Activity tab in model data under Occupancy header
Set the metabolic rate according to the level of activity within the space.
The metabolic rate determines the amount of heat gain per person in the zone under design conditions. This value is modified during simulations based on a correlation to account for variations in space temperature. This should be borne in mind when analysing occupant sensible heat output in the Cooling design and Simulation results screens. Metabolic rate has units Watts per person and represents the total heat gain per person including convective, radiant, and latent heat. An internal algorithm is used to determine what fraction of the total is sensible and what fraction is latent. Then, the sensible portion is divided into radiant and convective portions based on the assumption of 50% radiant fraction.
Metabolic rate data can be found in the ASHRAE Handbook of Fundamentals, Chapter 8, Table 5.
DesignBuilder data is derived from this data and is for adult males having typical surface area of 1.8m2. For women multiply the adult male value by 0.85 and for children multiply by 0.75.
The metabolic factor accounts for people of various sizes. Enter 1.00 for men, 0.85 for women, 0.75 for children or you can use an average value if there is a mix of sizes.
Heat is generated in the human body by oxidation at a rate called the metabolic rate. This heat is dissipated from the body surface and respiratory tract by a combination of radiation, convection and evaporation. The relative proportions of sensible and latent heat from people is a complex function of the metabolic rate and the environmental conditions.
EnergyPlus uses a polynomial function to divide the heat gain into sensible and latent portions. More details can be found in the EnergyPlus EngineeringDoc.pdf documentation.
Note: If the Occupancy latent gains model option is set to Dynamic calculation then the sensible/latent split for occupancy gains is affected by the internal temperature and relative humidity. With high internal temperatures, people cool themselves largely by evaporation (sweating) and sensible occupancy gains can be very low or even zero as the internal temperature approaches that of the human body.
You can define the clothing levels of the occupants for summer and winter periods. This data is used when generating comfort output.
Clothing reduces the body's heat loss and is classified according to its insulation value. The unit normally used for measuring clothing's insulation is the Clo unit. The more technical unit is m²°C/W is also used frequently (1 Clo = 0.155 m2°C/W). The Clo value can be calculated by adding the Clo value of each individual garment. The insulation value for individual garments can be found in ISO 7730.
Clo-Values for Different Items of Clothing and Ensembles
|
Clothing |
Clo-Value |
|
Naked |
0.0 |
|
Briefs |
0.06 |
|
T-shirt |
0.09 |
|
Bra and panties |
0.05 |
|
Long underwear |
|
|
upper |
0.35 |
|
lower |
0.35 |
|
Shirt |
|
|
White, short sleeve |
0.14 |
|
heavy, long sleeve |
0.29 |
|
Add 5% for tie or turtleneck |
|
|
Skirt |
0.22-0.70 |
|
Trousers |
0.26-0.32 |
|
Sweater |
0.20-0.37 |
|
Socks |
0.04-0.10 |
|
Light summer outfit |
0.3 |
|
Working clothes |
0.8 |
|
Typical indoor winter clothing combination |
1.0 |
|
Heavy business suit |
1.5 |
Note 1: Clo-values are additive, so one can calculate the clo-value for a person wearing a T-shirt and light socks (0.09 + 0.04) = 0.13. (Adapted from ASHRAE Fundamentals and "Technical Review of Thermal Comfort," Bruel and Kjaer, No. 2, 1982.)
Note 2: for equatorial regions where there is no clear 'summer/winter' weather pattern you should generally use a 'summer' value for both summer and winter clo factors.