Rebar Calculator
Calculate linear feet, bar count, total weight, and material cost for rebar in any concrete slab, footing, or wall. Supports #3–#11 bar sizes, Grade 40/60/75, ACI 318 lap splices, and imperial or metric units.
Whether you're reinforcing a concrete slab, a foundation footing, or a retaining wall, this calculator handles the rebar math. Choose your project type — slab or wall — enter the dimensions and bar spacing, select bar size and grade, and you'll get total linear footage, how many stock bars to buy, total project weight for delivery planning, and an estimated material cost. Lap splices are automatically calculated per ACI 318 when bars span longer than the stock length. A 10% waste allowance is included by default.
ASTM A615/A706 standard. Bar number = nominal diameter in ⅛-inch increments (e.g., #4 = 4⁄8 = ½ inch). Lap splice lengths shown for Grade 60 in 3,000 psi concrete (Class B).
| Bar # | Diameter (in / mm) | Weight (lb/ft) | Weight (kg/m) | Wt per 20 ft bar | Grade 60 lap (in) | Typical use |
|---|---|---|---|---|---|---|
| #3 | ⅜ in / 9.5 mm | 0.376 | 0.560 | 7.5 lb | ~15 in | Footings, thin slabs, masonry |
| #4 ★ | ½ in / 12.7 mm | 0.668 | 0.994 | 13.4 lb | ~20 in | Residential slabs, walls, columns |
| #5 | ⅝ in / 15.9 mm | 1.043 | 1.552 | 20.9 lb | ~25 in | Driveways, heavy slabs, beams |
| #6 | ¾ in / 19.1 mm | 1.502 | 2.235 | 30.0 lb | ~30 in | Retaining walls, structural beams |
| #7 | ⅞ in / 22.2 mm | 2.044 | 3.042 | 40.9 lb | ~35 in | Heavy structural members |
| #8 | 1 in / 25.4 mm | 2.670 | 3.973 | 53.4 lb | ~40 in | Columns, bridge decks |
| #9 | 1⅛ in / 28.7 mm | 3.400 | 5.059 | 68.0 lb | ~46 in | Structural beams, heavy columns |
| #10 | 1¼ in / 32.3 mm | 4.303 | 6.404 | 86.1 lb | ~51 in | Heavy structural members |
| #11 | 1⅜ in / 35.8 mm | 5.313 | 7.906 | 106.3 lb | ~56 in | Bridge work, large columns |
Standard rebar sizes and specifications
Reinforcing bar — commonly called rebar — is the backbone of virtually every concrete structure built in North America. Understanding the standard size system is the first step to accurate quantity estimation and informed material selection.
Rebar in the United States follows a numbering system defined by ASTM A615 and A706 in which the bar number equals the nominal diameter in eighths of an inch. A #4 bar is therefore 4/8 inch = ½ inch in diameter; a #8 bar is 1 inch in diameter. This convention applies consistently from #3 through #11, and from #14 and #18 for the large structural bars used in heavy civil construction. The diameter rule breaks at #9, #10, and #11, which are imperial equivalents of metric sizes and have actual diameters of 1.128, 1.270, and 1.410 inches respectively rather than the exact 1⅛, 1¼, and 1⅜ inches that would follow the pattern strictly.
| Bar # | Diameter (in) | Diameter (mm) | Weight (lb/ft) | Weight (kg/m) | Typical applications |
|---|---|---|---|---|---|
| #3 | ⅜ in | 9.5 mm | 0.376 | 0.560 | Footings, thin slabs, masonry bond beams |
| #4 | ½ in | 12.7 mm | 0.668 | 0.994 | Residential slabs, walls, light footings |
| #5 | ⅝ in | 15.9 mm | 1.043 | 1.552 | Driveways, heavy slabs, grade beams |
| #6 | ¾ in | 19.1 mm | 1.502 | 2.235 | Retaining walls, structural beams |
| #7 | ⅞ in | 22.2 mm | 2.044 | 3.042 | Heavy structural members |
| #8 | 1 in | 25.4 mm | 2.670 | 3.973 | Columns, bridge decks |
| #9 | 1.128 in | 28.7 mm | 3.400 | 5.059 | Structural columns, large beams |
| #10 | 1.270 in | 32.3 mm | 4.303 | 6.404 | Heavy structural members |
| #11 | 1.410 in | 35.8 mm | 5.313 | 7.906 | Bridge work, large columns |
Rebar weight per linear foot follows directly from the cross-sectional area and steel’s density of approximately 490 lb/ft³ (7,850 kg/m³). A #4 bar weighs 0.668 lb per linear foot (0.994 kg/m); a 20-foot stock bar weighs 13.4 lb (6.1 kg). A #8 bar weighs 2.670 lb per linear foot (3.973 kg/m), making a 20-foot bar 53.4 lb (24.2 kg) — heavy enough to require equipment-assisted placement on large pours.
Most suppliers stock #3 through #8 in 20-foot lengths as standard. Longer bars (#9 through #11) or lengths of 40 or 60 feet are available by special order or from steel service centers. When planning delivery logistics, the total rebar weight often exceeds expectations: a 1,000-square-foot slab with #4 at 12 inches on center (both directions) uses about 1,350 linear feet of rebar, weighing roughly 900 pounds (410 kg) — almost half a ton in rebar alone.
Rebar grades: 40, 60, and 75
Rebar grade designates the minimum yield strength of the steel, expressed in thousands of pounds per square inch (ksi). Grade 60 — with a minimum yield of 60,000 psi (414 MPa) — is by far the most common specification in North American construction today and has been the default for most residential and commercial work since the 1970s.
Grade 40 (40,000 psi / 276 MPa yield) is an older designation found in existing construction drawings and still specified in some lightweight residential applications and masonry bond beams. It is more ductile than Grade 60, which made it easier to bend on older job sites, but its lower strength means designs using Grade 40 require more steel to carry equivalent loads. Grade 40 is increasingly scarce; many suppliers stock only Grade 60.
Grade 60 (60,000 psi / 414 MPa yield) is the standard for virtually all current construction in the United States and Canada. When a structural drawing says “ASTM A615 Gr. 60” or simply “#4 @ 12” EW,” it means Grade 60. The calculator defaults to Grade 60 for this reason. ASTM A706 is a low-alloy variant of Grade 60 with tighter chemical composition requirements for improved weldability and ductility — it is specified on many seismic and moment-frame projects but is geometrically and structurally interchangeable with A615 Grade 60 for quantity estimation purposes.
Grade 75 (75,000 psi / 517 MPa yield) and Grade 80 are high-strength grades used where reducing steel tonnage is important — long-span bridges, high-rise columns, and infrastructure in seismic zones where ASTM A706 Grade 80 is increasingly specified. Higher grades require longer development and lap splice lengths per ACI 318 because higher-strength bars must transfer more force across the same bond area.
| Grade | Min. yield (psi / MPa) | Common standard | Class B lap multiplier | Best use |
|---|---|---|---|---|
| Grade 40 | 40,000 / 276 | ASTM A615 | ~30× diameter | Light residential, masonry |
| Grade 60 | 60,000 / 414 | ASTM A615 / A706 | ~40× diameter | Standard residential and commercial |
| Grade 75 | 75,000 / 517 | ASTM A615 | ~50× diameter | High-strength structural applications |
For quantity estimation purposes, the grade does not change how many bars a project requires — the grid geometry and spacing drive the quantity. Grade affects tensile capacity (relevant to structural design), required lap length (directly relevant to total linear footage when splices are needed), and cost per ton of steel.
How to calculate rebar quantity
Rebar estimation for a rectangular slab or footing uses a straightforward grid-counting formula. The slab is divided into parallel rows of rebar running in each direction. The number of bars in each direction depends on the slab dimension perpendicular to the bars and the on-center spacing.
The + 1 in each count accounts for the end bar at each edge of the slab — the first and last bar are at the edge, not at a spacing interval from nothing. For a 20 × 12 ft slab at 12-inch (1-foot) spacing:
Worked example — 20 × 12 ft slab, #4 Grade 60, 12-inch spacing both directions:
- Bars along length (running the 20 ft span, spaced 12” across the 12 ft width): ⌈12 ÷ 1⌉ + 1 = 13 bars × 20 ft = 260 lin ft
- Bars along width (running the 12 ft span, spaced 12” across the 20 ft length): ⌈20 ÷ 1⌉ + 1 = 21 bars × 12 ft = 252 lin ft
- Raw total: 260 + 252 = 512 lin ft
- Splices: no bar exceeds 20 ft stock length, so no splices needed
- With 10% waste: 512 × 1.10 = 563 lin ft → buy 29 × 20-ft bars
In metric: a 6.1 m × 3.7 m slab at 300 mm (12 in) spacing gives 13 × 6.1 m + 21 × 3.7 m = 79.3 m + 77.7 m = 157 m raw. With 10% waste: 173 m total.
For wall reinforcement, the formula adapts to the vertical/horizontal bar grid:
The calculation is identical in structure to the slab formula; only the dimension names change.
Spacing on center: what it means and how to use it
“On center” (abbreviated o.c.) means the distance from the center of one bar to the center of the next parallel bar. A 12-inch on-center spacing creates a grid with 12 inches between each bar centerline. This is the measurement used in design drawings, supplier specifications, and building code minimums — it is not the clear gap between bars (which would be approximately 11.5 inches for #4 bars at 12-inch o.c.).
Spacing determines both structural performance and material cost. Closer spacing increases the reinforcing ratio — the percentage of the cross-sectional area that is steel — which reduces crack width under loading and improves load distribution. The following spacings cover the full range of practical applications:
| Spacing | Reinforcing level | Common application |
|---|---|---|
| 6 in / 150 mm | Heavy structural | Transfer slabs, heavily loaded footings |
| 8 in / 200 mm | Heavy duty | Structural slabs, loaded retaining walls |
| 12 in / 300 mm | Standard | Residential slabs, driveways, footings |
| 16 in / 400 mm | Light duty | Lightly loaded slabs, interior floors |
| 18 in / 450 mm | Light reinforcement | Sidewalks, thin slabs over well-compacted fill |
| 24 in / 600 mm | Minimal | Decorative flatwork, non-structural applications |
Minimum and maximum spacing per ACI 318. The American Concrete Institute’s building code (ACI 318-19) requires a minimum clear spacing between parallel bars of at least the bar diameter or 1 inch (25 mm), whichever is greater, to allow concrete to flow between bars. Maximum spacing in slabs is limited to the smaller of three times the slab thickness or 18 inches (450 mm). For walls, ACI 318 sets maximum horizontal bar spacing at 18 inches and maximum vertical bar spacing at 18 inches for structural walls, though specific structural systems may have tighter requirements.
In practice, the most common choice for residential concrete work — driveways, patios, garage slabs, and foundation pads — is #4 rebar at 12 inches on center in both directions. This combination provides an adequate reinforcing ratio for most residential loads while using an amount of steel that is cost-effective and fast to place.
Lap splice requirements and ACI 318
Rebar comes in stock lengths of 20, 40, or 60 feet (6.1, 12.2, or 18.3 m). When a bar must span a distance longer than its stock length, two bars must overlap — this is a lap splice. The overlap length is not arbitrary; it must be long enough to transfer the full tensile force from one bar to the next through bond stress between the steel and the surrounding concrete.
ACI 318-19 (Building Code Requirements for Structural Concrete) defines two splice classes:
- Class A: minimum splice length equals the development length, ld. Used when the area of steel provided is at least twice the area required and no more than half the bars are spliced within one lap length.
- Class B: minimum splice length equals 1.3 × ld. Required in all other cases and is the default for most field splices.
The development length ld depends on bar diameter, concrete compressive strength, bar coating, and several modification factors. A conservative rule of thumb for uncoated Grade 60 bars in 3,000 psi (21 MPa) normal-weight concrete is:
where d_b is the nominal bar diameter. For Grade 40, the multiplier drops to approximately 30×; for Grade 75, it rises to approximately 50×. These are approximations suitable for material quantity estimation — a licensed structural engineer uses the full ACI 318 formula for design and must be consulted on any load-bearing application.
Applying the Grade 60 rule:
| Bar # | Diameter | Class B lap (~40×) |
|---|---|---|
| #3 | ⅜ in / 9.5 mm | ~15 in / 380 mm |
| #4 | ½ in / 12.7 mm | ~20 in / 508 mm |
| #5 | ⅝ in / 15.9 mm | ~25 in / 635 mm |
| #6 | ¾ in / 19.1 mm | ~30 in / 762 mm |
| #8 | 1 in / 25.4 mm | ~40 in / 1,016 mm |
Lap splices only add material when a bar’s required run exceeds the stock length. For a 20 ft slab with 20 ft bars, no splices are needed — each bar is cut to length from a single stock bar. For a 30 ft slab with 20 ft stock bars, each bar requires one splice, adding lapFt of extra length per bar. The calculator handles this automatically: for each direction, it computes splices per bar as max(0, ⌈run ÷ stockLen⌉ − 1).
Minimum concrete cover. ACI 318 also specifies minimum distances from the surface of a rebar to the nearest concrete face — called concrete cover. For cast-in-place slabs not exposed to weather or soil, the minimum cover is ¾ inch (19 mm) for #5 and smaller bars and 1½ inches (38 mm) for larger bars. Concrete exposed to weather requires 1½ inches (38 mm) minimum cover for #5 and smaller and 2 inches (51 mm) for larger. Bars in contact with the ground or cast against soil require at least 3 inches (76 mm) of cover. These cover requirements are enforced using plastic rebar chairs or “dobies” that hold the bars at the correct height above the form.
Real-world applications and typical quantities
Residential concrete slabs
The most common rebar application in residential construction is the concrete slab — for driveways, garage floors, patios, and outbuildings. A standard 4-inch (100 mm) slab uses #4 rebar at 12 inches on center in both directions, supported on chairs at 2–3 inches (50–75 mm) above the base. Typical quantities for common slab sizes at this specification:
- 20 × 20 ft patio (400 sq ft / 37 m²): 21 bars × 20 ft + 21 bars × 20 ft = 840 lin ft raw. With 10% waste: 930 lin ft → 47 × 20-ft bars, weighing about 620 lb (280 kg).
- 20 × 24 ft garage floor (480 sq ft / 44.6 m²): 25 bars × 20 ft + 21 bars × 24 ft = 500 + 504 = 1,004 lin ft raw. With 10% waste: 1,105 lin ft → 56 × 20-ft bars, weighing about 740 lb (335 kg).
- 12 × 30 ft driveway (360 sq ft / 33.4 m²): 13 bars × 30 ft + 31 bars × 12 ft = 390 + 372 = 762 lin ft raw. Bars running 30 ft each need 1 splice per bar (30 ft > 20 ft stock). 13 bars × 1 splice × 20 in / 12 = 21.7 extra ft. With 10% waste: 861 lin ft → 44 bars.
For driveways that will carry heavy vehicles (RVs, loaded trucks), upgrade to #5 at 12 inches — the extra cost in steel is small relative to the improvement in crack resistance.
Foundation footings
Strip footings under load-bearing walls and isolated column footings are the second most common residential rebar application. A typical residential perimeter footing, 12 inches wide and 8 inches deep, might carry 3 longitudinal #4 bars continuous along the footing length, plus #3 or #4 stirrups at 24-inch spacing. For a 100 linear-foot perimeter:
- 3 longitudinal bars × 100 ft = 300 lin ft
- Stirrups: 100 ft ÷ 2 ft spacing = 50 stirrups × (approximately 3 ft of bar each) = 150 lin ft
- Total: ~450 lin ft of #4 and #3 rebar
For isolated pad footings under columns, the depth and width of the footing determine the reinforcing, typically a grid pattern in both plan directions.
Retaining walls and CMU walls
Retaining walls typically require both vertical and horizontal steel. A 4-foot-high (1.2 m) CMU retaining wall with vertical #4 bars at 24 inches on center (grouted in cores) and horizontal bond beam reinforcement at 24 inches vertically, running 40 linear feet:
- Vertical bars: 21 bars × 4 ft = 84 lin ft
- Horizontal bars: 3 courses × 40 ft = 120 lin ft
- Total: ~204 lin ft
For reinforced concrete retaining walls taller than 4 feet, structural engineering is required. Wall thickness, footing size, and reinforcing layout depend on soil conditions, surcharge loads, and applicable code provisions.
Columns
Round or square concrete columns in residential construction (for decks, porches, and carports) typically use 4–8 vertical bars of #5 or #6 Grade 60 with #3 or #4 ties at 12-inch spacing. A 12 × 12-inch column 10 feet tall with 4 vertical #5 bars and #3 ties at 12 inches:
- Vertical bars: 4 × 10 ft = 40 lin ft
- Ties: (10 ft ÷ 1 ft) + 1 = 11 ties × ~3 ft (perimeter of tie) = 33 lin ft
- Total: ~73 lin ft for one column
Common mistakes to avoid
Rebar estimation and placement errors are among the most consequential in concrete construction. Unlike mortar or concrete mix, which can be adjusted during the pour, rebar placed incorrectly cannot be corrected once the pour is complete.
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Ordering by bar count instead of linear footage. The number of bars to buy depends on the stock length you select. If your calculation produces 560 linear feet and you’re buying 20-foot bars, that’s 28 bars — but if you switch to 40-foot bars, it’s only 14. Always calculate total linear footage first, then divide by the stock length to get bar count.
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Forgetting lap splices on long runs. A 30-foot slab span requires each bar to be spliced — a 20-foot stock bar covers only 20 feet, and the splice adds roughly 20–40 inches of extra bar. Forgetting laps on a large slab understates the required footage by 5–15 percent.
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Insufficient concrete cover. Rebar placed too close to the concrete surface corrodes when moisture penetrates the cover zone. Corrosion expands the bar, cracking the concrete in a self-reinforcing failure cycle. Use plastic rebar chairs or tie wire supports to hold bars at the correct height — never let rebar rest directly on the ground or form.
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Misidentifying the bar size. #4 and #5 bars look similar at a distance and may be mixed on a job site. Check the deformation pattern stamped on the bar: ASTM-standard bars have the bar number as a raised marking. Using #3 bars where #4 was specified reduces the reinforcing area by 44 percent.
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Using the wrong grade for the drawing. A structural drawing calling for Grade 60 cannot be satisfied with Grade 40 bars — a Grade 40 bar has only two-thirds the yield capacity of Grade 60 of the same size. Grade 40 bars are marked with a single line; Grade 60 bars show two lines or the number 60 on the deformation markings.
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Skipping bar chairs on slabs. Rebar that sinks to the bottom of a slab is at the wrong depth for flexural reinforcement (which is most effective in the bottom third of the slab) and may not achieve minimum cover. In practice, chairs or dobies cost almost nothing compared to the cost of the pour, yet they are frequently omitted on informal residential jobs.
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Skipping engineering review on structural applications. Quantity estimation tools determine how much rebar to buy. They do not and cannot determine whether a given bar size, spacing, grade, or layout meets the structural requirements of a specific load, span, or soil condition. Any load-bearing wall, column, bridge, retaining wall over 4 feet, or structure in a seismic zone should have reinforcing designed or reviewed by a licensed structural engineer referencing ACI 318 and applicable local codes.