Free Steel Brace Frame Calculator — CBF/SCBF Design

Design concentrically braced frames (CBF) and special concentrically braced frames (SCBF) for seismic and wind loading. The calculator checks brace section compactness, slenderness limits, expected strength, gusset plate stability, and connection overstrength per AISC 341-22, AS 4100 Section 8, EN 1993-1-1, and CSA S16 Section 27.

Typical configurations: X-bracing, chevron (inverted V), single-diagonal, and two-story X-bracing. Brace sections are typically HSS, WT, double-angle, or wide-flange shapes.

How to Use

1. Select brace type (SCBF, OCBF, or wind-only frame).
2. Enter brace geometry: length, angle, section properties.
3. Define seismic parameters: R factor, overstrength factor Omega_o.
4. Calculate required brace strength and expected brace strength.
5. Check gusset plate: Whitmore section, block shear, yield line.
6. Verify connection overstrength meets AISC 341 requirements.

Design Code Requirements

Brace Slenderness Limits (AISC 341-22)

Design Guidance

Key Design Parameters

When performing structural steel design calculations, the following parameters govern the design:

• Material properties: Yield strength (Fy) and tensile strength (Fu) determine section capacity. For US projects, common grades include A992 (Fy=50 ksi) for W-shapes and A36 (Fy=36 ksi) for angles and plates.
• Design method: LRFD (Load and Resistance Factor Design) or ASD (Allowable Stress Design). LRFD applies load factors >1.0 and resistance factors <1.0 for consistent reliability across limit states.
• Load combinations: Per ASCE 7-22, the governing combination depends on the direction and magnitude of each load type. Typically 1.2D + 1.6L governs for gravity-dominated cases.
• Limit states: Strength (ultimate) and serviceability (deflection, vibration). Both must be checked per the applicable design code.
• Applicable codes: AISC 360-22 (US), EN 1993-1-1 (EU), AS 4100 (Australia), CSA S16 (Canada).

Design Procedure

1. Establish design criteria: code edition, material grade, design method (LRFD/ASD)
2. Determine loads and applicable load combinations
3. Analyze structure for internal forces (axial, shear, moment, torsion)
4. Check member strength for all applicable limit states
5. Verify serviceability criteria (deflection, drift, vibration)
6. Detail connections to transfer calculated forces

Worked Example

Problem: Design a structural element for the following conditions:

Span/Height: 15 ft | Load: 50 kips (factored) | Section: W12×65 (A992, Fy=50 ksi) | Code: AISC 360-22 LRFD

Solution:

• Demand: Pu = 50 kips (axial compression)
• Section properties: A = 19.1 in², rx = 5.28 in, ry = 3.02 in
• Slenderness: KL/r = 1.0 × 15 × 12 / 3.02 = 59.6 (controls about weak axis)
• Critical stress: Fcr per AISC Eq E3-2 (intermediate slenderness range)
• Design strength: φcPn = 0.9 × Fcr × Ag — Verify against applied load
• Interaction: Check combined forces per AISC Chapter H if applicable

Result: Section is adequate if φcPn ≥ Pu (50 kips).

Frequently Asked Questions

What design codes does this calculator support?

This calculator supports AISC 360-22 (US LRFD and ASD), EN 1993-1-1 (Eurocode 3), AS 4100 (Australia), and CSA S16 (Canada). Each code edition is verified against the respective design standard. Select your governing code in the calculator interface before entering loads.

How accurate are the results from this calculator?

Results are verified against published design examples and textbook solutions. The calculation engine uses the exact code provisions from the applicable standard. Always verify critical results independently and have designs reviewed by a licensed Professional Engineer. Results are preliminary until independently verified.

Can I save and export my calculations?

Registered users can save calculations to their account for later reference. Currently 10 calculations per hour and 50 per day are available on the free tier. Pro subscription ($19.99/month) increases limits to 500 calculations per month with PDF export capability.

Frequently Asked Questions

What is the difference between SCBF, OCBF, and ordinary braced frames? SCBF (Special Concentrically Braced Frame) has the strictest ductility requirements per AISC 341 — braces must be highly ductile sections with maximum slenderness kl/r = 200 and width-to-thickness ratios meeting highly ductile limits. OCBF (Ordinary CBF) permits moderately ductile sections with slightly relaxed limits. Wind-only braced frames have no seismic ductility requirements.

What is the Whitmore section for gusset plates? The Whitmore effective width is the width of the gusset plate that is effective in resisting the brace force, determined by projecting 30-degree lines from each side of the connection length. The Whitmore section is used to check gusset plate yielding and buckling. For standard gusset plates, the Whitmore width typically exceeds the actual plate width, so gross section yield governs.

What is expected brace strength (RyFyAg) and why is it used? Expected brace strength accounts for the fact that actual yield strength exceeds specified minimum yield. Ry is the ratio of expected yield to specified minimum yield (typically 1.1-1.3 for common steels). The connection must be designed for the expected strength (or 1.1RyFy*Ag for SCBF connections per AISC 341 Section F2.6) to ensure the brace yields before the connection fails.

Is this brace frame design calculator free? Yes, completely free with unlimited calculations.

Related pages

• Steel moment frame design
• Diagonal bracing design
• Column capacity calculator
• Steel frame analysis

Disclaimer (educational use only)

This page is provided for general technical information and educational use only. It does not constitute professional engineering advice. All structural designs must be verified by a licensed Professional Engineer (PE) or Structural Engineer (SE). The site operator disclaims liability for any loss or damage arising from the use of this page.