------------- | -------- | -------- | ----- | ------ | | Bearing pressure | 4.08 MPa | 19.8 MPa | 0.21 | PASS | | Plate thickness | 14.9 mm | 16 mm | 0.93 | PASS | | Fillet weld | 500 kN | 1,075 kN | 0.47 | PASS |

Common Base Plate Size Reference

The table below gives typical starting-point dimensions for 200UC and 310UC sections under moderate axial loads. Always verify with the procedure above.

Column d (mm) bf (mm) Typical Plate (mm) Min t (Grade 350, ~400 kN)
200UC46.2 203 203 330 × 330 14 mm
200UC52.2 206 206 350 × 350 16 mm
200UC59.5 210 205 360 × 360 16 mm
310UC96.8 308 305 450 × 450 18 mm
310UC118 315 307 480 × 480 20 mm
310UC137 321 309 500 × 500 20 mm

Before You Start

Before designing a base plate per AS 4100, gather:

Common Pitfalls

  1. Using fy = 350 MPa for thick plates. AS/NZS 3678 Grade 350 has fy = 360 MPa for t <= 17 mm but only 340 MPa for 17 < t <= 40 mm and 330 MPa for 40 < t <= 80 mm. Using 350 MPa for a 25 mm plate is unconservative by about 3%.

  2. Forgetting the 0.80 bf and 0.95 d effective footprint. The cantilever projection is not measured from the column centreline. It is measured from an effective footprint that accounts for the column's ability to distribute load. Using the full column dimension overestimates the footprint and underestimates the cantilever, leading to an unconservative plate thickness.

  3. Omitting the confinement cap. The confinement factor sqrt(A2/A1) is capped at 2.0 per AS 3600. For a very large pedestal relative to the plate, the factor exceeds 2.0 but must be limited. Using the uncapped value overestimates the concrete bearing capacity.

  4. Ignoring the weld return at re-entrant corners. AS 4100 Section 9.6.3 requires a weld return of at least 2 x weld leg size at re-entrant corners. Omitting this causes stress concentrations and potential cracking at the flange-web junction.

  5. Using GP weld category for primary connections. SP category (phi = 0.80) requires NDT inspection but gives 33% more capacity than GP (phi = 0.60). For primary base plate connections, SP is standard practice. Using GP without realizing it reduces weld capacity significantly.

  6. Not checking all AS 1170 load combinations for uplift. A base plate may be in compression under the gravity combination but in tension under wind uplift (0.9G + Wu). The anchor bolt design must consider all combinations, not just the maximum compression case.

Code Comparison

Design Aspect AS 4100 / AS 3600 AISC 360 / ACI 318 EN 1993 / EN 1992-4 CSA S16 / CSA A23.3
Plate bending phi 0.90 0.90 gamma_M0 = 1.00 0.90
Bearing phi 0.65 (AS 3600 Cl 12.6) 0.65 (ACI 318 Sec 22.8) gamma_c = 1.50 0.65
Confinement factor sqrt(A2/A1) <= 2.0 sqrt(A2/A1) <= 2.0 sqrt(Ac0/Ac1) <= 3.0 sqrt(A2/A1) <= 2.0
Plate grade AS/NZS 3678 Grade 250/300/350 ASTM A36 (Fy = 36 ksi) or A572 S235, S275, S355 CSA G40.21 300W/350W
Weld phi 0.80 (SP), 0.60 (GP) 0.75 gamma_Mw = 1.25 0.67
Electrode E48XX (fuw = 480 MPa) E70XX (FEXX = 70 ksi / 482 MPa) Matched to base metal E49XX
Cantilever method 0.80 bf, 0.95 d effective footprint Thornton: m, n, lambda n' T-stub model per EN 1993-1-8 Similar to AISC Thornton
Anchorage code AS 5216 / AS 3600 Ch. 17 ACI 318 Chapter 17 EN 1992-4 CSA A23.3 Annex D
Min weld size (base plate) AS 4100 Table 9.7.3.2 AISC Table J2.4 EN 1090 execution standard CSA W59

Frequently Asked Questions

How do I size a base plate under AS 4100? Start with bearing pressure: set plate area A1 = N* / (φ × f'c × sqrt(A2/A1)), then work backward. A practical starting point is A1 ≈ N* / (0.5 × f'c) assuming no confinement benefit. Once plate dimensions B and D are set, check plate thickness from the cantilever bending formula tp ≥ n × sqrt(2 × fp / (φ × fy)), where n is the cantilever projection from the column face and φ = 0.9 for AS 4100.

What is the difference between the AISC and AS 4100 base plate method? Both use the same cantilever bending model. Key differences: AS 4100 uses φ = 0.9 for plate bending, weld φ = 0.8 (SP category) vs AISC φ = 0.75; plate grade AS/NZS 3678 Grade 350 gives fy = 360 MPa (thin plate) vs A36 fy = 250 MPa. The bearing capacity equations reference AS 3600 vs ACI 318 respectively, but both use the confinement factor sqrt(A2/A1).

What weld size connects a base plate to a column flange in AS 4100? A fillet weld to both column flanges is standard. Size from the weld capacity formula φvw = φ × 0.6 × fuw × tw, where fuw = 480 MPa for E48XX electrode and tw = 0.707 × weld leg size. Weld length = perimeter of both flanges. For lightly loaded columns, the minimum weld size per AS 4100 Table 9.7.3.2 governs (typically 6–8 mm for plates 10–25 mm thick).

When do anchor bolts carry tension in a base plate design? Anchor bolts carry tension when the factored axial load becomes net uplift (N* is tensile) or when moment causes net tension on one side of the plate. Under pure compression, anchor bolts only function as holding-down bolts during erection. AS 4100 combined with AS 3600 Chapter 17 governs anchor embedment, breakout capacity, and supplementary reinforcement requirements.

What concrete strength should I use for base plate bearing? Use the specified characteristic compressive strength f'c from the project specification. For pedestals supporting columns in industrial buildings, f'c = 25–32 MPa is common. Higher f'c reduces the required plate area and can reduce plate thickness. Apply the confinement factor sqrt(A2/A1) ≤ 2.0 only when the pedestal is significantly larger than the plate.

What is the minimum fillet weld size for a base plate to column flange connection per AS 4100? Per AS 4100 Table 9.7.3.2, the minimum fillet weld leg size depends on the thickness of the thicker part being joined. For plates 11–17 mm thick, the minimum is 5 mm; for 17–32 mm, the minimum is 6 mm; for over 32 mm, 8 mm. For a 16 mm base plate to a 200UC flange (tf = 12.5 mm), the governing thickness is 16 mm and the minimum weld is 5–6 mm. In practice, 8 mm SP-category welds are common for base plates to ensure adequate heat input for fusion at the thicker plate.

How does the cantilever projection formula differ between the flange and web directions for a UC section? For a UC section, the plate cantilevers beyond both the flange width and the web depth. The effective column footprint used in AS 4100 practice is 0.80 × bf in the flange direction and 0.95 × d_c in the web direction, giving cantilever projections n_f = (B - 0.80 × bf) / 2 and n_w = (D - 0.95 × d_c) / 2. For a 200UC52.2 with bf = d = 206 mm on a 350 × 350 mm plate, n_f = (350 - 164.8) / 2 = 92.6 mm and n_w = (350 - 195.7) / 2 = 77.2 mm — the flange direction governs. For wide shallow sections or plates that extend much further beyond the web, the web cantilever can govern instead.

Run This Calculation

→ Base Plate & Anchors Calculator — full AS 4100 design with bearing, plate bending, weld, and anchor bolt checks. Supports 200UC, 310UC, 250UC, WB, and custom sections.

→ Column Capacity Calculator — axial compression capacity check per AS 4100 with K-factor input.

→ Concrete Footing Calculator — pedestal and spread footing design per AS 3600.

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