Beam Deflection Calculator

Professional structural engineering calculator for beam deflection, stress, and moment analysis. Support for multiple beam types, materials, and loading conditions with safety verification.

Deflection Analysis

Stress Calculation

Moment Analysis

Safety Factors

Multiple Materials

Beam Types

Beam Deflection Calculator

Professional structural engineering calculator for beam deflection, stress, and moment analysis

⚠️ STRUCTURAL ENGINEERING WARNING: This calculator provides theoretical structural analysis for educational and preliminary design purposes. For actual construction and safety-critical applications, always consult licensed structural engineers and follow applicable building codes and standards.

Beam Configuration

Beam Type

Load Type

Material

Cross Section

Support: Beam supported at both ends, free to rotate
Formula: δ = (P×L³)/(48×E×I) for point load at center

Dimensions

Beam Length

Overall beam length

Width

Cross-section width

Height

Cross-section height

Material: Structural Steel S275
E: 200 GPa
fy: 275 MPa
Density: 7850 kg/m³

Loading Conditions

Point Load

Concentrated load magnitude

Load Position

Distance from left support (default: center)

Load Type: Point Load
Formula: P (kN) at distance a from left support

Structural Formulas

Essential beam deflection formulas for different support conditions and loading types.

δ = (P × L³) / (48 × E × I)

Variables:

δ = Maximum deflection (mm)
P = Point load (N)
L = Beam length (mm)
E = Elastic modulus (MPa)
I = Moment of inertia (mm⁴)

Applications:

Floor beams

Bridge girders

Simple structures

δ = (5 × w × L⁴) / (384 × E × I)

Variables:

δ = Maximum deflection (mm)
w = Distributed load (N/mm)
L = Beam length (mm)
E = Elastic modulus (MPa)
I = Moment of inertia (mm⁴)

Applications:

Floor joists

Roof beams

Storage loads

δ = (P × L³) / (3 × E × I)

Variables:

δ = Maximum deflection (mm)
P = Point load (N)
L = Beam length (mm)
E = Elastic modulus (MPa)
I = Moment of inertia (mm⁴)

Applications:

Balconies

Overhangs

Crane arms

δ = (P × L³) / (192 × E × I)

Variables:

δ = Maximum deflection (mm)
P = Point load (N)
L = Beam length (mm)
E = Elastic modulus (MPa)
I = Moment of inertia (mm⁴)

Applications:

Continuous beams

Portal frames

Rigid structures

Beam Types

Different beam support conditions and their structural characteristics.

Characteristics:

Pin support at one end
Roller support at other end
No moment restraint at supports
Statically determinate

Applications:

Building floor beams

Bridge girders

Roof purlins

Simple span structures

Key Formulas:

Moment: M_max = P×L/4 (point load at center)

Deflection: δ_max = P×L³/(48×E×I) (point load at center)

Characteristics:

Fixed support at one end
Free end
Moment restraint at fixed end
Statically determinate

Applications:

Balconies

Building overhangs

Crane structures

Diving boards

Key Formulas:

Moment: M_max = P×L (point load at free end)

Deflection: δ_max = P×L³/(3×E×I) (point load at free end)

Characteristics:

Fixed supports at both ends
No rotation at supports
Moment restraint at both ends
Statically indeterminate

Applications:

Continuous structures

Portal frame beams

Rigid connections

High precision applications

Key Formulas:

Moment: M_max = P×L/8 (point load at center)

Deflection: δ_max = P×L³/(192×E×I) (point load at center)

Characteristics:

Fixed support at one end
Pin/roller support at other end
Statically indeterminate
One degree of redundancy

Applications:

RC slabs

Composite construction

Pre-stressed beams

Bridge construction

Key Formulas:

Moment: Variable (depends on support conditions)

Deflection: Reduced compared to simple cantilever

Characteristics:

Multiple supports
Continuous over intermediate supports
Highly indeterminate
Moment redistribution

Applications:

Multi-span bridges

Building frames

Industrial structures

Long span applications

Key Formulas:

Moment: Negative moments at supports, positive in spans

Deflection: Significantly reduced due to continuity

Material Properties

Mechanical properties of common structural materials used in beam design.

S275 (Mild Steel)

E	200 GPa
fy	275 MPa
fu	430 MPa
ρ	7850 kg/m³

Applications:

General construction

Building frames

Bridges

Characteristics:

Good weldability
Moderate strength
Cost effective

S355 (High Strength Steel)

E	200 GPa
fy	355 MPa
fu	510 MPa
ρ	7850 kg/m³

Applications:

Heavy construction

High-rise buildings

Long span bridges

Characteristics:

High strength
Good toughness
Excellent weldability

S420 (Very High Strength)

E	200 GPa
fy	420 MPa
fu	550 MPa
ρ	7850 kg/m³

Applications:

Specialized structures

High stress applications

Weight critical designs

Characteristics:

Very high strength
Special welding requirements
Expensive

C25/30 (Standard Grade)

E	31 GPa
fy	25 MPa (compression)
fu	30 MPa
ρ	2400 kg/m³

Applications:

Building construction

Foundations

General structures

Characteristics:

Standard grade
Good workability
Cost effective

C40/50 (High Strength)

E	35 GPa
fy	40 MPa (compression)
fu	50 MPa
ρ	2400 kg/m³

Applications:

High-rise buildings

Bridges

Pre-stressed structures

Characteristics:

High strength
Good durability
Requires quality control

C60/75 (Very High Strength)

E	39 GPa
fy	60 MPa (compression)
fu	75 MPa
ρ	2500 kg/m³

Applications:

Specialized structures

Long span bridges

High-rise cores

Characteristics:

Very high strength
Special mix design
Expensive

C24 (Softwood)

E	11 GPa
fy	24 MPa
fu	40 MPa
ρ	420 kg/m³

Applications:

Residential construction

Roof structures

Floor joists

Characteristics:

Sustainable
Good strength-to-weight
Easy to work

GL32h (Glulam)

E	13.6 GPa
fy	32 MPa
fu	32 MPa
ρ	410 kg/m³

Applications:

Large span structures

Arches

Portal frames

Characteristics:

Engineered timber
Consistent properties
Large sizes available

LVL (Laminated Veneer)

E	14 GPa
fy	35 MPa
fu	44 MPa
ρ	500 kg/m³

Applications:

Structural beams

Headers

Rim boards

Characteristics:

High strength
Dimensional stability
Consistent quality

Deflection Limits

Standard deflection limits for different structural applications and building types.

Application	Limit	Description
General Building Beams	L/250	Standard deflection limit for building beams under service loads Reasoning: Prevents damage to finishes, partitions, and provides acceptable visual appearance
Floors Supporting Partitions	L/350	Stricter limit for floors supporting non-structural partitions Reasoning: Prevents cracking of partitions and finishing materials
Roofs (General)	L/200	Deflection limit for roof beams under service loads Reasoning: Prevents ponding, drainage issues, and damage to roofing materials
Cantilevers	L/125	More relaxed limit for cantilever structures Reasoning: Cantilevers naturally have higher deflections, limit prevents excessive sag
Industrial Floors	L/300 to L/500	Stringent limits for industrial applications Reasoning: Precision requirements for machinery, equipment operation
Bridges	L/300 to L/1000	Variable limits based on bridge type and usage Reasoning: User comfort, dynamic effects, fatigue considerations

Load Types

Different types of loads considered in structural beam design and analysis.

Examples:

Self-weight of structure
Fixed equipment
Architectural finishes
MEP systems

Typical Values:

Concrete slab (150mm): 3.6 kN/m²
Steel beam (UB 305×165×40): 0.39 kN/m
Masonry wall (200mm): 4.0 kN/m²
Roofing materials: 0.5-1.5 kN/m²

Design Considerations:

Calculate based on actual dimensions
Include all permanent fixtures
Account for construction tolerances

Examples:

People
Furniture
Equipment
Storage materials

Typical Values:

Residential floors: 1.5-2.0 kN/m²
Office floors: 2.5-3.0 kN/m²
Retail floors: 4.0 kN/m²
Industrial floors: 5.0-15.0 kN/m²

Design Considerations:

Follow local building codes
Consider actual usage patterns
Account for dynamic effects

Examples:

Lateral pressure on walls
Uplift on roofs
Dynamic effects

Typical Values:

Basic wind speed: 26-50 m/s
Wind pressure: 0.6-2.0 kN/m²
Exposure categories: Urban, Rural, Coastal

Design Considerations:

Site wind conditions
Building height and shape
Dynamic amplification factors

Examples:

Uniform snow load
Drift loads
Sliding snow
Ice dams

Typical Values:

Ground snow load: 0.5-4.0 kN/m²
Roof snow load: 0.7×ground load
Drift surcharge: Variable

Design Considerations:

Local climate conditions
Roof geometry and slope
Heat loss effects

Examples:

Base shear
Story forces
Overturning moments

Typical Values:

Seismic zone factors: 0.1-0.4
Structural response factors: 1.5-8.0
Site coefficients: 1.0-2.0

Design Considerations:

Local seismic hazard
Soil conditions
Structural system type

Design Considerations

Key engineering considerations for safe and efficient beam design.

Serviceability Limit States

Limits related to normal use and occupant comfort

Key Criteria:

Deflection limits (visual and functional)
Vibration limits (human comfort)
Crack width control (reinforced concrete)
Durability requirements

Importance: Critical for user acceptance and long-term performance

Ultimate Limit States

Limits related to structural safety and collapse prevention

Key Criteria:

Flexural strength (bending capacity)
Shear strength (shear failure)
Lateral-torsional buckling (steel beams)
Overall stability

Importance: Essential for life safety and structural integrity

Load Combinations

Various combinations of loads for design verification

Key Criteria:

1.35×Dead + 1.5×Live (Ultimate)
1.0×Dead + 1.0×Live (Serviceability)
Wind and seismic combinations
Construction stage loading

Importance: Ensures structure can handle all possible loading scenarios

Material Safety Factors

Factors accounting for material variability and uncertainties

Key Criteria:

Steel: γm = 1.0-1.1 (yield), 1.25 (ultimate)
Concrete: γm = 1.5 (compression), 1.15 (reinforcement)
Timber: γm = 1.3 (strength), 1.0 (stiffness)
Connection factors: 1.25-2.0

Importance: Provides adequate safety margin for material variations

Calculator Features

Deflection Analysis

Accurate deflection calculations with serviceability limit verification and deflection ratios.

Stress Analysis

Complete stress analysis with safety factors and allowable stress verification.

Moment Analysis

Maximum moment and shear calculations for different loading and support conditions.

Material Database

Comprehensive material properties for steel, concrete, and timber structures.

Loading Conditions

Support for point loads, distributed loads, and various loading configurations.

Safety Analysis

Comprehensive safety factor analysis and structural integrity assessment.

Beam Types

Multiple beam configurations including simply supported, cantilever, and fixed beams.

Educational Content

Comprehensive structural engineering education with formulas, examples, and design guides.

Structural Engineering Disclaimer: This beam deflection calculator provides theoretical structural analysis for educational and preliminary design purposes. For actual construction projects, safety-critical applications, and building permit submissions, always consult licensed structural engineers and follow applicable building codes, standards, and regulations. The calculated values are approximations and actual structural behavior may vary based on construction conditions, material properties, connection details, and environmental factors. Professional engineering judgment is required for all structural design decisions.

Dimensions

Loading Conditions

Simply Supported Beam - Point Load at Center

δ = (P × L³) / (48 × E × I)

Simply Supported Beam - Distributed LoadMaximum deflection for uniformly distributed load

Simply Supported Beam - Distributed Load

δ = (5 × w × L⁴) / (384 × E × I)

Cantilever Beam - Point Load at Free EndMaximum deflection for cantilever with end load

Cantilever Beam - Point Load at Free End

δ = (P × L³) / (3 × E × I)

Fixed-Fixed Beam - Point Load at CenterMaximum deflection for fixed ends beam

Fixed-Fixed Beam - Point Load at Center

δ = (P × L³) / (192 × E × I)

Beam Types

Simply Supported BeamBeam resting on two supports with freedom to rotate

Simply Supported Beam

Cantilever BeamBeam fixed at one end and free at the other

Cantilever Beam

Fixed-Fixed BeamBeam with both ends fully restrained against rotation and translation

Fixed-Fixed Beam

Propped CantileverCantilever beam with additional support at the free end

Propped Cantilever

Continuous BeamBeam extending over multiple supports with continuous connection

Continuous Beam

Material Properties

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Structural Steel

S275 (Mild Steel)

S355 (High Strength Steel)

S420 (Very High Strength)

Concrete

Concrete

C25/30 (Standard Grade)

C40/50 (High Strength)

C60/75 (Very High Strength)

Timber

Timber

C24 (Softwood)

GL32h (Glulam)

LVL (Laminated Veneer)

Deflection Limits

Load Types

Dead LoadsPermanent loads that remain constant throughout the life of the structure

Dead Loads

Live LoadsVariable loads due to occupancy and use of the structure

Live Loads

Wind LoadsLoads caused by wind pressure and suction on the structure

Wind Loads

Snow LoadsLoads due to accumulation of snow on roof surfaces

Snow Loads

Seismic LoadsLoads due to earthquake ground motion and structural response

Seismic Loads

Design Considerations

Serviceability Limit States

Ultimate Limit States

Load Combinations

Material Safety Factors

Calculator Features

Deflection Analysis

Stress Analysis

Moment Analysis

Material Database

Loading Conditions

Safety Analysis

Beam Types

Educational Content