Greenhouse Cooling Concepts - PowerPoint PPT Presentation

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Greenhouse Cooling Concepts

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Title: Greenhouse Cooling Concepts


1
Greenhouse CoolingConcepts
2
Why Cool Greenhouses?
  • Most places have a summer climate that requires
    greenhouse cooling even Vermont
  • A greenhouse must be capable of cooling in the
    winter and summer
  • With passive cooling greenhouses can reach
    temperatures of 20F greater (or more) than the
    air temperature

3
Too HOT!!
  • Loss of stem strength
  • Reduction of flower size
  • Delay of flowering
  • Bud abortion

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SUMMER COOLING
WINTER COOLING
  • Active
  • Fan-and-pad cooling
  • Fog
  • Passive
  • ventilators
  • HAF fans
  • Convection tube cooling

6
Passive Cooling
  • Percent of roof space ventilated has increased
    over time with design improvements
  • Success is very crop specific
  • Even fully retractable roof designs are now
    available
  • Cheaper to operate than active cooling systems,
    but construction costs arent less expensive

7
Acta Hortic. 443 31-38
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Effectiveness of Summer Cooling
  • Fan and pad cooling can lower to 80 of the
    difference between the wet and dry bulb
    temperatures
  • Fog cooling can lower the temperature by nearly
    all of the difference
  • Both of these systems are most effective at low
    humidity

11
Evaporative Cooling
  • Works well in most climates where might it not
    function effectively?
  • Based on heat absorption during the evaporation
    of water
  • Relatively inexpensive compared to other types of
    cooling

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nt/products.nsf/ByKey/OHAA-55GSWH
http//okfirst.ocs.ou.edu/train/meteorology/HeatTr
ansfer.html
14
Pad and Fan Cooling
  • Available for almost 50 years
  • Most common system for summer cooling
  • Originally the pad was composed of wood shreds
  • Today it is composed of cellulose
  • Exhaust fans are placed on the opposite wall

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Active Summer Cooling System Calculations (Basics)
  • Fan-and-Pad system
  • Rate at which warm air must be removed from the
    greenhouse
  • Types of pads used
  • Fan placement
  • Path of the airstream

18
Pad Types and Specifications
  • Excelsior pads (wood fiber) had to be framed in
    wire mesh for support required annual
    replacement
  • Cross-fluted cellulose is the most popular today,
    can last up to 10 years
  • Should be kept from heavy rains
  • Only move if dry
  • Other types of pads include aluminum fiber, glass
    fiber, and plastic fiber
  • Why are pads thick? and why do they have a cross
    fluted design?

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Cross-fluted cellulose pads
  • Come in height increments of ft
  • Available in 2, 4, 6, and 12 inches thick
  • A 4-inch-thick pad will handle an air intake of
    250 cfm/ft2 a six inch 350 cfm/ft2
  • By way of comparison excelsior pads can only
    support an airflow rate of 150 cfm/ft2
  • You want vents over the exterior of the pads to
    seal the external air source off when active
    cooling isnt needed

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More Details
  • Water must be delivered to a 4-inch pad at the
    rate of 0.5 gpm per linear foot of pad
  • For a 6-inch thick cellulose pad a 0.75 gpm per
    linear foot is required
  • Longest recommended delivery pipe is 60ft for the
    4 inch system and 50 ft for the 6 inch system1/8
    inch holes every three inches are required for
    both systems
  • Holes point upward and release water into an
    impingement cover water drips down onto a
    distribution pad

23
Rate of Air Exchange
  • Measured in cfm (cubic feet per minute)
  • NGMA uses 8 cfm/ft2 of floor space as astandard
  • In warmer climates 1 volume per
    minuterecommended roughly 11-17 cfm/ft2
  • As elevation increases so must the rate of air
    removal.  Why?

24
Other factors
  • Light Intensity
  • Temperature rise across the greenhouse
  • Pad-to-fan distance

25
Calculating Air Removal Rate
  1. Calculate the standard cfm Greenhouse area X 8
    cfm/ft
  2. Correct for the standard rate of air removal
    using the larger of Fhouse or (Fvel)
  3. Fhouse Felev X Flight X Ftemp
  4. Total cfm standard cfm X (Fhouse or Fvel)
  5. Select the fans to install

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Exhaust Fan Placement Rules
  • Should not be more than 25 ft apart
  • If the end of the greenhouse is 60 ft wide you
    will need at least 3 fans
  • Fans should be evenly spaced at plant height
  • Place fans on leeward side of the greenhouse
  • Rules change with multiple houses
  • Protect fans from weather and provide screening
    on both sides to protect workers, visitors, and
    wildlife
  • Air movement can cause special problems in larger
    houses

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Fog Cooling
  • 20-year-old technology
  • High pressure water delivery system generates a
    fog of very fine water particles (lt10 microns)
  • Drops evaporate in the air
  • Even dispersal of the particles means cooling of
    throughout the greenhouse

http//www.valproducts.com/Air/EvapFog.html
32
Fog Cooling
  • Initial cost usually close to that of fan and pad
    coolingsystems (water quality determining
    factor)
  • Operating cost less than fan-and-pad cooling
  • Dispersion of water particles in the greenhouse
    air where they extract heat from the air as they
    evaporate.
  • Rate of cooling increases proportionately as
    waterdroplet size decreases.
  • Systems allow near 100 percent cooling efficiency
    and wet bulb temperatures can essentially be
    obtained

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Fog Cooling II
  • Exhaust fans still used
  • Fog nozzles installed just inside the
    inletventilators
  • Roughly half the exhaust fan capacity of
    fan-and-pad cooling systems is necessary
  • High water quality is critical
  • Can also be used with plant propagation systems
  • Disease occurrence much lest than with a
    mistsystem. Why?

36
Fog Cooling Advantages
  • There is less electrical consumption
  • Heat rise across the greenhouse is controlled
  • Cooler average temperatures can be achieved
    across the greenhouse
  • System is good substitute for mist systems on
    propagation benches.

37
Effectiveness of Winter Cooling
  • Ventilators used to be the only way to winter
    cool problems
  • Convection-tube and HAF eliminate horizontal
    temperature gradient problems
  • Both modern systems circulate air in the
    greenhouse

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Active Winter Cooling
  • Convection tube cooling
  • Exhaust fan turned on
  • A louver opens in the gable
  • A pressurizing fan in the end of the polyethylene
    tubes turns on
  • Cool air mixes with greenhouse warm air and galls
    to thefloor cooling the plant growing area
  • Pressurizing fan must move as much air as the
    exhaustfan.
  • 2 cfm required

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HAF fans
  • Similar to convection-tube-system
  • Requires HAF fans in the place of convection
    tubes
  • HAF fans can be used for air circulation when
    neither heating nor cooling is in operation

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Integrating of Heating andCooling Systems
  • Remember there are some spring andfall days
    when you may have to use,summer heating, winter
    cooling andsummer cooling systems all on
    thesame day

47
BRINGCALCULATORSandTEXTBOOK on Thursday !!!!
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