Choosing Coil Thickness for Structural Metal Deck

Works compositely with concrete

Choosing Coil Thickness for Structural Deck

Complete Engineering & Design Guide

1️⃣ Structural Deck Is Not Roofing

Structural metal deck:

• Supports concrete slabs

• Acts as permanent formwork

• Transfers shear forces

• Works compositely with concrete

• Carries construction loads

Thickness selection is governed by structural design — not preference.

Incorrect thickness can cause:

• Excessive deflection

• Concrete cracking

• Shear failure

• Construction collapse

This is serious structural territory.

2️⃣ Common Structural Deck Thicknesses

Typical base metal thickness (mm):

Thickness (mm)	Approx US Gauge	Typical Use
0.75 mm	22 ga	Light span
0.90 mm	20 ga	Medium span
1.00 mm	19 ga	Commercial
1.20 mm	18 ga	Heavy duty
1.50 mm	16 ga	Long span / high load

Always specify in mm or decimal inches — not just gauge.

3️⃣ Key Factors That Determine Thickness

Thickness is selected based on:

• ✔ Span length
• ✔ Superimposed load (kN/m²)
• ✔ Concrete slab thickness
• ✔ Construction stage loading
• ✔ Fire rating requirements
• ✔ Steel grade
• ✔ Vibration limits

Deck thickness cannot be chosen without load data.

4️⃣ Construction Stage vs Composite Stage

Structural deck must survive:

A) Construction Stage

• Wet concrete load

• Workers and equipment

• Temporary loads

• No composite action yet

This stage often governs thickness.

B) Composite Stage

• Hardened concrete works with steel deck

• Increased bending capacity

• Shear stud interaction

Composite strength depends on thickness and embossing pattern.

5️⃣ Thickness & Bending Capacity

Bending strength increases significantly with thickness.

Moment capacity ∝ thickness² (approximate behavior in cold-formed steel).

Small thickness increases dramatically raise strength.

Example:

0.90 mm → 1.20 mm
Strength increase is substantial.

6️⃣ Deflection Limits

Codes typically limit deflection to:

Span / 180
Span / 240

Construction stage deflection is critical.

Too thin deck may:

• Sag under wet concrete

• Create uneven slab thickness

• Cause ponding

Thickness must control deflection.

7️⃣ Composite Slab Design

When deck acts compositely:

Thickness affects:

• Shear capacity

• Embossment strength

• Stud shear transfer

• Slab stiffness

Thinner deck may reduce composite efficiency.

8️⃣ Fire Rating Impact

Thicker deck:

• ✔ Provides more thermal mass
• ✔ Improves fire performance
• ✔ Delays temperature rise

Some fire ratings require minimum thickness.

9️⃣ Vibration Performance

Thin deck:

• More prone to vibration

• Lower stiffness

• More noise transmission

Commercial office buildings often require stiffer deck.

🔟 Steel Grade Interaction

Common grades:

• G350

• G450

• G550

Higher grade increases strength without increasing thickness.

However:

Higher grade increases forming load and springback.

Thickness and grade must be balanced.

1️⃣1️⃣ Machine & Forming Considerations

Structural deck machines must handle:

• ✔ Heavy gauge
• ✔ Deep ribs (38mm, 50mm, 75mm etc.)
• ✔ High forming load
• ✔ Embossing pressure

Thicker steel increases:

• Motor torque

• Shaft stress

• Roll wear

• Hydraulic requirements

Machine designed for 0.75 mm may not handle 1.5 mm.

1️⃣2️⃣ Punching & Shear Effects

Structural deck may include:

• Side lap fastener holes

• Shear stud preparation

• Cut-to-length shear

Thicker steel requires:

• Higher cutting force
• Stronger shear blades
• More robust hydraulic system

1️⃣3️⃣ Typical Selection Guidelines (Generalized)

⚠ These are NOT design values — always engineer properly.

3–4 m span:

0.75 – 0.90 mm

4–5 m span:

0.90 – 1.20 mm

5–6 m span:

1.20 – 1.50 mm

Longer spans:
May require thicker or deeper deck profile.

Span and profile depth must be evaluated together.

1️⃣4️⃣ Developed Width & Thickness

Structural deck has many bends.

Increasing thickness:

• Increases bend allowance

• Slightly increases developed width

Blank width must be calculated per thickness range.

Especially important when tooling near machine face limit.

1️⃣5️⃣ Common Buyer Mistakes

• ❌ Choosing thickness based on roofing standards
• ❌ Ignoring construction stage load
• ❌ Ignoring deflection criteria
• ❌ Using gauge without checking mm
• ❌ Not checking machine capacity
• ❌ Assuming thicker always solves all structural problems

Deck depth + thickness + grade must be engineered together.

1️⃣6️⃣ Economic Optimization

Thicker deck:

• ✔ Higher material cost
• ✔ Higher freight cost
• ✔ Higher forming cost

But:

• ✔ Reduces deflection
• ✔ Improves safety margin
• ✔ Reduces construction risk

Optimal thickness is engineering-driven, not cost-driven alone.

1️⃣7️⃣ Engineering Summary

Coil thickness for structural deck affects:

• ✔ Bending capacity
• ✔ Deflection control
• ✔ Composite slab strength
• ✔ Fire rating
• ✔ Machine load
• ✔ Developed width

Structural deck thickness must be selected by:

Load + span + code + grade + construction stage requirements.

This is structural engineering — not roofing selection.

FAQ Section

Is 0.75 mm enough for structural deck?

For short spans only. Engineering verification required.

Does thicker deck increase composite strength?

Yes, but slab thickness and shear connection also matter.

Can roofing machines form structural deck?

Usually no. Structural deck machines are heavier duty.

Does thickness affect coil width?

Yes, slightly through bend allowance.

Is steel grade more important than thickness?

Both matter. Higher grade can reduce thickness requirement, but forming becomes harder.

Who should decide thickness?

Structural engineer based on load and code requirements.