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idk about drag but lift was pretty easy as you might gather from some experiments i posted in the science area. and you might not need a tunnel at all to do simple comparative analysis in steady wind: 
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The reason it is so small is that I need the proper Reynolds number to test the airfoils. I should have said 7"x7"x36". The fan I have is a 20in. diameter and has a max windspeed of 6.2mph. I need the wind in the tunnel to be about 50mph to simulate the windspeed of RC aircraft when using equation of continuity and Reynolds Number equation. The problem with the wind is that is has updrafts and downdrafts and not very consistent. Can you give me a link on what you did for the lift calculations?
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if i were you id take avantage of the fan size and make it that big. also note that 2 fans are better than 1 in terms of homogeneous flow. probably 4 would be even better however... no cackle-ay-shuns at all for this test. i eyeballed scale readouts and attempting to make sense of the wildly jumping digits. tried to freeze them with photos but that didnt work too well due to lighting problems. intent was to compare two airfoils and that went pretty well in spite of the problems. |
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Sorry should specify. With an RC plane moving about 15km/hr, if I want to make the wing 1/5th of the size of the original, I need a windspeed of 75km/h to maintain the same reynolds number. to get a windspeed of aout 75km/h, I need a smaller windtunnel compared to the size of the fan. Does that make sense? Maybe I am saying gibberish
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ahhh yes.. fluid dynamics. the guys in the other thread finally convinced me that lines in those textbook drawings dont show compression but actually speed. im not sure how well high speed works out in our tunnels though. my buddy put a triac control to slow down the fans for smooth air. turbulence is our biggest enemy here. i found a pack of incense inside that was apparently intended to track the flow.
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Don't forget that most of the guys building back-yard wind tunnels are using some sort of collimator (dave1993's paper tubes) to get the spiral motion removed from the air and make it move in a linear fashion. The collimator takes up a certain amount of room, so even if the wind tunnel test chamber is a meter long you probby need at least that much length of collimator tubing or grid or whatever to get the air de-turbulated. Smoothed out, whatever.
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Sorry for double post, but notice that these guys also have rather small test sections for the wind tunnel.
http://www.aerolab.com/Display_Pages/OCT.html looks pretty crazy!  So to calculate lift of an airfoil, Can I just have a rod that is forced to move only up and down connected to a load cell? For drag, I suppose the same thing only horizontal? |
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Perhaps for drag, you could measure the torque on the vertical rod used to measure the lift. The guide for the vertical rod could be mounted on a pivot, and the reading from the force cell (either above or below the pivot) could be multiplied by the inverse of the ratio of the distance from the pivot to the airfoil and the pivot to the force cell (I think this is right - just doing it in my head which isn't overly reliable). This would eliminate an extra rod. Just an idea. If the angular displacement at the pivot would be over 1 deg. then it might be necessary to rig a parallelogram linkage to adjust the airfoil angle to compensate.
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Almost bedtime - I'll try for tomorrow. The same idea would work for a horizontal rod - then the lift would be measured as a torque on the rod, and the drag would be measured as a force along the axis of the rod.
Mitch |
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Oops - probably created confusion by referring to a torque in the context of a rod. Sorry. Substitute bar for rod and it will probably be easier to visualize. The axis of rotation for the torque would have to be parallel to the long dimension of the wing.
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So many of you have contributed to the development of the KF concept.
I wanted to share this info that I just received from India with all of you.... because many of you have done so much to help develop the KF vortex concept. Tony65X55 brought the idea to the RC Groups back in 2006.
It has evolved in many different ways since then and opened up the creativity in many RC pilots and designers. It is truly a collaborative effort on a rather large scale. It is truly a wonderful adventure. Dick Subject: Re: KF Airfoils Dear Mr Kline, Thank you for writing in to me. I began working with KF airfoils when my friends, Ashfaq Ali and Arvind, and I had to design a glider for a competition. The glider itself had to be un-powered and could have only one control, while still being able to manoeuvre through a 75m course with twists and bends, on being propelled using rubber bands. While looking for airfoil profiles that could be used, we came across the KF series of airfoils and found it perfect for our purpose. We made a delta wing glider utilising the KFm3 profile (Unfortunately, I do not have any pictures of it. Ashfaq might have some. I'll ask him to mail them if he does) and the performance was pretty good. Later, we found that though the KF airfoils were used widely in RC planes, there was not much theoretical or computational data available for it, and so, Ashfaq and I decided to do some CFD analysis ourselves. Our initial work, which was presented in the papers that you mentioned, consisted of comparison of lift, drag and moment coefficients of NACA 0009 airfoil with a KFm3 airfoil having similar thickness and chord dimensions, over a range of different angles of attack, at Mach 0.3. The results, along with the pressure and velocity contours are available in the attached document. It can be observed from the graphs that, when compared to a conventional symmetrical airfoil, Lift coefficient was slightly lesser at low angles of attack, when compared to symmetrical airfoils, although it was positive and higher at 0 deg. The drag coefficient was high at low angles of attack , but much lower at higher angles. NACA 0009 stalls at about 5.5 to 6 deg, but the KFm3 resisted stalling for a much wider range, as can be seen from the graphs. Except for certain angles, the stability was very good, much better than symmetrical airfoil In our free time, we are also working on the analysis of other profiles in the KF series. Recently, we also started considering the possibility of use of the KF profile in actual aircrafts. We are comparing the performance of wing of a Cessna 152 and the changes when NACA profiles are replaced with KF profiles. I'll keep you updated. Please do let me know if you would like to know anything more about our work. With Regards, D Abhinav |
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