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REL CONSTRUCTION DETAILS 

Metric SI Units

• Standard production home (NOT a custom home) with a few modifications on a small urban lot. 
• Modest size of 149 m², based on outside dimensions, with single floor living area, and conditioned crawl space
• Wall construction type can generally be described as having wood stud walls (about 44 x 140 mm), spaced at 610 mm on center, filled with wet cellulose and then covered on the outside with 51-mm thick rigid foam.  This construction approach for walls was compared by Building Science Corp. with other advanced wall construction types, and this approach was tied with two other approaches for the best wall design based on five, equally rated criteria: thermal control, durability, build-ability, cost, and material use (Building Science Wall Discussion).

• Loose cellulose (density spec. of 34.0 kg/m³) blown over attic floor, with thickness of about 480 mm giving R_SI* = 10.6 K-m²/W (same units used for all R values in the section, but noted simply as "R_SI").   Since the thermal  conductance U=1/R, then U_SI = 0.094 W/K-m².  Raised heel trusses used for full height insulation near edge of roof.  Ventilation baffles used for soffit ventilation with deep insulation levels. (Insulation not at full depth in picture below, but ventilation baffles and raised heel visible.)

• 44x140 mm wood stud wall spaced at 610 mm, covered with OSB (oriented strand board) sealed completely on sides, top. and bottom of every stud cavity and all penetrations with expanding foam, and filled to 140-mm thickness with sprayed-in wet cellulose (nominal density = 49.3 kg/m³)  Then the OSB is covered on the outside with 51-mm of XPS (extruded polystyrene Styrofoam) rigid foam, then Tyvek air barrier, and then concrete-fiber siding.  Interior wall height is 2.439 m, and walls are covered in Sheetrock.  This construction gives a wall with a thermal resistance value (including Sheetrock, sheathing, siding, and short-circuiting by studs) of about R_SI = 4.90, or thermal conductance of U_SI = 0.204, assuming a framing factor (fraction of wall area filled with studs, excluding open areas) of 19%.

• Infiltration reduction boxes around all electrical boxes on exterior walls, filled with fiberglass insulation after sealing electrical wiring feedthroughs

                                                               

• Conditioned crawl space with 38 to 50-mm of closed cell foam sprayed on inside of the rim joists that are about 300 mm high to provide an air barrier and insulation, covered with about 150-mm thick R_SI = 3.3 fiberglass insulation to the inside of the closed cell foam, plus 51-mm of XPS rigid foam (R_SI = 1.76) on the outside of the rim joists, for a total thermal resistance of about R_SI = 6.0, or U_SI = 0.167
• 0.91-m high crawl space walls below the rim joists insulated on the inside with R_SI = 3.3 fiberglass bats (continuous), and extending out on crawl space floor 0.3 m.  Crawl space walls extend 0.15 m above ground level on the outside, with the remainder 0.76 m below ground.  The use of fiberglass batts on crawl space walls can lead to moisture problems, and is not recommended by Building Science Corp., Building Science report on high-R value foundations although the REL is located in a high mountain desert with very low humidities.  
• 51-mm thick x 200-mm high XPS rigid foam on inside footings with R_SI = 1.76.  Gravel was filled in for the crawl space floor to the top of the rigid foam.  The R_SI = 3.3 fiberglass bats mentioned above overlap this rigid foam since the batts extend out onto the crawl space floor. 

• 25-mm thick XPS rigid foam (R_SI = 0.88) between ground and gravel (200 mm of coarse, round gravel) that makes up crawl space floor .  Fiber-reinforced 0.3-mm thick plastic covers the gravel. Since the gravel is insulated from the ground by the foam, and since the HRV pulls air from the first floor of the house into the crawl space, the gravel becomes a significant contributor to the thermal storage for the passive solar heat, weighing about 50,000 kg, or 50 metric tons.  (Pictures below show the rigid foam before gravel was added on top.)  

• Triple-pane, low-emissivity windows with high solar gain (SHGC = 0.49, with thermal conductivity U_SI = 1.76) on south, west, and some of the east side, and low solar gain (SHGC = 0.28, with U_SI = 1.65) on north and some of east side.  These thermal conductivities correspond to thermal resistance values for the high solar gain windows of R_SI = 0.57, and for the low solar gain of R_SI = 0.61.
• Double-cell cellular shades (most "room darkening" with foil liners) with side seals for all windows, and all are closed at night, with thermal resistance measured to be about R_SI = 0.35 for the room darkening shades and R_SI = 0.21 for the light-filtering shades.  Thus, the combined window and shade R-value (night-time only) for the high solar gain windows and room darkening shades is R_SI = 0.92, and for the low solar gain windows is R_SI = 0.82.  The air flow sealing at the sides of the shades is accomplished using a labyrinth-type seal as shown in the left hand figure below.  This image is looking almost vertically upward from the bottom of the window.  An end view of the penetrating piece that has been removed from the side of the window is shown in the right hand figure below.  The Z-shaped piece of flexible plastic seals against the inner set of cells in the cellular shade.   

• Two doors to the outside, both with storm doors, one combination estimated to be U_SI = 1.99 (R_SI = 0.50), and the other to be U_SI = 1.70 (R_SI = 0.59).  

• High-efficiency (97.5%), natural gas fired, modulating, condensing furnace with ECM fan motor.  The maximum firing rate is 17.6 kW.  "Modulating" means that the furnace first fires at 70% of the full rate for 30 to 45 s.  Then it reduces to the minimum firing rate of 35%.  The firing rate is automatically adjusted to meet demand, increasing gradually to maximum firing rate (100%) if the thermostat is not satisfied within a defined time.  
• Heat recovery ventilation (HRV) system (to recover thermal energy from exhaust air and transfer it to incoming fresh air) rated at about 75% heat recovery, and using about 26 W continuously on low speed, and 70 W continuously on high speed with ECM fan motors
• Natural-gas fired, 5.9-kW input, direct-vent fireplace.  "Direct-vent" means that the combustion system is sealed, with combustion air coming from the outside, and combustion products vented to the outside.  
• Motion sensor bathroom fans with ECM fan motors
• Kitchen vent fan with ECM motor
• Energy Star rated ceiling fans throughout, with no air conditioning 

• Yearly average solar radiation on a flat plate collector aimed due south and tilted at an angle equal to the latitude is 5.9 kWh/m²/day at this location, so plentiful solar energy to work with 
• 3.15-kW (DC rating) photovoltaic solar system tied to grid with net use metering.  System includes 14 panels rated at 225 W each.  Mounted on garage/workshop at 26.6° tilt angle from horizontal, and 22° east of due south.  DC to AC conversion specified by manufacturer to be about 83.5%. Detailed performance documented at Energy Use Details.  

• Small solar hot water preheater with 2.32 m² absorber area mounted at 36.9° tilt angle from horizontal compared to latitude of 38.6°, 189-liter stainless steel solar storage tank, followed by natural-gas fired, tankless water heater with variable input firing range from 3.2 to 58.3 kW  

• Passive solar heating using high solar gain windows on south, west, and east sides contributes about 40% of the heating energy requirement.  A roof overhang of 0.61 m on south side limits solar gain during warm weather. Gravel that makes up the floor of the crawl space, and which is insulated from the ground, may contribute to the thermal storage of solar heat, and weighs about 50,000 kg. or 50 metric tons.  (Pictures below show south side.)

• High-efficiency refrigerator (343 kWh/yr. is official spec., and measured value is same within measurement uncertainty)
• High-efficiency, front-loading, clothes washing machine (due to low water use)  
• Electric clothes dryer with exhaust from center of house through conditioned crawl space, so some heat recovery during cooling season
• Fluorescent lights throughout
• Low-flow shower heads
• All drains are through conditioned crawl space, so some thermal energy recovery before water leaves house

• Blower door test used to measure air infiltration into house (before addition of storm doors) with negative pressure differential of 50 Pa, with resulting flow of 1440 m³/h corresponding to 2.45 air changes per hour ( ACH_50Pa) that corresponds to a "natural" ventilation rate of about 0.15 ACH

*R_SI  = K-m²/W = °C-m²/W
U_SI = 1/R_SI = W/K-m² = W/°C-m²

Discussion:

House Orientation - The house was oriented with the long dimension mostly north-south, but with the southern exposure 22° east of south.  This orientation was chosen not as an optimum orientation, but rather due to the street layout in the subdivision, and the standard floor plans that have the long dimension of the houses running at right angles to the street.  The side of the street was chosen so that the solar panels could be mounted on the back of the house and garage, and would be hidden from the street view since there were no other solar panels in the neighborhood at the time of construction.  Also the porch on the front of the house would block much of the winter sun if the house had the front facing south.  By serendipity, solar PV panels operate at best efficiency at this location when pointed 11° east of south according to the computer model PVWatts v2.0, and the orientation 22° east of south is predicted to provide 0.2% better power than a due south orientation!  The effects of the tilt and azimuthal angles on collection efficiency are discussed in more detail in the section REL photovoltaic system.   

Ceiling Height - The ceilings are 2.74 m high throughout the house, with no cathedral or raised ceilings.  

Summer Cooling - The house is located in a high mountain valley in Colorado at about 2200 m elevation.  It has ceiling fans in every room, but no air conditioning.  July has the highest average temperatures, with an average daily high of 28°C, and an average daily low of 9°C.  By opening the windows at night and the closing the windows in the morning, cool air is sealed inside the house, and the house remains comfortable during the day.  The highest temperature inside the house observed during the past summer was about 24°C or 25°C. 

Solar Domestic Hot Water System - Using a tankless water heater downstream of the solar storage tank allows the solar hot water pumps to operate any time that the solar thermal panels are significantly hotter than the water in the storage tank.  If the solar storage tank were heated using axillary heat to a delivery temperature of approximately 52°C, then the solar hot water pumps would only run when the solar thermal panels were in excess of the 52°C.  Using the separate solar storage tank upstream of the tankless heater allows the solar collectors to operate more often and at higher efficiency, since the collection efficiency drops with increasing water-inlet temperatures.   A disadvantage of this approach is that at low hot water flows, the tankless water heater apparently cannot run at low enough heat input, so it does not turn on, and the delivered water is colder than desired.