1 / 37

X. INCREASING TEMPERATURE - HEATING A. Heating system requirements

X. INCREASING TEMPERATURE - HEATING A. Heating system requirements Optimum inside temperature Uniform temperature Prevent hot air on plants Low cost Fuel available Automated. Energy Loss from Greenhouse. B. Heating terminology refer to physical principles

jud
Télécharger la présentation

X. INCREASING TEMPERATURE - HEATING A. Heating system requirements

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. X. INCREASING TEMPERATURE - HEATING A. Heating system requirements • Optimum inside temperature • Uniform temperature • Prevent hot air on plants • Low cost • Fuel available • Automated

  2. Energy Loss from Greenhouse

  3. B. Heating terminology • refer to physical principles C. Factors affecting heating • Q = Qc + Qi • Qc = U x A x (ti-to) • Qi = .018 x V x N x (ti-to) Q - heat loss Qc - conduction & radiation heat loss Qi - infiltration heat loss U - heat transfer coef. A - area of coverings ti-to - inside set pt – coldest temp

  4. 1. House surface area vs volume • Surface area • Reducing surface area • lower eaves • ridge and furrow • shape of house perimeter & surface area correlated 2. Temperature differential • (ti -to)

  5. 3. Covering: Number of layers • Heat transfer coeffieicnt • 2 layers 40% less energy than 1 • 3 layers 16% less energy than 2 4. Types of coverings • Heat transfer coefficient 5. Air leakage • Tight house vs loose house • Leaks around fans, doors, vents • Thermal radiation

  6. 6. Side walls • Heat transfer coefficient 7. Structure - conductional heat loss • 8% more loss through metal than wood • Frame on double layer not exposed to outside 8. Wind • Sweep away boundary layer

  7. D. Sources of heat 1. Fossil fuels • Major: Coal Natural gas Oil Propane • Minor: Wood chips Straw Wheat Sawdust 2. Electricity

  8. 3. Other possible sources • Generating plants • Natural gas compression stations • Ethanol plants • Geothermal • hot springs • ground water • underground caverns

  9. Greenhouse heat: Gas from Landfill

  10. Mine Air Heated Greenhouse

  11. E. Types of Heating Systems • hydronic • forced air • Infrared 1. Hydronic - water or steam a. heating process • conduction • convection • radiation

  12. b. Steam vs hot water • boiler • steam higher pressure • steam cools faster

  13. c. boiler • fuel - gas, coal, propane • operation and maintenance • manual or automatic control

  14. d. distribution system • sidewalls, under benches, above benches • 2) circulate air • natural • forced convection • 3) finned pipe • 2/3 along side wall, 1/3 under benches

  15. Greenhouse Heat: Hot water or steam

  16. Forced Air - Unit Heater a. Types • hot water or steam • boiler required • fuel fired unit heaters • Fuel burned in house • Air distribution • forced convection • electricity

  17. b. distributing heat from unit heaters • Polytube • Heater fan and HAF c. problems arising from heat distribution • Hot air on plants • Uneven temperatures • Incomplete combustion CH3-CH2-CH2- + O2 -----> CO2 + H2O + (CH2-Ch2, CO, SO2) • Remedy • 1 sq in/2000BTU/hr for air inlet

  18. 3. Infrared Heater a. Principles • Energy not absorbed by air • Leaves, etc., absorb energy • Increase in temp. • Air warmed • conduction - leaves, etc., to air • convection - air rises b. Possible less condensation • Plants warmer than air at night • Air up to 7 deg cooler • Other systems - plants cooler than air at night • Radiation heat loss • Transpiration

  19. Infrared Heating

  20. c. Energy savings • 30-70% • Fuel combustion 90% • Less temperature differential • Air up to 7 deg cooler • Less energy loss • Do not use circulation fans • Less electricity • Installation cost higher

  21. Bottom heat Can provide 25-50% of heat during winter a. Root system warmer b. Natural air currents c. Water • small rubber tubes on bench or floor • Finned pipe under bench • Plastic pipe in floor d. Electricity • Resistance coil

  22. e. Advantages • Uniform temperature • Crop time reduced • Reduced disease • Root rot- soil dries faster • Foliar - leaves warm less condensation • Crop uniformity • Compact plants • Zone flexibility

  23. Bottom Heating Bottom heating: tube placement

  24. Bottom heating: Biotherm (tube)

  25. F. Special Heating Needs 1. Propagation • Warm bottom temperatures • Cable, pad, pipe under bench 2. Sterilization/pasteurization • Steam best if available

  26. G. Using Less Energy 1. Conservation • Seal cracks • Burner efficiency • Insulation - side walls, north wall • Double layer • movable curtains • Foam between polyethylene • Styrene beads

  27. 2. Management practices • Optimum space utilization • progressive spacing • movable benches • grow under benches • hanging baskets • Reduce container size • Improved varieties • faster production • cooler temp. requirements

  28. 2. Management practices (cont) • Supplemental lighting • CO2 increase • Reduce crop losses • Reduce night temperature

  29. Reduce Energy Use: Management Practices

  30. Reduce Energy Use: Use space more efficiently

  31. Supplemental heating: collect and store solar radiation

More Related