Right now, it seems like your hard-earned dollars are flying out of your house! High heating bills, excess energy wasting, and the impact of fossil fuels on the environment raise plenty of concerns: Should you spend your paycheck on utility bills or on improving your home’s efficiency? Should you add insulation? Should you replace your windows? What are the most cost effective options? And how does your heating relate to issues like mold, moisture and ice dams? The possibilities are endless, but which options are worth the investment? It is very confusing.
R-Value is a Lie (And Other Provocative Titles)
Or at least as Allison Bailes posted earlier this year, it is not a constant.
Green Building Advisor once published my post on thermal bridging. The audience there is an extraordinarily knowledgeable one which leads to some spirited discussions. Following the thermal bridging article, there was some jockeying over whether R-value is an objective value and if it is over-rated. My belief is that R-value measuring a material’s thermal resistance is just one material property that needs to be considered.
There’s air permeance, vapor permeance, water resistance, etc. Some commentators opined that being overly concerned about some of these other properties colors the fact that fiberglass is largely effective. Or is it?!? (*DUN DUN DUNNN!!*)
Building Science Corp to the Rescue
It is. Building Science Corp, notorious through the building industry for pursuing building science, released some findings of their insulation material testing. What they’re doing is that having constructed one of the most advanced testing facilities in the world, Building Science is putting building materials to the Building Science Test (TM). One verdict: temperature matters.
Temperature matters for insulation performance but not uniformly for all types of insulation. First, the good news. Fiberglass, cellulose, Expanded polystyrene (EPS) and Extruded Polystyrene (XPS) foam board performed better than the R-value that was tested at lower temperatures. The bad news? Polyisocyanurate, an insulation with one of the highest R-value per inch and very commonly used for exterior sheathing, performed below the tested R-value. Not so good.
Polyisocyanurate Foiled
What does this revelation mean for insulation and green building? Polyisocyanurate is primarily used for exterior sheathing insulation. In warm climates, this shouldn’t be a problem. Cooling climates that are more concerned with the hot summers than cold winters won’t have any issues. Knock yourself out with the exterior insulation and when the January weather dips down to 45, well, that is tough.
In cold climates, this changes. Polyisocyanurate insulation performance drops as the temperature drops meaning 6 inches of exterior foam board may not be delivering the R-value advertised on the label.What does this mean for construction and design? The main upshot is that if you use polyisocyanurate insulation, plan for reduced performance in cold climates. Design for an extra layer of polyiso or some similar adjustment to hit the target R-values.
It would be nice if there were one number with which to gauge the effectiveness of insulation. It has many different properties like any material. That the r-value flucuates with temperature may be a bit disconcerting but ultimately requires only a modest adjustment in your planning for home projects.
How to Avoid Mold Part 2 – Control Temperature
An Energy Auditing Blog article on reducing mold risk by reducing the homeowner’s ‘water sports’ (water related activities in the house) was published at GBA last week. Allison Bailes, the self-described energy guy with the funny name, rightly pointed out that temperature plays a key role as well.
Temperature Makes Humidity Relative
Relative humidity is exactly that…relative. Relative to the current temperature and pressure conditions. Moisture exists in the air as water vapor, one of the gases in the atmospheric mix. As the temperature rises, water vapor can make up a larger portion of the gaseous mixture.
Relative humidity is the amount of water vapor in the air as a percent of the maximum possible humidity at that temperature. If you lower the temperature with the same moisture, the relative humidity rises.
And when humidity reaches 100%, well, $%^& gets real.
100% Humidity Means Temperature Problems
When air is saturated with moisture and the temperature drops further, it can no longer hold the moisture. The moisture is wrung out of the air mix as condensation. It’s the reason you see morning dew on grass. The temperature plunges overnight and can’t hold the same moisture it could 30 degrees ago. This temperature where water vapor condenses out of the air is the dew point.
Allison’s point was that under normal humidity conditions, cold surfaces can still grow mold. The temperature dip increases relative humidity and the likelihood of condensation. It recalled one of my favorite audit photos:
This picture showed some poorly installed insulation near the house’s shower. The high humidity would rapidly cool as it neared the uninsulated section of ceiling. The moisture condensed out of the saturated air and eventual grew that nice patch of mold.
What Does This Mean for Buildings?
What does this mean for buildings? Controlling moisture is one factor in curbing mold growth but controlling surface temperatures is another. The house’s air barrier needs to be wholly intact to keep interior air from contacting cold sheathing material. Properly installed insulation will warm potential condensation surfaces, keeping them over the dew point. Buildings sheathed with foam board insulation warm the interior walls, ameliorating condensation-based mold issues.
Mold creation has a few different factors. One is temperature. So control your surface temperatures and control the mold.
Should I Insulate My Basement Ceiling – Infrared Chimes In
The most popular post on this site is, Should I Insulate My Basement Ceiling. Yay, 1st spot on Google searches! The number of reader comments is also a pretty good measure and I get a number of emails. There are tons of questions and some dissenting opinions. My view is that the easiest, most consistent approach in any house is to marry the structural boundary with the thermal, vapor and air controls as closely as possible. Put the insulation etc. where the wall is.
Put The Insulation On The Wall
It is what makes closed cell spray foam great (ignoring the merits of it’s green credentials for a moment) and the foundation wall lousy. Closed cell spray foam is the Swiss Army knife of insulation, combining the thermal, vapor and air control layers of the building enclosure in one application. Concrete foundations do exactly one thing well: sitting there and holding up your house. They have almost no insulating value (about r-1 per 8 inches of concrete), they’re porous to moisture and depending on a bunch of factors can even have some small air permeability (for example, a giant crack).
Add to that the difficulty of truly defining the building enclosure at the basement ceiling. You’ve got radon mitigation pipes, electrical penetrations, plumbing chases, chimneys, stink pipes, thermal bridging across the floor joists and oh, yeah, the stairwell. Did you insulate and seal that giant hole for the stairway? No? Then your basement ceiling isn’t the thermal boundary.
So where should we stick the insulation?
Here are a couple of thermal images of foundations:
These were taken in July with an outdoor temperature around 80 F. You can see the heat radiating through the concrete.
During the winter, these images would be inverted. Outdoor temperatures would’ve plunged to 10 F or lower and the above grade portion of the foundation would be cold. The above grade concrete would show very aggressive heat loss, right next to the hot water pipes strung along the basement ceiling joists. Yech.
Stick your basement insulation on the structural barrier to the exterior and where the most aggressive heat loss is occurring.
Options for Insulating the Basement
I’m copying this over from the other post as it is a good summary.
It is worthwhile to add insulation over your exposed foundation walls. Before insulating, the basement moisture should be well controlled with exterior and interior systems (french drains, gutters and contoured landscaping outside, sub-slab ventilation, perimeter drains and vapor barriers inside).
You should opt for a water resistant insulation such as closed-cell spray foam or XPS foam board. Avoid using fibrous insulations like fiberglass, rock wool or cellulose which could trap moisture, especially if installed with an interior vapor barrier. Be sure you check with your local building department as some insulations that are flammable – such as closed cell foam – must be covered with drywall or other approved material to prevent rapid fire/flame spread.
This article details the questions and concerns with basement insulation in greater depth.
Other Reading
For more details on the exact thermal and hydro dynamics, Joe Lstiburek of Building Science helps with ‘Understanding Basements‘.
A brief how to guide on insulating a basement wall.