Valve Flow Calculator

Calculator inputs

Choose Known Cv for manufacturer data, or estimate using size and opening.

White theme • Responsive grid

Cv mode

Known Cv is best for accurate sizing.

Valve type

Used for estimation curve and multiplier.

Nominal size (in)

Planning sizes for common irrigation valves.

Opening (%)

100% means fully open.

Known Cv (if applicable)

Used only in Known Cv mode.

Pressure drop

Use expected valve pressure loss.

Specific gravity

Water is 1.00 at typical temperatures.

Parallel identical valves

Cv adds in parallel for identical runs.

Override base Cv (optional)

Use if you know a better base value.

Override exponent (optional)

Higher values throttle more at partial openings.

Pipe inner diameter (optional)

Adds velocity output for quick checks.

Reset

Formula used

This calculator uses standard Cv flow sizing for liquids.

For water-like liquids, valve flow is estimated using: Q = Cv × √(ΔP / SG)

Q = flow rate in gallons per minute (gpm)
Cv = valve flow coefficient (capacity)
ΔP = pressure drop across the valve (psi)
SG = specific gravity (water ≈ 1.00)

In Estimate Cv mode, the tool applies a planning Cv for the chosen size and a simple opening model: Cvₑff = Cv₍base₎ × multiplier × (opening)ᵉˣᵖ. Use manufacturer Cv/Kv data for final design.

How to use this calculator

A quick workflow for irrigation planning and troubleshooting.

Select Known Cv if you have valve data. Otherwise choose Estimate Cv.
Enter the expected pressure drop across the valve for your scenario.
Set opening if the valve is throttled, then calculate.
Optionally enter pipe inner diameter to view velocity.
Download CSV or PDF to share results with your plan.

Example data table

Sample scenarios for common garden irrigation setups.

Scenario	Valve	Opening	ΔP	SG	Estimated Flow
Drip zone manifold	1 in Ball	100%	3 psi	1.00	~104 gpm
Sprinkler mainline	1.5 in Gate	80%	5 psi	1.00	~264 gpm
Throttled balancing	2 in Butterfly	60%	8 psi	1.00	~238 gpm

Examples use planning Cv values and simple opening behavior. Real results vary by brand and trim.

Practical sizing for garden irrigation valves

Planning guidance aligned with the calculator outputs.

Why valve flow matters in irrigation design

Valve flow capacity influences zone performance, emitter uniformity, and cycle times. If a valve is undersized, pressure drop rises and downstream sprinklers or drippers may underperform. If it is oversized, throttling to “tune” flow can create unstable control and noisy operation. This calculator converts your pressure drop and Cv into comparable flow units so you can match a valve’s capacity to real garden demand.

Understanding Cv, pressure drop, and specific gravity

Cv is a standardized capacity value for liquids: higher Cv means more flow at the same pressure loss. Pressure drop (ΔP) is the energy lost through the valve, while specific gravity (SG) adjusts for liquids heavier or lighter than water. For most irrigation water, SG is close to 1.00, so ΔP is the primary driver. Small ΔP values can change noticeably with minor system adjustments, so use realistic pressure-loss estimates.

Using partial opening for throttled or balancing scenarios

Many installations partially close a valve to balance zones or protect misting lines. The calculator applies an opening-based effective Cv model to represent throttling behavior across common valve styles. Use it to compare “fully open” versus “partially open” cases, then choose a setting that preserves adequate downstream pressure and keeps velocities within a comfortable range.

Parallel valves and manifold planning

When identical valves feed parallel branches, their capacities add, increasing total flow potential. This is useful for manifolds that split irrigation zones or for redundancy. Enter the number of parallel valves to see combined flow. Confirm the piping and fittings can support the combined rate, because manifold losses can offset the gain.

Interpreting velocity to protect piping and emitters

Pipe velocity helps flag operational risk. High velocity can increase noise, wear, and water hammer sensitivity, while very low velocity may reduce flushing effectiveness in drip systems. If you provide pipe inner diameter, the calculator estimates velocity from the computed flow. Use this as a screening tool, then validate with full hydraulic calculations for long runs, elevation changes, and friction losses.

FAQs

Quick answers for common irrigation sizing questions.

1) Should I use Known Cv or Estimate Cv?

Use Known Cv when you have manufacturer data for the exact valve and trim. Estimate Cv is for early planning, quick comparisons, and troubleshooting when the precise Cv is unavailable.

2) What pressure drop should I enter?

Enter the expected loss across the valve at operating flow. If you are unsure, start with a small range (for example, 2–10 psi), compare outcomes, then refine using field readings or valve charts.

3) Why does specific gravity matter?

Specific gravity adjusts flow for liquids that are not water. Heavier liquids reduce flow for the same Cv and pressure drop. For typical irrigation water, SG is usually close to 1.00.

4) How accurate is the opening percentage model?

It is a planning approximation. Real valves differ by geometry, trim, and manufacturer. Use it to understand trends between openings, then confirm final settings with measured pressures and product performance curves.

5) How do parallel valves affect results?

For identical valves in parallel, total capacity increases because Cv effectively adds. The calculator multiplies flow by the number of parallel valves, but real systems may see less gain due to manifold and piping losses.

6) What velocity is “too high” for garden systems?

Many irrigation designers aim to avoid sustained high velocities to reduce noise and water hammer risk. If the velocity output is high, consider larger pipe, lower flow per zone, or a different valve strategy.