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Coolant Properties

Reference data and engineering information about coolant properties for hvac systems applications.

coolantpropertiesData Table

Overview

Engineering reference data for Coolant Properties in HVAC systems.

Key Formulas

Sensible Heat

Q=m˙cpΔTQ = \dot{m} c_p \Delta T

Heat causing temperature change.

Latent Heat

Q=m˙hfgΔωQ = \dot{m} h_{fg} \Delta\omega

Heat causing moisture change.

COP (Cooling)

COP=Qc/WCOP = Q_c / W

Coefficient of performance.

Variables

SymbolDescriptionUnit
QQHeat transferW
m˙\dot{m}Mass flow ratekg/s
cpc_pSpecific heat of airJ/(kg·K)
ΔT\Delta TTemperature differenceK

Coolant Properties Overview

Secondary coolants are essential in refrigeration and HVAC systems for heat transfer when direct cooling isn't feasible. The main types include:

  • Ethylene glycol – widely used in automotive and industrial applications
  • Propylene glycol – preferred in food/pharmaceutical applications due to lower toxicity
  • Calcium chloride – common in industrial applications requiring low temperatures
  • Sodium chloride – used in ice-making and some industrial cooling systems

Temperature Conversion Formula

The relationship between Fahrenheit (tFt_F) and Celsius (tCt_C) temperatures is:

tC=59(tF32)t_C = \frac{5}{9}(t_F - 32)

This conversion is essential when working with engineering data from different unit systems.

Key Property Comparisons

When selecting a secondary coolant, engineers typically evaluate three critical properties:

  1. Specific gravity – affects system pumping power and heat transfer capacity
  2. Freezing point – determines minimum operating temperature
  3. Viscosity – impacts pumping requirements and heat transfer efficiency

These properties vary significantly with concentration and temperature, requiring careful system design.

References