Rebar spacer

Last updated August 22, 2024

Linear rebar spacer RebarLinearSpacer.JPG — Linear rebar spacer

A rebar spacer is a short, rod-like device used to secure reinforcing steel bars, or rebar, within cast assemblies for reinforced concrete structures. The rebar spacers are fixed before the concrete is poured and remain within the structure.

Function

The engineering study of every reinforced concrete construction, whether it is a building, a bridge, a bearing wall, or another structure, dictates the positioning of steel rebars at specific positions in the volume of concrete (predicted concrete cover of steel reinforcement bars). This cover varies between 10 mm and 100 mm.

The statics of every concrete construction is designed in such a way that steel and concrete properties are combined in order to achieve the most possible strength for the particular construction (e.g. anti-earthquake protection) as well as to prevent the long-term corrosion of steel that would weaken the construction.

The function of rebar spacers is to maintain the precise positioning of steel reinforcement, facilitating the implementation of theoretical design specifications in concrete construction. This includes ensuring the appropriate steel cover for specific structural elements (such as in a concrete slab or a beam) should be generally uniform within the element.^[1]

The use of spacers is particularly important in areas with high earthquake activity in combination with corrosive environments (like proximity to the salt water of the sea),^[2] for example Japan, Iran, Greece, California, etc.

Plastic versus concrete spacers and bar supports

Plastic spacers and bar supports

Plastic spacers and bar supports do not bond well with concrete and are not compatible materials.^[1] Plastic has mechanical properties (holds the bar in position) but no structural properties, and is a foreign element within the construction.

When the concrete is poured into the form, a small gap is created between the concrete and the plastic. Plastic has a coefficient of thermal expansion and contraction 10 to 15 times that of concrete.^[1] When subjected to temperature variations, the plastic continues to expand and contract at the higher coefficient.

At elevated temperatures, plastic may melt. Consequently, this leads to a disconnection between the spacers and the concrete that has been cast. Such separation establishes an unobstructed pathway for corrosive substances to access the steel reinforcement from the concrete product's exterior. This process initiates the corrosion of the steel, which ultimately extends to the concrete.

If steam curing is applied to the concrete, the heat in the curing process causes the plastic to expand while the concrete is relatively fresh and weak. After reaching the maximum curing temperature and volume expansion of the plastic, the temperature is held at this level until the concrete reaches the desired strength. After curing, the subsequent lower temperatures cause the plastic to contract, and a gap remains at the interface between the plastic and concrete.

Plastic spacers are also subject to corrosion when they come into contact with chlorides and chemicals, whereas concrete has a much higher resistance.^[2]

Concrete spacers and bar supports

Concrete spacers and bar supports are often made of the same material properties as the poured concrete, so thermal expansion and contraction are equal. As a result, the concrete and spacers will bond without gaps. Often these spacers are manufactured from extruded fiber-reinforced concrete which improves crack resistance.^[3]

Concrete spacers and bar support help maintain material integrity and uniformity of the concrete, and provide a cover over the reinforcement that protects against corrosion.

Concrete spacers with a plastic clip or other fixing mechanism

Concrete spacers and bar supports help maintain material integrity and uniformity of the concrete.^[1] They provide a cover over the reinforcement that protects against corrosion.

Concrete spacers with a plastic clip or fixing mechanism do not have a negative effect on material integrity and do not weaken the corrosion protective cover over the reinforcement.

The plastic clip or fixing mechanism is hinged from the top of the spacer and does not come into contact with the soffit of the concrete. The plastic clip or fastening mechanism is incorporated at a depth of merely 5 mm into the spacer, thereby preserving the material's integrity at the surface of the product.

This plastic component in the clip or fastening mechanism serves exclusively for attachment and securing of the reinforcement, allowing the concrete segment to fulfil the spacer's functional role.

Related Research Articles

Concrete is a composite material composed of aggregate bonded together with a fluid cement that cures to a solid over time. Concrete is the second-most-used substance in the world after water, and is the most widely used building material. Its usage worldwide, ton for ton, is twice that of steel, wood, plastics, and aluminium combined.

Masonry is the craft of building a structure with brick, stone, or similar material, including mortar plastering which are often laid in, bound, and pasted together by mortar. The term masonry can also refer to the building units themselves.

Reinforced concrete, also called ferroconcrete, is a composite material in which concrete's relatively low tensile strength and ductility are compensated for by the inclusion of reinforcement having higher tensile strength or ductility. The reinforcement is usually, though not necessarily, steel bars (rebar) and is usually embedded passively in the concrete before the concrete sets. However, post-tensioning is also employed as a technique to reinforce the concrete. In terms of volume used annually, it is one of the most common engineering materials. In corrosion engineering terms, when designed correctly, the alkalinity of the concrete protects the steel rebar from corrosion.

Corrosion is a natural process that converts a refined metal into a more chemically stable oxide. It is the gradual deterioration of materials by chemical or electrochemical reaction with their environment. Corrosion engineering is the field dedicated to controlling and preventing corrosion.

Rebar, known when massed as reinforcing steel or steel reinforcement, is a steel bar used as a tension device in reinforced concrete and reinforced masonry structures to strengthen and aid the concrete under tension. Concrete is strong under compression, but has low tensile strength. Rebar significantly increases the tensile strength of the structure. Rebar's surface features a continuous series of ribs, lugs or indentations to promote a better bond with the concrete and reduce the risk of slippage.

Insulating concrete form or insulated concrete form (ICF) is a system of formwork for reinforced concrete usually made with a rigid thermal insulation that stays in place as a permanent interior and exterior substrate for walls, floors, and roofs. The forms are interlocking modular units that are dry-stacked and filled with concrete. The units lock together somewhat like Lego bricks and create a form for the structural walls or floors of a building. ICF construction has become commonplace for both low rise commercial and high performance residential construction as more stringent energy efficiency and natural disaster resistant building codes are adopted.

<span class="mw-page-title-main">Concrete slab</span> Flat, horizontal concrete element of modern buildings

A concrete slab is a common structural element of modern buildings, consisting of a flat, horizontal surface made of cast concrete. Steel-reinforced slabs, typically between 100 and 500 mm thick, are most often used to construct floors and ceilings, while thinner mud slabs may be used for exterior paving.

<span class="mw-page-title-main">Formwork</span> Molds for cast

Formwork is molds into which concrete or similar materials are either precast or cast-in-place. In the context of concrete construction, the falsework supports the shuttering molds. In specialty applications formwork may be permanently incorporated into the final structure, adding insulation or helping reinforce the finished structure.

Structural steel is a category of steel used for making construction materials in a variety of shapes. Many structural steel shapes take the form of an elongated beam having a profile of a specific cross section. Structural steel shapes, sizes, chemical composition, mechanical properties such as strengths, storage practices, etc., are regulated by standards in most industrialized countries.

Concrete cover, in reinforced concrete, is the least distance between the surface of embedded reinforcement and the outer surface of the concrete. The concrete cover depth can be measured with a cover meter. The purpose of concrete cover is to protect the reinforcement from corrosion, fire, and other potential damage.

Fiber-reinforced concrete or fibre-reinforced concrete (FRC) is concrete containing fibrous material which increases its structural integrity. It contains short discrete fibers that are uniformly distributed and randomly oriented. Fibers include steel fibers, glass fibers, synthetic fibers and natural fibers – each of which lend varying properties to the concrete. In addition, the character of fiber-reinforced concrete changes with varying concretes, fiber materials, geometries, distribution, orientation, and densities.

A cement accelerator is an admixture for the use in concrete, mortar, rendering or screeds. The addition of an accelerator speeds the setting time and thus cure time starts earlier. This allows concrete to be placed in winter with reduced risk of frost damage. Concrete is damaged if it does not reach a strength of 500 pounds per square inch (3.4 MPa) before freezing.

Structural engineering depends on the knowledge of materials and their properties, in order to understand how different materials resist and support loads.

<span class="mw-page-title-main">Textile-reinforced concrete</span> Type of reinforced concrete

Textile-reinforced concrete is a type of reinforced concrete in which the usual steel reinforcing bars are replaced by textile materials. Instead of using a metal cage inside the concrete, this technique uses a fabric cage inside the same.

Concrete degradation may have many different causes. Concrete is mostly damaged by the corrosion of reinforcement bars due to the carbonatation of hardened cement paste or chloride attack under wet conditions. Chemical damage is caused by the formation of expansive products produced by chemical reactions, by aggressive chemical species present in groundwater and seawater, or by microorganisms Other damaging processes can also involve calcium leaching by water infiltration, physical phenomena initiating cracks formation and propagation, fire or radiant heat, aggregate expansion, sea water effects, leaching, and erosion by fast-flowing water.

A reinforced concrete column is a structural member designed to carry compressive loads, composed of concrete with an embedded steel frame to provide reinforcement. For design purposes, the columns are separated into two categories: short columns and slender columns.

Sulfur concrete, sometimes named thioconcrete or sulfurcrete, is a composite construction material, composed mainly of sulfur and aggregate. Cement and water, important compounds in normal concrete, are not part of sulfur concrete. The concrete is heated above the melting point of elemental sulfur at ca. 140 °C (284 °F) in a ratio of between 12% and 25% sulfur, the rest being aggregate.

The durability design of reinforced concrete structures has been recently introduced in national and international regulations. It is required that structures are designed to preserve their characteristics during the service life, avoiding premature failure and the need of extraordinary maintenance and restoration works. Considerable efforts have therefore made in the last decades in order to define useful models describing the degradation processes affecting reinforced concrete structures, to be used during the design stage in order to assess the material characteristics and the structural layout of the structure.

The reinforcement of 3D printed concrete is a mechanism where the ductility and tensile strength of printed concrete are improved using various reinforcing techniques, including reinforcing bars, meshes, fibers, or cables. The reinforcement of 3D printed concrete is important for the large-scale use of the new technology, like in the case of ordinary concrete. With a multitude of additive manufacturing application in the concrete construction industry—specifically the use of additively constructed concrete in the manufacture of structural concrete elements—the reinforcement and anchorage technologies vary significantly. Even for non-structural elements, the use of non-structural reinforcement such as fiber reinforcement is not uncommon. The lack of formwork in most 3D printed concrete makes the installation of reinforcement complicated. Early phases of research in concrete 3D printing primarily focused on developing the material technologies of the cementitious/concrete mixes. These causes combined with the non-existence of codal provisions on reinforcement and anchorage for printed elements speak for the limited awareness and the usage of the various reinforcement techniques in additive manufacturing. The material extrusion-based printing of concrete is currently favorable both in terms of availability of technology and of the cost-effectiveness. Therefore, most of the reinforcement techniques developed or currently under development are suitable to the extrusion-based 3D printing technology.

References

1 2 3 4 Rostam, Steen (2005). Design and Construction of Segmental Concrete Bridges for Service Life of 100 to 150 Years. American Segmental Bridge Institut. pp. 24–25.
1 2 Çomak, Bekir; Aykanat, Batuhan; Aydin, Sait; Emiroğlu, Mehmet (2022-10-01). "Characterization of cement-based spacers for high performance concretes". Journal of Building Engineering. 57: 104780. doi:10.1016/j.jobe.2022.104780. ISSN 2352-7102. S2CID 249944155.
↑ Löfgren, Ingemar (2005-08-12). "Fibre-reinforced Concrete for Industrial Construction - a fracture mechanics approach to material testing and structural analysis". Doktorsavhandlingar vid Chalmers Tekniska Hogskola. Retrieved 28 February 2024.

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[:0-1] 1 2 3 4 Rostam, Steen (2005). Design and Construction of Segmental Concrete Bridges for Service Life of 100 to 150 Years. American Segmental Bridge Institut. pp. 24–25.

[:1-2] 1 2 Çomak, Bekir; Aykanat, Batuhan; Aydin, Sait; Emiroğlu, Mehmet (2022-10-01). "Characterization of cement-based spacers for high performance concretes". Journal of Building Engineering. 57: 104780. doi:10.1016/j.jobe.2022.104780. ISSN 2352-7102. S2CID 249944155.

[3] Löfgren, Ingemar (2005-08-12). "Fibre-reinforced Concrete for Industrial Construction - a fracture mechanics approach to material testing and structural analysis". Doktorsavhandlingar vid Chalmers Tekniska Hogskola. Retrieved 28 February 2024.

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