Title: Greenhouse Energy Efficiency
1- Greenhouse Energy Efficiency
- Scott Sanford
- Sr. Outreach SpecialistFocus on Energy / Rural
Energy Issues
- Biological Systems Engineering
- University of Wisconsin Madison
This presentation is funded in part by the
Wisconsin Focus on Energy program
2Greenhouse Energy Use
- Energy
- 2nd largest cost behind labor
- 70-80 for space heating
- 10-15 Electricity
- The Economic-Energy Balance
- Light transmission for plant growth
- Environmental factors humidity, temperature
- Structure cost
- Operating costs
3Principles of Heat Loss
- Conduction
- Heat conducted through a material
- Convection
- Heat exchange between a moving fluid (air) and a
solid surface
- Radiation
- Heat transfer between two bodies without direct
contact or transport medium Sunlight
- Infiltration
- Exchange of interior and exterior air through
small holes in building shell
4Greenhouse types
5Structure Efficiency
- Gutter Connected
- Lower heat loss / less surface area
- Better space utilization
- 1.5 ratio heat loss area to floor area (25,000
sq. ft.)
- Stand alone (quonset, gable, gothic)
- Isolated growing conditions
- Natural Ventilation with open / roll-up side
walls
- Heat as filled
- 1.7-1.8 ratio - heat loss area to floor area
(3000 sq. ft.)
6Structural Efficiency
- Space heating comparison
- All Glazing Double poly IR
- 24,000 ft2 growing area
- Black fabric covered floor
- LP power vent unit heaters _at_ 78 seasonal
efficiency
- Farm A Eight greenhouses 30 x 100 x 15H x
3 side
- Energy use 1793 gallons LP per house (14,344
gal. total)
- Farm B Gutter connected greenhouse
- 5 bay 30 (150) x 160 x 10H (15 peak)
- Energy use 11,929 gallons
- Energy savings 2415 gallons (18 savings)
7Common Glazing Materials
- Glass
- Fiberglass-reinforced plastic
- Polyethylene film
- Acrylic
- Polycarbonate
8Glazing Materials
- Heat loss
- Single pane glass
- Highest heat loss (1.1 Btu/sq. ft.-hr-F)
- Longest life (Unless large hail) 25 years
- Highest cost / Structure
- High light Transmittance
- Double Polyethylene Film
- Low heat loss ( 0.5 to 0.7 Btu/sq. ft.-hr-F)
- Shortest life 3-4 years (UV degradation)
- Low cost
- Lowest Light Transmittance
9Glazing Material Comparison
10Infrared Radiation
- Plants, soil greenhouse
- - absorb solar or short radiation
- Reradiate heat out - long wave radiation
- Glass and rigid plastic
- - inhibit loss of IR radiation (
- Polyethylene film
- - IR loss 50
- Polyethylene film with IR additives
- - reduce heat losses by 20
- - without loss of light transmission
11Infrared Radiation pathways
12Polyethylene film w/ IR additive
- Reduces heat loss by 15-20
- Incremental Cost 0.015 / sq. ft.
- Payback 2-3 months / one season
- Diffuses light
- AT Plastics Dura-Film 4 Thermal AC
- Dura-Film 4 Thermal AC Plus
- Tyco Plastics Tufflite Infrared
- Klerks K50 IRAC
- Green-Tek Sunsaver
- Ginegar Plastics Sun Selector AD-IR / Suntherm
- www.agra-tech.com/thermal_glazings.htm
13Glazing Materials vs Infiltration
- Infiltration Rates
- Louvers, doors, holes, laps in glazing
- Glass high (2x compared with double poly)
- Double Poly lowest
- Air Exchanges
- New Construction Per Hour
- Glass, fiberglass, polycarbonate, acrylic 0.75 to
1.5
- Double-layer plastic film 0.5 to 1.0
- Old Construction
- Glass, good condition 1.0 to 2.0
- Glass, poor condition 2.0 to 4.0
14Infiltration Factors
- Glazing types
- Wind
- Still air versus 15 mph wind can double heat
loss
- High infiltration reduces CO2 enrichment
effectiveness
- Wind breaks
- Cut heat loss by 5 to 10
- Reduces risk of wind damage to structures
- Acts as snow fence
15Infiltration leaks
- Save 3-10 in heating costs
- Check Roof and wall vents - seal tight
- Tight Cover
- Glazing / lap seals on Glass
- Fix holes in cover
- Weather stripping around doors
- Door Sills
- Ventilation louvers close tight
- Dry Lubricant - use graphite
- Cover unneeded fans / vents during winter
- Foam and plastic
- Plug gaps around foundation
- Double/Single polyethylene over glass 40
savings
16Factors effecting Light
- Light growth
- Greenhouse orientation
- Single span East/West maximize winter
sunlight
- Multi span North/South gutter shadows move
- Glazing Transmittance
- Differences between materials
- Dust
- Anti-Dust additive
- Condensation can reduce light 25-50
- Anti-Condensate / Anti drip additive
17GE Lexan ZigZag
- Heat loss 20-40 less than single glass
- Light transmittance
- Glass 89-92 ZigZag 89 direct / 81 diffuse
- 4-6 more light to plants in winter faster
growth
- Orientation
- East/West gutters - 2 light gain
- North/South gutters 4 light gain
- Less Support profiles than glass 2 light gain
- www.gestructuredproducts.com/sp1/LexanZigZag/LEX_E
ng_Products_ZigZag2.html
18Conduction Heat Loss
- Insulate walls to plant height
- North walls insulate all opaque surfaces
- and more?
- Perimeter 24 below ground 1 to 2 Foam
- New construction
19Night-time Heat Loss
- Night Curtains
- 80 of greenhouse heating at night
- Reduces night heating up to 50
- Double poly w/ internal thermal blanket
- 0.4 Btu/hr-F-ft2
- Curtain must be sealed to prevent chimney effect
- Double as summer shade system
- Automated curtains expensive for seasonal grower
- Manual open curtains? - Lower cost
20Thermal / Shade Curtains
21Types of Curtain Systems
- Gutter to Gutter
- Truss to Truss
- Flat
- At bottom of truss
- Reduces night time volume to be heated
- Slope - Flat Slope
- Follows roof profile part way
- Installed without moving equipment
- Slope Slope
- Minimizes cold air trapped above curtain
22Thermal / Shade Materials
- Porous curtains
- Allows condensate and rain leakage to drain
- Lower heat retention than nonporous materials
- Semi-porous materials (preferred)
- Allows moisture to migrate
- High heat retention
- Non-porous material
- Highest heat retention
- Impervious to water and air movement - can fail
if water collects on top of curtain
- Shade in summer / heat retention
- Higher shading factor Higher heat retention
23Curtain Materials Semi porous Aluminized and
clear polyethylene woven fabric
100
75
65
55
15
24Shading Material Comparison
25Which shade to Choose?
- Heat of summer maximum sunlight (June, July)
- 10,000 footcandles
- Most bedding and flowering plants can tolerate
4000 to 5000 footcandles of light
- Greenhouse glazing light transmission
- Glass 90
- Double Poly 80
- 10,000 fc x 80 x 55 LT 4400 footcandles
- 45 shading recommended (52 energy savings)
26Other Material parameters
- Flammability
- Roll up or folding
- Shading
- Day length control (blackout)
- Heat retention
27Curtain Installation Issues
- Plants hanging from rafters
- Irrigation hanging from rafters
- LOTS of Things hanging from rafters
- Heating pipes
- Poly tubes
- Heaters
- Gable or roof vents or open roof systems
- Fully drawn curtain will restrict summer air flow
28Greenhouse unit heats
- Low cost
- Low installation costs
- Easily staged
- Reliable
- Location / heat distribution system affects
heating costs
-
29Unit heater Seasonal Efficiency
- TE Cost
- Gravity Vent heaters 80 858
- Power Vent Heaters 80 943
- Separated Combustion 82 1845
- TE Thermal Efficiency Combustion and heat
transfer efficiency.
- Reference Gas-Fired Unit Heaters A guide to
greenhouse heating strategies, Calalog
10-115,Modine Mfg., September 1996.
30Unit heater Seasonal Efficiency
- TE SE
- Gravity Vent heaters 80 65
- Power Vent Heaters 80 78
- Separated Combustion 82 80
- TE Thermal Efficiency Combustion and heat
transfer efficiency.
- SE Seasonal Efficiency Includes TE plus heat
loss out exhaust vents when heater is idle.
- Reference Gas-Fired Unit Heaters A guide to
greenhouse heating strategies, Calalog
10-115,Modine Mfg., September 1996.
31Unit heater Cost per kBtu output
- 250,000 Btu input, 80 Thermal Efficiency
- Type SE Cost
/kBtu out
- Gravity Vent 65 858 5.28
- Power Vent 78 943 4.84
- S Combustion 80 1845 9.23
- Heater cost / (Btu input x SE) x 1000
32Unit Heater cost justification Gravity Vent or
Power Vent?
- Greenhouse 30 x 96 located in Madison, WI
- Two 250,000 Btu Output LP Unit heaters
- Incremental cost for PV heaters - 85 /ea
- All other costs assumed the same
- Growing season Feb 1 to June/July
- Estimated Fuel consumption
- Gravity vent 2179 gallons
- Power vent 1816 gallons
33Unit Heater cost justification Gravity Vent or
Power Vent?
- Total Incremental heaters - 170
- Assumed LP Cost - 1.00 / gallon
- Fuel cost difference - 363 / season
- Simple payback 170 / 363 0.47 season
- Since this is based on the greenhouse being used
5 or 6 months, the incremental cost is paid back
in 3 months.
34Non-vented unit heaters
35Non-vented unit heaters
- MUST be used with fresh air intakes
- Oxygen depletion in tight greenhouses poor
combustion
- 1 in2 air intake area per 1000 to 2000 Btu/hr of
furnace capacity
- 2 to 3 diameter opening for a 250,000 Btu/hr
heater
- Increases CO2 levels
- Good for plants
- Could be used in place of a CO2 generator
- Increases H2O levels
- Can increase / cause disease problems
- Increased condensation lower light levels
- Only recommend using NG or LP gas
- Combustion byproducts from oil / kerosene harmful
to some plants (tomatoes)
- Ethylene, Sulfur Dioxide, Nitrous Oxide, CO
36Outdoor Wood Boiler
- Cheaper Fuel? What is the true cost?
- Disposal of Ash
- Labor to re-fuel
- Great for use with floor heating
- Can use with Air Exchanger
- Fuel with scrap materials?
37Heating Maintenance
- Heat Equip. Maintenance
- Insulation of pipes and ducts in head-house
- Clean Air heat Exchanges
- Lubricate motors fans
- Remove Soot can reduce fuel consumption by 10
- Steam trap maintenance
- Burner tune up
- Change fuel filter
- Correct nozzle
- Thermostat Calibrate annually
- Up to 20 fuel savings
- Provide air intakes for Boilers and unit heaters
- Smell of combustion gases indicated lack of large
enough air intakes
38Greenhouses - Heating
- 2 Heating system efficiency increase
- in 30 foot by 100 foot greenhouse
- Saves 200 gallons of Fuel oil
- or 330 gallons of Propane
- or 285 Therms of Natural Gas
- per year
39Greenhouses - Heating
- Heating System Distribution
- In-Floor heating w/ Floor growing system
- Concrete floor not needed
- Bench heating
- Lower heating costs 20-25
- Study - 7 increased yields for tomatoes
- Forced Air Under-bench distribution
- Poly tubes under bench
- Approximately equivalent to a 5F reduction in
greenhouse temperature.
40Central Heating Systems
- High Efficiency Heating equipment 90
- Hot water systems - Munchkin Boiler 92 AFUE
- Residential Forced Air Furnace 90
- Radiant heating
- Waste oil boilers
-
41Environmental Controls
- Central Unit to control
- Heaters
- Fans
- Louvers / Vents
- Irrigation
- Lighting
- CO2
- Computer control ensures systems are not
competing
- Example - Heater on while fan is running
- Computer tied to on site weather data
- Anticipates heating and ventilation needs
42Alternative Energy Sources
- Utilize Waste heat cogeneration
- Landfill gas
- Dane Co Landfill - 2 MW of waste heat
- Manure Digesters
- Power plant reject heat
- Wind Turbines
- Geo-Thermal
43Space Utilization
- Racking Systems
- Take advantage of different plant light and
temperature requirements
- Bench Layout
- Longitudinal 59
- Peninsula 69
- Movable 81
44Bench LayoutSpace Utilization
45Greenhouses - Ventilation
- Energy-Efficient Fans
- Efficiency ranges from 12 to 27 CFM/watt
- Test data available at
- BESS Lab - http//www.bess.uiuc.edu/index2.htm
- Air Movement Control Association
www.amca.org
- http//cart.amca.org/publications/product.asp?PN2
62/ND
- 36 or 48 fans efficiency greater than 20 CFM
/ watt _at_ 0.05 H2O
46Greenhouses - Ventilation
- Fan Maintenance
- Shutter lubrication (dry lubricant graphite) /
maintenance
- Shutter can reduce air flow by 40
- Belt tension / alignment Automatic tighteners
- Loose belt can reduce air flow by 30
- Trim weeds shrubs
- Bearing lubrication?
- Should be using Totally Enclosed motors (with
sealed bearings)
47Greenhouses - Ventilation
- Shade Cloth
- Aluminized shades 10ºF lower air temperatures
- Internal Shade cloth can double as thermal
curtain
- Evaporative cooling
- Misting
- Roll-up side walls
- Open Roof Designs
48Supplemental lighting
- Shorten / predictable time to market
- Plant later Less heating
- Earlier Flowering
- T-8 Fluorescent lamps Growing Chambers
- HID lamps Greenhouse
- High Pressure Sodium most energy efficient
- Pulse Start Metal Halide more blue light
- Incandescent lamps inefficient, low output /
lamp
- Lamp Controls
- Timer
- Light integral controller
49Supplemental Lighting
- Response and effect varies greatly
- Short-day plant
- Day-neutral plant
- Long day plant
- Plug and Liners more root development
- Greenhouse Veg. High daily light integral (DLI)
requirements.
- Cut Flowers supplemental lighting common
- Use Off-Peak electric?
- Lighting Up Profits, Paul Fisher Erik Runkle,
2004.
- www.pllight.com/horticultural/publications.php
50Greenhouse Tools / Resources
- Greenhouse audit tool
- AgEnergy Resource web site
- www.uwex.edu/energy
- Energy Conservation for Commercial Greenhouses,
NRAES-3, Ithaca, NY, 2001.
- Greenhouse Engineering, NRAES-33, Ithaca, NY,
1994.
- www.nraes.org
- National Greenhouse Manufacturers Association
- www.ngma.com
51Wisconsin Focus on Energy
- Public / Private partnership - goal to conserve
energy
- Focus is on electricity and natural gas / propane
- Services are available to 85 of homes
businesses in WI
- Promotes Energy conservation Renewable energy
- Program areas
- Residential
- Business
- Industry
52Wisconsin Focus on Energy Agricultural
Program
- Free Energy Audits
- Information collected via farm visit or by phone
/ mail
- Standardized model used to estimate energy
savings
- GRANTS available to encourage installation of
high
- efficiency equipment
- Consultants are independent dont sell
equipment
- Must be serviced by a participating utility to
receive
- grants
- Provide educational materials
53Focus on Energy
- www.focusonenergy.com
- 1-800-762-7077
- 1-608-273-0182 direct line to Ag program
- Renewable Energy program
- (wind, bio-gas, solar)
- 1-888-476-9534
- Larry Krom
54USDA 9006 Energy Efficiency
- Open to rural businesses
- Cover up to 25 of project costs
- Minimum grant 2500 10,000 project
- Must have a minimum of 15 energy savings
- Competitive grant process - 23 M available
- Application period now open
- Closes June 26, 2005
- http//www.rurdev.usda.gov/rbs/farmbill/
- Video conference April 26,2005
55Contact Information
- Scott Sanford
- Sr. Outreach SpecialistFocus on Energy / Rural
Energy Issues
- Biological Systems Engineering
- University of Wisconsin Madison
- 608-262-5062
- sasanford_at_wisc.edu
- Energy Resource Site - www.uwex.edu/energy
- www.focusonenergy.com 1-800-762-7077