Higher power density
More generation per pole, tower, or site footprint.
Lower system cost
Reduced balance-of-system and infrastructure expenditure.
Faster time to power
Deployment measured in months, not years.
Grid-optional
Operates with local low-voltage networks or storage.
All-weather resilience
Engineered for extreme environments - sandstorms, high wind, and temperature variance.
Integrated hardware + software
Nano-MPPT electronics and real-time optimisation built into every deployment.
// ENERGY AS A SERVICE
Power without the project.
Energy delivered as a service. Zero CapEx. Months, not years.
Infrastructure-Grade Energy. Deployed in Months, Not Years.
A fully integrated TaaS platform with patented hardware, embedded software, and low-voltage energy systems deployed on existing infrastructure. No land. No grid connection required. Built for the hardest environments on earth.
Higher power density
More generation per pole, tower, or site footprint.
Lower system cost
Reduced balance-of-system and infrastructure expenditure.
Faster time to power
Deployment measured in months, not years.
Grid-optional
Operates with local low-voltage networks or storage.
All-weather resilience
Engineered for extreme environments - sandstorms, high wind, and temperature variance.
Integrated hardware + software
Nano-MPPT electronics and real-time optimisation built into every deployment.
01
Energy as a Service
20–25 yr PPA. We own. You buy kWh.
02
Tech as a Service
Telemetry, predictive maintenance, fleet ops.
03
Zero CapEx
No upfront cost. No land. No grid extension.
"Solar generation has fallen 90%. Grid build-out has not. The bottleneck has moved."
1–3 yrs
For land
1–3 yrs
Grid extension
1–3 yrs
To first kWh
898 MW pipeline. 10 countries. Today.
Mesa del Sol
USA · Active
1 MWp → GW
Deployment
MRCB Malaysia
Q3 2026 PPA
500 MW
MOU
Rebooz MENA
2026–2030
100 MW → 3 GW
Exclusive MOU
Bangalore + Singapore
16.9 GWh/yr
Trial → PPA
Tabuk University
Saudi Arabia
5 MW
PPA draft
Energy cost is driven by infrastructure, not sunlight.
In conventional solar projects, the delivered cost of electricity is dominated by non-generation factors. Land acquisition, high- and medium-voltage grid extensions, substations, wayleaves, and prolonged planning cycles increase capital risk and delay revenue.
As a result, many projects are constrained not by solar resource, but by infrastructure availability and grid capacity.
Generating power where infrastructure already exists.
In conventional solar projects, the delivered cost of electricity is dominated by non-generation factors. Land acquisition, high- and medium-voltage grid extensions, substations, wayleaves, and prolonged planning cycles increase capital risk and delay revenue.
As a result, many projects are constrained not by solar resource, but by infrastructure availability and grid capacity.
Urban & Municipal Infrastructure
Deployment on street lighting and distribution poles enables local generation within cities, reduced transmission losses, and improved utilisation of existing public assets.
Telecom Towers
Integration with telecom infrastructure reduces reliance on diesel generation and supports hybrid or decentralised power configurations.
Industrial & Campus Sites
On-site generation for industrial estates, logistics hubs, and campuses where land is limited and predictable power supply is required.
Grid-Constrained Regions
Immediate local generation with optional future grid connection, supporting phased electrification and flexible commercial models.
Where It Deploys
Typical infrastructure environments suitable for vertical deployment.
MENA (Middle East and North Africa) Regions
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