Lecture Objectives

1. Lecture Objectives • Finish the cooling load example • Learn about Heating Systems

2. HW2 due date • Moved to March 5th • On Friday we will have TA office hours to help with specific questions for this HW

3. Example problem • Calculate the cooling load for the building in Pittsburgh PA with the geometry shown on figure. On east north and west sides are buildings which create shade on the whole wall. • Windows: Champion Window CDP number CHW-A-8 https://www.energystar.gov/products/most_efficient/horizontal_slider_windows • Walls: 4” face brick + 2” insulation + 4” concrete block, Uvalue = 0.1, Dark color • Roof: 2” internal insulation + 4” concrete , Uvalue = 0.120 , Dark color • Below the building is basement wit temperature of 75 F. • Internal design parameters: • air temperature 75 F • Relative humidity 50% • Find the amount of fresh air that needs to be supplied by ventilation system.

4. Example problem (continuing) • Internal loads: • 10 occupants, who are there from 8:00 A.M. to 5:00 P.M. doing moderately active office work • 1 W/ft2 heat gain from computers and other office equipment from 8:00 A.M. to 5:00 P.M. • 0.2 W/ft2 heat gain from computers and other office equipment from 5:00 P.M. to 8:00 A.M. • 0.5 W/ft2 heat gain from suspended fluorescent lights from 8:00 A.M. to 5:00 P.M. • 0.1 W/ft2 heat gain from suspended fluorescent lights from 5:00 P.M. to 8:00 A.M. • Infiltration: • 0.5 ACH per hour

5. Example solution • SOLUTION steps (see handouts): • 1. Calculate cooling load from conduction through opaque surfaces using TETD. • 2. Calculate conduction and solar transmission through windows. • 3. Add sensible internal gains and infiltration. • 4. The result is your raw sensible cooling load. • 5. Calculate latent internal gains. • 6. Calculate latent gains due to infiltration. • 7. The sum of 5 and 6 is your raw latent cooling load.

6. Example solution • SOLUTION: • For which hour to do the calculation ? • With computer calculation for all and select the largest.

7. Example solution For which hour to do the calculation when you do manual calculation? • Identify the major single contributor to the cooling load and do the calculation for the hour when the maximum cooling load for this contributor appear. • For example problem major heat gains are through theroof or solar through windows! Roof: maximum TETD=61F at 6 pm (Table 2.12) South windows: max. SHGF=109 Btu/hft2 at 12 am (July 21st Table 2.15 A) If you are not sure, do the calculation for both hours: at 6 pm Roof gains = A x U x TETD = 900 ft2 x 0.12 Btu/hFft2 x 61F = 6.6 kBtu/h Window solar gains = A x SC x SHGF =80 ft2 x 0.71 x 10 Btu/hft2 = 0.6 kBtu/h total = 7.2 kBtu/h at 12 am Roof gains = A x U x TETD = 900 ft2 x 0.12 Btu/hFft2 x 30F = 3.2 kBtu/h Window solar gains = A x SC x SHGF =80 ft2 x 0.71 x 109Btu/hft2 = 6.2 kBtu/h total= 9.4 kBtu/h For the example critical hour is July 12 AM.

8. Solution • On the board

9. Heating systems

10. Choosing a Heating System • What is it going to burn? • What is it going to heat? • How much is it going to heat it? • What type of equipment? • Where are you going to put it? • What else do you need to make it work?

12. Choosing a Fuel Type • Availability • Emergencies, back-up power, peak demand • Storage • Space requirements, aesthetic impacts, safety • Cost • Capital, operating, maintenance • Code restrictions • Safety, emissions

13. Selecting a Heat Transfer Medium • Air • Not very effective (will see later) • Steam • Necessary for steam loads, little/no pumping • But: lower heat transfer, condensate return, bigger pipes • Water • Better heat transfer, smaller pipes, simpler • But: requires pumps, lower velocities, can require complex systems

14. Choosing Water Temperature • Low temperature water (180 °F – 240 °F) • single buildings, simple • Medium and high temperature (over 350 °F) • Campuses where steam isn’t viable/needed • Requires high temperature and pressure equipment • Nitrogen system to prevent steam formation

15. Choosing Steam Pressure • Low pressure (<15 psig) • No pumping for steam • Requires pumping/gravity for condensate • Medium and high-pressure systems • Often used for steam loads

16. Steam Systems • Steam needs bigger pipes for same heat transfer • Water is more dense and has better heat transfer properties

17. What About Air? • Really bad heat transfer medium • Very low density and specific heat • Requires electricity for fans to move air • Excessive space requirements for ducts • But ! • Can be combined with cooling • Lowest maintenance • Very simple equipment • Still need a heat exchanger

19. Furnace • Load demand, load profile • Amount and type of heat • Response time • Efficiency • 80 – 85 % is typical • Electricity is ~100 % • Combustion air supply • Flue gas discharge (stack height)

20. Choosing a Boiler • Fuel source • Transfer medium • Operating temperatures/pressures • Equipment • Type • Space requirements • Auxiliary systems

21. Water Boilers Types • Water Tube Boiler • Water in tubes, hot combustion gasses in shell • Quickly respond to changes in loads • Fire Tube Boiler • Hot combustion gasses in tubes, water in shell • Slower to respond to changes in loads

23. Electric Types • Resistance • Resistor gets hot • Typically slow response time (demand issues) • Electrode • Use water as heat conducting medium • Bigger systems • Cheap to buy, very expensive to run • Clean, no local emissions

24. Auxiliary • Burner type (atmospheric or power vented) • Feedwater systems • Returns steam condensate (including accumulator) • Adds water to account for blowdown and leaks • Preheats the water • Removes dissolved gasses • Blowdown system • Periodically drain and cool water

25. Auxiliary • Water treatment • Dissolved minerals and gasses cause: • Reduced heat transfer • Reduced flow (increased pressure drop) • Corrosion • Treatment options • Chemical (add bases, add ions, add inhibitor) • Temperature (heat to remove oxygen)

26. Location • Depends on type • Aesthetics • Stack height • Integration with cooling systems

27. Reading Assignment Tao and Janis Chapter 5