Showing posts with label wing design. Show all posts
Showing posts with label wing design. Show all posts

Saturday, November 10, 2012

Wing Build Update #2

Please note: James' blog has moved to a Wordpress site. To access it, please visit http://jameswiebe.wordpress.com/. All posts have been transferred to the new site, and all new posts will only be accessible via Wordpress. Thank you for your interest!


Back to my wood wing build update.  It's another series of pictures, and we're picking up exactly where we left off a few days ago.

(My earlier post on this wood rib wing topic may be found here).


Clamping on the anti warp anti crush tubing.

Clamps removed showing anti crush anti warp structure.

Gluing 4 inch wood gussets, 1/4" thickness, to ribs.
Glue up for gussets, close up.

Trailing edge riveted in place.
Slot cut on some ribs to fit flaperon hard points.
Flaperon attachment right angle material, with spacing for 3/16" rivet holes shown.

Flaperon attachment clamped in place, showing 1/4" overhang at rear of trailing edge.
Flaperon cable post, showing how it has to be cut and drilled.
In the above photo, the post is backwards.  This was fixed later in the assembly.  Also, the mark barely visible on the top of the rib is 6" from the trailing edge.

Use 3/16" rivets and large backing washers.
Post bolted in place using AN3 bolts, cut down washers, spacers as necessary.  This post is still backwards.  
Right angle with two 1/8" rivet holes each side.  3/4" x 3/4 x 3/4, or larger.
Rivet four right angle braces in place.  (Two at each end of rib; both end ribs.)

Complete anti-crush anti-warp structure in place on end rib.
Note that the wood 'riblets' have been trimmed.  Consider using a deeper cut angle on the riblets than as shown.  This will aid in covering the wing with fabric later on, so that the riblets don't interfere with fabric.

Hardpoints for anti-sail tubes will be riveted on spars.  Exact placement determined by tubing lengths.
The length of the anti-sail tubes is 2', 4', 3', 3' 1", and 2'.  For these tubes, we're using 3/4" thin wall aluminum tubing of a soft temper.  The ends flatten easily in a vise.

Anti-sail hardpoint riveted in place.
Anti-sail tubing layout.  2', 4', 3', 3'1", 2' lengths from near to far.
Anti-sail hardpoint with AN3 bolts.  Use appropriate washers to ensure clearance.
Lift strut machined attachment, riveted in place.
This is one step to check, recheck, and triple check the placement of each lift strut fitting.  This is also one area that I insist on using aircraft quality rivets, with their higher shear strength.
Trim plates riveted in place.  

Another view of trim plates.  Note spacing washers under plates/rivets to ensure straight / parallel trim plates.
Pitot tube installation using 1/4" aluminum tubing and grommets.
Routing of pitot tubing line.
Another view of pitot tubing attachment.  Pitot tube may extend and retract.
Trailing edge material butt joint.  Sweet and simple.
What's missing from this post?

a)  Never did show the installation of the jury strut fittings.  I'll add that.
b)  Didn't show the wooden structure being painted with spar lacquer.
c)  Didn't show the fabric covering.

Thursday, November 8, 2012

Wing Build Update with wood ribs, Part 1

Please note: James' blog has moved to a Wordpress site. To access it, please visit http://jameswiebe.wordpress.com/. All posts have been transferred to the new site, and all new posts will only be accessible via Wordpress. Thank you for your interest!


The wing design with wood ribs has been tweaked.  Not all of the following is in the blueprint or latest assembly manual, so I thought you'd enjoy a construction update.  I'll be sparse on words but heavy on pictures.  Here goes:

Belite ultralight aircraft wood wing setup.  Nothing glued yet.  All locations marked on layup table.
Rear spar glued with Gorilla glue.  Use water mist and roll the glue in by twisting the spar.
After marking the location of ribs, remove front spar and scuff glue locations on spar.
Glue the front spar.
Glue on false ribs.  Note pre-made slotted wood spacers.
After front spar glue sets, slide wood spacers up.
Glue false spar to false ribs.  Use gorilla glue, moisture and twist the spar around.
Gather the parts for the anti-crush anti-warp assembly.  One set for each end of wing.   Note approximate length (24 3/4 inch)
Note spacing marks.  2 3/8" at each end; 5" spacing inbetween.
Fit tubing into notches.  May require some filing in the wood notches.
Use gorilla glue and some weight.  Let set.
Use high quality wood glue and clamp inside end rib. 
Repeat the anti-crush anti-warp process on each end of the wing.

More soon...

Sunday, August 9, 2009

Breaking a Carbon Fiber Wing!

EDITOR'S NOTE, added NOVEMBER 4, 2010:

1)  The stated load of about 1100 pounds, is loaded onto one wing in this test.  Multiply by 2 for the total load that the wing structure would 'see'.  It has come to my attention that this lack of clarity has confused some people.  Sorry!  1134*2 = 2268.  2268 / 4 = 567 pounds.

2)  We are now using an improved carbon fiber spar --  more carbon fiber than the one tested below.  We now have our spars made for us by Forte Carbon.

Original Post:

We received requests before and during Airventure to show actual G testing of our Carbon Fiber wing. I'd promised one person to post some photos shortly after Airventure. While I had performed testing on individual spars, I'd yet to test a wing as a completed assembly. So yes, I was working in the theoretical, and it was time to 'show me', as our friends in Missouri would say.

The timeline to do all of this was significantly accelerated by the fact that both wings took damage in transit to Oshkosh on the truck. To add insult to injury, we managed to pierce the fabric of one wing with a prop blade on the way home, and then bent the rear trailing edge beyond the point of easy repair. In other words, the wings were now ideal candidates for further destructive load testing, rather than repair and reuse.

As background, carbon fiber does not behave like any metal. Whereas metal, when highly stressed, will begin to deform yet still provide strength, carbon fiber will take loads nearly to 100% of strength without permanent deformation. Therefore, the testing of a carbon fiber structure provides a different set of insights into the construction and engineering of the wing than does an aluminum spar. Unfortunately, the test regulations cloud the issue a little, but then again, we're part 103, so those regulations don't apply to us.

Carbon Fiber has the nasty habit of shattering when it hits the load limit. We do our testing with an air of caution. We don't want to be under the wing when it breaks, nor do we want to catch splinters from the destructive force of all that tension as the wing shatters into piles of useless jaggies.

We wanted to demonstrate that our carbon fiber wing statically exceeded our stated spec of 3.8/1.5 Gs. I had mentioned to some that I thought the wing would sail past the requirements without difficulty. FWIW, if you're paying a premium for Carbon Fiber, it's nice to know that it's both lighter and stronger.

I was a little intimidated by the idea of flipping the airplane upside down to measure. So we started with the easy test: a negative G test.

This simply involves piling loads of weights on the top of the wing. The most significant thing this demonstrates is that the lift and jury strut assembly is up to the task of holding the weight.

So, without further ado, here's a pic of our Belite 254 holding 2G worth of weight off the ground. This is a negative G test.


You can see that we removed the wheels from the plane prior to the test.

I had a good look at the Carbon Fiber lift struts in our part 103 airplane. While it's hard to say in this kind of test, they didn't appear to be too stressed. (If they fail in this compressive load, it's fair to say that the disintegration would by quick and dramatic, as the entire load on the wing would tumble to floor.)

Now, on to the test that really concerned me -- the positive G load test.

We attached our wings to another fuselage, which was flipped over and held off the floor on the bolt attach points using concrete blocks.

We proceeded to lay foam over the wing, and then we started to pile the weight on.

When we hit close to 3Gs of weight, one of my employees began to have that stunned look on his face, as if we were demonstrating an impossibility. I knew that aerobatic airplanes went to +9 or even higher demonstrated G loads in their wings, and I mentioned that to him. He still looked stunned.

Now the first piece of bad news.

As we came close to 3Gs of positive load, the wing made a few popping sounds, but did not collapse. My employees thought I'd call off the test, but that's just not the way I do things. We
continued to load weight on, and the wing continued to make popping sounds. Then I realized what was happening: the individual ribs were failing under compressive loads coming through the fabric, but the spars were holding fine. We pulled the weights off, and the bottom of the wing showed crush damage into the wing. I cut the fabric open, and sure enough: the ribs had failed.

Well, I'd rather have it happen now than after delivery to a customer.

Several ribs showed crush damage, with the failure mode essentially being delamination of ribs under compressive load. (The load vector was from the bottom of the rib, through to the top of the rib.) Instantly the gears turned in my head: I needed to add some strength from the top to the bottom, which would always be in compression, never in tension. That characteristic immediately made me think of the use of plywood stiffeners, not carbon fiber.

A few days later, another wing panel was ready to test, with a slightly revised rib design. (The addition of the rib stiffeners added about 10 ounces of weight to each wing, while increasing the crush characteristics of the rib probably by a factor of 3x+...)

Weight remains critical to everything we do. This new set of carbon fiber wing panels were coming in very light in weight (we're getting better and more uniform), so we really didn't change our net weight on the wing. A quick run on the scales, and the numbers were confirmed: the weight of the wing panel was well under 14 pounds, even with the improved, heavier rib. Less than 14 Pounds!

Caveat: This wing panel wasn't yet covered (and covering adds strength) but I was eager to give the positive G loading another test. So the sawhorses were set up to catch the weight at the fuselage strut attach points, and at the spar attach points, exactly like attachment to the airplane fuselage and struts. The lift vectors would resolve differently (in flight, the main spar would be in compression, and this vector was not in our test; likewise, we didn't use lift struts, and they would be in tension through the strut attach points).

A few minutes later, the wing panel had a load of a little over 1100 pounds on it. 4Gs! So Cool!

I grabbed the camera and started to position myself to take a few shots.

And then it happened: a loud pop, and the wing visibly settled downward. I knew immediately that one of the spars had snapped in two.

EXCEPT I WAS WRONG!

One of the sawhorses had failed, causing the popping sound. The wing was fine, unbroken.

The wing was now suspended on the other good sawhorses, and on the remainder of the broken sawhorse, and on a 'safety' post which had been under the end of the wing just for such a situation.

In other words, the failure of the sawhorse caused the load to instantaneously shift from the design configuration, to some other configuration, and nothing in the wing was broken, even as the 4G load shifted around the wing. It was sort of like a lift strut failed in flight.

Very. Impressive.

I could see that an additional further failure of the broken sawhorse would be a catastrophic problem. I quickly unloaded 1100 pounds of sand from the wing without even taking a photo.

I rearranged the sawhorses, and made a couple of wood cross bars to spread the load from the wings to the sawhorses. Newly confident that the sawhorse configuration would now hold, the wing was loaded up again to 1134 pounds. Would our little wing, our very high technology carbon fiber, be up to the task for our part 103 ultralight?

I knew it would be.

Here's a photo of the resulting 4G load.



Facts:

1. The wing panel weighs less than 14 pounds.
2. The weight under test is about 1134 pounds.
3. Deflection at the tip was 2.5 inches. (Would not include deflection due to lift strut stretching under tension, if any).
4. The first 5 rib positions have 200 pounds each. The sixth has 100 pounds. The seventh position, or wingtip has 20 pounds. The weight of the wing is just under 14 pounds. There is a clamp on the rear of the wing which weighs a pound or two. Total weight: 1134 pounds.

Opinion:

1. With covering, this wing design will hit an ultimate load of 5+Gs. How much, exactly, I don't know. But based on the deflection, and the characteristics of carbon fiber, someone smarter than I should be able to offer a guess.

Our stated strength is +3.8/-1.5Gs. We do not approve aerobatic maneuvers. :-)

Sunday evening: I've decided to add a bonus photo of the original test which failed the ribs.


In this earlier positive G loading test, the weight is 14*32.4 pounds + 6*50 pounds per wing for a total of about 1530 pounds across both wings, and as can be seen, the test was done with the fuselage inverted. As a result, all loads are resolved as if the wings were really being stressed in flight. We continued to load a few more bricks on the wing before we stopped the test, due to rib failures.

Monday, July 27, 2009

Oshkosh / Airventure and Belite, Day 1


It's the end of the first day of Oshkosh. I'm the only one in our group of five who's still up. I just got done creating a 38 slide .ppt document for my presentation tomorrow, "How to reduce weight in ultralight aircraft". It covers 4 major areas: engines, carbon fiber wings, wheels & brakes, and miscellaneous things like our fuel tank design. All in all, it explains step by step how we cut over 50 pounds out of the weight of our aircraft design. Cool! By using a different (lower HP) engine, we could have cut 80+ pounds. Very cool!!

In hindsight, it appears that it would have been possible to fly our bird with a weight of less than 210 pounds. We could have done it, but we focused on improving it and using our weight budget wisely.

Pricing: We're offering the airplane at the show with a free engine and free wing assembly, so you can end up with a 'bolt together' kit that includes just about everything except paint and propeller, all for $25K. This would be for what we call the 'classic' kit, which uses wood and aluminum in the wing. The Carbon Fiber option costs $7K more. We'll build and cover it for you for $19K more; We'll upgrade the engine to 45HP for just $1K more. Lots of bargains, just at Oshkosh.

I heard some great comments today about our airplane -- many thanks! Here's what attracts people's attention:

1) The overall design.
2) The fact that it can be flown with no medical, or even a busted medical.
3) The visibility -- the rear window design.
4) The fishing rod compartment.
5) The lightweight engines.
6) Of course, people love the Carbon Fiber.
7) No FAA registration.
8) No pilot license. (We do strongly recommend tailwheel proficiency,... )
9) Very quick building. About the fastest build possible.
10) The steel fuselage (even though it only weighs about 42 pounds.) Because it's crashworthy!
11) The quick performance with the big engine.
12) Really meeting part 103's weight requirement!

There's a few other features that I haven't spoken about much. We have carpet in our plane, and the fuel tank is quick disconnect, so you can refuel it outside of the plane. The battery is quick clip removable as well, so you can start the engine, and remove the battery, should you desire. This can save weight, too.

I now have a new email address as well: james AT beliteaircraft DOT com.

I'm also pleased to report that it looks like we are getting some significant media coverage: I'm expecting a great article on the airplane, and I did two great interviews today as well.

The picture I posted at the top of this post is from our photo shoot, a few weeks ago at Jabara.

We repainted the cowl just before we left for Airventure, it looks fantastic. I'll try and get pictures posted tomorrow.

See you tomorrow,

James

Saturday, June 6, 2009

A picture of a wing for the upcoming Belite Aircraft


Here's a sneek peak of the new wing design for the Belite aircraft. Notice: carbon fiber spar tubes, carbon fiber ribs, carbon fiber false ribs. Also note plywood veneer (0.4mm) which is bonded on top of carbon fiber rib cap strips for purposes of bonding to ceconite covering. Some of the glue joints have been made (EG: rib to spar) while others haven't yet been made. (EG: front false ribs). The entire weight of everything you see here is less than 14 pounds. (Not counting sand bag and level. :-)

Also note the really cool wing work benches we made. The stripes are exactly 6 inches apart, and the entire work surface has been leveled.

The end ribs have a solid sheet of carbon fiber bonded to them, for appearance. They are beautiful and they are completely visible, even after the ceconite covering has been finished.

I will have a completed aircraft, along with a completed airframe/wing without covering on display at Airventure. Come take a look!!