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Sustainability through thermally charged buildings

Reduce the cost and carbon footprint of your educational buildings with rechargeable buidlings
How to plan low carbon buildings in 3 Simple Steps using your lean budget

A - Start with

One floor – 5 systems: is your Path of Least Resistance to cost effective climate smart outcomes today.

B - Link to Your HVAC

Heating or cooling delivered via Main Duct “C” through smart floors into the space as required. Temperature controlled by user via wall mounted thermostats to suit their preferences.

C - Use Regular Workers

No new skills or new materials required to link smart floor kits with Ventilation, Heating or Cooling to deliver low carbon building.

How to plan low carbon buildings using lean budget

Track where you money goes with Geothermal systems

Cut Cost

Building as a Thermal Battery validated in real buildings elevates performance and profitable outcomes from the start. This transformational innovation that expands outcomes of todays specified materials and creates new operational reliability.

Heating and Cooling reduced

We help you to unlock new way to plan and construct Climate Smart Buildings with smaller Heating and Cooling equipment.

It includes above ground geothermal loops, year-round thermal energy storage and radiant comfort without wet in-floor systems.


Connected to profitable decarbonization

Buildings connected to Thermal Energy Storage (TES) become rechargeable. Desired Thermal Energy Storage (TES) is critical climate smart response to weather situations. In additional, they benefit buildings from energy grid surpluses seamlessly. TES enables frequent and flexible customized digital interactions in energy balancing edge, lower energy, carbon and costs

675,000 sq.ft.Net Positive K-12 school portfolio listed in Guide to Net Zero

Decision Makers

How Important to you the following decarbonization issues?

Controlling Financial Losses

1.Conduct cost and lifecycle cost analysis to identify cost-saving oppourtunities
2.Implement energy management systems and monitor energy consumption
3.Buildings in auto-pilot mode reduce the need to train building occupants on energy-efficicent practices.
4.Preventative maintenance or repair costs reduced due to fewer moving parts.
5.Need to renewable energy sources reduced by 25%-30%

Control Material Losses

1.Adopt sustainable construction practices (e.g., use recycled materials, minimize waster generation)
2.Implement waste management strategies (e.g. expand dormant concrete properties to eliminate several carbon intensive mechanical systems)
3.Optimize material waste and usage through efficient design and construction techniques

Environmental Benefits

1.Reduced environmental impact throught lower energy and resource consumption
2.Cost savings through reduced utility bills and maintenance expenses
3.Improved occupant comfort and productivity
4.Enhanced building reputationa nd market value
5.Compliance with environmental regulations and certifications

Let’s build a better building together.