Humidity and Dew Point

Water in the air is enemy #1 of compressed air.

Why Does Air Have Water?

Water constantly evaporates from oceans, rivers, lakes, and soil. This water vapor mixes with air and travels with it.

Air Capacity

The amount of water vapor air can hold depends on temperature:

Temperature	Maximum content
32°F (0°C)	4.8 g/m³
68°F (20°C)	17.3 g/m³
86°F (30°C)	30.4 g/m³
104°F (40°C)	51.1 g/m³

Hotter air = can hold more water

Relative Humidity

Relative humidity (RH) indicates what percentage of maximum capacity is occupied:

$$RH = \frac{\text{Current water}}{\text{Maximum possible water}} \times 100\%$$

Example: At 77°F (25°C), air can hold ~23 g/m³. If it contains 11.5 g/m³:

$$RH = \frac{11.5}{23} \times 100\% = 50\%$$

The Problem: Compression

What happens when you compress humid air?

1. You take 247 ft³ (7 m³) of air at 68°F and 70% RH
2. You compress it to 100 psig (reduce to 35 ft³ or 1 m³)
3. Same water in 1/7 of the space
4. Air becomes supersaturated at 700%
5. Excess condenses as liquid

Rule of thumb

For every 35,000 scf (1,000 m³) of compressed air at 100 psig, approximately 2.5-4 gallons (10-15 liters) of condensate is generated.

Dew Point

The dew point is the temperature at which air begins to condense water.

Type	Description
Atmospheric dew point	At atmospheric pressure
Pressure dew point (PDP)	At system pressure

Important

A PDP of +37°F (+3°C) means if your air drops below 37°F, it will condense water.

Outdoor piping in winter? You need a lower PDP.

Why do we need dryers?

Without dryer	With refrigerated dryer	With desiccant dryer
PDP = ambient temp	PDP = 37-50°F	PDP = -40°F or lower
Always condenses	Condenses below 37°F	Almost never condenses