Chilled Water System Fundamentals

A chilled water system is a centralized cooling system that uses water as the heat transfer medium. The chiller removes heat from water, and this chilled water is then circulated through the building to cool the air.

System Components

Chiller: Removes heat from water (typically 6-7°C supply)
Cooling Tower: Rejects heat to atmosphere
Pumps: Primary, secondary, and condenser water pumps
Air Handling Units (AHUs): Transfer cooling to air
Fan Coil Units (FCUs): Terminal cooling units
Piping Distribution: Supply and return piping network
Expansion Tank: Accommodates thermal expansion
Controls: Building automation and control systems

Design Temperatures (ASHRAE Standards)

Parameter	Typical Value	Range
Chilled Water Supply (CHW Supply)	6-7°C (42-44°F)	4-10°C
Chilled Water Return (CHW Return)	12-14°C (54-57°F)	10-16°C
ΔT (Temperature Difference)	6°C (10.8°F)	4-8°C
Condenser Water Supply	29-32°C (85-90°F)	27-35°C
Condenser Water Return	35-38°C (95-100°F)	32-40°C

System Configurations

1. Primary-Only System

Single pump configuration with variable flow through chillers. Suitable for smaller systems (<500 TR).

2. Primary-Secondary System

Most common configuration with constant flow through chillers (primary) and variable flow to loads (secondary). Provides chiller protection and flexible operation.

3. Variable Primary Flow (VPF)

Modern approach with variable flow through chillers. Requires minimum flow protection. Higher efficiency potential.

Note: ASHRAE Standard 90.1 mandates variable flow systems for energy efficiency in most commercial applications.

Fundamental Design Equations

1. Cooling Load Calculation

Heat Transfer (Sensible Cooling)

Q = ṁ × Cp × ΔT

Q = Cooling load (kW or BTU/hr)
ṁ = Mass flow rate (kg/s or lb/hr)
Cp = Specific heat of water = 4.186 kJ/(kg·K) or 1 BTU/(lb·°F)
ΔT = Temperature difference (°C or °F)

Simplified Form (SI Units)

Q (kW) = V̇ (L/s) × ΔT (°C) × 4.186

Or approximately: Q ≈ 4.2 × V̇ × ΔT

Simplified Form (Imperial Units)

Q (tons) = GPM × ΔT (°F) / 24

Or: Q (BTU/hr) = 500 × GPM × ΔT

2. Flow Rate Calculations

Volumetric Flow Rate (SI)

V̇ (L/s) = Q (kW) / (4.186 × ΔT)

For standard ΔT = 6°C:
V̇ (L/s) = Q (kW) / 25.1 ≈ Q / 25

Volumetric Flow Rate (Imperial)

GPM = (Tons × 24) / ΔT

For standard ΔT = 10°F:
GPM = Tons × 2.4

3. Pump Head Calculations

Total Dynamic Head (TDH)

H = h_friction + h_static + h_equipment + h_control

h_friction = Friction losses in piping
h_static = Elevation difference
h_equipment = Losses through equipment (coils, chillers)
h_control = Control valve authority

Darcy-Weisbach Equation (Friction Loss)

h_f = f × (L/D) × (v²/2g)

f = Friction factor (0.015-0.025 for turbulent flow)
L = Pipe length (m or ft)
D = Pipe diameter (m or ft)
v = Flow velocity (m/s or ft/s)
g = Gravitational constant (9.81 m/s² or 32.2 ft/s²)

4. Pump Power

Pump Power (SI Units)

P (kW) = (ρ × g × V̇ × H) / (η × 1000)

Or simplified:
P (kW) = (V̇ (L/s) × H (m)) / (102 × η)

ρ = Water density ≈ 1000 kg/m³
g = 9.81 m/s²
η = Pump efficiency (typically 0.70-0.85)

Pump Power (Imperial Units)

BHP = (GPM × H (ft)) / (3960 × η)

Where 3960 is a conversion constant

5. Pipe Sizing

Velocity Method

v = (4 × V̇) / (π × D²)

Recommended velocities:
– Chilled water mains: 1.5 – 3.0 m/s (5-10 ft/s)
– Branches: 1.0 – 2.4 m/s (3-8 ft/s)
– Risers: max 1.5 m/s (5 ft/s) to prevent noise

6. Expansion Tank Sizing

ASHRAE Method

V_tank = (V_system × e × P_a) / (P_a – P_f)

V_system = Total system water volume
e = Coefficient of thermal expansion ≈ 0.0004 per °C
P_a = Absolute fill pressure
P_f = Absolute final pressure

7. Chiller Performance

Coefficient of Performance (COP)

COP = Q_cooling / W_input

Typical values:
– Air-cooled chillers: 2.5 – 3.5
– Water-cooled chillers: 4.5 – 6.5

Energy Efficiency Ratio (EER)

EER (BTU/W·h) = COP × 3.412

kW/Ton = 12 / EER

8. Cooling Tower Performance

Heat Rejection

Q_reject = Q_cooling × (1 + 1/COP)

Or: Q_reject ≈ Q_cooling × 1.25 (typical)

Approach Temperature

Approach = T_cw_leaving – T_wb_ambient

Typical approach: 3-5°C (5-9°F)

Applicable Codes & Standards

ASHRAE Standards

ASHRAE 90.1 – Energy Standard for Buildings Mandatory requirements for chilled water systems including minimum efficiency (COP), pipe insulation, variable flow pumping, and waterside economizers for systems ≥300 tons.
ASHRAE 15 – Safety Standard for Refrigeration Systems Requirements for refrigerant safety, machinery room ventilation, pressure relief devices, and system testing.
ASHRAE 62.1 – Ventilation for Acceptable Indoor Air Quality Minimum ventilation rates and indoor air quality requirements affecting cooling load calculations.
ASHRAE 55 – Thermal Environmental Conditions Comfort criteria for occupied spaces, establishing temperature and humidity setpoints.
ASHRAE Guideline 14 – Measurement of Energy Demand Methods for measuring and verifying building energy performance.

International Building Codes

IBC – International Building Code General building requirements including structural support for equipment and seismic considerations.
IMC – International Mechanical Code Mechanical system design, installation, and maintenance requirements. Chapter 12 covers hydronic piping.
IPC – International Plumbing Code Water supply and drainage requirements for HVAC systems.
IECC – International Energy Conservation Code Energy efficiency requirements similar to ASHRAE 90.1, often adopted by local jurisdictions.

Industry Standards

AHRI 550/590 – Performance Rating of Water Chilling Packages Standard rating conditions: 44°F leaving chilled water, 85°F entering condenser water.
AHRI 210/240 – Performance Rating of Unitary Air-Conditioning Equipment Rating standards for air-cooled equipment including SEER, EER, and IEER.
CTI Standards – Cooling Technology Institute Performance and certification standards for cooling towers (STD-201, ATC-105).
HI Standards – Hydraulic Institute Centrifugal pump standards including ANSI/HI 9.6.3 for variable frequency drives.

Piping Standards

ASME B31.9 – Building Services Piping Design requirements for building service piping including materials, pressure ratings, and supports.
ASTM Standards Material specifications: A53 (steel pipe), B88 (copper tube), D2846 (CPVC), F2389 (PE-RT).

Key Design Requirements (ASHRAE 90.1)

Minimum Equipment Efficiency

Equipment Type	Size Category	Min. Efficiency	Test Standard
Water-Cooled Centrifugal	<150 tons	0.610 kW/ton	AHRI 550/590
Water-Cooled Centrifugal	150-300 tons	0.596 kW/ton	AHRI 550/590
Water-Cooled Centrifugal	≥300 tons	0.570 kW/ton	AHRI 550/590
Air-Cooled Chiller	≥150 tons	9.562 EER	AHRI 550/590
Water-Cooled Screw	All sizes	0.640 kW/ton	AHRI 550/590

Mandatory Requirements

Variable speed drives on all pumps ≥10 HP
Two-way control valves on all cooling coils
Differential pressure reset for variable flow systems
Waterside economizer for systems ≥300 tons (climate dependent)
Chilled water supply temperature reset based on outdoor air or load
Pipe insulation: R-3 minimum for 1″ and smaller, R-5 for larger pipes
Automatic shutoff for pumps when no demand exists

Design Guidelines

Diversity Factors

Building Type	Diversity Factor
Office Buildings	0.75 – 0.85
Hotels	0.60 – 0.75
Hospitals	0.85 – 0.95
Retail	0.80 – 0.90
Schools	0.70 – 0.80

Important: Diversity factors account for the fact that not all spaces reach peak load simultaneously. Apply to total connected load, not individual zone calculations.

Interactive Design Calculators

1. Cooling Load & Flow Rate Calculator

Cooling Load (kW or Tons):

Unit System:

Temperature Difference (ΔT):

2. Pump Head Calculator

Pipe Length (m or ft):

Flow Velocity (m/s or ft/s):

Pipe Diameter (mm or inches):

Friction Factor (f):

Equipment Loss (m or ft):

Static Head (m or ft):

3. Pump Power Calculator

Flow Rate (L/s or GPM):

Total Head (m or ft):

Pump Efficiency (%):

Motor Efficiency (%):

4. Pipe Sizing Calculator

Flow Rate (L/s or GPM):

Target Velocity (m/s or ft/s):

5. Chiller Efficiency Calculator

Cooling Capacity (kW or Tons):

Power Input (kW):

System Design Considerations

Primary-Secondary System Design

Most reliable configuration for medium to large systems (500-5000 tons).

Primary Loop (Chiller Loop)

Constant flow through chillers for stable operation
Flow rate: Q / 25 L/s per 100 kW (2.4 GPM per ton)
Primary pump head: Chiller evaporator + piping losses (typically 15-25m)
Decoupler pipe connects primary and secondary loops

Secondary Loop (Building Loop)

Variable flow to match building load
Two-way control valves at all cooling coils
Differential pressure sensor in most remote circuit
DP reset based on valve position (min 50% open)
VFD controlled pumps for energy savings

Variable Primary Flow (VPF) Design

Modern approach for high-efficiency systems.

Key Requirements

Chiller minimum flow protection (typically 30-40% of design flow)
Automatic bypass valve or dedicated bypass loop
Headered chillers with individual isolation
Lead-lag staging based on load optimization
Lower first cost (eliminates primary pumps)
Higher energy efficiency potential

Critical: VPF requires careful control design to prevent low flow through operating chillers. Always verify chiller manufacturer approval for variable flow operation.

Chiller Sequencing Strategies

Load Range	Number of Operating Chillers	Notes
0-40%	1 Chiller	Base load operation
40-80%	2 Chillers	Stage on at 95% capacity
80-120%	3 Chillers	Stage on at 90% capacity
>120%	All + Reserve	Peak demand

Pipe Insulation Requirements

Pipe Size	Min. Insulation (ASHRAE 90.1)	Recommended
<1″ (25mm)	R-3 (0.5m²K/W)	1″ (25mm) thickness
1″-2″ (25-50mm)	R-4 (0.7m²K/W)	1″ (25mm) thickness
2″-4″ (50-100mm)	R-5 (0.9m²K/W)	1.5″ (38mm) thickness
4″-8″ (100-200mm)	R-6 (1.1m²K/W)	2″ (50mm) thickness
>8″ (200mm)	R-8 (1.4m²K/W)	2.5″ (65mm) thickness

Energy Conservation Measures

Chilled Water Reset: Increase supply temperature during low loads (saves 1-2% per °F increase)
Condenser Water Reset: Lower condenser water temp when possible (1% energy savings per °F)
Waterside Economizer: Free cooling when outdoor conditions permit (required ≥300 tons)
Variable Speed Cooling Towers: Match fan speed to load and wet-bulb
Heat Recovery: Use rejected heat for reheat or domestic hot water
Thermal Storage: Shift cooling production to off-peak hours
VFD Pumps: Reduce pumping energy at part load (energy ∝ flow³)

Balancing and Commissioning

Per ASHRAE Guideline 1.1 and Standard 202:

Verify design flow rates at all coils (±10% tolerance)
Test and balance all pumps to design conditions
Verify control valve authority (25-50% of system ΔP)
Commission all control sequences and interlocks
Measure chiller efficiency at multiple loads (25%, 50%, 75%, 100%)
Verify waterside economizer operation and switchover
Document system performance and create O&M manuals