Size: length ft., bay width ft., number of bays: Square feet of floor space: Sq. ft. of bench/floor space covered by crops:

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Greenhouse Energy Conservation Checklist/Audit (Adapted by A.J. Both, Rutgers University, and Paul Fisher, University of Florida from a checklist developed by John W. Bartok Jr., Professor Emeritus, University of Connecticut) 2007 Structure #/name Approximate year built Dimensions and space use Size: length ft., bay width ft., number of bays: Square feet of floor space: Sq. ft. of bench/floor space covered by crops: % Space utilization (floor area used for crop production/total floor space)? Number of hanging baskets: Sq. ft. of floor space per hanging basket: List main crops [in general groups (e.g., plugs)] grown in the greenhouse at different times of year: Crop type Months Sq. ft. of greenhouse space filled Is the greenhouse used for production? retail? both? Are crops grown on floor, benches, overhead? (check all that apply) Are plants grown in one or multiple levels (e.g., hanging baskets)? Yes No Is a roll-out bench system used for spring bedding plant production? Yes No Is the greenhouse completely filled with plants during the time it is heated? Yes No Suggestions (consult an expert) to improve space utilization: Greenhouse Energy Conservation Checklist/Audit Page 1 of 8

Greenhouse glazing and leaks What type(s) of film/rigid panel/glass is(are) used? What is the condition of the glazing material? Excellent Good Fair If polyethylene film, does it have an IR barrier? Yes No does it have a no-drip surface? Yes No is it inflated using outside air? Yes No Which greenhouses surfaces are covered with a double layer (including multi-wall panels)? End walls Sidewalls Roof Is the greenhouse located in a wind sheltered area (without reducing sunlight)? Yes No Are windbreaks installed around the greenhouse (without reducing sunlight)? Yes No Does the greenhouse feel drafty? Yes No Do you observe any undesirable leaks/openings in the greenhouse cover? Yes No Are doors/windows closing properly and kept closed when not in use? Yes No Does the ventilation window close properly? Yes No Do the fan louvers close properly? Yes No NA Suggestions (consult an expert) in terms of glazing and leaks: Shade curtain Is a shade curtain installed? Yes No If yes, does the shade curtain also serve as energy blanket? Yes No what is the shade factor (%) of the curtain? what is the energy savings factor (%) of the curtain? what is the control strategy followed for closing the curtain to conserve energy? what is the control strategy followed for opening the curtain after a cold night? what is the control strategy for using the curtain as shade screen? Suggestions (consult an expert) in terms of shade curtains: Greenhouse Energy Conservation Checklist/Audit Page 2 of 8

Perimeter insulation Has perimeter insulation been installed? Yes No If yes, what material, how thick and to what depth? If applicable, are knee walls (or side walls to bench height) insulated? Yes No NA Is the wall area directly behind side wall heating pipes insulated? Yes No NA What is the condition of the various insulation materials? Excellent Good Fair NA Suggestions (consult an expert) in terms of perimeter insulation: Heating system (Note: calculation methods are provided at the end of this checklist) What type of heating system is used? Hot water Hot air Steam Other What is the manufacturer and model of the heating system? What is the total installed capacity of the heating system? What is the nighttime set point temperature? F What is the local minimum design temperature (consult figure on page 7)? F What is the total calculated heat requirement (calculate yourself or ask manufacturer)? Is the installed capacity adequate, given the heat requirement and desired delta T? Yes No What fuel source(s) is(are) burnt in the boiler/heaters? Does the grower use floor and/or bench heating? Yes No Is the temperature sensor or thermostat shielded from sunlight? Yes No in an aspirated box? Yes No within 3 feet of the crop canopy? Yes No at a representative location in the house? Yes No calibrated during the last 12 months? Yes No If the grower uses a thermostat, what is its accuracy? ± F is it an electronic thermostat? Yes No NA Are HAF fans installed and in use? Yes No commercial grade or residential house fans? turned off when venting air? Yes No Commercial Residential Greenhouse Energy Conservation Checklist/Audit Page 3 of 8

Did you observe any leaks in the hot water distribution system? Yes No NA Are the hot water heating pipes clean? Yes No NA Are the hot water distribution pipes insulated? Yes No NA Are hot water tanks close to largest and most frequent point of use? Yes No NA What is the temperature setting on the hot water storage tank? F Are heat exchangers (e.g., located inside unit heaters) clean? Yes No NA Is the unit heater or boiler power vented? Yes No NA Was the heating system serviced immediately before or during this cold season? Yes No Is there more than one heating zone (e.g. bench/perimeter zones or multiple bays)? Yes No Is there a backup heating source in case the main heater fails? Yes No Suggestions (consult an expert) in terms of heating system: Ventilation and Cooling Is the greenhouse naturally or mechanically ventilated? Naturally Mechanically If naturally, is the ventilation system motorized? Yes No If mechanically, is it an open-roof greenhouse? Yes No are the fans AMCA rated (check AMCA seal) and do they have a ventilation efficiency ratio (VER) larger than 15? Yes No Don t know are the fan motors variable speed motors? Yes No are the fans staged (and what is their staging)? Yes No are the belts on the fans tightened and aligned properly? Yes No are the blades balanced and in good condition? Yes No Are outside doors routinely kept closed when the greenhouse is venting? Yes Are indoor doors routinely kept closed between compartments? Yes No NA Does the greenhouse have an evaporative cooling system? Yes If yes, what type? Pad and Fan System Fog System Does the grower report any humidity problems? Yes No Suggestions (consult an expert) in terms of ventilation and cooling: No NA No Greenhouse Energy Conservation Checklist/Audit Page 4 of 8

Insect Screening Is the ventilation opening outfitted with insect screening? Yes No If no, does the grower report insect problems? Yes No If yes, what is(are) the type(s) of insect(s) that need to be screened out? If yes, what is the mesh size (or opening size) of the screen material? If yes, what is the pressure drop across the screen material? Inches of water gauge If yes, is the insect screen in good condition (i.e., without unwanted openings)? Yes No If yes, how often is the screening material cleaned? If yes, does the ventilation system provide adequate ventilation on warm summer days? Yes No Suggestions (consult an expert) in terms of insect screening: Drainage Does rain and melt water drain away from the building properly? Yes No Is there excess irrigation water on the floor Yes No Suggestions (consult an expert) in terms of drainage: Conserving Electricity Are all electrical motors high efficiency? Yes No Were any incandescent lamp bulbs replaced with fluorescent or HID bulbs? Yes No Was a licensed electrician involved in design of the system? Yes No Has the entire electric system been checked recently by a licensed electrician? Yes No How many phases does the electric system have? What is the voltage provided to the various electrical services? Is there a backup generator? Yes No Suggestions (consult an expert) in terms of electricity: Greenhouse Energy Conservation Checklist/Audit Page 5 of 8

Equations, figures and tables useful for heat loss calculations: Step 1: Determine greenhouse dimensions (in feet). Wall height A = House width B = House length C = Rafter Length D = Lower wall height E = Upper wall height F = Gable height G or H = Step 2: Calculate surface areas (in ft 2 ) and perimeter distance (in ft) Note: N is the number of greenhouse bays. N = 1 for a single bay greenhouse. Lower side wall area: 2N(E x B) + (E x 2C) = Upper side wall area: 2N(F x B) + (F x 2C) = Or, Single material side wall: 2N(A x B) + (A x 2C) = Gable-style greenhouse roof surface area: 2N x D x C = Gable-style greenhouse gable area (end wall above gutter): N x B x G = Curved-roof style greenhouse roof surface area: N x D x C = Curved-roof style greenhouse gable area (end wall above gutter): 1.1N x B x H = Hoop-house end wall area: 1.5N x B x H = Perimeter: 2[(N x B) + C] = Step 3: Determine U-values for each material used in the various surface areas. Lower wall area: U 1 = Upper wall area: U 2 = Single material wall: U 3 = Greenhouse Energy Conservation Checklist/Audit Page 6 of 8

End wall area: U 4 = Roof: U 5 = The U-values (heat transfer coefficients) can be determined from the data shown in the table below. Material U in Btu/hr per ft 2 per F Single (double) layer of glass 1.1 (0.7) Single (double) layer of poly 1.1 (0.7) Double layer plus energy curtain 0.3 0.5 Double layer acrylic 0.6 Double layer polycarbonate 0.6 ½ plywood 0.7 8 concrete block 0.5 2 Polystyrene 0.1 (R = 10) Step 4: Calculate the structural heat loss (Q STRUC in Btu/hr) Q STRUC = Σ(U i x A i ) x ΔT (i.e., the sum of all applicable heat losses) Heat loss from lower wall area: Lower side wall area x U 1 x ΔT = Heat loss from upper wall area: Upper side wall area x U 2 x ΔT = Or, Heat loss from single material wall area: Single material side wall area x U 3 x ΔT = Heat loss from gable or curved-end area: Gable or curved-end area x U 4 x ΔT = Heat loss from roof area: Roof area x U 5 x ΔT = Total Q STRUC = ΔT (pronounced delta T ) is the temperature difference between inside and outside, or the difference between the nighttime temperature set point (inside) and the local minimum design temperature (outside). This minimum design temperature can be determined for a particular location from historical weather data, or estimated from the figure shown below. Step 5: Calculate the perimeter heat loss (Q P in Btu/hr) Q P = Perimeter heat loss factor x Perimeter x ΔT Greenhouse Energy Conservation Checklist/Audit Page 7 of 8

For perimeter heat loss factor, use a value of 0.4 or 0.8 Btu/hr per linear foot of perimeter per F depending on whether the perimeter is insulated or not. Step 6: Calculate the greenhouse volume (in cubic feet) Gable-style greenhouse volume: N[(A x B x C) + (B x G x C/2)] = Single curved roof greenhouse volume: 2H x B x C/3 = Multiple curved roof greenhouse volume: N[(A x B x C) + (2H x B x C/3)] = Step 7: Calculate the infiltration heat loss (Q A in Btu/hr) Q A = 0.02 x Greenhouse volume x Air exchanges per hour x ΔT = For air exchanges per hour use the following table. Type of construction Air exchanges per hour New, glass 0.75-1.5 New, double poly 0.50-1.0 Old, glass and in good condition 1.0 2.0 Old, glass and in poor condition 2.0 4.0 Step 8: Calculate the total heat loss (Q T in Btu/hr) Q T = Q STRUC + Q P + Q A = Adjustment to the heat loss calculations should be made for situations with a large ΔT and/or locations with high average wind velocities: If ΔT is larger than 70 F, and if the average wind velocity is larger than 15 mph, multiply the calculated total heat loss by: (1 + 0.08) for every increase in ΔT of 5 F above 70 F and (1 + 0.04) for every 5 mph increase in average wind velocity above 15 mph. For example, if ΔT = 80 F and the average wind velocity is 25 mph, multiply the calculated total heat loss by a factor of: 1 + (0.16 + 0.08) = 1.24. If the greenhouse heating system is designed properly, the capacity of the heating system should match the calculated total heat loss Q T (that is the predicted heat loss on the coldest night). Make sure that the heating system has an output rating that equals the calculated total heat loss. When the heating system is rated by input, multiply this value by the efficiency of the system (generally in the 70-80% range) to determine the rated output. Additional reading: Aldrich, R.A. and J.W. Bartok. 1994. Greenhouse Engineering, NRAES Publication No. 33. Natural Resource, Agriculture, and Engineering Service. P.O. Box 4557 Ithaca, NY 14852. http://www.nraes.org. Bartok, J. W. 2001(revision). Energy Conservation for Commercial Greenhouses. NRAES Publication No. 3. Natural Resource, Agriculture, and Engineering Service. P.O. Box 4557 Ithaca, NY 14852. http://www.nraes.org. Greenhouse Energy Conservation Checklist/Audit Page 8 of 8

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