Water–cement ratio

The water–cement ratio is the ratio of the weight of water to the weight of cement used in a concrete mix. A lower ratio leads to higher strength and durability, but may make the mix difficult to work with and form. Workability can be resolved with the use of plasticizers or super-plasticizers.

Often, the ratio refers to the ratio of water to cement plus pozzolan ratio, w/(c+p). The pozzolan is typically a fly ash, or blast furnace slag. It can include a number of other materials, such as silica fume, rice husk ash or natural pozzolans. Pozzolans can be added to strengthen concrete.

The notion of water–cement ratio was first developed by Duff A. Abrams and published in 1918. Refer to concrete slump test.

Concrete hardens as a result of the chemical reaction between cement and water (known as hydration, this produces heat and is called the heat of hydration). For every pound (or kilogram or any unit of weight) of cement, about 0.42 pounds (or 0.42 kg or corresponding unit) of water is needed to fully complete hydration reactions.

However, a mix with a ratio of 0.42 may not mix thoroughly, and may not flow well enough to be placed. More water is therefore used than is technically necessary to react with cement. Water-cement ratios of 0.45 to 0.60 are more typically used. For higher-strength concrete, lower ratios are used, along with a plasticizer to increase flowability.

Too much water will result in segregation of the sand and aggregate components from the cement paste. Also, water that is not consumed by the hydration reaction may leave concrete as it hardens, resulting in microscopic pores (bleeding) that will reduce final strength of concrete. A mix with too much water will experience more shrinkage as excess water leaves, resulting in internal cracks and visible fractures (particularly around inside corners), which again will reduce the final strength.

The 1997 Uniform Building Code specifies a maximum of 0.5 ratio when concrete is exposed to freezing and thawing in a moist condition or to de-icing chemicals, and a maximum of 0.45 ratio for concrete in a severe or very severe sulfate condition.

Concrete

History	Roman concrete Roman engineering Ancient Roman architecture

Composition	Cement Portland cement Water Water–cement ratio Aggregate Reinforcement Fly ash Ground granulated blast furnace slag Silica fume Metakaolin

Production	Plant Concrete mixer Volumetric mixer Reversing drum mixer Slump test Flow table test Curing Concrete cover Cover meter Rebar

Science	Properties Degradation Environmental impact Recycling Segregation in concrete

Types	Energetically modified cement Fiber reinforcement Rosendale cement (natural cement) Perviousity Precasting Pre-stressing Ready-mix Reinforcement Roller-compacting Self-consolidating Mass Polymer Filigree Voided biaxial slab Lunarcrete Reinforced column Foam

Construction	Formwork Climbing formwork Slip forming Screed Power screed Finisher Power trowel Pump Float Sealer

Organizations	American Concrete Institute Institution of Structural Engineers Indian Concrete Institute Nanocem Portland Cement Association

Book:Concrete Category:Concrete

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