Culvert inlet vs outlet control: a 48-inch CMP crossing under a county road in Wake County, NC
County maintenance wants to replace a failing crossline before the next subdivision upstream comes online. The question is not just "will the pipe carry 110 cfs?" but whether inlet or outlet control governs — because that sets headwater over the road and whether you need a better entrance or a larger pipe. This walks both HDS-5 checks for a 48-inch CMP with a square-edged headwall.
Crossing inputs
| Parameter | Value | Source |
|---|---|---|
| Pipe | 48-in CMP, n = 0.024 | Existing / proposed standard |
| Length, L | 120 ft | Roadway width + embankment |
| Slope, So | 0.020 (2%) | Profile |
| Entrance | Type III — square edge with headwall | HDS-5 Chart 8 |
| Design discharge, Q | 110 cfs | 10-yr peak from upstream TR-55 model |
| Tailwater, TW | 3.4 ft (TW/D = 0.85) | Downstream channel depth at Q |
| Barrel diameter, D | 4.0 ft | 48-in inside diameter |
Step 1 — Outlet control (barrel + tailwater)
Outlet control uses the barrel resistance and downstream tailwater. Manning full-flow capacity (check the pipe is not capacity-limited):
138 cfs > 110 cfs — the barrel can carry the design flow at normal depth. Headwater depth Ho (from HDS-5 outlet nomograph / equation form) with entrance loss ke = 0.5 and TW/D = 0.85:
At Q = 110 cfs, V = Q/A = 8.75 fps, friction slope ≈ So for full flow:
Step 2 — Inlet control (entrance geometry)
Inlet control sets headwater independent of barrel friction when the entrance chokes flow. HDS-5 Chart 8 for CMP, headwall, square edge (type III):
At Q = 110 cfs with Ku = 1.0 (US units), read HWi/D = 1.35 from the inlet nomograph:
Step 3 — Governing condition
| Control | HW/D | Headwater (ft) | Governs? |
|---|---|---|---|
| Outlet | 1.05 | 4.2 | No |
| Inlet | 1.35 | 5.4 | Yes |
Inlet control governs at 5.4 ft headwater. The county freeboard criterion is 1.0 ft below the road edge (crest elev. 742.0, allowable HW = 741.0). At 5.4 ft above invert (inv = 735.5), HW elev = 740.9 — barely passes. Any rounding or debris knockdown fails.
Step 4 — Fix options
| Option | Effect on inlet HW/D | New HW (ft) |
|---|---|---|
| Improve entrance to type I (beveled) | 1.35 → 1.15 | 4.6 |
| Upsize to 54-in CMP (same entrance) | 1.35 → 1.20 | 5.4 (D = 4.5 ft) |
| Lower tailwater (channel improvement) | Outlet may govern instead | Recalculate both |
Model the crossing inside the watershed
HydroComplete links the upstream hydrograph to the culvert rating, checks headwater across storm sizes, and keeps the conveyance network in the same project as runoff and detention.
Sources and further reading
- FHWA. HDS-5 Hydraulic Design of Highway Culverts. 3rd ed. — inlet and outlet control procedures.
- FHWA. HDS-4 Introduction to Highway Hydrology. Design discharge frequency for crosslines.
- NCDOT. Hydraulics Unit — standard entrance types and freeboard at county roads.
- USDA-NRCS. TR-55 — peak discharge feeding the crossing (referenced, not re-derived here).
— Michael Flynn, PE
Inlet/outlet nomographs in HDS-5 are chart-based; this example uses the equation forms consistent with PE-Calc's culvert tool and HydroComplete's Conveyance engine.
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