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Solar Water Heater Project
- 1. The Effect of Flow Rate on Heat Transfer from a Solar Water Heater MICHAEL CALFE, KAYLA KERNICH, EMILY SKIBENES
- 2. What is a Solar Water Heater? Conversion of sunlight into heat for water heating using a solar thermal collector Fuel = Sunlight = Free! Two Types of Systems: ◦ Passive → Circulate water or antifreeze from the solar collector to the storage tank using the warm liquid’s natural tendency to rise ◦ Active → Use electric pumps to increase the efficiency of the water circulation and to move hot water into the home
- 3. Importance of Solar Water Heaters More than 1.5 million homes and businesses currently use solar water heating in the United States Assuming that 40 percent of existing homes in the United States have sufficient access to sunlight, 29 million solar water-heating systems could be installed. ◦ Can operate in any climate. ◦ Performance varies depending on how much solar energy is available at the site, as well as how cold the water coming into the system is. Solar water heaters reduce the need for conventional water heating by about two-thirds and pay for their installation within 4 to 8 years with electricity or natural gas savings.
- 4. Objectives of the Experiment ➢Determine optimal flow rate for maximum heat transfer from a solar water heater ➢Determine the efficiency of the solar water heater ➢Develop a predictive model for the solar water heater
- 5. Materials: ➢Solar Water Heater ➢Peristaltic pump ➢Bucket of water ➢Tubing and connectors ➢Graduated cylinder ➢Timer ➢Thermometer ➢HOBO dataloggers with 3 temp sensors ➢Hot water, cold water, air
- 6. Methods: 1) Connect temperature sensors to HOBO; launch 2) Set up solar heater and peristaltic pump (varying flow rates) 3) Measure water flow rate with beaker and timer 4) Place inlet and outlet water temperature sensors; start HOBO datalogger 5) Allow water to run for ~10 min for each trial 6) Download temperature data 7) Calculate rate thermal energy gained by heater
- 7. Steps for Thermal Energy Balance
- 8. Specifications: Location: Clemson, SC Sustainability Shed Date and time: 4/16/17 2pm-3pm Dimensions of heater: 19.25 in x 71 in
- 9. Results: Low flow rate (6.81 mL/s) Steady State Values: Ti = 25 deg C To = 39 deg C
- 10. Results: Middle flow rate (12.23 mL/s) Steady State Values: Ti = 24 deg C To = 31 deg C
- 11. Results: High flow rate (21.34 mL/s) Steady State Values: Ti = 24 deg C To = 28.5 deg C
- 12. Calculated Results Trial # Temp In (deg C) Temp out (deg C) Flow Rate (mL/s) Heat Transfer (W) Heat Flux (W/m^2) Efficiency (%) 1 25 39.04 6.81 399.660 453.246 47.44 2 24 31.5 12.23 383.411 434.818 45.51 3 24 28.17 21.34 371.969 421.842 44.15
- 13. Flow rate vs Heat Generated
- 14. Conclusions ➢In this experiment, the optimal flow rate for maximum heat transfer was determined to be the lowest flow rate of 6.81 mL/s ➢Theoretically, the results should represent a bell shaped curve. If more data was taken at lower flow rates, this would show this trend. ➢The slower the volumetric flow rate, the higher the outlet temperature due to the elongated retention time in the solar water heater ➢The colder the inlet temp, the greater the delta T and heat flux would be
- 15. Appendix
- 16. References Dorsey, Inc. Piccirilli. "Fact Sheet: Solar Water Heating." EESI - Environmental and Energy Study Institute. EESI, 1 May 2006. Web. 26 Apr. 2017. <http://www.eesi.org/papers/view/fact-sheet- solar-water-heating?%2Fsolar_water_0506>. Quick Solar Calculator. N.p., n.d. Web. 20 Apr. 2017. <https://barani.biz/apps/solar/>. Chris, Ian, and Sarah’s group for using the pyranometer correctly and giving us our G value