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Indoor Temperature Humidity

Reference data and engineering information about indoor temperature humidity for air psychrometrics applications.

indoortemperaturehumidity

Overview

Engineering reference data for Indoor Temperature Humidity in air psychrometrics.

Key Formulas

Humidity Ratio

ω=0.622PvPa\omega = 0.622 \frac{P_v}{P_a}

Mass of water vapor per mass of dry air.

Relative Humidity

ϕ=PvPvs×100%\phi = \frac{P_v}{P_{vs}} \times 100\%

Ratio of actual to saturation vapor pressure.

Wet Bulb Temperature

Twb=TdbPvsPvγT_{wb} = T_{db} - \frac{P_{vs} - P_v}{\gamma}

Temperature measured by wet-bulb thermometer.

Enthalpy of Moist Air

h=cpT+ωhgh = c_p T + \omega h_g

Sensible + latent heat per unit mass of dry air.

Variables

SymbolDescriptionUnit
ω\omegaHumidity ratiokg/kg
ϕ\phiRelative humidity%
PvP_vVapor pressurePa
PvsP_{vs}Saturation vapor pressurePa
TdbT_{db}Dry bulb temperature°C
TwbT_{wb}Wet bulb temperature°C
2 rows
Estimated sensible heat from lights (Installed effect, W) for different illumination levels.
Type of Lights
200 lux(W)
400 lux(W)
600 lux(W)
800 lux(W)
1000 lux(W)
Incandescent lamp3875110145180
Fluorescent tubes1525364860

Source: engineeringtoolbox.com

5 rows
Normal illumination levels for various office activities.
Office Activity
Illumination(lux)
Normal work200
PC work500
Archive200
Drawing work, normal500
Drawing work, detailed1000

Source: engineeringtoolbox.com

4 rows
Human respiration and carbon dioxide (CO₂) emission rates for different activity levels.
Activity
Respiration per person(m³/h)
CO₂ generation per person(m³/h)
Sleeping0.30.013
Sitting, relaxed0.50.02
Working, moderate2 - 30.08 - 0.13
Working, heavy7 - 80.33 - 0.38

Source: engineeringtoolbox.com

8 rows
Occupational exposure limits for common polluting gases and vapors.
Product
Smell
Limit(mg/m³)
AmmoniaSticking0.5
Carbon disulphideAromatic, little sticking2.6
ChlorineSticking0.06
Chlorate phenolMedical0.18
EtherGeranium0.069
Prussic AcidBitter almond1
Hydrogen sulphideRotten egg0.26
OzoneLittle sharp0.096

Source: engineeringtoolbox.com

Calculation Equations

Sensible Heat from Lights: Hl=PinstK1K2H_l = P_{inst} K_1 K_2

Sensible Heat from Electric Equipment: Heq=PeqK1K2H_{eq} = P_{eq} K_1 K_2

Sensible Heat from Machines:

  • Motor inside, machine outside: Hm=PmηmPmH_m = \frac{P_m}{\eta_m} - P_m
  • Motor and belt inside, machine outside: Hm=PmηmPmηbH_m = \frac{P_m}{\eta_m} - P_m \eta_b
  • Both motor and machine inside: Hm=PmηmH_m = \frac{P_m}{\eta_m}
  • Motor outside, machine inside: Hm=PmH_m = P_m
  • Motor and belt outside, machine inside: Hm=PmηbH_m = P_m \eta_b

Evaporation from Water Surfaces:

  • Mass flow rate of evaporated water: m˙q=A(x1x2)αe\dot{m}_q = A (x_1 - x_2) \alpha_e
  • Evaporation constant: αe=25+19v3600\alpha_e = \frac{25 + 19 v}{3600}
  • Water surface temperature: t1=t2t2t38t_1 = t_2 - \frac{t_2 - t_3}{8}
  • Heat for evaporation: He=m˙qx1x2(h1h2)H_e = \frac{\dot{m}_q}{x_1 - x_2} (h_1 - h_2)

Flow of Polluting Fluid: qf=22.4qeMT273q_f = \frac{22.4 q_e}{M} \cdot \frac{T}{273}

Indoor Climate Sources Summary

The primary sources of heat and pollutants affecting indoor climate are:

  • Sensible and latent heat from persons
  • Sensible heat from lights
  • Sensible heat from electric equipment
  • Sensible heat from machines
  • Latent heat from evaporation from water surfaces
  • Evaporation from polluting fluids
  • Carbon dioxide (CO₂) and other pollutants from persons, materials, and processes

Interactive Charts

Indoor Comfort Temperatures vs. Outdoor Temperatures

References