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| one of us |
I got my copy of Gun World yesterday and sat down to read the article about inexpensive custom guns you can build. The part of the article concerning barrel flutes stated something along the line of �there are claims that spiral flutes counteract the torque from the bullet spinning in the barrel.� As far as I can tell, the only kind of �flutes� that a barrel has that would impact bullet or gun torque is the grooves along the bore! I wish the authors of these gun magazine articles (or perhaps their editors) would raise the bar. Maybe think before they print something and actually give us a product that is worth out time and money to read. | ||
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| one of us |
I guess the author meant "counteracting the torque twisting the barrel" because the torque is not negated, but barrel distortion can be partially compensated. | |||
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| <333-OKH> |
According to a flyer from E. R. Shaw helical flutes provide up to "30% more ridged barrel than a conventional fluted barrel. More cooling than a conventional barrel, and the most important part of helical fluting it COUNTERACTS ROTATIONAL TORQUE." [Capitals in the original copy.] So says the shepard, what say the flock? ------------------ | ||
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| one of us |
I was surprised when I read about the E.R. Shaw flyer (Thanks 333-OKH). I think Pyrotek has the right idea. I think we can assume that as long as the bullet spins upon exit there was some torque (physics still applies). Maybe the spiral flutes keep the barrel from twisting radially as the bullet is spun while traveling down the barrel. Also mentioned is that fluting makes the barrel more rigid. I always thought of the barrel bending along the axis of the bore when it was shot. I wonder if the spiral flutes perform both tasks, keeping the barrel rigid along its axis and keeping the barrel from twisting? I also wonder how much the barrel actually twists. Is there a measurable difference? Does anyone know if the bench-rest shooters use spiral fluting? [This message has been edited by Ben_Wazzu (edited 04-18-2002).] | |||
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| One of Us |
this is back to that same old (stupid) statement that infers that flutes make the barrel stiffer. Tell me how removing metal can make the barrel resist torque. I don't care if God sent out a flyer. I did not think much of Shaw before, and I think even less of them now. It doesn't wash. Maybe if we remove all the metal it will get EVEN STIFFER. | |||
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| <500 AHR> |
Chic, The only way the flutes provide a stiffer barrel is if you consider it on a pound for pound basis. In that scenario you will get a larger area moment of inertia with a fluted barrel than a same weight nonfluted barrel. Do you follow me. For example. If I take two contour #4 barrels, one fluted the other is standard. The fluted barrel will be less stiff. If however the fluting is such that the fluted contour #4 barrel weighs the same as a standard contour #3 then the fluted barrel (contour #4) will be stiffer than the standard #3 contour. If you utilize an helix angle (twist) in the fluting which is of an opposite hand to the rifling twist you will in fact increase the torsional stiffness of the barrel. The interesting part is that the majority of the bullet upsetting will occur within inches of the chamber. There want be much torquing going on near the muzzle. So the twisted fluting is most likely of little real advantage. Todd E | ||
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| One of Us |
Todd, I understand that perfectly but they are talking about taking a round barrel and fluting it and the flutes helping resist torque. So much bull. And yes the moment of inertia would be greater than a smaller diameter barrel of the same weight, but not the one you started with, and after you paid these Bozo's a lot of money to cut away metal that resists torque. Still doesnt wash. The cooling is there but minimal. [This message has been edited by Customstox (edited 04-18-2002).] | |||
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| one of us |
On the bright side your ER Shaw barrel wouldn't be any worse after fluting than it was before! | |||
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| one of us |
quote: It'll damn sure be less stiff! Wally | |||
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| one of us |
Hey, remember an I-beam is more stiff than an equal weight, equal length round bar. If a "truely fluted" barrel is being cut into a piece, the cross section is much like a star. Most "fluted" barrels out there start out as a round barrel with only shallow grooves cut into it, Such "flutings" do not stand out as much as one that is "really fluted", nor is as effective, but it makes up a little bit of strength for the metal being cut. | |||
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| one of us |
An easy way to determine if someone knows what they are talking about is if they use the right terminolgy: surely these flutes are helical, the same form as the rifling. ------------------ | |||
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One of Us |
Even if Chic weren't an engineer, I'd go along with him on this one... first time I saw those flutes and heard the claim I thought it was utterly absurd... I'm more convined now. Spiral flutes (or any fluting, I've come to believe) is the automotive equivelant of pin-stripes and tail-fins. BA | |||
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| one of us |
quote: Do vector analysis on an "I" beam then on a cylinder with several flutes cut right out of the meat. Sure they look butch! Wally | |||
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| <500 AHR> |
Chic, I didn't mean to offend you. I was only getting a little more specific. I agree with you 100% as I my last post says. I don't know where the I beam discussion came from. Anyone ever see a barrel with a I beam section? Todd E | ||
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one of us |
I figured the torque on my .500 A-Sq with 600 grain bullet at muzzle velocity of 2400fps through a barrel with effective length of 20.25 inches to be 15.81 ft/lb. Remember the inertia of the rifle must be overcome before you would begin to feel it. I have very lightly held on to the forearm of my .500 and it has laid over many times. I see this is why. Since this force is relatively insignificant the spiral fluting is a maketing gimmick. [This message has been edited by Roger Rothschild (edited 04-19-2002).] | |||
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| <500 AHR> |
Roger, You are in over your head. The torsional load imparted to the barrel by the bullet getting upset is much higher than a few measely foot pounds. If you don't believe me try bushing that bullet through your bore! This torsional excitation occurs so quickly that you cannot feel it. The barrel however does and reacts by vibrating (torsionally due to this input). The helical fluting, if designed correctly, can help to stiffen the barrel torsionally and reduce the effect of the vibrations. Again the real benefit of fluting is to allow a greater section for the same weight. It is essentially a weight savings feature and does increase the available surface area for convective and radiate heat transfer. If you wanted a heavier contour but not the weight the fluting is the compromise which is struck. Todd E [This message has been edited by Todd E (edited 04-19-2002).] | ||
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| one of us |
"You are in over your head." I love you too Todd. "The torsional load imparted to the barrel by the bullet getting upset" What? "The bullet getting upset" from the following, don't you mean the bullet getting squashed? "If you don't believe me try bushing that bullet through your bore!" Do you mean "pushing" Man you come up with the wildest concepts it's refreshing actually. Ok: Sit down and let Dr. Rothschild show you how it's done. Torque imparted to a barrel of a rifle. Angular acceleration = (angular velocity final - angular velocity initial/ time) Ang. accel.=(18095.57 Rads/s - 0)/6.872x10^-4sec. Ang. accel. = 2.6332x10^7 Rads/sec Sum of torque forces = Moment x ang. accel. 1 Joule = 1 Newton x meter 1 Joule = 0.737 ft/lb So: T = 21.52 Nxm/s^2(0.737) = 15.8 ft/lbs. Thanks for bringing this to my attention Todd.
[This message has been edited by Roger Rothschild (edited 04-19-2002).] | |||
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one of us |
I too am a mechanical engineer by training and profession. Roger is correct on this one less than 16 ft-lbs (the bullet is not a true and complete cylinder, unless you shoot wadcutters, so the rotational moment is also much less) In addition, spiral flutes will decrease the axial stiffness. In fact it is mainly just the top and bottom "ribs" that account for the higher stiffness/weight ratio. Todd. As to ever seeing a barrel with an I-Beam section. No, I haven't. BUT one that DID have such a section would have the highest stiffness/weight ratio. But it would also have the highest possible distortion due to heating as well. The higher the temperature gradient throughout the cross section the higher the probability that POI will "wander". Stiffness is great, but it's consistency that accuracy buffs are looking for. Any non symetrical machining done to a barrel runs the risk of creating or releasing internal stresses resulting in a "less than straight" barrel. Long story short. I'll take mine round. | |||
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quote: You have given the formula for "Shock factor". Torgue is a measurement of rotational (angular) results of force, work and time. ergo, rifling twist is a major factor in computing force. We can carve, helically if you wish, to our hearts content. Very cute. We could decide the characteristics we need in a barrel then design a trust barrel that would shift tension and compression where we want. Might not be pretty and might be difficult to chuck for threading and chambering. Wally | |||
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| One of Us |
Todd, you didnt upset me at all, hope I didnt sound like you did. I was just reacting to the utter stupidity of this whole concept. Chic | |||
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Its much easier to bend a rod of steel with a certain diameter than a bundle of steel rods with same combined diameter as above. Even if that means less material! Also a tube with only small hole will be about the same ( or stronger ? ) to bend than a steel rod of same outside diameter. ?? ------------------ | |||
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| one of us |
I believe that the claim on spiral flutes is that they resist torsional twisting better than straight flutes. Problem is, unless the twisted flutes conteract the torsional vector exactly, and I mean EXACTLY, the torsional vector will be redirected into axial motion of the barrel. I'ld much rather have my barrel twisting than swinging! | |||
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| <DuaneinND> |
Advertising guys, in order to sell something you have have to create a reason for it. Can Shaw prove the claim-probably no more then someone can disprove it, but it looks neat and sounds mysterious, and sells the product-thats what advertising is about. | ||
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| One of Us |
ahunter, think about what you said about a tube with a small hole relative to one that is solid. The only thing that resist torque in a shaft is the cross sectional area, everything being equal, strenght of materials etc. The material in the bore tube that restist torque does a better job of doing its work when it further away from the axis of the torgue so the metal at the outer diameter does more. The metal in the middle still works and you posed the question that one with a small hole would be stronger????? No way, you have removed material that resists torque although that material is at the most disadvantageous position to do it. As far as the other following posts, believe what you will. It is a fallacy and Shaw could not prove diddly in this issue and it is easily proved to be just the opposite. In fact just consider this. I am trying to do it with common sense instead of formulae. Torgue will be induced by the bullet pressing, if you will, agains the edge of the rifling. That will take place on the side of the left side of the rifling in a right hand twist because that is the side that will be resisting movement. That torque will be moving down the barrel with the bullet and the resistanc of the barrel will be more concentrated at the point of the bullet in time but the adjacent volume of barrel will be resisting it also but to a lesser degree as the distance from the bullet increases. I think everyone agrees that a fluted barrel will have less resistance to this torque than one that is left unchanged in its round configuration. If you do not agree, then the nurses in the home need to put another bib on you to catch the drool and we will not worry about your confidence in this discussion. The arguement is that helically fluted barrels will resist that torgue more than straight flutes. And I am assuming that all are in agreement with the concept that removing the steel at the outside of the barrel is detrimental to resisting torgue, hence the round barrels are stronger. Now consider how much material is removed in those flutes with straight flutes versus helical flutes. It is obvious that the helical flutes remove more material since the path is longer going around the barrel to reach the end versus straight. You have reduced the material even further that resists torgue. You are on a downward spiral trying to fight torque with this approach. Hope that did not confuse the issue. | |||
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| one of us |
Actually that was an excellent visualization. | |||
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| one of us |
OK, I'm no engineer (I can't even pretend to be), but why should I care about radial torque on the barrel anyway? Seems to me if it does torque less radially, that much more energy will be transmitted to the action where it can make a real difference in consistency. Also, assuming there is merit to this, wouldn't the flutes have to go in the SAME direction as the rifling to produce the greatest effect? - John | |||
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| <500 AHR> |
Roger, You calculated a torque do solely to the rotational energy of the bullet. How much force and torque is reqired to extrude the bullet? You were correct I used the wrong term again. You sir are not as smart as you believe yourself to be. Your attitude is typical of a young know it all kid however. Next thing you need to tell me smarty is what the Eigenvalues are for the different barrel systems. A barrel is a cantilevered beam and it is also a spring. The forces inputed to the barrel by the bullet and the expanding gases produce an excitation (a forcing function) upon the barrel. So Roger you need to do the following to understand the solution to this problem:
An I beam is not stiff in torsion. It is an engineered section which provides maximum bending strength to weight ratio. We are not discussing bending, we are discussing torsional excitation and stiffness. I am just a stupid LEO not a brilliant engineer like you Vibe or a Chemistry Major like Roger. Todd E [This message has been edited by Todd E (edited 04-20-2002).] | ||
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| one of us |
Todd, This will be my last answer to you, not because I "think" I am better or smarter or any other B.S. but because my perception is your desire is to argue for arguments sake. A "torque" is the sum of the rotational forces acting on something, whether it is your Crescent wrench adjusting your kids bicycle axle or spinning up a bullet, accelerating it rotationally (angular rotation) to a given angular velocity. Now to find the "force" necessary to accelerate that bullet does two things. It finds us the "force" necessary to accelerate it and in so doing due to Newtons Second Law, we have the "force" on the barrel since it is the "thing" imparting the spin through the rifling. That "force" is the "torque". It is just giving a name to the force. As for squashing the bullet I don't know what it takes to mash it into the bore, I really don't care. The lands have to engrave the bullet and that metal has to go somewhere. I was simply looking at just the average torque in an ideal system. Since I am taking the algebra based physics rather than the calculus based this is what I can get. I had asked my professor about integrating the acceleration over the time in the barrel but it doesn't tell me anything more than what I wanted to know. And that is 15.8 ft/lbs isn't going to concern me but does tell me why my .500 lays over when I do not grip it well. Don't take things so personally Todd, it isn't like someone is calling into question your heritage though sometimes it seems as if you perceive that to be the case. | |||
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| <500 AHR> |
Roger, Torque and force are two separate things. Torque is a force applied to a moment arm. The torque applied to the barrel by the bullet after the bullet has been extruded is simply: mass X acceleration X radius of the bullet. The thrust imparted to the barrel by the bullets reaction against the riflings is simply: mass X acceleration X cos helix angle. (longitudal) mass X acceleration X sin helix angle. This is all high school level physics. To determine the force (thrust and torsional) due to the bullet extrusion you simply need to understand the total deformation of the bullet, the yield strengths of the bullet materials, and you need to make some assumptions about stress and strain at this point unless you have a stress strain plot for the particular bullet. From all of this you can begin to derive a forcing function. Anyway, I think this has gone on long enought to. I have not checked your work, but 15 lb-ft of torque is a significant quantity. You can only hand tighten to about 1.5 - 2 lb-ft. I am not sure of the precise wave form generated in a barrel due to firing, but I would expect it to be manifest itself as a "circular whipping" of the muzzle. Again the only advantage to be gain by fluting is to reduce weight and provide additional stiffness at that lower weight as opposed to a solid round barrel. The helical application of fluting my provide additional stiffness, but I cannot be certain without modelling it. I don't get to the symphony much. Todd E [This message has been edited by Todd E (edited 04-20-2002).] | ||
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| <dsverdrup> |
quote: Girly-man! | ||
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| <pshooter> |
You guys show me where all this "cyphering" means one ounce of anything to all but a robot shooter, and I'll be on board. I want to see paper results before someone sell's me another vacuum cleaner. As for me, all my deer and hogs die, flutes or no. What I don't see taken into account is actual bbl. hardness,(rockwell C, carbon, stainless, etc.), How much static stress is present from machining, (relieved or not, {cryo.})This isn't my field so maybe I should stay out, But I still see too many unaccounted variables to have a working hypothesis. But it's fun to watch you guys expound in your field of expertise. mvm [This message has been edited by pshooter (edited 04-20-2002).] | ||
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| <500 AHR> |
dsverdrup, YOU are the girly man. You are only appling 0.875 foot pounds of torque. Even if you doubled it you would only be doing 1.75 foot pounds. Remember you are also using both hands to get to that measely 0.875 lb-ft of torque. I suggest you take a good torque wrench grasp the socket with one hand and the handle of the wrench with the other and twist the socket has hard as you can. Watch your torque reading. If you are a real man you might get 3 foot pounds, but more likely you will achieve 1.5 to 2. I can get over 2 barely, but I am getting old and weak. To put this in perspective. 15 foot pounds is approximately the torque on the cover plate bolts in the axles of your pick up trucks. Go out and see if you can tighten then up anymore by hand. Hell try loosening them by hand. Torque to loosen will most likely only be about 10-11 foot pounds. Todd E [This message has been edited by Todd E (edited 04-20-2002).] | ||
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| <dsverdrup> |
quote: Doh! You are right! | ||
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| <Gary Rihn> |
quote: You win this argument, simply cause I don't have any good evidence to dispute it. Heck, I don't even understand it! I was lost by about the second line! Heck, just give me a good non-fluted barrel, a bunch of bullets, and I'm happy! | ||
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| one of us |
I believe "torsional excitation" is a technical term first used by an exotic dancer in Calgary, Alberta. She apparently used this technique in her film making sideline. Sounded painful to me. Regards, Bill. | |||
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| One of Us |
Bill, That was choice. I think I may have seen her at that topless, bottomless, sideless, nothing left to the imagination place in Penticton a few years back. It was painful even to watch, lol. (I did anyway, must expand our horizons) chic | |||
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| one of us |
There's much debate going on about whether fluting makes a stiffer barrel. The question is "stiffer than what?" An equal outside-diameter barrel? NO; An equal weight round barrel? Maybe, depend on the style of fluting. (I-beam mentioned for an example that an equal weight bar can be stiffer in one aspect, not that I am proposing an I-beam shaped barrel.) The debate goes on for that those who disbelieve, simply disbelieve; those who believe, can only prove it in math and theory. An experiment can be done to visually show the effectiveness of fluting. Barrels, made of homogeneous material, can be substituted with plastic. Here we got plastic barrels, rifled, fluted and un-fluted. Now you jam a lead slug into the bore or simply twist these barrels from outside. Until then, I stick to whichever barrel that is accurate. | |||
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| <500 AHR> |
Bill, That is my kinda torsional excitation! The term torsional excitation is used most often with engine crankshafts. There is a torsional damper on your crank hub. You crank pulley (sheaves) are bolted to it. The flutes are there simply for mass savings. If the mass savings is significant enough the may afford one some stiffness improvement with no weight penalty. A better way to control vibration is with mass or better yet a tuneable damper. Todd E | ||
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| one of us |
Todd Chill dude. I was trying to highlight the point that helical fluting sacrifices logitudinal stiffness for the illusion of increased tortional stiffness. And I only claimed to be AN Engineer, not a briliant one. I am still human and thus quite capable of making mistakes (like calling people I don't know "stupid", but wait, I DIDN'T do that, you did in an attempt to put word in MY mouth) and overlooking other pertenant factors. I do not think that the torque generated during the bullets engraving is all that relevant to the discussion. I say this for several reasons. One - because that section of barrel just ahead of the chamber is rarely included in the fluting. And imparts NO torque on the various versions of fluted barrels whose fluting would be in front of this section. Two - the pressure/acceleration curve of the burning powder/bullet acceleration is still quite far from developing. Often it is just the pop of the primer that will push a bullet into and sometimes past this point. Three - Due to #2 the rotational acceleration at this point is exceedingly low. The 15.8Ft-Lb figure is derived from accelerating the bullet to full RPM uniformly, and is assumed to be an average value. Since the acceleration of the bullet in not linear due to the pressure driving it also being non linear, then the rotational acceleration will also be non-linear. Thus allowing us to discount the torque generated this close to the chamber. Particularly with larger bores and slow burning powders. Also since the 16 ftlb figure was arrived at using a 50 caliber, then yes I do see it as rather inconsequential in the larger scope of things. Particularly in the smaller calibers where this debate is the hottest.
I would agree with this completely. | |||
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That is with one hand applying torque at a time so it is still a valid measuring. 'Just need to keep adding weight to see what my peak force is. 