Speargun Dynamics

Your handwriting says your a Doctor not a Engineer. :D:D
My gun is as heavy as a crow bar, it helps me get down fast and muzzle flip is not an issue.:D:D
Hey I hope you know I just joking about the handwriting.:D
Cheers, Don Paul

I reserve any judgment until I see some recognizable patterns of letters and numbers

Stop trying to copy the denton

Is that an ancient greek facsimile??

When did you learn to write hieroglyphics?:D

hahaha, see, this is what happens when a real engineer sees a non-engineer's scematics...he has to draw better ones...nice.

in comparing the force loads from parallel bands to those mounted a little lower in the muzzle, what is the difference in the additional force pulling up on the muzzle?

As Davie noted in his calcs, it's pretty small.

If we had a band slot 1" below the shaft, and the bands were stretched 40", then the angle would be about 1.4°. If we had a 200 lb band load, then the vertical component would be 200 x Sin(1.4°) = 5 lbs.

But here's the part that has always confused me. That small vertical force only serves to pull the shaft and stock together. Whatever force is pulling the stock up, is exactly the same as the force pulling the shaft down. They are already touching, so one cannot be pulled closer to the other. So I don't understand how the vertical component of the band force can generate muzzle jump, even if this component were large.

I can see it if this were an old style gun where the spear were unsupported over much of its length, because then there can be relative motion between the shaft and stock. But that's not the case for most guns.

In my head, it has always seemed that muzzle jump had more to do with the way the recoil force acted about 1) the grip, and 2) the gun's center of mass. Davie points out that the mass of the gun is small compared to the mass of the diver, so it would seem that the height of the grip would dominate. If you follow Davie's analysis a little further, it may even reach the theoretical conclusion that you could reduce muzzle jump by LOWERING the band slot, to put it inline with the grip?

It seems to me that if the Band Slot, grip, and Center of Mass of the gun were all in line, then you should have no muzzle jump. I have wondered if the way the bands jump around at the end of their contraction could somehow cause the muzzle to move. But I don't know how this would be different for inline versus normal bands.

wow! those are actual ACME plans to build a speargun to catch the roadrunner!!!:thumbsup2:

Quote from Tin Man

As Davie noted in his calcs, it's pretty small.

If we had a band slot 1" below the shaft, and the bands were stretched 40", then the angle would be about 1.4°. If we had a 200 lb band load, then the vertical component would be 200 x Sin(1.4°) = 5 lbs.

But here's the part that has always confused me. That small vertical force only serves to pull the shaft and stock together. Whatever force is pulling the stock up, is exactly the same as the force pulling the shaft down. They are already touching, so one cannot be pulled closer to the other. So I don't understand how the vertical component of the band force can generate muzzle jump, even if this component were large.

I can see it if this were an old style gun where the spear were unsupported over much of its length, because then there can be relative motion between the shaft and stock. But that's not the case for most guns.

In my head, it has always seemed that muzzle jump had more to do with the way the recoil force acted about 1) the grip, and 2) the gun's center of mass. Davie points out that the mass of the gun is small compared to the mass of the diver, so it would seem that the height of the grip would dominate. If you follow Davie's analysis a little further, it may even reach the theoretical conclusion that you could reduce muzzle jump by LOWERING the band slot, to put it inline with the grip?

It seems to me that if the Band Slot, grip, and Center of Mass of the gun were all in line, then you should have no muzzle jump. I have wondered if the way the bands jump around at the end of their contraction could somehow cause the muzzle to move. But I don't know how this would be different for inline versus normal bands.

Display More

Jeff,
I follow what you're saying but the fact that the bands are stationary on one end confuses me a bit. If the bands were being released from both ends then the force would be equal, but it isn't. When the bands are released the center point of the bands(contraction) continues to change(forward) until the shaft is released. Even after this occurs the bands will contract further than their resting state and then come to a rest. Maybe this is the point that you are talking about. When the bands ends actually push away from their center instead of toward one another.
One more thing ,the holes in comparison to handle does make sense. Interesting to say the least.

the hand on the gun has to act like a fulcrum to some extent. the muzzle is a lot easier to move than your hand and arm. I always felt the gun wants to come up because of you arm moving the force that was going back, up

Maybe this is a good place to make a distinction. I think that muzzle flip is a very real phenomenon. I'm just not sure that it's due to parallel (or non-parallel) band pull. I haven't used band elevators, but I have read where others swear by them. Maybe there is another interaction at work. Maybe the band elevators (or parallel bands in a euro) do something else to reduce muzzle flip.

For example, the motion of the bands at the end of the firing sequence. Or the way they disengage from the fins / notches, etc.

I wonder if anyone has ever setup a high speed (super slow motion) camera underwater. It sure would be nice to be able to see what is happening during the firing of a speargun. When watching an arrow shot from a bow is super slow motion, I was stunned at how much the arrow was bent. I wouldn't be surprised to see that there are things going on that we didn't fully expect - especially with "high power" guns.

Jeff, if you want to come over sometime soon, we could take some video that will at least show whether or not the front of our guns are kicking up during the shot. One of us can film the side of the gun while the other shoots at the target. I have a new HD underwater video camera which might capture some decent data. You need to pull the trigger on the hybrid don't you?

Hell Yeah!

Quote from griswold

I wonder if anyone has ever setup a high speed (super slow motion) camera underwater. It sure would be nice to be able to see what is happening during the firing of a speargun. When watching an arrow shot from a bow is super slow motion, I was stunned at how much the arrow was bent. I wouldn't be surprised to see that there are things going on that we didn't fully expect - especially with "high power" guns.

Jeff, if you want to come over sometime soon, we could take some video that will at least show whether or not the front of our guns are kicking up during the shot. One of us can film the side of the gun while the other shoots at the target. I have a new HD underwater video camera which might capture some decent data. You need to pull the trigger on the hybrid don't you?

I have lots of pool tests shot on Hi 8 and 8mm film but I would need to get permission to post on the
web. I used to use a spring scale and blue grease to measure shaft energy at the end of the wire rope.
later on some guys were using mono with precision black marks and a bar code reader feeding a lap top.This
gave good data on shaft velocity. Shite :0:0 this is sounding too much like work.... now where is that bikini
thread?:D:D FWIW my bands are on the same axis of symmetry as the thumb and index finger of my
gun handle.
Cheers, Don