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#11
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Gordon Arnaut wrote:
There are many types of wood that can be used in constructing a proper airframe, as per AC-43.13b. I happen to like northern white pine, which has nearly the same strength-to-weight ratio as spruce -- and better than that of Douglas fir. NWP is about 15 percent lighter and about 15 percent less strong than spruce, so if your plans specify spruce you will want to increase the dimensions by about 15 percent. Trouble is it isn't that simple. Strength of many load bearing members (those loaded in bending or torsion, for example), is a linear function of size. It would take virtually a re-engineering of the structure to change species in most cases. Matt |
#12
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Matt Whiting wrote:
Gordon Arnaut wrote: There are many types of wood that can be used in constructing a proper airframe, as per AC-43.13b. I happen to like northern white pine, which has nearly the same strength-to-weight ratio as spruce -- and better than that of Douglas fir. NWP is about 15 percent lighter and about 15 percent less strong than spruce, so if your plans specify spruce you will want to increase the dimensions by about 15 percent. Trouble is it isn't that simple. Strength of many load bearing members (those loaded in bending or torsion, for example), is a linear function of size. It would take virtually a re-engineering of the structure to change species in most cases. Matt Matt, did you mean to say that it is NOT a linear function of size. Take a cantilevered beam. Regardless of the thickness, it's bending strength is the square of the thickness times the tensile strength. Say the beam as designed is 1" thick and can hold 1000lbs. You substitute a material twice as strong. Make it 1" thick and it can hold 2000lbs. Cut it in half (because it's twice as strong) and it can only hold (.5")^2 * 2000lbs = 500lbs. I'm not a mechanical engineer, and I've learned just enough to know that I don't know enough, so I may be wrong on the particulars; but I know for a fact that twice as strong but half as thick doesn't get you to where you started. -- This is by far the hardest lesson about freedom. It goes against instinct, and morality, to just sit back and watch people make mistakes. We want to help them, which means control them and their decisions, but in doing so we actually hurt them (and ourselves)." |
#13
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Ernest Christley wrote:
Matt Whiting wrote: Gordon Arnaut wrote: There are many types of wood that can be used in constructing a proper airframe, as per AC-43.13b. I happen to like northern white pine, which has nearly the same strength-to-weight ratio as spruce -- and better than that of Douglas fir. NWP is about 15 percent lighter and about 15 percent less strong than spruce, so if your plans specify spruce you will want to increase the dimensions by about 15 percent. Trouble is it isn't that simple. Strength of many load bearing members (those loaded in bending or torsion, for example), is a linear function of size. It would take virtually a re-engineering of the structure to change species in most cases. Matt Matt, did you mean to say that it is NOT a linear function of size. Take a cantilevered beam. Regardless of the thickness, it's bending strength is the square of the thickness times the tensile strength. Say the beam as designed is 1" thick and can hold 1000lbs. You substitute a material twice as strong. Make it 1" thick and it can hold 2000lbs. Cut it in half (because it's twice as strong) and it can only hold (.5")^2 * 2000lbs = 500lbs. I'm not a mechanical engineer, and I've learned just enough to know that I don't know enough, so I may be wrong on the particulars; but I know for a fact that twice as strong but half as thick doesn't get you to where you started. Yes, that is what I meant to say. Too bad my fingers aren't always connected to my brain. Hopefully, the context of the rest of what I wrote made the typo obvious. Matt |
#14
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Matt,
You are correct that resizing structural members is not as simple as simply increasing size by the same percentage amount that the substitute wood varies in strength. Yes, you do have to recalculate the structural stresses, but this is not that difficult. You can do this by applying the bending stress formula. This will give you the exact dimensions that you will need of the substitute material, in order to carry the same loads. There is an old Sport Aviation article that works through this, called "Selection and Evaluation of Wood," by Noel J. Becar. It is included in the EAA book, "Wood: Aircraft Building Tecniques." Regards, Gordon Arnaut. "Matt Whiting" wrote in message ... Ernest Christley wrote: Matt Whiting wrote: Gordon Arnaut wrote: There are many types of wood that can be used in constructing a proper airframe, as per AC-43.13b. I happen to like northern white pine, which has nearly the same strength-to-weight ratio as spruce -- and better than that of Douglas fir. NWP is about 15 percent lighter and about 15 percent less strong than spruce, so if your plans specify spruce you will want to increase the dimensions by about 15 percent. Trouble is it isn't that simple. Strength of many load bearing members (those loaded in bending or torsion, for example), is a linear function of size. It would take virtually a re-engineering of the structure to change species in most cases. Matt Matt, did you mean to say that it is NOT a linear function of size. Take a cantilevered beam. Regardless of the thickness, it's bending strength is the square of the thickness times the tensile strength. Say the beam as designed is 1" thick and can hold 1000lbs. You substitute a material twice as strong. Make it 1" thick and it can hold 2000lbs. Cut it in half (because it's twice as strong) and it can only hold (.5")^2 * 2000lbs = 500lbs. I'm not a mechanical engineer, and I've learned just enough to know that I don't know enough, so I may be wrong on the particulars; but I know for a fact that twice as strong but half as thick doesn't get you to where you started. Yes, that is what I meant to say. Too bad my fingers aren't always connected to my brain. Hopefully, the context of the rest of what I wrote made the typo obvious. Matt |
#15
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Gordon Arnaut wrote:
Matt, You are correct that resizing structural members is not as simple as simply increasing size by the same percentage amount that the substitute wood varies in strength. Yes, you do have to recalculate the structural stresses, but this is not that difficult. You can do this by applying the bending stress formula. This will give you the exact dimensions that you will need of the substitute material, in order to carry the same loads. There is an old Sport Aviation article that works through this, called "Selection and Evaluation of Wood," by Noel J. Becar. It is included in the EAA book, "Wood: Aircraft Building Tecniques." Yes, not that difficult, but definitely tedious and time consuming. I'd rather spend a little more time locating quality wood of the species specified by the designer than recalculating the sizes of all of the stressed members of the structure - which is a lot of calculation even on simple airframes. And then you may have to adjust a lot of other items (brackets, etc.) to accomodate the different dimensions. All in all, a lot of work and the increased chance of a miscalculation that could cause problems later. If someone was planning to make many airplanes using the new wood, then it would be worthwhile, but for a single airplane, it seems to me that the work would greatly outweight any benefit of using a different specie. Matt |
#16
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Matt,
You are right that resizing creates complications with brackets and other hardware. But this will take only a little time and effort to address. The calculations for the structural sizing are not that time consuming either. Let's take a Baby Ace spar for example which is made of sitka spruce, and for which we want to substitute white pine. The first thing is to calculate the moment of inertia (I) of the spar: I = width x height (cubed) divided by 12. So for the 3/4" wide by 5-1/8" high Baby Ace spar, the moment of inertia calculates to 0.75 x 5.125(cubed) / 12 = 8.41. Now we simply look up the modulus of rupture (Fbu), which is the strength in bending, for spruce and pine: 10,100psi for sitka and 8,800psi for pine (according to Forest Products Laboratory data). By plugging in the moment of inertia into the bending stress formula, we arrive at the maximum load this spar is capable of carrying: My = Fbu x I Where M = bending moment in inch pounds y = distance of neutral axis of spar to outer surface on compression side I = 8.41 (as we just calculated) So to arrive at the ultimate strength of the Baby ace spar we simply multiply I (8.41) x modulus of rupture of sitka (10,100). The answer is 84,941 inch pounds. This figure is the amount of load the spar was designed to carry, using sitka spruce. Now to subsitute pine all we have to do is rearrange the bending stress formula using the slightly lower modulus of rupture (Fbu) of pine. So first we want to solve for bending moment (I) using the substitute wood: I = My / Fbu = 84,941 / 8,800 = 9.65 Now that we know the moment of inertia we can solve for the increased width of the spar using pine: w = I x 12 / h(cubed) = 9.65 x 12 / 134.61 = 0.860 So the new width (thickness) of the pine spar is 0.860 inch, a little less than 7/8" (0.875). So we would only need to increase the thickness of the spar by a mere 1/8". Remember the stock Baby Ace sitka spar is 3/4", so our 7/8" pine spar would actually be a little stronger. That's all the calculation you would need to do for the whole airplane if most of the structure is made of 3/4" stock. If the longerons were specified as 3/4" sitka, you would again simply substitute 7/8" pine. I don't think this is a lot of work, because now I can go down to Home Depot and pick out some nice clear pine, bring it right home and start building an airplane. I think this is so much better than sending hundreds of dollars to some mail-order outfit and wondering what kind of beating the boards took in transit. One of the biggest dangers in using wood as a structural material is compression failures that are almost invisible to the naked eye. A piece of wood that has been severely stressed (such as sitting under some big heavy boxes on the UPS truck) may look perfectly good, but its fibers may be have completely lost their strength. A small amount of load and it will now snap like a twig. That's one of the reasons I don't like mail-order wood. That's also why you need to test a sample from each board you buy and look very carefully for compression failures or wood "crush." The EAA book I mentioned previously has a good article on this, written by Sam Evans, the designer of the Volksplane. Regards, Gordon. "Matt Whiting" wrote in message ... Gordon Arnaut wrote: Matt, You are correct that resizing structural members is not as simple as simply increasing size by the same percentage amount that the substitute wood varies in strength. Yes, you do have to recalculate the structural stresses, but this is not that difficult. You can do this by applying the bending stress formula. This will give you the exact dimensions that you will need of the substitute material, in order to carry the same loads. There is an old Sport Aviation article that works through this, called "Selection and Evaluation of Wood," by Noel J. Becar. It is included in the EAA book, "Wood: Aircraft Building Tecniques." Yes, not that difficult, but definitely tedious and time consuming. I'd rather spend a little more time locating quality wood of the species specified by the designer than recalculating the sizes of all of the stressed members of the structure - which is a lot of calculation even on simple airframes. And then you may have to adjust a lot of other items (brackets, etc.) to accomodate the different dimensions. All in all, a lot of work and the increased chance of a miscalculation that could cause problems later. If someone was planning to make many airplanes using the new wood, then it would be worthwhile, but for a single airplane, it seems to me that the work would greatly outweight any benefit of using a different specie. Matt |
#17
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"Gordon Arnaut" wrote One of the biggest dangers in using wood as a structural material is compression failures that are almost invisible to the naked eye. A piece of wood that has been severely stressed (such as sitting under some big heavy boxes on the UPS truck) may look perfectly good, but its fibers may be have completely lost their strength. ???????????????????????????????????/ You HAVE to be totally kidding. Unless that wood was sitting under a 10,000 lbs box on the UPS truck, it WILL NOT get compressive failure like that. Most compressive fractures take place when the tree is felled, and lands across a swag, or on another log. You had a pretty good writing going, but you lost all credibility, with that last line of crap. Also, rupture is not the only mode of failure that is important. You have to know if the part you are replacing is in tension, compression, bending, or what. There are different values for each mode. -- Jim in NC |
#18
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Do you have some sort of personality disorder?
If you disagree with something I said, then address it in civil terms as I have done when I disagreed with the other poster's point. There is no excusable reason to launch into a personal attack and what I wrote "crap." I would address your objections, but I don't argue with people who don't adhere to basic civility. You are obviously an odiferous idiot and as such I will ignore your stupid outburst. Gordon Arnaut. "Morgans" wrote in message ... "Gordon Arnaut" wrote One of the biggest dangers in using wood as a structural material is compression failures that are almost invisible to the naked eye. A piece of wood that has been severely stressed (such as sitting under some big heavy boxes on the UPS truck) may look perfectly good, but its fibers may be have completely lost their strength. ???????????????????????????????????/ You HAVE to be totally kidding. Unless that wood was sitting under a 10,000 lbs box on the UPS truck, it WILL NOT get compressive failure like that. Most compressive fractures take place when the tree is felled, and lands across a swag, or on another log. You had a pretty good writing going, but you lost all credibility, with that last line of crap. Also, rupture is not the only mode of failure that is important. You have to know if the part you are replacing is in tension, compression, bending, or what. There are different values for each mode. -- Jim in NC |
#19
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"Gordon Arnaut" wrote If you disagree with something I said, then address it in civil terms as I have done when I disagreed with the other poster's point. There is no excusable reason to launch into a personal attack and what I wrote "crap." I am normally a _very_ civil person, but I go off the deep end when someone makes a post retorting to have a command of subject matter, then displays an utter *lack* of grasp on the subject. People who know no better might believe you, and commit a design change/substitution that kills them. this is big stuff, with life ending possibilities. In order to have a compression fracture to take place, the wood has to be compressed past the ultimate failure of the species, in compression, or if it were bent, in rupture on the side of the board that is in the "low" side of the bend. How much force would be required would then depend on the specifics of the size of the stock. I would dare to say, that the loads required would be HUGE; it would be enough to crush the floor, and suspension, and blow the tires of a UPS truck, if it were say, a spar, of unremarkable size. That is not going to happen from having a box, or boxes, or even a V-8 engine sitting on it. How ridiculous! If you purport to write as an expert, dispensing advise, you must be prepared to take your lumps when you blow it. You blew it. Oh, by the way, pot, kettle, black. You seemed to do a pretty good job of not addressing me in a civil manner. I do not have a personality disorder, nor am I odiferous, nor am I an idiot. I was, however, bold enough to call you bluff on a subject you should not be writing about, if you are so far off base from knowing the basic causes of this kind of failure in wood. It seriously makes me wonder how far off base you are on the rest of the figures and concepts you wrote about. I might suggest that other readers also view the previous posts made by you with a *very* large grain of salt. Civil enough? If not, tough. Live with it. -- Jim in NC |
#20
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Morgans wrote:
In order to have a compression fracture to take place, the wood has to be compressed past the ultimate failure of the species, in compression, or if it were bent, in rupture on the side of the board that is in the "low" side of the bend. How much force would be required would then depend on the specifics of the size of the stock. I would dare to say, that the loads required would be HUGE; it would be enough to crush the floor, and suspension, and blow the tires of a UPS truck, if it were say, a spar, of unremarkable size. That is not going to happen from having a box, or boxes, or even a V-8 engine sitting on it. How ridiculous! Hey, Jim, I'm not trying to be odiferous (whatever that may be), I'd just really like to know. Does it make a difference that they UPS truck will bring the wood in strips that are much smaller than a forest log? That is, will it stand more of possibility from damage in the cut and cured state? Another factor...an object doesn't have to weigh 10,000lbs to apply 10,000psi of force. If the wood ends up supporting another object by an edge or a corner (or even a point), and the truck hits a bump, 10,000psi might not be so extreme. A somewhat strained example: someone traps a coat hanger between the sitka bundle and a V-8 engine place on top. My sister-in-law got a new hardwood floor installed (I sweated a lot putting that one in), and started to set little round indentations in it. She was livid, blaming it on husband and children, started to call Home Depot and give them what-for. Luckily, I stopped her in time and pointed out her spiked high-heels. Lot of pressure there from a one-hundred and ????? pound woman. I guess that's all just to say, "Don't trust the UPS man." I used to work a dock. I've seen the forklifts used to help a load 'fit' in the truck. -- This is by far the hardest lesson about freedom. It goes against instinct, and morality, to just sit back and watch people make mistakes. We want to help them, which means control them and their decisions, but in doing so we actually hurt them (and ourselves)." |
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