What gage deck should I specify for a typical office floor?

For composite floor deck in an office building, 20 ga or 18 ga 1.5WR or 2WR deck is the most common choice. 20 ga is sufficient for spans up to 7-9 ft between beams, which is typical for 8-10 ft beam spacing in office layouts. 18 ga extends the unshored span to 9-11 ft and provides better embossment engagement for composite action. 16 ga is used for spans over 12 ft or heavy construction loads. The material cost difference between 20 ga and 18 ga is approximately $0.15-$0.25/ft^2.

Do I need to specify Vulcraft or can any manufacturer's deck be substituted?

The deck profile (depth, rib spacing, embossment pattern) is the functional specification, not the manufacturer name. Specifying Vulcraft 2WR or approved equal is standard practice. Equivalent profiles from other manufacturers: Verco W2 FormLok (similar depth but wider rib spacing), New Millennium HSB series, Canam P-3600 series. The key requirement is SDI certification — the manufacturer must follow SDI QA/QC standards. Always specify per SDI C-2017 rather than naming a specific manufacturer.

How do I account for deck orientation relative to the supporting beam?

Deck ribs perpendicular to the beam: shear stud capacity is reduced per AISC 360-22 Eq. I8-1 with a reduction factor that accounts for the deck profile. Typically one stud per rib is placed (stud spacing = rib spacing = 6-12 in.). Deck ribs parallel to the beam: studs can be placed at any spacing, but the concrete in the ribs is not effective for composite action. Perpendicular orientation is standard because it maximizes the composite beam's effective flange width. For parallel orientation, wider beam flanges are needed to accommodate studs in the flat portion of the deck.

What is the difference between Grade 33 and Grade 50 steel deck?

Grade 33 (Fy = 33 ksi) is standard for steel deck and meets the requirements of SDI standards for most applications. Grade 50 (Fy = 50 ksi) provides 50% more yield strength and is available for some profiles at 14 ga and thicker. However, Grade 50 deck is not always more economical because stiffness (E = 29,000 ksi regardless of grade) controls deflection for typical spans. Higher strength only helps where strength governs (short spans, heavy loads). For typical floor and roof spans, Grade 33 is sufficient and more available.

How are composite deck span tables used?

Composite deck span tables provide maximum unshored spans for deck-as-form during concrete placement. The tables are based on SDI C-2017 criteria: allowable stress of 0.6 Fy and deflection limit of L/180 or 3/4 in. maximum under wet concrete load. For example, 20 ga 1.5WR deck on a 3-span continuous condition can span 7'-6 in. under 50 psf construction live load. After concrete curing, the composite slab capacity is checked separately per AISC 360 Chapter I using shear studs. Always use the manufacturer's published span tables (Vulcraft, Verco) for the specific profile and gage.

Steel Deck Selection Guide — Vulcraft & Verco Types, SDI Standards

--------- | ----------- | ------------------- | ----------------------- | -------------------------- | | 1.5WR | 1-1/2 | 6 | 4 to 8 | Lowest (tightest profile) | | 2WR | 2 | 6 | 6 to 12 | Moderate | | 3WR | 3 | 6 | 10 to 20 | High (deepest profile) |

The WR suffix denotes "wide rib." Narrow rib (NR) profiles exist but are less common in composite construction because the narrower flute makes shear stud placement more constrained. Always verify the minimum flute width at the top for your specified stud diameter — AISC 360 Section I3.2c requires the stud diameter not exceed 2.5 times the deck flange thickness for studs welded through the deck.

Vulcraft Composite Deck Profiles

Vulcraft, a division of Nucor, supplies approximately 60% of US steel deck. Their composite deck product line uses VLI and VL designations with the 6 in. rib pitch standard.

1.5VLI (1-1/2 in. Deep, Type WR)

The 1.5VLI is the economy option for short-span conditions (4 to 8 ft). It minimizes concrete volume but limits unshored span capability.

Gage	Base Steel Thickness (in.)	Weight (psf)	Max Unshored Span (ft)	Section Modulus S_e (in.^3/ft)
22	0.0295	1.64	5.5	0.118
20	0.0358	1.99	6.5	0.150
18	0.0474	2.64	7.5	0.216
16	0.0598	3.35	8.0	0.286

Common application: Residential and light commercial floors with 5 to 7 ft beam spacing. The 1.5VLI at 20 gage handles the typical 45 psf construction live load at 6 ft spans.

2VLI (2 in. Deep, Type WR)

The 2VLI is the workhorse for office and institutional floors. It balances span capability, concrete volume, and fire rating.

Gage	Base Steel Thickness (in.)	Weight (psf)	Max Unshored Span (ft)	Section Modulus S_e (in.^3/ft)
22	0.0295	1.89	7.0	0.163
20	0.0358	2.30	8.5	0.209
18	0.0474	3.05	10.0	0.300
16	0.0598	3.87	11.5	0.397
14	0.0747	4.85	13.0	0.528

Common application: Office buildings with 8 to 10 ft beam spacing. The 2VLI at 20 gage handles 50 psf construction live load at 8 ft without shoring and supports 3-1/4 in. lightweight concrete (110 pcf) to achieve a 2-hour fire rating when combined with appropriate reinforcement.

3VLI (3 in. Deep, Type WR)

The 3VLI targets long-span conditions (over 12 ft) where minimizing the number of beams and girders provides floor layout flexibility. The deeper profile adds significant stiffness.

Gage	Base Steel Thickness (in.)	Weight (psf)	Max Unshored Span (ft)	Section Modulus S_e (in.^3/ft)
22	0.0295	2.27	9.0	0.250
20	0.0358	2.76	11.0	0.318
18	0.0474	3.66	13.5	0.452
16	0.0598	4.64	15.5	0.596
14	0.0747	5.82	18.0	0.792

Common application: Office buildings with 12 to 15 ft beam spacing, parking structures, and high-bay industrial floors. The 3VLI at 18 gage handles 50 psf construction live load at 12 ft without shoring.

Verco Deck Profiles

Verco (now part of Nucor via the Verco Decking division) offers the W2 and W3 FormLok profiles featuring a unique trapezoidal rib with embossments that provide mechanical interlock with the concrete slab. This interlock enhances composite action beyond what chemical bond alone provides.

W2 FormLok (2 in. Deep)

Gage	Base Steel Thickness (in.)	Weight (psf)	Max Unshored Span (ft)	I_d (in.^4/ft)
22	0.0295	1.94	7.5	0.206
20	0.0358	2.36	9.0	0.262
18	0.0474	3.13	10.5	0.372
16	0.0598	3.96	12.0	0.486

W3 FormLok (3 in. Deep)

Gage	Base Steel Thickness (in.)	Weight (psf)	Max Unshored Span (ft)	I_d (in.^4/ft)
20	0.0358	2.87	11.5	0.492
18	0.0474	3.81	14.0	0.685
16	0.0598	4.81	16.5	0.884

FormLok advantage: The embossed rib pattern provides horizontal shear transfer capacity (per SDI test data) that exceeds the AISC 360 Section I3.2c calculated values for plain deck. This can reduce the number of shear studs required for full composite action. Always use the manufacturer's published shear transfer values (from ICC-ES evaluation reports) rather than the generic AISC formulas when specifying FormLok.

Gage Selection Guidelines

Steel deck gage follows the Manufacturers' Standard Gage for uncoated sheet steel. The SDI Diaphragm Design Manual, 4th Edition provides section properties for each gage and profile combination.

Heavier Gage Uses

16 and 14 gage: High diaphragm shear demands (over 400 plf), concentrated loads from partitions or equipment, and construction loads exceeding 50 psf
18 gage: Typical office and commercial floors with 8 to 12 ft spans. The default for most projects
20 gage: Residential and light commercial where spans are 6 to 8 ft and loads are moderate
22 gage: Roof deck only — not recommended for composite floor deck where shear studs are welded through the deck, because the thin material may burn through during stud welding

Minimum Thickness for Shear Stud Welding

Per AWS D1.1 and AISC 360 Section I3.2c, the deck thickness must be sufficient to support through-deck stud welding without burn-through:

Minimum deck thickness for 3/4 in. dia. studs: 0.028 in. (22 gage)
Practical minimum for reliable welding: 20 gage (0.0358 in.)
For studs 7/8 in. diameter and larger: 18 gage minimum recommended

Construction Loads on Unshored Deck

Per AISC 360 Section I3.2c and SDI, the bare steel deck (before concrete placement) must support:

Dead load: Deck self-weight + wet concrete weight (typically 145 pcf normal weight or 110 pcf lightweight)
Construction live load: 20 psf uniform OR 150 lb concentrated over a 1 ft square area per OSHA 1926 Subpart R

The deck is typically analyzed as a continuous beam over the supporting steel with the span equal to the beam spacing. The deck manufacturer's load tables provide the maximum unshored span for each profile and gage, accounting for the SDI-specified deflection limit of L/180 or 3/4 in., whichever is smaller.

Construction Load Deflection Example

For a 2VLI 20 gage deck spanning 8 ft with 3-1/4 in. normal weight concrete (39 psf wet concrete + 2.3 psf deck = 41.3 psf dead load):

w_construction = 41.3 psf + 20 psf = 61.3 psf (per foot width)
M = w L^2 / 8 = 61.3 x 8^2 / 8 = 490 lb-ft/ft = 5,880 lb-in (per foot width)

For 2VLI 20 gage: I_d = 0.262 in.^4/ft, E = 29,000 ksi
delta = 5 w L^4 / (384 E I) = 5 x (61.3/12) x (96)^4 / (384 x 29,000 x 0.262)
delta = 5 x 5.11 x 84,934,656 / (384 x 29e6 x 0.262) = 2.17e9 / 2.917e9 = 0.74 in.

L/180 = 96/180 = 0.53 in. -> Deflection exceeds L/180. Shoring required.

This example illustrates why unshored construction spans are limited — deflection at the wet concrete stage often controls over strength. Shoring at mid-span reduces the effective span by half, reducing deflection to approximately 1/16 of the unshored value.

Diaphragm Shear Capacity

Steel deck, when attached to the supporting steel with puddle welds or screws, acts as a diaphragm transferring lateral loads to the vertical bracing system. The SDI Diaphragm Design Manual provides the nominal shear strength S_n (plf) for each deck profile, gage, attachment pattern, and span condition.

Typical Diaphragm Shear Values (2VLI 20 gage, 36/4 weld pattern)

Span (ft)	S_n (plf)	phi x S_n (plf)	Stiffness G' (kip/in.)
6	1,850	1,110	32
8	1,450	870	25
10	1,100	660	19
12	820	492	14

The 36/4 pattern means a weld at every flute (6 in. spacing) with a 3/4 in. dia. puddle weld plus four side-lap screws per span at the sheet sidelaps. For higher diaphragm demands, the 36/0 pattern (welds at every flute, no sidelap fasteners) provides approximately 60% of the 36/4 capacity.

Diaphragm selection note: The same deck that serves as composite formwork also provides the lateral diaphragm. The deck gage, profile, and attachment pattern must be checked for BOTH the construction condition (wet concrete) AND the final condition (lateral loads). A 20 gage deck that works for gravity may need to be upgraded to 18 gage for seismic diaphragm demands over 800 plf.

Profile Selection Decision Flow

When selecting a deck profile, answer these questions in order:

What is the beam spacing? Select the deck depth based on unshored span: under 7 ft to 1.5 in. deck, 7 to 11 ft to 2 in. deck, over 11 ft to 3 in. deck.
Is shoring acceptable? If the GC will allow shoring, a lighter gage may be used because the shoring reduces the effective span during concrete placement. Note that shoring adds cost and schedule time.
What is the required fire rating? 2-hour rated floors typically require a minimum of 3-1/4 in. slab thickness above the deck. The total slab depth = deck depth + concrete above deck. To minimize total structural depth, use a shallower deck (1.5 in. or 2 in.).
What is the diaphragm shear demand? In high-seismic regions (SDC D, E, F), diaphragm demands can reach 1,500+ plf. Check whether the default 36/4 attachment pattern provides sufficient capacity or if a heavier gage is needed.
Are shear studs welded through the deck? If yes, the deck thickness must support the stud welding process. 18 gage minimum for most reliable results.
Is roof deck or floor deck? Roof deck uses narrower-rib (NR) profiles for better insulation support. Floor deck uses wide-rib (WR) for stud placement. Do not use WR roof deck as composite floor deck — the rib geometry is not tested for composite action.

Worked Example — Office Building Floor Deck Selection

Given: 8-story office building, 10 ft beam spacing, 3-1/4 in. NWC slab, 2-hour fire rating, SDC C (moderate seismic), unshored construction preferred. Construction live load = 20 psf.

Step 1 — Span capability: 10 ft beam spacing requires 2 in. or 3 in. deck. Check 2VLI 20 gage first — max unshored span = 8.5 ft. Too short. Try 2VLI 18 gage — max unshored span = 10.0 ft. OK. Or 3VLI 20 gage — max unshored span = 11.0 ft. OK.

Step 2 — Concrete volume: 3-1/4 in. above 2VLI = total 5-1/4 in. Above 3VLI = total 6-1/4 in. The 2VLI saves 1 in. of slab depth per floor. Over 8 stories, that is 8 in. total building height savings. At 2 in. less concrete volume per square foot (17 psf), the 2VLI reduces seismic mass.

Step 3 — Diaphragm check: Assume wind shear of 450 plf at the floor diaphragm (wind-governed for SDC C). 2VLI 18 gage at 10 ft span with 36/4 pattern: phi S_n is approximately 580 plf which exceeds 450 plf. OK.

Step 4 — Fire rating: 2VLI with 3-1/4 in. NWC achieves 2-hour fire rating per UL assembly D902 with welded wire fabric 6x6 W2.9xW2.9 at the slab mid-depth. Verify with the specific UL design for the project.

Step 5 — Cost comparison: 2VLI 18 gage is approximately 3.05 psf deck weight + 39 psf NWC = 42 psf total. 3VLI 20 gage is 2.76 psf + 39 psf + additional 1 in. concrete (12 psf) = 54 psf. The 2VLI saves approximately 12 psf per floor or about 5-8% on the steel framing weight due to reduced seismic mass.

Selection: 2VLI 18 gage, 36/4 weld pattern. Unshored construction. UL D902 2-hour fire rated assembly.

Regional Standards Comparison

Parameter	US (SDI / AISI S100)	Canada (CSSBI / CSA S136)	Australia (AS 2327)	Europe (EN 1994-1-1)
Deck standard	SDI ANSI/SDI C-2017	CSSBI 10M	AS 2327.1	EN 1994-1-1 Section 9
Cold-formed steel	AISI S100-16	CSA S136-16	AS/NZS 4600	EN 1993-1-3
Composite design	AISC 360-22 I3	CSA S16:24 Cl. 17	AS 2327.2	EN 1994-1-1 Section 6.6
Diaphragm design	SDI DDM04	CSSBI B15	AS/NZS 4600 Section 3.3.7	EN 1993-1-3 Section 10
Stud welding	AWS D1.1 / AISC I3.2c	CSA W59	AS/NZS 1554.2	EN ISO 14555

Frequently Asked Questions

What is the difference between Vulcraft VLI and Verco FormLok decks? VLI (Vulcraft) uses a trapezoidal rib profile with re-entrant sidewalls that provide mechanical bond with the concrete. FormLok (Verco) uses embossments pressed into the rib sidewalls that create a positive mechanical interlock. Both function as composite deck, but FormLok's embossments typically provide higher horizontal shear transfer values — which can reduce the number of shear studs required for full composite action. Always use the manufacturer's ICC-ES report values, not generic AISC formulas, when specifying FormLok.

Can I use roof deck as composite floor deck? No. Roof deck (Type NR — narrow rib) has a different flute geometry designed for insulation support and roofing attachment. The narrow ribs do not provide adequate space for shear stud placement and the profile has not been tested for composite action per AISC 360 Section I3.2c. Use Type WR (wide rib) composite deck specifically listed in the SDI Composite Deck Design Handbook.

Why does my deck need to be thicker for unshored construction? During concrete placement, the bare steel deck must support the full wet concrete weight plus construction live load without excessive deflection. A thicker gage (lower gage number) increases the section modulus and moment of inertia of the deck profile, allowing longer unshored spans. If shoring is provided, the deck can be one or two gages lighter because the shoring reduces the effective span. The cost trade-off: thicker deck is a material cost increase of approximately $0.30-0.50 per square foot per gage increment vs. shoring which adds labor and schedule cost.

How do I calculate the number of shear studs for my deck? Per AISC 360-22 Section I3.2c, the nominal strength of a shear stud welded through steel deck is Qn = 0.5 x A_sc x sqrt(f'c x E_c) <= R_g x R_p x A_sc x Fu. The reduction factors R_g and R_p account for the deck profile and stud position within the rib. For a single stud per rib in a 2 in. deck perpendicular to the beam: R_g = 0.85, R_p = 0.75. These reductions are substantial — a 3/4 in. stud that provides 26.1 kip in a solid slab may only provide 16.6 kip through a 2 in. deck. Always check the manufacturer's ICC-ES report for tested values, which may be higher than the AISC generic formula.

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Educational use only. Verify against manufacturer load tables (Vulcraft, Verco) and SDI ANSI/SDI C-2017.

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