The actual performance of a wall depends as much on its design as on its implementation. Designing complete walls helps to reduce the gap between the plan and the site.
During the design phase, the performance of a wall is evaluated based on theoretical values: thermal resistance, material composition, construction details. On paper, several solutions can meet the same requirements.
On the construction site, the reality is different.
The actual performance of a wall depends as much on its design as on its implementation. Each additional step, each junction between materials, and each intervention by trades increase the risks of discrepancies between the expected performance and the performance achieved.
A wall made up of several layers installed at different times relies on perfect execution to reach its full potential. The slightest discontinuity can affect insulation, air management, or the long-term behavior of the wall.
In contrast, a wall designed as a complete system reduces these variables. By integrating the envelope, insulation, and finishes into a single product, the performance defined at the design stage is closer to the actual performance once the building is delivered.
For engineers and architects, this approach allows for the design of more predictable walls. The stated values no longer depend on a succession of critical steps, but on a coherent system designed to be assembled as intended.
It is precisely this logic that guides Isobloc. By allowing a complete wall to be assembled in a single step, the system reduces the gap between what is planned and what is delivered on the construction site.
Helping to build better also means reducing this gap.
So why do without it?
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The actual performance of a wall depends as much on its design as on its implementation. Discover how a complete wall in one step reduces the gap between the plan and the site.