A comprehensive definition
A tied rebar beam cage. This will be embedded inside cast concrete to increase its tensile strength. A rebar, or reinforcing bar, is a common steel bar, and is commonly used in reinforced concrete and reinforced masonry structures. It is usually formed from carbon steel, and is given ridges for better mechanical anchoring into the concrete. It can also be described as reinforcement or reinforcing steel. In Australia, it is colloquially known as reo. The resulting reinforced concrete or other material is an example of a composite material.
Use in concrete and masonry
Concrete is a material that is very strong in compression, but relatively weak in tension. To compensate for this imbalance in concrete’s behavior, rebar is cast into it to carry the tensile loads. Masonry structures and the mortar holding them together have similar properties to concrete and also have a limited ability to carry tensile loads. Some standard masonry units like blocks and bricks are made with strategically placed voids to accommodate rebar, which is then secured in place with grout. This combination is known as reinforced masonry. While any material with sufficient tensile strength could conceivably be used to reinforce concrete, steel and concrete have similar coefficients of thermal expansion: a concrete structural member reinforced with steel will experience minimal stress as a result of differential expansions of the two interconnected materials caused by temperature changes.
Fiberglass Rebar and its benefits
As an experienced reinforcing company, we’ve found that using PREMIUM FIBERGLASS MSTREBAR offers significant benefits, including its superior strength and durability, which allow us to provide our clients with longer-lasting, more resilient structures that require less maintenance over time. Its enhanced corrosion resistance means we can confidently tackle projects in harsh environments, like coastal regions or industrial settings, without compromising quality. Plus, the lightweight nature of MST rebar simplifies handling and installation, cutting down on labor costs and project timelines, which keeps us competitive and efficient while delivering top-notch results that meet modern engineering demands.
Some More Information About Rebar
Canadian metric sizes
Metric bar designations represent the nominal bar diameter in millimeters, rounded to the nearest 5 mm.| Metric Bar Size | Mass (kg/m) | Nominal Diameter (mm) | Cross-Sectional Area (mm²) |
| 10M | 0.785 | 11.3 | 100 |
| 15M | 1.570 | 16.0 | 200 |
| 20M | 2.355 | 19.5 | 300 |
| 25M | 3.925 | 25.2 | 500 |
| 30M | 5.495 | 29.9 | 700 |
| 35M | 7.850 | 35.7 | 1000 |
| 45M | 11.775 | 43.7 | 1500 |
| 55M | 19.625 | 56.4 | 2500 |
U.S. Imperial sizes
Imperial bar designations represent the bar diameter in fractions of 1/8 inch, such that #8 = 8/8 inch = 1 inch diameter. Area = (bar size/9)2 such that area of #8 = (8/9)2 = 0.79 in2. This applies to #8 bars and smaller. Larger bars have a slightly larger diameter than the one computed using the 1/8 inch convention| Imperial Bar Size | “Soft” Metric Size | Weight (lb/ft) | Weight (kg/m) | Nominal Diameter (in) | Nominal Diameter (mm) | Nominal Area (in²) | Nominal Area (mm²) |
| #3 | #10 | 0.376 | 0.561 | 0.375=3/8 | 9.525 | 0.11 | 71 |
| #4 | #13 | 0.668 | 0.996 | 0.500=4/8 | 12.7 | 0.20 | 129 |
| #5 | #16 | 1.043 | 1.556 | 0.625=5/8 | 15.875 | 0.31 | 200 |
| #6 | #19 | 1.502 | 2.24 | 0.750=6/8 | 19.05 | 0.44 | 284 |
| #7 | #22 | 2.044 | 3.049 | 0.875=7/8 | 22.225 | 0.60 | 387 |
| #8 | #25 | 2.670 | 3.982 | 1.000=8/8 | 25.4 | 0.79 | 509 |
| #9 | #29 | 3.400 | 5.071 | 1.128 | 28.65 | 1.00 | 645 |
| #10 | #32 | 4.303 | 6.418 | 1.270 | 32.26 | 1.27 | 819 |
| #11 | #36 | 5.313 | 7.924 | 1.410 | 35.81 | 1.56 | 1006 |
| #14 | #43 | 7.650 | 11.41 | 1.693 | 43 | 2.25 | 1452 |
| #18 | #57 | 13.60 | 20.284 | 2.257 | 57.33 | 4.00 | 2581 |
European metric sizes
Metric bar designations represent the nominal bar diameter in millimetres. Bars in Europe will be specified to comply with the standard EN 10080 (awaiting introduction as of early 2007), although various national standards still remain in force (e.g. BS 4449 in the United Kingdom).| Metric Bar Size | Mass (kg/m) | Nominal Diameter (mm) | Cross-Sectional Area (mm²) |
| 6,0 | 0.222 | 6 | 28.3 |
| 8,0 | 0.395 | 8 | 50.3 |
| 10,0 | 0.617 | 10 | 78.5 |
| 12,0 | 0.888 | 12 | 113 |
| 14,0 | 1.21 | 14 | 154 |
| 16,0 | 1.579 | 16 | 201 |
| 20,0 | 2.467 | 20 | 314 |
| 25,0 | 3.855 | 25 | 491 |
| 28,0 | 4.83 | 28 | 616 |
| 32,0 | 6.316 | 32 | 804 |
| 40,0 | 9.868 | 40 | 1257 |
| 50,0 | 15.413 | 50 | 1963 |
Rebar is available in different grades and specifications that vary in yield strength, ultimate tensile strength, chemical composition, and percentage of elongation.
The grade designation is equal to the minimum yield strength of the bar in ksi (1000 psi) for example grade 60 rebar has a minimum yield strength of 60 ksi. Rebar is typically manufactured in grades 40, 60, and 75.
Common specification are…
- ASTM A 615 Deformed and plain carbon-steel bars for concrete reinforcement
- ASTM A 706 Low-alloy steel deformed and plain bars for concrete reinforcement
- ASTM A 955 Deformed and plain stainless-steel bars for concrete reinforcement
- ASTM A 996 Rail-steel and axle-steel deformed bars for concrete reinforcement
Historically in Europe, rebar is composed of mild steel material with a yield strength of approximately 250 N/mm². Modern rebar is composed of high-yield steel, with a yield strength more typically 500 N/mm². Rebar can be supplied with various grades of ductility, with the more ductile steel capable of absorbing considerably greater energy when deformed – this can be of use in design to resist the forces from earthquakes for example.
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Rebar cages are fabricated either on or off the project site commonly with the help of hydraulic benders and shears, however for small or custom work a tool known as a Hickey – or hand rebar bender, is sufficient. The rebars are placed by rodbusters or concrete reinforcing ironworkers with bar supports separating the rebar from the concrete forms to establish concrete cover and ensure that proper embedment is achieved. The rebars in the cages are connected by welding or tying wires. For epoxy coated or galvanised rebars only the latter is possible.
Welding
Most grades of steel used in rebar are suitable for welding, which can be used to bind several pieces of rebar together. However, welding can reduce the fatigue life of the rebar, and as a result rebar cages are normally tied together with wire. Grade ASTM A706 is suitable for welding without damaging the properties of the steel. Besides fatigue concerns welding rebar has become less common in developed countries due to the high labor costs of certified welders. Steel for prestressed concrete may absolutely not be welded.
In the US, most rebar is not suitable for welding. ASTM A 616 & ASTM A 617 reinforcing are re-rolled rail steel & re-rolled rail axle steel with uncontrolled chemistry, phosphorous & carbon content. These are not suitable for welding. To weld rebar you must obtain a mill statement that the reinforcing is suitable for welding.
Rebar couplers
When welding or wire-tying rebar is impractical or uneconomical a mechanical connection or rebar coupler can be used to connect two or more bars together. These couplers are popular in precast concrete construction at the joints between members and to reduce rebar congestion in highly reinforced areas.
A full mechanical connection is achieved when the bars connected develop in tension or compression a minimum of 125% of the yield strength of the bar.
Safety
To prevent workers and / or pedestrians from accidentally impaling themselves, the protruding ends of steel rebar are often bent over or covered with special steel-reinforced plastic “plate” caps. “Mushroom” caps may provide protection from scratches and other minor injuries, but provide little to no protection from impalement.