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Minimum Flow Rate Calculator

Determine the required flow rate for heat transfer applications.

System Heat Load (BTU/hr)

Heat Transfer Fluid Pure Water 10% Propylene Glycol 20% Propylene Glycol 30% Propylene Glycol 50% Propylene Glycol 10% Ethylene Glycol 30% Ethylene Glycol 50% Ethylene Glycol

Supply Temperature (°F)

Return Temperature (°F)

Please check your inputs. Temperatures cannot be equal.

Temperature Differential (ΔT): –

Fluid Factor Used: –

Required Minimum Flow Rate: 0.0 GPM

Understanding Minimum Flow Rate in HVAC & Process Systems

Calculating the minimum flow rate is a critical step in designing hydronic systems, chillers, and boilers. This calculation ensures that the heat transfer fluid circulates with enough volume to effectively carry heat away from a source (cooling) or deliver heat to a destination (heating). If the flow rate is too low, the system may experience laminar flow, poor heat transfer efficiency, or equipment shutdown due to high-limit temperature trips.

The Universal Hydronic Formula

This calculator uses the fundamental thermodynamic equation for heat transfer in fluids. For the US Imperial system, the formula is simplified as follows:

GPM = Q / (k × ΔT)

GPM: Flow rate in Gallons Per Minute.
Q: Heat Load in BTU/hr (British Thermal Units per hour).
ΔT (Delta T): The temperature difference between the supply and return fluid in Fahrenheit (°F).
k: The fluid factor. For pure water, this is approximately 500. This constant is derived from: 8.33 lbs/gal (density) × 60 min/hr × 1.0 (specific heat).

Effect of Glycol on Flow Rate

It is crucial to adjust calculations when using anti-freeze solutions like Propylene or Ethylene Glycol. Glycol is more viscous and has a lower specific heat capacity than pure water. As the calculator demonstrates, adding glycol reduces the "Fluid Factor" (k). To transfer the same amount of heat (BTU/hr) with the same Delta T, a system using 50% Glycol requires a higher flow rate than a system using pure water.

Typical Design Delta T Values

When designing systems, different equipment requires different temperature differentials:

Standard Boilers: Typically designed for a 20°F ΔT.
Condensing Boilers: Often utilize wider differentials (30°F – 40°F) to promote condensation.
Chillers: Standard building chillers often operate on a 10°F to 12°F ΔT.

Why Minimum Flow Matters

Operating below the calculated minimum flow rate can lead to several issues:

Equipment Safety: Boilers may overheat, and chillers may freeze their evaporator bundles if flow is insufficient.
System Stability: Low flow can cause erratic control valve hunting.
Efficiency Loss: Without turbulent flow, heat transfer coefficients drop significantly.

Minimum Flow Rate Calculation