Wall Footing (ACI 318-14)
Footing loads link to the wall above, so load changes propagate downstream automatically. Design continuous wall footings to ACI 318-14 (IBC 2018) - results cover ultimate load checks, bearing capacity verification, flexural reinforcement design, and serviceability.
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What it calculates
Footing loads link to the wall above, so load changes propagate downstream automatically. Design continuous wall footings to ACI 318-14. Results cover ultimate load, bearing capacity, and serviceability.
Code standards
- ACI 318-14
How it calculates
The Wall Footing (ACI 318-14) calculator designs continuous strip footings per ACI 318-14 (IBC 2018), using ASCE 7-16 load combinations. It checks bearing pressure under service loads, flexural reinforcement demand, one-way shear, and development length adequacy.
Bearing pressure check (ASD, ASCE 7-16, Ch. 2)
Service loads are combined using ASD load combinations to compute the gross soil bearing stress q_s across the footing width:
utilization = q_s / q_a ≤ 1.0
Stability checks for sliding (FS_s) and overturning (FS_ovt) are also reported. The calculator confirms the footing remains in total compression (resultant within the kern) under service loads.
Flexural design (ACI 318-14, Cl. 22.2)
Factored moment demand M_u is taken at the critical section (face of the wall) from the net upward bearing pressure under LRFD load combinations. Required reinforcement area is determined and compared to the provided area and minimum steel:
A_s,min = 0.002 × H × b (temperature and shrinkage reinforcement governs for most plain wall footings)
utilization = M_u / (phi × M_n) ≤ 1.0
One-way shear (ACI 318-14, Cl. 22.5)
The critical shear section is at distance d from the wall face. Plain concrete shear strength:
phi × V_n = phi × 2 × lambda × sqrt(f'c) × b × d
utilization = V_u / (phi × V_n) ≤ 1.0
No shear reinforcement is included. If shear demand exceeds capacity, the calculator checks whether a plain concrete design will satisfy the requirements.
Development length (ACI 318-14, Cl. 25.4)
Available development distance l_a = B/2 - b/2 - cover. Required development length l_d is calculated per ACI 318-14 and reduced for excess reinforcement area. If insufficient, the calculator automatically checks whether a plain concrete design passes.
Top reinforcement for negative bending
Where overturning moments generate tension at the top of the footing, top bar reinforcement is checked for negative bending capacity and development length per ACI 318-14 Cl. 22.2 and 25.4.
Assumptions
Wall is centred on the footing. Lateral loads are only used for sliding checks. No shear reinforcement is considered. Compression reinforcement is not included in bending calculations. Wall reinforcement is assumed to continue into the footing without splice checks at the interface.
What engineers say
Just the simple feature of being able to link loads is a really big time-saver.
Sam Hensler
Principal, Dynamic Analysis Engineering Consulting
The load linking feature is huge for us. Before, we had to use separate calculators and manually input everything.
John Cagle
Project Engineer, CHM Engineering
Frequently asked questions
What design standard does this calculator use?
What are the key inputs?
What does the calculator check and output?
When should I use the ACI 318-14 version versus the ACI 318-19 version?
Can I link wall loads directly from a wall or column calculation?
Does this calculator support load linking from walls above?
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