1. ET 494 Senior Design II Fall 2013 By: Justin Cifreo, Benjamin Gabriel, Nathan Taylor Instructor: Dr. Cris Koutsougeras Advisor: Dr. Junkun Ma Mechanical Engineering Technology Southeastern Louisiana University SOLAR POWERED HVAC SYSTEM

2. PURPOSE The objective of this project is to research and design a solar heating, ventilation, and cooling system that will reduce Southeastern Louisiana University’s energy consumption. 2

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4. Overlay of System on Site 4

5. CURRENT CONDITION Present HVAC system in use 5

6. GREENHOUSES Currently use propane fueled convection heaters 6

7. CHALLENGES Heat Load Calculation Ventilation Flow Rates Chiller Size Availability Control Design Unknowns 7

8. Solar Panels Selection Manufactured by Schuco Solar Thermal Panels Array of 5 Panels Mixture of Propylene 79.2% Efficiency Rating Glycol and Water 8

9. SOLAR ABSORPTION PANEL 9

10. COMSOL PROTOTYPE 10

11. Finished Solar Panel Array Mounted Atop Steel Structure 11

12. HEAT EXCHANGERS Manufactured by Schuco Plate-Style heat exchangers Transfer heat gathered by propylene glycol to water 12

13. HOT WATER STORAGE TANK Manufactured by Lochinvar 1,000 Gallon Capacity Provides latent heat storage 13

14. CHILLER CHARACTERISTICS Adsorption Silica gel Efficiency Operating Temperatures Operating Conditions 14

15. CHILLER CHARACTERISTICS cont. Environmentally friendly Temperature range Noise Small electricity consumption Durability Maintenance Lifespan 15

16. CHILLER EFFICIENCY 16

17. Chiller Availability Old Chiller LineNew ADCM7 Chiller line 17 8 min cycle time Limited availability New ADCM7 Chiller Line release 1-40 TR @ 1k – 1.5k/ton ¼ Cycle Time 2 min. 4 times

18. COOLING TOWER AND POND Utilization of a cooling tower with the adsorption chiller Assists in cooling process of the chiller condenser 18

19. EXTERIOR GEOTHERMAL HEAT SINK 19

20. HEAT LOSS Two types of building material Concrete Masonry Units (CMUs) Nominal size 16×8×8 inch Insulated Metal Panels (IMPs) 26 gauge metal Sandwiched Insulation 20

21. Heat Loss Analysis U-values & R-values Doors, Windows, Walls, Ceilings & Floors Infiltration 21

22. Heat Loss Calculation 22

23. Heat Lost or Gained During Fluid Transfer 23

24. OVERALL SYSTEM CONTROL 24

25. OVERALL SYSTEM CONTROL 25

26. OVERALL SYSTEM CONTROL 26

27. DELIVERABLES/ SOLUTIONS Researched existing solar heating and cooling systems on the market  Came up with a theoretical solar HVAC system schematic  Measure interior volumes of all facility spaces for heat load calculation  Measure area of exterior walls for heat values  Measure windows and doors for heat values  Log present and future equipment for heat gains  27

28. DELIVERABLES Cont.… Obtain heat load and flow rate equations  Make excel spreadsheet for heat load calculation and flow rate analysis  Research heat exchangers and design simple heat exchanger in COMSOL  Research duct flow rate calculation, material selection, and geometry specifications  Design and analyze simple solar heating panel in COMSOL  Design system control layout and flow charts for system  28

29. DELIVERABLES Cont.… Complete system specification Calculate overall system cost Build table-top model of HVAC system Make specification sheet for system components Contact local HVAC professional 29

30. TIMELINE 1/25 System introductory meeting with Mr. Byron Patterson and Dr. Junkun Ma, obtained floor plan and area measurements 1/28Solar HVAC systems researched 1/30 Researched different solar energy collector units, selected rough schematic system diagram 2/1 Collected height measurements at project site, calculated volumes for heat calculations 2/6Visio schematics constructed to present to Mr. Byron 2/7Meeting with Dr. Ma, discussed system components and operations of components 30

31. TIMELINECont. 2/27Brainstorming meeting Mr. Byron, Dr. Ma, Dr. Rode 3/6Biology building system walkthrough 3/8 Calculate total heat of each volume section, learn heat flow analysis, take pictures Biology Building 3/13Meet with Byron to solidify specifications 3/14Calculate and analyze individual system components 3/20Meet with Byron and Dr. Ma to get input and take next step in design 31

32. TIMELINECont. 3/27 Discussed back tracking, heat load and general duct work design 4/11 Researched duct work and sizing along with heat load factors 4/18Created excel spreadsheet 4/20Collected wall, window, and equipment loads 5/3Calculate Total Heat Load 5/10Set up Sensors ( Humidistat, Thermometer) 32

33. TIMELINECont. Fall Obtain and Learn Manual J for heat load Fall Contact local HVAC professional Fall Construct table-top system model Fall Analyze system design compared to available system components Fall Control 33

34. REFERENCES 34 Engineeringtoolbox.com Modern Refrigeration and Air Conditioning 18 th edition Shuco USA Lochinvar Corporation Adsorptionchiller.com Manual J: Calculating Heat Losses, Manual 3, Sixth Edition

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