Beam Deflection Calculator — Simply Supported, Cantilever & Fixed Beams
Calculate maximum beam deflection, bending moment, and shear reactions for steel, concrete, and wood beams. Results include automatic IBC 2024 Table 1604.3 code compliance checks for L/360, L/240, and L/480 deflection limits.
How the Beam Deflection Calculator Works
Choose Support Conditions
Select simply supported, cantilever, or fixed-fixed. Each condition produces a different deflection equation and reaction force distribution.
Define the Load
Enter a point load at midspan or any position, or a uniformly distributed load in lb/ft. Add self-weight for total-load deflection checks.
Select Material and Section
Pick from steel (E = 29,000,000 psi), concrete, or wood presets, or enter a custom modulus. Use the W-shape database for standard steel sections.
Read Code Compliance Results
The calculator applies IBC 2024 Table 1604.3 limits and returns pass/fail status, demand-to-capacity ratio, and maximum bending moment.
IBC 2024 Allowable Deflection Limits — Table 1604.3
The International Building Code sets maximum deflection limits based on element type and load case. These limits protect finishes, prevent occupant discomfort, and avoid damage to supported elements. The slab load calculator uses the same reference table for two-way slab checks.
| Structural Element | Load Case | Limit | Example: 20 ft Span |
|---|---|---|---|
| Floor beams | Live load only (L) | L/360 | 0.667 in |
| Floor beams | Total load (D + L) | L/240 | 1.000 in |
| Roof beams | Live load only (L) | L/360 | 0.667 in |
| Roof beams | Total load (D + L) | L/240 | 1.000 in |
| Beams with brittle finishes (tile, plaster) | Live load only (L) | L/480 | 0.500 in |
| Cantilever beams | Live load only (L) | L/180 | 1.333 in (10 ft cant.) |
| Residential floors (IRC) | Live load only (L) | L/360 | 0.667 in |
Source: IBC 2024 Table 1604.3. Spans are measured center-to-center of supports. For steel members, dead load deflection is set to zero per Table 1604.3 footnote g.
Beam Deflection Formulas Used in This Calculator
All deflection equations follow standard structural engineering references including AISC Steel Construction Manual Table 3-22 and Roark's Formulas for Stress and Strain, 8th Edition. For concrete beam design, refer to our concrete flexural strength calculator and the concrete modulus of elasticity calculator.
δmax = PL³ / (48EI)
Mmax = PL / 4
AISC Table 3-22a, Case 1
δmax = 5wL⁴ / (384EI)
Mmax = wL² / 8
AISC Table 3-22a, Case 2
δmax = PL³ / (3EI)
Mmax = PL
Roark's 8th Ed., Table 8.1
δmax = wL⁴ / (8EI)
Mmax = wL² / 2
Roark's 8th Ed., Table 8.1
δmax = PL³ / (192EI)
Mmax = PL / 8
Roark's 8th Ed., Table 8.2
δmax = wL⁴ / (384EI)
Mmax = wL² / 12
Roark's 8th Ed., Table 8.2
Where: δmax = maximum deflection (in), P = point load (lb), w = distributed load (lb/in), L = span (in), E = modulus of elasticity (psi), I = moment of inertia (in⁴), M = bending moment (lb-in).
What Is Beam Deflection and Why Does It Matter?
Beam deflection is the vertical displacement of a structural beam under applied loads. Every beam deflects when loaded; the question is whether that deflection exceeds the limit that causes serviceability problems.
Excessive deflection causes cracked plaster, sticking doors, sloped floors, and visible sagging that makes occupants uncomfortable. In severe cases it can damage supported partitions, tile finishes, and mechanical systems. For structural adequacy, see the concrete load-bearing capacity calculator and the concrete stress calculator for combined stress checks.
Three variables control deflection: span length (L), load magnitude, and flexural stiffness (EI). Span length has the greatest impact because deflection scales with L to the third or fourth power. Doubling a beam's span increases deflection by 8x for a point load and 16x for a distributed load, at the same load intensity.
Elastic Modulus (E) by Material
| Material | E (psi) | E (ksi) | Standard |
|---|---|---|---|
| Structural Steel (A36, A572, A992) | 29,000,000 | 29,000 | AISC SCM 16th Ed. |
| Concrete, f'c = 3,000 psi | 3,122,000 | 3,122 | ACI 318-19 §19.2.2.1 |
| Concrete, f'c = 4,000 psi | 3,605,000 | 3,605 | ACI 318-19 §19.2.2.1 |
| Douglas Fir-Larch, No. 2 | 1,700,000 | 1,700 | NDS 2018 Supplement Table 4A |
| Southern Pine, No. 2 | 1,600,000 | 1,600 | NDS 2018 Supplement Table 4B |
| Glulam / LVL (typical) | 1,800,000 | 1,800 | NDS 2018 Supplement Table 5A |
Sample Deflection Calculations
These worked examples follow the formulas in AISC Table 3-22 and IBC 2024 Table 1604.3. For rebar sizing in concrete beams, the rebar spacing calculator handles that step separately.
Example 1 — Steel Floor Beam, Simply Supported
| Span | 20 ft |
| Load | 8,000 lb point load at center |
| Section | W14x34 (Ix = 340 in⁴) |
| Material | Structural Steel (E = 29,000,000 psi) |
| Application | Floor — Live Load (L/360) |
Calculation: (8,000 × 240³) / (48 × 29,000,000 × 340) = 0.394 in. Allowable = 240 / 360 = 0.667 in. PASS (D/C = 0.59).
Example 2 — Cantilever Wood Beam
| Span | 8 ft |
| Load | 600 lb/ft uniform distributed |
| Section | 6x12 Lumber (Ix = 697 in⁴) |
| Material | Douglas Fir (E = 1,700,000 psi) |
| Application | Roof — Live Load (L/360) |
Calculation: (600/12 × 96⁴) / (8 × 1,700,000 × 697) = 0.711 in. Allowable = 96 / 180 = 0.533 in (cantilever uses L/180). FAILS — upsize section or shorten span.
Example 3 — Concrete Beam, Fixed-Fixed
| Span | 24 ft |
| Load | 1,200 lb/ft uniform distributed |
| Section | 12 in × 24 in rectangle (Ix = 13,824 in⁴) |
| Material | Concrete f'c 4,000 psi (E = 3,605,000 psi) |
| Application | Floor — Total Load (L/240) |
Calculation: (1,200/12 × 288⁴) / (384 × 3,605,000 × 13,824) = 0.341 in. Allowable = 288 / 240 = 1.200 in. PASS (D/C = 0.28). Note: Long-term creep per ACI 318-19 §24.2.4 may increase this by up to 2x under sustained loads.
Common Beam Deflection Calculation Errors
The deflection formulas require L in inches. A 20 ft span is 240 inches. Entering 20 directly into the formula understates deflection by a factor of 1,728 (20³ = 8,000 vs. 240³ = 13,824,000). This calculator handles the conversion automatically.
A W14x48 steel beam weighs 48 lb/ft. Over a 30 ft span, that adds 1,440 lb of dead load that many calculators omit. Per AISC Code of Standard Practice Section 3.1.2, self-weight must be included in total-load deflection checks.
ACI 318-19 Section 24.2.3.5 requires using the effective moment of inertia (Ie) for cracked concrete beams under service loads. Using Ig overstates stiffness and understates deflection, often by 40-60%. This matters most for lightly reinforced sections.
A cantilever with a point load at the free end deflects 16 times more than a simply supported beam of the same span and load, because the formula coefficient changes from 1/48 to 1/3. Misidentifying the support condition is the most frequent input error.
ACI 318-19 Section 24.2.4 requires that total deflection (including long-term creep) be compared to the L/240 or L/480 limit. The creep multiplier ranges from 1.2 to 2.0 depending on the compression reinforcement ratio. Checking elastic deflection alone against L/240 is not code-compliant for concrete.
Design tip: For steel floor beams, the AISC recommends pre-setting camber equal to 75% of the calculated dead-load deflection on beams longer than 20 ft (AISC Code of Standard Practice, Section 6.1). Use the camber field in Advanced Options to see the net deflection under live load only.
Frequently Asked Questions
Per IBC 2024 Table 1604.3, the live-load deflection limit for a 20 ft floor beam is L/360 = (20 × 12) / 360 = 0.667 inches. The total-load limit is L/240 = 1.000 inch. If the beam supports a brittle finish such as ceramic tile, the live-load limit tightens to L/480 = 0.500 inches.
A fixed-fixed beam is 4 times stiffer than a simply supported beam under a center point load. The simply supported formula is PL³/(48EI) while the fixed-fixed formula is PL³/(192EI). For a uniformly distributed load, the fixed-fixed beam is also 4 times stiffer. This is why fixing a beam at both ends dramatically reduces midspan deflection.
Yes. For a rectangular section, moment of inertia I = bh³/12. Depth (h) appears cubed, so doubling depth increases I by a factor of 8. Doubling width only doubles I. For this reason, deep narrow beams are far more efficient at controlling deflection than shallow wide beams of the same cross-sectional area.
Per ACI 318-19 Section 19.2.2.1, Ec = 57,000 × √f'c for normal-weight concrete (approximately 145 pcf). For f'c = 4,000 psi: Ec = 57,000 × √4,000 = 57,000 × 63.25 = 3,605,000 psi (3,605 ksi). This is about 8 times lower than structural steel's 29,000 ksi, which is why concrete beams require larger sections for equivalent stiffness.
Camber is an intentional upward bow built into a beam to counteract anticipated dead-load deflection. Per AISC Code of Standard Practice Section 6.1, minimum camber is 75% of the calculated dead-load deflection for beams longer than 20 ft. After dead loads are applied, the beam deflects to near-flat, and the remaining deflection budget is then available for live load. Camber does not increase stiffness; it shifts the deflection baseline upward.
This calculator covers single-span beams: simply supported, cantilever, and fixed-fixed. Multi-span continuous beams require more complex analysis involving compatibility equations or the three-moment theorem. As a conservative estimate, treat each span as simply supported and add 15-20% for continuity effects. For multi-span concrete beams, ACI 318-19 permits using the gross section Ig with span length L taken as the center-to-center distance of supports.
For an eccentric point load at distance 'a' from the left support on a simply supported beam, the maximum deflection is Pa²b² / (3EIL) where b = L - a (per AISC Table 3-22a). The maximum deflection occurs at x = √((L² - b²)/3) from the left support when a > b. Select "Point Load — Any Position" and enter the distance from the left support to use this formula.
Sources and Methodology
- AISC Steel Construction Manual, 16th Edition (2022) — Table 3-22 (beam diagrams and formulas), Table 1-1 (W-shape section properties). aisc.org/manual
- ACI 318-19 — Building Code Requirements for Structural Concrete — Section 19.2.2.1 (modulus of elasticity for concrete), Section 24.2 (deflection calculations and limits). concrete.org
- IBC 2024 — International Building Code — Table 1604.3 (allowable deflection of structural members). iccsafe.org
- Roark's Formulas for Stress and Strain, 8th Edition (2012) — Table 8.1 (cantilever beams), Table 8.2 (fixed-fixed beams). Warren Young, Richard Budynas, Ali Sadegh.
- NDS 2018 — National Design Specification for Wood Construction — Supplement Table 4A/4B (reference design values for sawn lumber). awc.org
- AISC Code of Standard Practice for Steel Buildings and Bridges, 10th Edition (2022) — Section 6.1 (camber requirements). aisc.org
Last reviewed: May 2026. Built by Muhammad Ramzan Babar, physics researcher (PhD candidate). Reviewed by site author.
⚠ Engineering Disclaimer
This calculator provides estimates for planning purposes. For permitted structural work, foundations, multi-story construction, retaining walls over 4 feet, and commercial projects, calculations must be verified by a licensed structural engineer per IBC 2024 Section 1604. ConcreteCalculate.com is not liable for structural decisions made from these estimates.
Concrete beam deflection results do not account for long-term creep per ACI 318-19 Section 24.2.4. Multiply calculated deflection by the ACI creep factor (1.2 to 2.0) for total long-term deflection.
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