Chilled Water Pump Head Calculation May 2026

Abstract The proper sizing of chilled water pumps is critical for the efficiency, reliability, and cost-effectiveness of HVAC systems. This paper presents a systematic methodology for calculating the total pump head required in a closed-loop chilled water system. It covers fundamental fluid mechanics principles, component pressure drop analysis, safety factors, and practical considerations such as open vs. closed systems, variable flow, and common pitfalls. 1. Introduction In a chilled water system, the pump provides the energy to overcome friction and elevation changes, ensuring adequate flow through chillers, coils, pipes, and fittings. Pump head (expressed in meters or feet of fluid column) is the pressure difference the pump must generate. Overestimation leads to oversized pumps, high energy costs, and control instability; underestimation leads to inadequate flow and poor cooling. 2. Fundamental Equation for Total Pump Head For a closed-loop chilled water system (no open tank), the total head ( H_total ) is:

| Component | Pressure drop (m water column) | |-----------|-------------------------------| | Chiller evaporator | 5–10 | | AHU coil | 2–5 | | 2-way control valve | 2–5 | | Strainer (clean) | 1–2 | | Pipe friction | 2–6 m per 100 m | chilled water pump head calculation

Note: All values for water at 5–12°C, velocities 1–3 m/s. This paper provides a complete, practical guide for HVAC engineers to perform chilled water pump head calculations with confidence. Abstract The proper sizing of chilled water pumps

Example: A 100 mm (4″) 90° elbow ≈ 3 m equivalent pipe length. [ h_fitting = K \cdot \fracv^22g ] Where ( K ) = loss coefficient (from manufacturer or tables). closed systems, variable flow, and common pitfalls