A stud wall looks like the simplest part of the framing, and that is exactly why it gets underspec'd on bad jobs. OBC Section 9.23.10 publishes a prescriptive table — a matrix of size, spacing, and load — that tells you the maximum unsupported height for each combination. Miss a row, ignore a footnote, and the wall still looks fine on the day it goes up. The problems show up months later when the basement wall bows or the second-storey gable racks in the first winter storm. Here is what is actually going on behind Table 9.23.10.1, from a Red Seal Carpenter who has built plenty of walls.
Studs are columns that also carry bending — wind pushes against them sideways while the roof and floors push down from above. Make them too tall or too slender and two things happen: first, they buckle (the column-failure mode that collapses a wall in one snap), and second, they deflect too much (the wall bows inward under wind load until drywall cracks, windows bind, or air seals fail). The code's deflection limit for stud walls is L/180 under wind load — a 3-m tall wall is permitted to bow 17 mm mid-height at design wind pressure. Taller walls need either more depth (bigger stud), tighter spacing (more studs sharing the load), or both. Table 9.23.10.1 encodes every permitted combination as a lookup so you do not have to run column-buckling math on a typical residential job. Once you exceed the table's heights, you leave prescriptive framing and the wall becomes an engineered element.
Ontario residential framing runs 2×4 exterior walls by default, with 2×6 used for deeper insulation cavities or where loads demand the extra depth. The depth difference is significant: a 38 × 89 mm (2×4) stud in a loadbearing exterior wall carrying roof-plus-one-floor tops out at 3.0 m at 16″ o.c., while a 38 × 140 mm (2×6) at the same spacing and load reaches 3.6 m. Insulation value tells the same story: a 2×4 cavity holds R-14 batt, a 2×6 cavity holds R-20 — and under current OBC energy performance paths, most new exterior walls land at 2×6 anyway just to make the envelope work. Cost is modest — 2×6 studs run roughly 30–40% more per piece, but the wall frames at the same speed and the deeper cavity pays back the material cost in heating savings within a decade. The only place a 2×4 exterior wall still makes clear sense is in an unheated accessory building or where the envelope is achieved with exterior rigid foam over a 2×4 cavity.
16″ on-centre is the residential standard because 4×8 plywood and OSB sheathing lands cleanly on 16″ layout — a stud every 16″, joists every 16″, and the sheet edges fall on the middle of every fourth stud with no cutting. Drywall layout matches. Electrical and plumbing rough-in are laid out around the same module. Go to 12″ o.c. when the wall is carrying heavy load (roof-plus-two-floors in a 3-storey), when the wall is unusually tall and you are pushing the table limits, or when you need extra sheathing nailing in a braced-wall panel. Go to 24″ o.c. for lightly loaded single-storey gables, non-loadbearing interior partitions, or advanced-framing 2×6 walls where stud alignment between floors lets you skip trimmers and cripples. Every combination is codified in Table 9.23.10.1 — check the table before you shift spacing, not after you have lumber on site.
Platform framing is how Ontario houses are built today — each storey is framed as a separate deck on top of the storey below, and studs are short (single-storey) columns. The Table 9.23.10.1 heights match that assumption: 2.4–4.2 m unsupported. Balloon framing — studs running continuously from foundation to roof eave, two-storey or more — is still permitted under OBC but rare in new work. Two things change: first, studs are much longer, which pushes you past the prescriptive table into engineered territory almost immediately (a 15-ft continuous stud exceeds every 2× size in Table 9.23.10.1). Second, OBC 9.10.16.2 fire-blocking becomes critical — a balloon-framed wall is a continuous vertical chimney for fire through the stud bays unless you fire-block at every floor line and every 3 m vertical. Gable ends on cathedral-ceiling rooms are the practical exception: they are one storey tall on the ground floor side and two storeys tall to the ridge, and the code treats them as balloon-framed. Those walls need the engineered sheathing-plus-blocking treatment under 9.23.10.1.(2) or a stamped design.
Anything over about 12 ft (3.6 m) of unsupported height usually steps outside prescriptive framing. OBC 9.23.10.1.(2) gives one escape hatch: 9.5 mm plywood/OSB sheathing outside plus 12.5 mm gypsum inside, solid bridging at ≤ 1.2 m o.c., three 82-mm toe nails stud-to-plate, 76-mm nails at 200 mm o.c. between double top plates, four 82-mm toe nails fastening roof framing every 600 mm max, and 82-mm nails at 200 mm o.c. through the bottom plate — then the wall can be sized from the engineered Span Tables 9.23.10.1.-A to -D. Beyond that scope — garage-door headers stacked on studs, engineered point loads, cathedral walls, or any wall over about 5 m (16 ft) — the wall goes to Part 4 under a stamped engineered design. Watch for it on two-storey gable ends, walk-out basement walls, and any wall with large window openings.
Out-of-plumb studs are the quiet one. A wall plumbed to the top plate but with studs bowed mid-height shows up in the drywall finish three months later. Sight every stud down the edge before firing sheathing nails — any stud with a 6 mm crown gets flipped (crown inside), cut in half, or kicked to a short-wall job. Missing fire-blocks are the inspection failure waiting to happen. OBC 9.10.16.2 requires fire blocks at the top and bottom of every stud cavity that passes through a floor or ceiling, and at any point where vertical runs exceed 3 m. Framers skip them on tall walls thinking the top plate counts — it does not if the wall continues past a dropped soffit. Cut studs near services is the common renovator mistake. OBC 9.23.6.2 caps notches in loadbearing studs at one-third of the stud depth (about 30 mm in a 2×4) and holes at one-third centrally drilled. Past that, sister the stud. Missing double top plates on loadbearing walls happens when a framer defaults to interior-partition assembly on what turned out to be a bearing wall — under 9.23.11.3, loadbearing walls need two staggered top plates, not one. Walk every interior wall at rough-in and confirm which are bearing before the top plates go on.