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How Much Does Wood Move2/26
On another Board, we had the question "How does wood, especially oak, move when the humidity changes (or moisture changes) and can movement be accurately predicted?" Because the answer impacts Cabinet Making too, the answer is repeated here.
#1. Wood shrinks and swells across the grain when the moisture content (MC) changes...swelling if the MC goes up and shrinking if the MC goes down. Wood seldom shrinks lengthwise. (The limited lengthwise shrinkage is why plywood, with the lengthwise direction being at 90 degrees in each adjacent sheet of veneer, is overall so much more stable than a solid piece of wood.)
There are two directions for across the grain- -TANGENTIAL (meaning parallel to the annual growth rings; the width of a flatsawn piece) and RADIAL (meaning perpendicular to the growth rings or the width of a quartersawn piece). The values for tangential movement would be the maximum movement; the values for radial movement would be the minimum. In practice, a perfectly flatsawn or perfectly quartersawn piece is not common, so we will likely have a bit less than the maximum for most flatsawn pieces and a bit more for most quartersawn or rift sawn pieces.
When dealing with oak, the highest shrinking commonly used species in North America, there are twenty species of red oak and twenty species of white oak that will show up in the commercial market. Each species within the grouping of red oak or white oak does move different amounts, as shown in the figure attached below.
#2. When dealing with shrinkage, green means 28% MC and 0% means 0% MC. Shrinkage from 28% to 0% (or swelling in the reverse) is a straight line with MC, so you can divide the total number by 28 to get the movement for each 1% MC change. Example, northern red oak is 4.0% radially and 8.6% tangentially. So that is (4.0 / 28 =) 0.143% size change radially for a 1% MC change, and (8.6 / 28 =) 0.307% tangentially for a 1% MC change. (Actually, the numbers are for thin pieces of wood; the thicker the wood is, the movement will be somewhat less, but not a whole lot less.
The values for every commercial species can be found in the WOOD HANDBOOK, Table 13-5 at www.fpl.fs.fed.us/documnts/fplgtr/fplgtr190/chapter_13.pdf
Two more points to go, so hang in there.
#3. The moisture content of wood changes about 1% for every 5% RH change...
Note that EMC (equilibrium moisture content) refers to the moisture in the air. It is the connection between humidity in the air and the MC in the wood.)
So, as a rough approximation, you could use the 0.143% and 0.307% size change for 1% MC change numbers above as the predicted size change for a 5% RH change as well.
Of course, the change is not instantaneous...the surface and ends change quickly (unless coated with a vapor resistant coating); the core may take days, weeks or months to change. (In fact, the core MC is often the MC that the lumber left the kiln at, as it takes quite a while for the core MC to change.) This slow change or movement of the core is also why thicker pieces of wood have less movement than thin pieces.
#4. Here is a minor point, but do read it please. If wood has been shrinking and the RH is lowered by 5% RH (or 1% EMC), then the wood will continue to dry by 1% MC and continue to shrink, as predicted. However, if a piece has been shrinking, but now is exposed to a humidity increase, there will actually be a lag in the response tot he RH and a lag in the change from shrinking to swelling. (Technically, this is called the hysteresis effect.) This effect is why, if we have lumber that has been drying and then this lumber is a bit too wet, but we use it anyway and then the wood is put into a dry environment so that the wood dries more, the size change can be fairly significant, resulting in gluing issues like open joints, size changes, warp, etc. On the other hand, if we have dry wood and then it goes into a summertime humid environment, the swelling change will not be as big as we calculated. Knowing this fact is why we often specify an incoming moisture of 7.0% MC, as we know the wood might dry to 6.0% MC in use during the wintertime or increase to 9.0% MC use in the humid summertime, but the 9.0% EMC will actually behave more like 8.0% EMC. Then the next winter when the wood dries again, it will be 6% EMC, but due to hysteresis, it will seem like 7.0% EMC. Again, that is why we almost always see moisture problems the first year the wood is put into use because the wood is often not quite dry enough, etc. So, maybe hysteresis is not a minor point after all.
If you want even a bit more practical stuff, consider two items:
B. Second. Do not humidify your shop above the humidity that your customer will have. If I humidify my shop to much, I am pushing the undesired shrinkage to the customer. But, I would rather have a defect show up in my shop (where I can repair them more easily) than in the customer's home or office. Of course, if I get the correct MC in my lumber initially, then I will not have to worry. Of course, some kiln drying operations do not dry all the pieces dry enough, as it is too expensive for them (shortsighted)- -it is actually not too expensive from your point of view.
Thanks for sharing this great information, the amount of people you have helped over the years will never go unnoticed!
Thanks for sharing a information with us.. If wood has been shrinking and the RH is lowered by 5% RH (or 1% EMC), then the wood will continue to dry by 1% MC and continue to shrink, as predicted.
If I may, please allow to me to add a real-world aspect to wood expansion and shrinkage. Although I am in south-central Texas, the temperatures can range from the occasional low 20's in winter to 95-100 in summer. The humidity can go from 25% to 65% and higher. At one time, my shop was totally in sync with the elements.
As a test, I attached one end of an 18" wide piece of red oak to a backer board and marked the width of the oak. Over a 2-year period, that piece of oak changed 3/8" from its point of minimum contraction to its point of maximum expansion.
So, extrapolation would indicate that a 72" (4x18") red oak tabletop -with the grain running side-to-side- could have an expansion/contraction range of 1-1/2" (4x3/8"). Of course, in an air-conditioned home, the relative humidity would not change quite so drastically, and applying a film finish would help buffer the changing moisture content. But actually seeing the range of possible movement in wood did make me re-think my design approach and my method of attaching the various components to one another.
Thank you very much for sharing this informative information with us, the number of people you have helped over the years will never go unnoticed!
Thanks for your very kind and appreciated words.