Selected materials and construction strategies embody the era they are invented in. Pozzolanic ash concrete provided Roman builders with an artificial stone to erect vaulted and domed structures that still stand today. Industrialization harnessed new energies for steel and concrete elevating construction capacity for edifices of scopes, sizes and heights impossible to imagine before then. Reinforced concrete, a robust and intrinsically fire-proof material, came to represent the modern industrialized housing block. Casting this malleable and resistant material into shapes reformed onsite construction as surface elements for floors, walls, roofs, and other required components like stairs or balconies could be precast in quantities offsite, delivered and easily assembled onsite. The precast large panel blocks of postwar France epitomize the marriage of a material's properties and overwhelming demand for its use.
Today, critical decarbonization of building activities to reduce construction’s environmental footprint, increasing urbanization and a demand for quickly built housing is stimulating the demand for another twentieth century material: engineered laminated timber. Both glulam and cross laminated timber are embraced as eco-friendly as their low carbon footprint when compared to energy intensive materials like steel or concrete has unveiled a competitive edge in the age of rapidly evolving climate change.
Engineered laminated mass timber is relatively simple to produce, and components can be fashioned in any geometry and precisely cut as customizable offsite produced kits for building. Parts, slabs, panels, columns can also be normalized or standardized according to spans and dimensional requirements of reproducible building types. The Sylva scalable timber construction system by European forestry company Stora Enso demonstrates the straightforward mass timber approach: post and beam glulam is complemented by cross-laminated elements for bearing or spanning elements. Along with their school kit, Stora Enso produces components ranging from simple linear elements to comprehensive modular volumetric building sub-assemblies to be stacked into multiple configurations. Along with sequestering carbon during their lifespan, if the timber is protected adequately and its joinery designed for disassembly, components can be deployed over multiple lifecycles, making mass timber perfect for low embodied energy building.
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School ConstructionComponents by Store Enso |