When Drip Edge Becomes A Double Agent

Drip edge flashing is supposed to push water away from houses. It is the front line of defense for most horizontal planes in a building: top and bottom of a window, roof eave, balconies, base of wall, etc.

Because of water has a unique ability to stick to surfaces—like when you wash your hands, and then lift them from the sink, and the water runs down your arms to your elbows (instead of dropping straight from your hands). Because houses don't have elbows, people use geometry to kick water away from walls.

Drip edge /drip ej/ (noun)

"The leading edge of a flashing, sill, overhang or other linear, horizontal building element designed to shed water."
—RDH Building Science Labratories

Without elbows, water flows over the surface of a house—the wall—until it hits the ground. And soaks into the basement. If the surface of the house is brick, then all of this water can have serious freeze/thaw implications. If it is wood, then there could be serious rot implications. If it is something else, then there are other implications.

So, can you trust drip edge to do its job?

Jonathan Smegal is a senior researcher with RDH Building Science Laboratories and he wondered that too. So he built an apparatus to test it.

Driop edge profiles tested by Jonathan Smegal

Smegal tested scenarios using different edge profiles, materials, and overhang distances.

Turns out, there are turncoats in the drip edge ranks: some profiles actually do more harm than good.

Hemmed drip edge metal can actually direct water toward a building

Key findings:

Hemming the drip edge has the greatest effect on its water-shedding ability—and not the good way. Because of surface tension, water follows the radius of the hem, so it actually directs the stream toward the house, even if the hem is angled out. This effect was greater for thick drip edge (12 gauge) than for the thinner drip edge (20 gauge) because thick metal makes a wider radius when you bend it.

Larger overhangs (45 mm or 1-3/4 inches if you live in the states) shed more water than smaller overhangs (20 mm or 3/4 inch). This was the case in every test but one. #TheresOneInEveryCrowd.

Adding a 45° kickout increases shedability from the apparatus compared to a 90° vertical drip edge (image at right shows 90 degree bend that is hemmed—worst of two worlds).

In general, thinner metal distributes water better than thick metal, but thin metal may require a hemmed edge for strength and rigidity, so go back to finding 1 and remember that hemming is bad.

Stone distributes water horizontally into a line of many drips, whereas metal concentrates water horizontally into a few fast-moving streams.
Sloped stone (8°) with a 3/4 inch overhang shed all of the water to the ground, directing none to the wall. The water moved slower and horizontally before driping neatly to the ground.

Jonathan's recommendations:

Something is better than nothing. Less-than-ideal drip edges may still perform well, but they may potentially stain the cladding.
Thicker is better, but don't hem it. One practical conclusion suggested by this study is that drip edge performance can be improved by increasing the thickness of the metal drip edge so that it does not require a hemmed edge. For example, it would be better to use 12 gauge without a hemmed edge, compared to a 20 gauge with a hemmed edge, especially when the overhang distance is small.

Read the original research paper:

Effectiveness of Different Drip Edge Designs, Smegal, et al

When Drip Edge Becomes A Double Agent

Key findings:

Jonathan's recommendations:

Read the original research paper:

About the Author

Dan Morrison

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