Interactive Building Performance Explorer

How Rechargeable Buildings Work

Termobuild transforms concrete floors and ceilings into active thermal infrastructure that amplifies mechanical system performance—delivering stable comfort, reducing peak demand, lowering operating costs, and improving building performance.

Reactive Building Waits for loads to arrive, then equipment works harder to catch up.
Proactive Building Prepares the structure in advance, then releases comfort when needed.
Same HVAC. Same design choices. Same specifications. Different strategy.
Up to 75% Daytime Load Shifting
3.2M+ sq.ft. Installed
Featured in NREL Guide
RETScreen Validated
18+ Years Proven
Storing Energy
CTRL
GRID
Activated Concrete Floors & Ceilings
Structure Storing Energy
Energy Input

Charge the structure when demand is lower.

Termobuild helps buildings use available off-peak energy to pre-condition the concrete structure. The goal is not to add separate storage equipment, but to activate the thermal capacity of the structure already being built.

Uses off-peak operating windows when appropriate
Can support low-carbon energy strategies if desired
Prepares the building before peak demand periods
Take the tour Click each step below to see how the building charges, stores, delivers, and shifts energy.
Measured Building Performance

Actual Project Data. Real Operating Results.

Measured operating data from a deployed Termobuild project — presented as engineering evidence, not a simulation.

Live Project Performance Measured Operating Dashboard
Project Type Educational Building
Status Verified • Measured • Operational
Period 12-Month Operating Performance
Operational Carbon
65%

More carbon saved in measured operation.

Natural Gas Consumption
38%

Lower gas consumption versus baseline.

Greenhouse Gas Emissions
67%

More GHG reduction in measured operation.

Electrical Consumption
36%

Lower electricity use in measured operation.

Comfort Evidence

Stable conditions from measured building operation.

The dashboard connects the interactive concept above to real project performance below: the building structure helps stabilize conditions while reducing mechanical workload.

Measured operating performance from an actual project
Comfort maintained while energy use was reduced
Performance evidence supports the rechargeable building strategy

Operational Carbon

Baseline 1,300 tons 1,179 t
Rechargeable 2,145 tons 1,946 t

65% increase in measured carbon savings.

Natural Gas Consumption

Baseline 58,570 m³ 2.07M ft³
Rechargeable 36,112 m³ 1.28M ft³

38% reduction in measured natural gas consumption.

Greenhouse Gas Emissions

Baseline 5,145 kg 11,343 lb
Rechargeable 8,575 kg 18,905 lb

67% increase in measured GHG savings.

Electrical Consumption

Baseline 468,947 kWh 1,600 MMBtu
Rechargeable 302,468 kWh 1,032 MMBtu

36% reduction in measured electrical consumption.

Lower Operating Cost

Reduced gas and electricity use translates into a lower utility burden over time.

Measured Performance

Real building data from actual operation — not theoretical modeling.

Lower Environmental Impact

Improved energy performance reduces operational carbon and greenhouse gas impact.

Building as Infrastructure

The structure becomes part of the building’s energy strategy, helping reduce demand and improve performance.

Measured. Verified. Repeatable. Real building performance starts with the structure.
Measured operating data from a deployed Termobuild project. Weather and occupancy conditions normalized.

Proven Across Building Types

The same structural energy storage strategy has been successfully applied across multiple building types and climate zones.