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Is Your Envelope “Effective”?
Mark Lawton P.Eng Morrison Hershfield Limited Vancouver
Designing an “Effective Envelope”
• Roofs • Below Grade Walls and
slabs • Glazing & Windows • Opaque portions of walls
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Energy Consumption in Buildings
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LEED and Energy
• As a prerequisite (EAp.1) you must: • Reduce design energy cost by 18% over the reference building built to
ASHRAE 90.1-1999 • An additional 10 points are available for exceeding the minimum. • Compliance shall be demonstrated using whole-building simulations
HOWEVER, THE RULE OF MODELING IS GARBAGE IN = GARBAGE OUTSO WHAT VALUES DO YOU PUT IN YOUR MODEL?
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LEED and ASHRAE 90.1
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• For steel-framed walls, ASHRAE 90.1 specifies amaximum effective conductivity of U-0.08 (R-13effective)
• To reduce effective U-value by 18% we require R-16effective
• In terms of nominal (rated) R-values, R-16 could be achieved using R-12 battinsulation + R-9 continuous insulation, or R-16 continuous insulation
Why Use Effective R-values?
• Nominal R-values are the rated insulation values provided by the manufacturer
• Effective R-values are the actual thermal resistances provided by the insulation in a given assembly
• Effective R-values can be much less than the nominal R-value of the insulation due to thermal bridging.
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Opaque Wall Examples
• “Loss” in insulation value is due to thermal bridges: conductive elements which pass through the building thermal envelope
• Use of elements such as steel stud framing, z-girts, or exposed concrete slabs can result in major thermal bridging effects
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Opaque Wall Examples
• Note continuous rigid insulation • Referred to as “continuous”
since no steel passes through Concrete Mass Wall Building type the insulation layer
• Not a lot of exposed concrete • Panel on left is window wall
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Opaque Wall Examples
Steel Stud & Metal Panel Wall Cladding Girts Metal Panel Wall
• More than 50% opaque wall • Can be horizontal or vertical • Exterior insulation fits between
girts creating thermal bridging
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Opaque Wall Examples
Masonry Veneer Over Steel Stud Masonry Veneer Wall Ties
• Minimal exposed structure • Thermal bridge at shelf angle • Minimum thermal bridge at ties
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Thermal Bridging – 3D, 2D or 1D
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Effects of Thermal Bridging Ef
fect
ive
Wal
l R-v
alu
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16
14
12
10
8
6
4
2
0
5.5" cavity with insulation (R20 Batt) 3.5" cavity with insulation (R12 Batt) 5.5" uninsulated cavity 3.5" uninsulated cavity
0 5 10 15 20 25 30 35
Nominal R-Value of Exterior Insualtion
• Thermal bridging affects both the stud space and the exterior insulation
• R20 Batt in 5 ½” cavity gives and effective R14
• Maximum effective R value levels off around R16
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Effects of Thermal Bridging
• MH conducted thermal modeling to establish effective U-values for standard wall assemblies
• Modeling indicated that traditional cladding attachment methods, such as z-girts, greatly reduce insulation performance
• Nominal R-values of insulation Vertical Z-girts are deceptive
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Layered Girts
• A layer of insulation and horizontal z-girts topped by a layer of insulation and vertical z-girts
• Roughly 60% improvement over regular z-girts
Combined Horizontal and Vertical Z-girts
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Thermally Broken Girts
• MH also modeled “alternative” cladding supports, designed to reduce thermal bridging and thus improve wall U-values
• Thermally broken z-girts
• Roughly 45% improvement over regular z-girts
Thermally Broken Vertical Z-girts
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Intermittent Girts
• A layer of insulation and horizontal z-girts topped by a layer of insulation and vertical z-girts
• Percent improvement depends on how much of the girt is left
Intermittent Vertical Z-girts
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Slab Edge Detailing
• MH also performed modeling to determine the impact of slab edge detailing on effective wall U-values
• Shelf angles or exposed concrete slabs provide a thermal bridge through the exterior plane of insulation
Shelf Angle and Brick Ties
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Slab Edge Detailing
• Mounting shelf angle on brackets substantially reduces thermal bridging
• Other slab edge modeling included: • fully exposed slabs (i.e.
balconies, eyebrows) • insulation and z-girts outboard
of slab edge
Shelf Angle Mounted on Brackets
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Effective R Value Tool
Program to compute the effective R-value of an elevation
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Lookup Tables
• MH developed a tabular method of presentingresults
• Select the desired effective R-value, then look acrossthe table to see the necessary insulation thickness for common insulation types and cladding systems
• Tables allow easy comparison of different wallsystems when trying tomeet a required effective R-
Summary of Effective Thermal Resistances for Exterior value Insulated Walls (No Insulation in Frame Cavity, Slab
Effects Ignored)
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22 2.62.60.00.00.0 4.23.80.40.40.5 5.44.80.70.81.0 7.56.31.41.72.0 97.32.12.53.0
10.38.22.83.44.0 11.59.13.54.25.0 12.6104.25.06.0 13.410.64.95.97.0Exterior
Insulation Placed
Outboard of Slab
2.62.62.60.00.00.0 3.83.83.40.40.40.5 4.84.74.20.70.81.0 6.46.465.11.41.72.0 7.87.675.72.12.53.0 98.57.96.32.83.44.0
10.29.48.76.93.54.25.0 11.210.39.47.44.25.06.0 12.111.19.97.84.95.97.0Exposed
Concrete Slab or Balcony
2″ x 1/16″ Brick Ties
Vert. & Hor. Girts
Hor. GirtsVert. GirtsSpray foamEXPSMineral Wool
Effective Wall R-ValueInsulation Thickness (Inches) Type ofThermal
Bridging atSlab
Type ofThermal
Bridging atSlab
Insulation Thickness (Inches) Effective Wall R-Value
Mineral Wool EXPS Spray foam 2″ x 1/16″ Brick Ties
Shelf Anglebolted to slab
Shelf Anglefastened to 3”x
¼” steel brackets spaced
at 24” o.c. 7.0 5.9 4.9 13.8 16.8 6.0 5.0 4.2 12.8 15.2 5.0 4.2 3.5 11.5 13.5
¼” Shelf Angle
4.0 3.4 2.8 10.1 11.6 3.0 2.5 2.1 8.7 9.7 2.0 1.7 1.4 7.1 7.7 1.0 0.8 0.7 5.1 5.3 0.5 0.4 0.4 4 4.1 0.0 0.0 0.0 2.6 2.6
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The Payback
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Thank You
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