1. Energy use in buildings Dr. Atila Novoselac Associate Professor Department of Civil, Architectural and Environmental Engineering, ECJ 5.422

2. Primary energy consumption in U.S. (latest data from DOE) EJ - 10 18 J Tester J.W. DOI: 10.1039/c1ee01721g

3. Comparison of energy for heating and cooling How to compare heating energy from gas and electric energy? 1) Convert all to end primary energy 2) Convert end use energy from gas to electric energy you would get from using this gas You will need: - Conversion factors: 1000 BTU = 0.293 KWh, 1,000,000J=0.278 KWh - Efficiency of electric generation systems (including transport): ≈33%

4. Energy Principles Primary, Secondary and Site energy Primary energy refers to the energy embodied in the natural resources that has not undergone any form of artificial conversion or transformation. Examples of primary energy sources are coal, crude oil, sunlight and uranium. Secondary energy refers to the energy obtained from the transformation of primary energy sources. Examples of secondary energy sources are electricity or energy from gas delivered to consumer. Site energy refers to the energy consumed by the final users.

5. Site Energy vs. Primary Energy Site (End-use) energy is the energy directly consumed by end users. Secondary energy is site energy plus the energy consumed in the production and delivery of energy products Primary energy is site energy plus the energy consumed in the production and delivery of energy products. Site energy (End use) Secondary Energy Primary Energy Site Energy Primary Energy HVAC System HVAC – Heating, Ventilation and Air-Conditioning

6. Electric Energy Generation in Power Plants

7. Reason for such a large energy conversion losses or Boiler that burns fossil fuels Temperature Entropy TcTc THTH 3 4 1 2 Rankine cycle T condensation K Major loss is in power plant (thermodynamics) Can be improved with cogeneration systems

8. Analysis of energy consumption in residential buildings We are going to use real data and model based on Austin Energy data Model house: - Location in Austin -2300sf -R13 walls -R30 attic -4 occupants -Surface absorptivity to Solar rad.: 0.7 -Typical (average) internal loads -Infiltration/Ventilation 0.5 ACH - Double glazed widows -Glazing are 20% south, 25 north, 5% east and west - SHGC=0.54 (reflective – bronze - glass)

9. Energy consumption in Austin’s residential house (data from Austin Energy) End use energy where energy from gas is converted to equivalent electric energy

10. Energy consumption New single family 2262 sf, 2-story home in Austin (AE data) Desired Value !

11. Energy consumption: kWh/year (to get approximate cost multiply by 0.1) Units are in kW/h per year

12. Data from the model house (House built in 2010) How to convert this data into this data? Convert end use energy from gas to electric energy

13. Impact of outdoor temperature vs. impact of solar radiation We need to understand impacts of solar radiation Through: - radiation - conduction - convection for roof, walls, and windows

14. Example: Direct calculation by eQUEST energy simulation tool http://doe2.com/equest/ Class analysis: Impact of temperature of outdoor air vs. Impact of solar radiation – Eliminate all impact of solar radiation and compare energy consumption results before and after solar radiation – Consider the relevant (comparable) type of energy – Be aware that that increase cooling energy demand could decrease heating demands For example internal loads

15. Analysis result: Case Heating [10e6 Btu of heat] Heating [kWh of EE] Cooling [kW of EE] Base case20.8920204730 Same like above with no internal loads (cooling an heating of empty house)34.9333773030 Same like above with no solar radiation on windows (SHGC =0)48.4946881960 Same like above with no solar radiation on external surfaces (surface absorbtivity=0)53.8952111450 Same like above with no infiltration/ventilation (ACH=0)48.8847261110

16. Summary For a typical home in Austin built in 2000 energy is used for: – 30% cooling, 14% heating, 12% hot water, 44% light and appliances, and other internal electric devices – Considering cooling only internal loads 36% energy consumed for cooling radiation through window 23% of cooling effect of solar radiation to roof and walls 11% of cooling infiltration 7% of cooling (2.2% of total energy consumed) conduction: roof, walls, floor and windows 23% of cooling (7.0% of total energy consumed) We should consider combined effect on cooling and heating since removal of internal loads and solar radiation will increase demand for heating. – Considering combined heating and cooling effects: contribution of internal heating loads: 2.3% of total energy consumed contribution of all solar radiation: ~19% of total energy consumed contribution of infiltration: 5.5% of total energy consumed contribution of conduction through roof, walls, floor and windows: ~17% of total For different climate condition, or non-typical house, or non- typical users these numbers will be different ! – For other climate conditions, we would build this house differently

17. You can do further analyze specific impact of different building components For the same internal load you can analyze: Impact of infiltration rate and heat recovery Impact of windows – Area – Glass properties Impact of R value – Roof – Walls – Windows Impact of surface absorptivity to solar radiation – Roof – Walls – Floor Impact of different location Efficiency of mechanical system … Boiling energy modeling tips: -Energy efficiency measures are NOT additive -Most of the time you have to consider the whole building -There is no single solution