Insights & Updates

The structural engineer on a commercial new construction project is involved long before ground breaks and long after the concrete is poured. For developers, owners, and general contractors who haven’t worked with a structural PE from the beginning of a project, the scope of that involvement is often surprising. The engineer isn’t just drawing beams — they’re selecting a structural system, running lateral and gravity analysis, producing stamped construction documents, answering requests for information during construction, and signing off on the as-built work.

This guide walks through the full arc of commercial structural design — what happens at each phase, who the engineer coordinates with, and what owners should expect from a good PE firm on a ground-up commercial project. If you’re planning a new build and trying to understand where your structural engineering fees are going, this is the roadmap.

Why Commercial New Construction Always Involves a PE

Every commercial new construction project in the United States requires engineered structural design. The International Building Code (IBC), adopted with amendments in every state we work in — Georgia, Florida, South Carolina, North Carolina, and Tennessee — explicitly requires engineered design for commercial occupancies. There is no prescriptive path for commercial buildings the way there is for simple single-family homes under the IRC.

That means from day one, the project has an “engineer of record” — a licensed structural PE whose stamp will ultimately appear on the drawings submitted for permit. The engineer of record carries professional liability for the structural design and is responsible for confirming that the final built condition matches the stamped drawings. Nothing about commercial structural engineering is optional.

The corollary: if you’re planning a commercial project without a structural engineer engaged, you’re planning a project that won’t get permitted. Get the engineer involved early — during schematic design, not after the architect finishes drawings — and the rest of the project runs more smoothly.

The Commercial Structural Design Process

A typical commercial new construction project moves through five major phases. The structural engineer is involved in all of them.

Phase 1: Schematic Design (SD)

At schematic design, the project is an idea. The architect has sketched massing, floor plates, and basic organization. The structural engineer’s job at this phase is to:

• Select a structural system. Steel frame? Concrete frame? Precast? Wood-framed (for mid-rise)? Masonry bearing wall? The decision depends on span, height, occupancy, site conditions, budget, and schedule. Each system has tradeoffs.
• Evaluate site constraints. Soil conditions from the geotech report drive foundation selection. Shallow spread footings? Piles? Mat foundation? The engineer needs geotechnical data early or the design can’t progress.
• Rough the gravity and lateral systems. Even at SD, the engineer is running back-of-the-envelope analysis to confirm the system choice is viable and pricing the material quantities.
• Coordinate with architect. Architectural moves (column spacing, double-height spaces, cantilevers, overhangs) all have structural implications. Good SD coordination prevents expensive late changes.

Schematic design is often underestimated by owners. It’s the phase where the project’s structural DNA is set. Changes after SD become increasingly expensive as the design develops.

Phase 2: Design Development (DD)

Design development takes the SD concept and starts turning it into an engineered system. The structural PE:

• Runs full gravity analysis. Dead loads, live loads, snow loads, roof loads, equipment loads. Every beam, column, and slab is sized.
• Runs lateral analysis. Wind loads (especially critical in hurricane zones like Miami or Tampa) and seismic loads — per ASCE 7, the governing standard for structural loads. The engineer checks story drift, overturning, and base shear.
• Develops foundation design. Working with the geotechnical engineer, the structural PE sizes footings, pile caps, or mat foundations.
• Coordinates with MEP trades. Mechanical, electrical, and plumbing engineers need to know where beams and columns are. The structural engineer provides coordination drawings showing structural constraints for MEP routing.
• Produces preliminary structural drawings. By end of DD, there are framing plans, typical details, foundation plans, and a preliminary structural system described in enough detail for cost estimating.

DD is where the design starts to look like something buildable. It’s also where the engineer catches issues — beams that won’t fit, columns that conflict with architectural intent, foundations that need to grow to carry the load. Fixing these issues in DD is much cheaper than fixing them later.

Phase 3: Construction Documents (CD)

Construction documents are the deliverable the building department and contractor care about. CDs are the stamped, sealed drawings and specifications that a PE signs and that become the basis for permitting, bidding, and construction. At this phase, the structural engineer:

• Finalizes all framing plans. Every floor, every roof, every foundation — drawn at a scale the contractor can build from.
• Produces connection details. How does beam meet column? How does column meet footing? How does slab meet wall? Each connection is detailed and sized.
• Writes specifications. The structural spec describes concrete mix designs, steel grades, bolt specifications, welding requirements, testing and inspection requirements, and quality control.
• Coordinates with all disciplines. Architectural, MEP, civil — every drawing that touches structure has to match.
• Applies the PE stamp. The final drawings are signed and sealed. The engineer is now the engineer of record and is personally liable for the design.

A complete set of structural CDs for a mid-size commercial project typically runs 20–60+ sheets. For a complex building, it can exceed 150 sheets.

Phase 4: Permitting and Bidding

Once CDs are complete, the project goes through two parallel tracks:

• Permit review. The local building department (or third-party plan reviewer) reviews the structural drawings for code compliance. Reviewers may request clarifications, calculations, or modifications. The structural engineer responds to each review comment — either by revising drawings or by providing supporting documentation.
• Bidding. The general contractor bids the project based on the CDs. Bid questions routinely come back to the structural engineer (“Can this connection be simplified?” “Is this framing member really needed?” “Can we substitute this steel section?”) The engineer answers bid questions to keep the bid process moving.

This phase is often invisible to owners but can take weeks or months depending on the jurisdiction. Atlanta, Miami, Nashville, and Charlotte all have their own review timelines. Engineers who know the local reviewers tend to get faster approvals.

Phase 5: Construction Administration (CA)

Once the permit is issued and construction starts, the engineer’s role shifts to construction administration. CA is the phase where a lot of engineers get underpaid — it can take significantly more time than owners expect. The engineer:

• Responds to RFIs (Requests for Information). The contractor asks questions. A lot of questions. Most are minor clarifications; some require actual engineering work to answer.
• Reviews shop drawings. Steel fabricators, precast suppliers, rebar detailers, and other subcontractors produce shop drawings based on the CDs. The engineer reviews them for conformance.
• Observes construction in the field. Periodic site visits to confirm the work is being built to the drawings. Special inspections may be required under IBC for certain elements (bolting, welding, concrete).
• Issues supplemental sketches (SKs). When field conditions require design changes — and they always do — the engineer issues clarifications and revisions.
• Signs off on the completed structure. At the end, the engineer of record certifies that the structure was built in substantial conformance with the stamped drawings. Without that sign-off, you don’t get a certificate of occupancy.

CA on a commercial project typically runs the duration of construction — 6 to 18+ months depending on project size.

What a Good Structural Engineer Brings to a New Build

Experienced structural engineers bring value beyond just “drawing beams.” A few of the things a good PE firm adds to a commercial new construction project:

• System-level thinking. Picking the right structural system for the project type, site, and schedule is worth far more than cheaper member sizing.
• Constructibility. Designs that are elegant on paper but impossible to build cause change orders. A good engineer designs for the field.
• Code fluency. Knowing the local amendments and how reviewers interpret them prevents re-submittals.
• Coordination discipline. Catching conflicts with architectural and MEP in DD instead of in the field.
• Responsiveness during CA. Fast RFI response saves schedule, which saves money.

How to Engage a Structural Engineer for Commercial New Construction

If you’re planning a commercial new build, a few practical suggestions:

1. Engage early. Bring the structural engineer in during schematic design, not after the architect’s drawings are locked. Late structural engagement forces expensive rework.
2. Share the geotechnical report. Without geotech, the engineer is guessing on foundations. Commission the geotech early.
3. Clarify the scope. Is the structural fee for SD through CDs only, or does it include CA? CA is often billed separately and can be 15–30% of the base fee.
4. Confirm PE licensure in your state. Georgia is not Florida. A firm with multi-state licensure (Strut E&I is licensed in 28+ states) simplifies multi-state or regional projects.
5. Ask about construction observation frequency. More site visits cost more but catch more field issues. A good engineer will recommend an appropriate observation schedule.

Frequently Asked Questions

How long does structural design take on a commercial new build?
It depends heavily on project size and complexity. A small mid-size commercial building (two-story, 20,000 sq ft) may move from SD through CDs in two to four months. A larger or more complex building can take six months or more. Add permit review and bidding on top of that.

Who selects the structural system — the architect or the engineer?
Both, collaboratively. The architect starts with form and function; the engineer evaluates which structural systems work for that form and proposes tradeoffs. Good design is a dialogue. The final call usually comes down to cost, schedule, and constructibility.

What’s included in a structural engineering fee for new construction?
Typically: schematic design participation, design development calculations and drawings, construction documents (stamped), specifications, response to permit review comments, and some amount of construction administration. Confirm in writing what’s included — especially CA scope, which is often the biggest gray area.

Do I need a structural engineer during construction, or only during design?
Both. The engineer of record remains engaged during construction to answer RFIs, review shop drawings, perform field observations, and issue any necessary design clarifications. A new building cannot receive its certificate of occupancy without the engineer of record’s sign-off.

What if something doesn’t match the drawings in the field?
Field conditions rarely match drawings exactly. Small deviations are typical and handled via RFIs or supplemental sketches. Major deviations — missing connections, substituted materials, undersized members — require the engineer to review and either accept, reject, or require remediation.

Can one engineer handle a multi-state commercial project?
Only if they’re licensed in every state the project touches. Multi-state projects require PE licensure in each jurisdiction where the work is performed. Firms with broad multi-state coverage (like our 28-state footprint) avoid the delay and coordination cost of sub-consulting separate engineers per state.

What happens if the project budget comes in high after structural design is complete?
This is a common situation. The engineer can work with the team on value engineering — simplifying connections, reducing steel tonnage, switching systems, or rethinking spans. Value engineering after CDs is more expensive than designing efficiently from the start, which is why early structural engagement pays off.

Planning a commercial new build in the Southeast? Strut Engineering & Investment, Inc. provides structural design, construction documents, and construction administration for commercial projects across Georgia, Florida, the Carolinas, Tennessee, and beyond. Contact our team for a scoped proposal.