DrainageCalculators

Trench Drain Calculator

Calculate trench drain capacity using Manning's equation. Determines flow capacity, velocity, and grate interception efficiency for linear drainage systems.

What This Solves

Calculates the flow capacity and sizing for a surface trench drain (channel drain with grate) using open channel flow principles.

Best Used When

  • You need to size a surface-level linear drain for a parking lot, driveway, or loading dock
  • You are designing a channel drain with a grate to intercept sheet flow before it reaches a building or low area
  • You need to determine whether an existing trench drain has adequate capacity for the design flow

Do NOT Use When

Key Assumptions

  • Flow follows open channel hydraulics using Manning's equation
  • The channel has a uniform cross-section and slope along its length
  • Grate interception efficiency can be estimated from the open area ratio
  • Flow is steady and uniform (not rapidly changing)
  • The grate is clean and not clogged with debris

Input Quality Notes

Grate interception efficiency depends heavily on grate type and maintenance. Consider using a safety factor for clogging, especially in areas with leaves or other debris.

Size a linear trench (channel) drain for surface runoff. Enter the design flow and channel geometry to get the full-flow and grate-adjusted effective capacity from Manning's equation, plus normal depth, velocity and Froude number — so you can confirm the channel and grate convey the flow without surcharging.

Calculate Trench Drain Capacity

For educational purposes only. Not a substitute for professional engineering judgment.

Input Parameters

Design Requirements

cfs

Peak flow rate the trench drain must convey

ft

Total length of the trench drain

Channel Geometry

Cross-sectional shape of the trench

ft

Width at the bottom of the channel

ft

Total depth of the channel

Longitudinal slope (ft/ft or m/m)

Material & Grate

Material affects Manning's roughness coefficient

Grate type affects flow interception efficiency

Override default open area ratio (0-1, optional)

Trench Drain Design Overview

Trench drains (channel drains) are linear drainage systems used to collect and convey surface runoff from paved areas. They consist of a channel with a grate that intercepts sheet flow.

  • Channel Capacity - Calculated using Manning's equation for open channel flow
  • Grate Efficiency - Fraction of approaching flow intercepted by the grate
  • Normal Depth - Uniform flow depth that will develop for the design flow
  • Froude Number - Determines if flow is subcritical, critical, or supercritical

Manning's Roughness Coefficients

MaterialMin nTypical nMax n
Concrete0.0110.0130.015
Polymer Concrete0.0100.0120.014
Fiberglass0.0090.0110.013
HDPE0.0090.0110.012
Galvanized Steel0.0120.0140.016
Stainless Steel0.0110.0130.015
Cast Iron0.0120.0140.017

Source: FHWA HEC-22 (2009), Table 7-1

Grate Interception Efficiency

Grate TypeOpen AreaEfficiency Factor
Parallel Bar Grate70%90%
Reticuline Grate65%85%
Curved Vane Grate60%80%
Tilt Bar Grate55%75%
Slot Drain15%70%

Source: FHWA HEC-22 (2009), Chapter 4

How the trench drain calculation works

A trench drain is a prismatic open channel, so its capacity is governed by Manning's equation for uniform flow:

Q = (k / n) · A · R2/3 · S1/2

where:

  • Q = flow capacity (cfs, or m³/s in metric)
  • k = unit conversion factor = 1.486 for US customary units, 1.0 for SI/metric
  • n = Manning's roughness coefficient (depends on channel material — see table below)
  • A = cross-sectional flow area (ft² or m²)
  • R = hydraulic radius = A / P, where P is the wetted perimeter (ft or m)
  • S = longitudinal (channel) slope (ft/ft or m/m)

The geometry terms A and R depend on the channel shape. For a rectangular channel, A = b·y and P = b + 2y; for a trapezoidal channel, P = b + 2y√(1 + z²) with side slope z (H:V). The tool computes A, P and R at full depth, evaluates the full-flow capacity, then solves Manning's equation iteratively for the normal depth at your design flow.

Because a grate cannot intercept all of the approaching water, the usable effective capacity is the full-flow capacity reduced by the grate's interception efficiency:

Qeff = Qfull · Egrate, where Egrate = Aopen · fgrate

Aopen is the grate open-area ratio and fgrate is the interception efficiency factor for the grate type. Finally the Froude number, Fr = V / √(g · Dh) where Dh = A / T (hydraulic depth), classifies the flow as subcritical (Fr < 1), critical (Fr = 1) or supercritical (Fr > 1). The design is adequate when the effective capacity meets or exceeds the design flow and the normal depth stays below the channel depth.

Method: FHWA HEC-22 (2009), Eq. 7-1 & Chapter 4; Chow, Open-Channel Hydraulics (1959); ASCE MOP 77 (2006).

Grate interception efficiency by type

The effective capacity of a channel drain depends heavily on the grate. The table below gives typical open-area ratios and interception efficiency factors used by this calculator. Effective grate efficiency is their product (open area × efficiency factor), which is the fraction of full-flow capacity the grate can actually capture.

Grate type Typical open area Efficiency factor Effective efficiency
Parallel bar70%0.9063%
Reticuline65%0.8555%
Curved vane60%0.8048%
Tilt bar55%0.7541%
Slot drain15%0.7011%

Open-area ratios from manufacturer specifications; efficiency factors per FHWA HEC-22 (2009), Chapter 4. Bar grates intercept the most flow; slotted and narrow-opening grates the least. Values shown are typical defaults — enter a custom open area in the calculator to override.

Frequently asked questions

How is trench drain capacity calculated?

This calculator uses Manning's equation for open-channel flow, Q = (k/n) A R^(2/3) S^(1/2), to find the full-flow capacity of the channel, then multiplies that by a grate interception efficiency to get the effective capacity. It also solves iteratively for the normal (uniform-flow) depth at your design flow and reports the Froude number so you can see whether flow is subcritical or supercritical. The method follows FHWA HEC-22 (2009) and Chow's Open-Channel Hydraulics (1959).

Why is the effective capacity lower than the full-flow capacity?

A grate does not capture 100% of the water flowing toward it. The calculator reduces the channel's full-flow capacity by a grate efficiency equal to the grate's open-area ratio multiplied by an interception efficiency factor (E_grate = A_open x f_grate). For example, a parallel-bar grate with a 0.70 open area and a 0.90 efficiency factor gives an effective efficiency of about 0.63, so only ~63% of the theoretical channel capacity is usable. Bar-type grates intercept more than slotted or curved-vane grates.

What flow velocity should a trench drain have?

A common target is roughly 2 to 10 ft/s (about 0.6 to 3 m/s). Below about 2 ft/s, sediment and debris can settle out and clog the channel; above about 10 ft/s, the higher velocity can cause abrasion and erosion at the outlet and may overshoot the grate openings. The calculator flags the full-flow velocity when it falls outside this range.

What is the difference between a trench drain and a French drain?

A trench (channel) drain is a surface drain: a hard-walled linear channel with a grate, set flush with paving, that intercepts sheet flow and carries it away by gravity in open-channel flow. A French drain is a subsurface, perforated pipe in a gravel-filled trench that collects groundwater and infiltration. This calculator is for surface channel/trench drains; use it for paved areas, loading docks, pool decks, and plazas.

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Last verified: February 2026