models for PV, wind, and storage.
Sizing and configuration optimisation
Mathematical optimisation (MILP, metaheuristics) for optimal sizing of generation, storage, and grid-connection capacity minimising LCOE or maximising project NPV under defined technical constraints.
Storage integration and co-optimisation
Joint optimisation of renewable generation and battery storage, including dispatch strategies for energy arbitrage, ancillary services, and grid-supportive operation.
Digital twins and dynamic models
System-level digital twins for performance forecasting, operational planning, and what-if analysis of individual assets or portfolios.
Business model development
Designing commercial structures that connect technical assets to viable revenue pathways. Business model development is rarely about a single decision. It requires evaluating the supply route, the offtake or end-use, and the revenue stack as one integrated commercial picture.
Electricity supply strategy
Comparative evaluation of on-grid, off-grid, and PPA-based supply configurations, including physical and virtual PPAs. We assess each option against project economics, risk exposure, regulatory framework, and integration with on-site generation or storage.
Revenue stream analysis
Review of the revenue streams available to the project and how they shape its commercial outlook.
Offtake and end-use strategy
For projects producing hydrogen or other energy carriers, the choice of end-use is a primary driver of value. We evaluate alternative pathways such as industrial offtake, e-fuels, mobility, or grid injection — and identify the configuration that best aligns technical capability with market demand and project economics.
Have a renewable energy project in mind?
Tell us where you are and where you want to go. A direct technical conversation, no pitch and no obligation.