Lightweight concrete

Lightweight concretes can either be lightweight aggregate concrete, foamed concrete or auto claved aerated concrete (AAC). Lightweight concrete blocks are often used in house construction.

Lightweight aggregate concrete

Lightweight aggregate concrete can be produced using a variety of lightweight aggregates. Lightweight aggregates originate from either:

Natural materials, like volcanic pumice.

The thermal treatment of natural raw materials like clay, slate or shale i.e. Leca.

Manufacture from industrial by-products such as fly ash, i.e. Lytag.

Processing of industrial by-products such as pelletised expanded slab, i.e. Pellite.

The required properties of the lightweight concrete will have a bearing on the best type of lightweight aggregate to use. If little structural requirement, but high thermal insulation properties, are needed then a light, weak aggregate can be used. This will result in relatively low strength concrete.

Foamed concrete

Foamed concrete is a highly workable, low-density material which can incorporate up to 75 percent entrained air. It is generally self-levelling, self-compacting and may be pumped. Foamed concrete is ideal for filling redundant voids such as disused fuel tanks, sewer systems, pipelines, and culverts - particularly where access is difficult. It is a recognized medium for the reinstatement of temporary road trenches. Good thermal insulation properties make foamed concrete also suitable for sub-screeds, filling under-floor voids and insulation on flat concrete roofs.

Lightweight structural concrete

Lightweight aggregate concretes can be used for structural applications, with strengths equivalent to normal weight concrete.

The benefits of using lightweight aggregate concrete include:

Reduction in dead loads making savings in foundations and reinforcement.

Improved thermal properties.

Improved fire resistance.

Savings in transporting and handling precast units on site.

Reduction in formwork and propping.

The elastic modulus of lightweight concretes is lower than the equivalent strength normal weight concrete, but when considering the deflection of a slab or beam, this is counteracted by the reduced self-weight.

The lighter the concrete, the greater are the differences to be accounted for in the properties of the concrete. The tensile strength, ultimate strains and shear strengths are all lower than a normal weight concrete with the same cylinder strength. Lightweight concretes are also less stiff than the equivalent normal strength concrete. However, this is mitigated by the reduction in self-weight to be carried, so the overall effect tends to be a slight reduction in the depth of a beam or slab.

Creep and shrinkage for lightweight concretes are higher than that for the equivalent normal weight concrete, and this should be taken into account when designing the structure.