Beams: Shear and Serviceability

Beams: Shear and Serviceability

Learning Objectives

Distinguish between shear yielding and shear buckling.
Calculate nominal shear strength using web shear coefficients.
Check local web yielding and crippling.
Understand serviceability limits including deflection, ponding, and floor vibration.

A comprehensive lesson on analyzing and designing steel beams for shear capacity and ensuring they meet critical serviceability limits, including deflection, ponding, and floor vibration, in accordance with AISC standards.

Introduction

While flexure (bending moment) often governs the size of steel beams, they must also be explicitly checked for shear capacity and serviceability requirements. Shear failure can occur near supports or under heavy concentrated loads. Serviceability involves ensuring the beam performs well under everyday use without excessive deflection, vibration, or localized damage.

Shear Yielding

A ductile failure mode where the entire web cross-section yields plastically under shear forces.

Shear Buckling

An instability failure mode where a slender web buckles out-of-plane under shear forces before yielding can occur.

Shear Yielding vs. Shear Buckling

Shear Yielding: Occurs in compact, thick webs where the entire web cross-section reaches its shear yield stress ( $\tau_{yield} \approx 0.60 F_y$ ). The web deforms plastically in shear. This is the dominant failure mode for almost all standard rolled W-shapes.

Shear Buckling: Occurs in slender webs (like plate girders) before the material yields. The web buckles diagonally out-of-plane due to the principal compressive stresses induced by the shear force. Once buckled, the web's capacity to carry shear drops significantly unless tension field action (TFA) is permitted.

Nominal Shear Strength

Calculates the fundamental shear capacity of the section without Tension Field Action (AISC Chapter G).

V_n = 0.60 F_y A_w C_v

Variables

Symbol	Description	Unit
$F_y$	Specified minimum yield stress of the type of steel being used.	ksi or MPa
$A_w$	Area of the web (overall depth $d$ multiplied by web thickness $t_w$ ).	$in^2 or mm^2$
$C_v$	Web shear coefficient accounting for shear buckling.	-

Web Shear Coefficient ( $C_v$ )

A reduction factor that accounts for the transition from shear yielding to inelastic and elastic shear buckling as the web becomes more slender.

Web Shear Coefficient ( $C_v$ ) and Buckling Regimes

The value of $C_v$ heavily depends on the web's slenderness ratio ( $h/t_w$ , where $h$ is the clear distance between flanges). The web slenderness determines which buckling regime controls the shear capacity:

Yielding ( $C_v = 1.0$ ): Compact webs where the entire web yields before any out-of-plane buckling occurs.
Inelastic Buckling ( $C_v < 1.0$ ): Moderately slender webs where some yielding occurs, but buckling initiates before full plastic shear capacity is reached.
Elastic Buckling ( $C_v \ll 1.0$ ): Slender webs (like deep plate girders) that buckle completely elastically without reaching the shear yield stress.

For most standard rolled W-shapes, the webs are thick enough (compact) that $C_v = 1.0$ .

Cv for Unstiffened Webs (Yielding)

If $h/t_w \le 2.24\sqrt{E/F_y}$ , the web yields completely before buckling. Most standard W-shapes with $F_y \le 50$ ksi fall into this category.

C_v = 1.0

Variables

Symbol	Description	Unit
$C_v$	Web shear coefficient	-

Cv for Unstiffened Webs (Inelastic Shear Buckling)

If $2.24\sqrt{E/F_y} < h/t_w \le 1.10\sqrt{k_v E/F_y}$ , the web undergoes inelastic buckling.

C_v = \frac{1.10\sqrt{k_v E/F_y}}{h/t_w}

Variables

Symbol	Description	Unit
$k_v$	Web plate shear buckling coefficient ( $k_v = 5.34$ for unstiffened webs without transverse stiffeners)	-

Cv for Unstiffened Webs (Elastic Shear Buckling)

If $h/t_w > 1.10\sqrt{k_v E/F_y}$ , the web undergoes elastic buckling (common in deep plate girders).

C_v = \frac{1.51 k_v E}{(h/t_w)^2 F_y}

Variables

Symbol	Description	Unit
$k_v$	Web plate shear buckling coefficient	-

Resistance and Safety Factors for Shear

For standard W-shapes with $h/t_w \le 2.24\sqrt{E/F_y}$ (where $C_v = 1.0$ ), the LRFD resistance factor is $\phi_v = 1.00$ .

For all other webs (built-up sections, slender webs, channels, etc.), the LRFD resistance factor is $\phi_v = 0.90$ .

Bearing Stiffeners

Vertical steel plates welded to the web of a beam at locations of heavy concentrated loads or reactions to prevent local web yielding or crippling.

Concentrated Forces & Local Web Failures

When a beam is subjected to heavy concentrated loads (like a column bearing on the top flange) or at reaction points, the highly localized compressive force can crush or buckle the thin web beneath it. If the web fails these checks, bearing stiffeners must be added.

Local Web Yielding (Interior Load)

Occurs when the concentrated compressive load causes the web to yield at the flange-to-web junction. Formula for loads acting far from the member end (AISC J10.2).

R_n = F_{yw} t_w (5k + l_b)

Variables

Symbol	Description	Unit
$R_n$	Nominal strength for local web yielding	kips or N
	Web yield stress	ksi or MPa
$t_w$	Web thickness	in or mm
$k$	Distance from outer face of flange to the web toe of the fillet	in or mm
$l_b$	Length of bearing	in or mm

Local Web Yielding (Edge Load)

Formula for loads acting near the support (AISC J10.2).

R_n = F_{yw} t_w (2.5k + l_b)

Variables

Symbol	Description	Unit
$R_n$	Nominal strength for local web yielding near support	kips or N

Web Crippling

A local instability failure where the beam's web buckles like a short column under an intense concentrated compressive load.

Web Crippling (Interior Load)

Occurs when the web buckles locally under compression, treating the web like a short column (AISC J10.3).

R_n = 0.80 t_w^2 \left[ 1 + 3\left(\frac{l_b}{d}\right)\left(\frac{t_w}{t_f}\right)^{1.5} \right] \sqrt{\frac{E F_{yw} t_f}{t_w}}

Variables

Symbol	Description	Unit
$R_n$	Nominal strength for web crippling	kips or N
$d$	Overall beam depth	in or mm
$t_f$	Flange thickness	in or mm
$l_b$	Length of bearing	in or mm

Web Sidesway Buckling (AISC J10.4)

Occurs when the compression flange is restrained against rotation but the tension flange is not. If the beam is subjected to a heavy concentrated load, the entire web can buckle sideways.

The nominal capacity $R_n$ depends on the ratio of $h/t_w$ and the ratio of $L_b/b_f$ .

If the web fails this check, it must be braced laterally at the load point, or bearing stiffeners must be installed.

Serviceability: Deflection Limits

Serviceability limits ensure the structure remains functional, aesthetically pleasing, and comfortable for occupants during normal everyday use. Excessive deflection can crack plaster ceilings, misalign doors, or cause ponding.

Standard industry deflection limits depend on the application and the attached non-structural elements:

Live Load Only: $L/360$ (typical for floors supporting plaster ceilings to prevent cracking).
Total Load (Dead + Live): $L/240$ for typical floors.
Roof Members (Total Load): $L/180$ or $L/240$ depending on whether the roofing material is susceptible to damage.

Use Unfactored Service Loads

Crucially, service (unfactored) loads (e.g., $D, L, W$ ) are ALWAYS used for deflection calculations. Never use LRFD factored loads (like $1.2D + 1.6L$ ) when checking serviceability.

Uniformly Distributed Load Deflection

Calculates maximum deflection on a simply supported beam with a uniformly distributed load.

\Delta_{max} = \frac{5 w L^4}{384 E I}

Variables

Symbol	Description	Unit
	Maximum deflection	in or mm
$w$	Uniformly distributed load	kips/in or N/mm
$L$	Span length	in or mm
$E$	Modulus of elasticity	ksi or MPa
$I$	Moment of inertia about the axis of bending	$in^4 or mm^4$

Point Load Deflection

Calculates maximum deflection at midspan of a simply supported beam with a point load.

\Delta_{max} = \frac{P L^3}{48 E I}

Variables

Symbol	Description	Unit
	Maximum deflection	in or mm
$P$	Point load at midspan	kips or N
$L$	Span length	in or mm
$E$	Modulus of elasticity	ksi or MPa
$I$	Moment of inertia	$in^4 or mm^4$

Interactive Simulation

Use the interactive simulation below to explore beam deflection behavior under various loading conditions.

Beam Deflection Check

Uniform Load ($w$): 5.0 kips/ft

Span ($L$): 30 ft

Moment of Inertia ($I_x$): 510 in$^4$

\\Delta_{max}

Actual Deflection ( $\\Delta_{max}$ ):6.161 in
Allowable Deflection ($L/360$):1.000 in
Status: FAILS - Excessive Deflection

Ponding

A progressive instability on flat roofs where the deflection from water accumulation leads to further water accumulation until structural failure.

Ponding in Roof Systems

Flat roofs are uniquely susceptible to ponding, a progressive instability.

Prevention: The primary defense is providing adequate roof slope (minimum 1/4 inch per foot) and proper overflow drainage.

Design Check (AISC Appendix 2): The entire roof system must be explicitly checked for stiffness ( $C_p$ and $C_s$ ) to ensure the framing is stiff enough to resist the cascading weight of accumulated water.

Floor Vibrations (AISC Design Guide 11)

Long-span, lightweight steel floors can experience unacceptable vibrations caused by human activity.

Natural Frequency ( $f_n$ ): A natural frequency greater than 3 to 5 Hz is often recommended to avoid resonance with the walking excitation frequency ( $1.5 - 2.5$ Hz).

Solution: Increasing the stiffness (moment of inertia, $I$ ) of the floor beams and girders is the primary way to increase the natural frequency and reduce peak acceleration.

Torsional Behavior

Standard W-shapes perform exceptionally poorly when subjected to torsion because they are "open" sections.

Pure (St. Venant) Torsion: Resisted by shear stresses. Closed shapes (HSS) have massive torsional constants ( $J$ ) and are highly efficient. Open shapes (W-shapes) have tiny $J$ values.

Warping Torsion: When an open section twists, its cross-section distorts.

Design Rule: For significant torsion, HSS (Hollow Structural Sections) or box girders are strongly preferred over open I-shapes.

Key Takeaways

Beam shear capacity ( $V_n$ ) is primarily provided by the web area ( $d \times t_w$ ) and is reduced by the $C_v$ factor if the web is slender enough to buckle.
Most standard W-shapes have compact webs ( $h/t_w \le 2.24\sqrt{E/F_y}$ ) that fail by ductile shear yielding, allowing a shear coefficient $C_v = 1.0$ and a resistance factor $\phi_v = 1.00$ .
Heavy, concentrated point loads can cause local web yielding or brittle web crippling, which may necessitate bearing stiffeners.
Deflection calculations must always use service (unfactored) loads, not ultimate (factored LRFD) loads.
Open W-shapes are terrible at resisting torsion; closed HSS shapes should be used whenever significant twisting forces are present.

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Learning Objectives

Introduction

Shear Yielding

Shear Buckling

Shear Yielding vs. Shear Buckling

Nominal Shear Strength

Web Shear Coefficient (CvC_vCv​)

Web Shear Coefficient (CvC_vCv​) and Buckling Regimes

Cv for Unstiffened Webs (Yielding)

Cv for Unstiffened Webs (Inelastic Shear Buckling)

Cv for Unstiffened Webs (Elastic Shear Buckling)

Resistance and Safety Factors for Shear

Bearing Stiffeners

Concentrated Forces & Local Web Failures

Local Web Yielding (Interior Load)

Local Web Yielding (Edge Load)

Web Crippling

Web Crippling (Interior Load)

Web Sidesway Buckling (AISC J10.4)

Serviceability: Deflection Limits

Use Unfactored Service Loads

Uniformly Distributed Load Deflection

Point Load Deflection

Interactive Simulation

Beam Deflection Check

Ponding

Ponding in Roof Systems

Floor Vibrations (AISC Design Guide 11)

Torsional Behavior

Web Shear Coefficient ( $C_v$ )

Web Shear Coefficient ( $C_v$ ) and Buckling Regimes