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Lecture Objectives: Discuss –solar radiation and heat transfer through windows –Internal heat loads Introduce Homework Assignment 1b –solve 1/3 of the.

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Presentation on theme: "Lecture Objectives: Discuss –solar radiation and heat transfer through windows –Internal heat loads Introduce Homework Assignment 1b –solve 1/3 of the."— Presentation transcript:

1 Lecture Objectives: Discuss –solar radiation and heat transfer through windows –Internal heat loads Introduce Homework Assignment 1b –solve 1/3 of the problem

2 Internal Boundaries Window Transmitted Solar radiation Internal sources

3 Distribution of transmitted solar radiation DIRECT solar radiation

4 Distribution of transmitted solar radiation diffuse solar radiation

5 Transmission for single and double glazed window,,,

6 Heat transfer for double glazed window

7 Internal Heat sources Occupants, Lighting, Equipment Typically - Defined by heat flux –Convective Directly affect the air temperature –Radiative Radiative heat flux “distributed” to surrounding surfaces according to the surface area and emissivity

8 Internal Heat sources Lighting systems –Source of convective and radiative heat flux –Different complexity for modeling

9 Surface Balance Conduction All radiation components Convection Convection + Conduction + Radiation = 0 For each surface – external or internal :

10 Air balance - Convection on internal surfaces + Ventilation + Infiltration h1 Q1 h2 Q2 What affects the air temperature? - h and corresponding Q - as many as surfaces mimi Ts1 Tair Uniform Air Temperature Assumption! Q convective = ΣA i h i (T Si -T air ) Q ventilation = Σm i c p,i (T supply -T air ) Tsupply -m air c p.air Δ T air = Qc onvective + Q ventilation Energy balance:

11 Air balance – steady state Convection on internal surfaces + Infiltration = Load h1 Q1 h2 Q2 - h, and Q surfaces as many as surfaces - infiltration – mass transfer (m i – infiltration) Q air = Q convective + Q infiltration mimi Ts1 Tair Uniform temperature Assumption Q convective = ΣA i h i (T Si -T air ) Q infiltration = Σm i c p (T outdoor_air -T air ) Q HVAC = Q air = m·c p (T supply_air -T air ) T outdoor air HVAC In order to keep constant air Temperate, HVAC system needs to remove cooling load

12 Homework assignment 1b West 10 m 2.5 m South conduction T air_in I DIR I dif Glass T inter_surf T west_i T west_o T south_i T south_oi T air_out Styrofoam I DIR I dif Surface radiation Surface radiation Top view

13 Homework assignment 1 Surface energy balance 1) External wall (west) node 2) Internal wall (west) node Q solar =  solar ·(I dif +I DIR ) A Q solar +C 1 ·A(T sky 4 - T west_o 4 )+ C 2 ·A(T ground 4 - T west_o 4 )+h ext A(T air_out -T west_ o )=Ak/  (T west_o -T west_in ) C 1 =  ·  surface  long_wave ·  ·F surf_sky Q solar_to west_surf =  portion of transmitted solar radiation that is absorbed by internal west surface C 3 A(T _in 4 - T internal_surf 4 )+C 4 A(T west_in 4 - T west_in 4 )+ h int A(T west_in -T air_in )= =kA(T west_out-- T west_in )+Q solar_to_west_surf C 3 =  niort_in ·  ·  north_in_to_ internal surface

14 Howe to solve system of equation by Using MathCad

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