Getting rid of cabinet drop
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- Karlis Abolins
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Getting rid of cabinet drop
I recently began thinking about cabinet drop as an issue because my guitar experiences a lot of cabinet drop (about 3 to 4 times more than most other guitars). I started to look at what the guitar makers have done to address the issue and found some hints at what they have done. A couple of guitar makers, Emmons and Remington, have put compensators on the underside of the guitar to offset the deflection caused by the increased tension when a string is raised in pitch. GFI has lowered the string height relative to the neck and increased the strength of the neck resulting in very minimal cabinet drop. For the most part, the changer and nut have been strengthened so that they don't enter into the cabinet drop equation.
The main culprit is tension. Most guitar strings are up to pitch at about 22 to 27 pounds of tension. If you assume an average tension of 25 pounds for each string, a 10 string steel guitar has 250 pounds of tension on the strings between the tuners and the changers. The force is transmitted into the body of the guitar at the changer and the nut. The typical string height above the body of the guitar is 1 1/2".
You can think of the steel guitar in this configuration as a kind of bow. Because of the strength of the body, the bowing effect is not visible but is measurable with a deflection gauge. Using the bow paradigm, if you pull on the string (raise the pitch of the string with a pedal) the bow bends. This is the root cause of cabinet drop.
A novel idea occurred to me as I thought about this problem. Change the force. Instead of tension on the guitar body, make the force compression. How? Modify the changer and the nut. Instead of mounting these on the surface of the body, make the frame of the changer extend through the body and make the frame of the nut extend through the body as well. Attach tensioning rods between the nut and changer to counter the tension of the strings. Also attach tensioning rods between the nut and the tuner frame. The idea is to make the tension of the strings and the tensioning rods equal. So now the body is not in tension anymore rather it is in compression.
If the tension of the top and bottom are equal the body of the guitar will be straight (provided it is strong enough to withstand the 500 pounds of compression). The force will be transmitted into the body evenly throughout the thickness of the guitar rather than on one side as is the case with current guitar designs.
I can see two major benefits of this approach. The first is the virtual elimination of cabinet drop making the guitar easier to tune and play. The second is increased sustain due to increased pressure on the body.<FONT SIZE=1 COLOR="#8e236b"><p align=CENTER>[This message was edited by Karlis Abolins on 27 June 2002 at 02:36 AM.]</p></FONT><FONT SIZE=1 COLOR="#8e236b"><p align=CENTER>[This message was edited by Karlis Abolins on 27 June 2002 at 06:01 AM.]</p></FONT>
The main culprit is tension. Most guitar strings are up to pitch at about 22 to 27 pounds of tension. If you assume an average tension of 25 pounds for each string, a 10 string steel guitar has 250 pounds of tension on the strings between the tuners and the changers. The force is transmitted into the body of the guitar at the changer and the nut. The typical string height above the body of the guitar is 1 1/2".
You can think of the steel guitar in this configuration as a kind of bow. Because of the strength of the body, the bowing effect is not visible but is measurable with a deflection gauge. Using the bow paradigm, if you pull on the string (raise the pitch of the string with a pedal) the bow bends. This is the root cause of cabinet drop.
A novel idea occurred to me as I thought about this problem. Change the force. Instead of tension on the guitar body, make the force compression. How? Modify the changer and the nut. Instead of mounting these on the surface of the body, make the frame of the changer extend through the body and make the frame of the nut extend through the body as well. Attach tensioning rods between the nut and changer to counter the tension of the strings. Also attach tensioning rods between the nut and the tuner frame. The idea is to make the tension of the strings and the tensioning rods equal. So now the body is not in tension anymore rather it is in compression.
If the tension of the top and bottom are equal the body of the guitar will be straight (provided it is strong enough to withstand the 500 pounds of compression). The force will be transmitted into the body evenly throughout the thickness of the guitar rather than on one side as is the case with current guitar designs.
I can see two major benefits of this approach. The first is the virtual elimination of cabinet drop making the guitar easier to tune and play. The second is increased sustain due to increased pressure on the body.<FONT SIZE=1 COLOR="#8e236b"><p align=CENTER>[This message was edited by Karlis Abolins on 27 June 2002 at 02:36 AM.]</p></FONT><FONT SIZE=1 COLOR="#8e236b"><p align=CENTER>[This message was edited by Karlis Abolins on 27 June 2002 at 06:01 AM.]</p></FONT>
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You bring up some interesting points, Karlis. There are a number of possibilities for the cause of cabinet drop- and each guitar is a bit different. One of the semi-popular thoughts is that changer axle flex contributes to it and, while this may be the case, due to the work I've done in this area my feeling is that it is negligible. On a 12 string the string pressure approaches 330#- a 14 string approaches 400#. I think that the counter force idea that you propose has merit but I wonder if the tension on the cabinet is responsible for some of the tonal characteristics of the guitar? Are you planning on implementing your idea? I'd like to hear what the results are.
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That's a good start, Karlis, but the body flex due to string tension is only one cause of what we term "cabinet drop". Also in the equation are changer-axle flex, cross-rod flex, body distortion due to pedal forces, and nut movement/axle flex. Presently used technologies permit minimum "cabinet drop" if the guitar is designed right. It's just my opinion that, at this time, we don't need more "mechanical intrusions and complications" in the instrument.
A two-to-three cent drop is both obtainable and acceptable (read...insignificant), IMHO. <FONT SIZE=1 COLOR="#8e236b"><p align=CENTER>[This message was edited by Donny Hinson on 27 June 2002 at 08:32 AM.]</p></FONT>
A two-to-three cent drop is both obtainable and acceptable (read...insignificant), IMHO. <FONT SIZE=1 COLOR="#8e236b"><p align=CENTER>[This message was edited by Donny Hinson on 27 June 2002 at 08:32 AM.]</p></FONT>
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Interesting thoughts, Karlis. Your analogy of a steel guitar as a bow is right on. In terms of compression and tension, like a bow the guitar has compressive forces close to the strings and tensile forces carried on the bottom. Equalizing the tension as you have suggested would change the forces on the body to all compression (the tension would not double though, just be distributed differently). If the changer pulled against an independent tension rod on the underside, the forces would theoretically be neutralized. But, since the total load is still being changed in a complex way as the strings are worked, you'll still have stability issues to contend with. The biggest problem I see with your design is how thick it is. Kind of hard to get your knees under there.
In a way, the space frame body of the guitars I'm making act like the system you describe. The continuous lateral struts on the top have pure compressive load, and the bottom ones have tensile loading. The ones in between distribute the difference in an equal way- it is inherent in the geometry.
On the pedal steel prototype I'm working on, The frame body is the same as the lap steel- it weighs 13 ounces between the ends- carrying a load of 13 strings. I don't have enough pulls hooked up yet to see what kind of cabinet drop problems it will have, but so far it is promising. And it sounds great, of course!
T. Sage Harmos
Harmos Steel Guitars http://www.harmosmusic.com
In a way, the space frame body of the guitars I'm making act like the system you describe. The continuous lateral struts on the top have pure compressive load, and the bottom ones have tensile loading. The ones in between distribute the difference in an equal way- it is inherent in the geometry.
On the pedal steel prototype I'm working on, The frame body is the same as the lap steel- it weighs 13 ounces between the ends- carrying a load of 13 strings. I don't have enough pulls hooked up yet to see what kind of cabinet drop problems it will have, but so far it is promising. And it sounds great, of course!
T. Sage Harmos
Harmos Steel Guitars http://www.harmosmusic.com
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Donny,
"A two-to-three cent drop is both obtainable and acceptable (read...insignificant), IMHO"
With much Christian love and respect, a 3 cent drop is totally UNacceptable to me. ONLY Zero drop is acceptable to me.
I predict one day that WILL be standard. Without having to use a counterforce option like the LeGrande III.
When, I haven't a clue.
God bless you,
carl
"A two-to-three cent drop is both obtainable and acceptable (read...insignificant), IMHO"
With much Christian love and respect, a 3 cent drop is totally UNacceptable to me. ONLY Zero drop is acceptable to me.
I predict one day that WILL be standard. Without having to use a counterforce option like the LeGrande III.
When, I haven't a clue.
God bless you,
carl
- Karlis Abolins
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It is a pleasure to see such insightful and informative comments being posted in response to my suggestions.
Kyle, your solution about carbon composite necks will shortly be seen on your new guitars. I wish you the best.
Carl and Andy, Thank you for your kind words of encouragement.
Jim, I agree that the changer axle deflection on most current guitars is not a factor.
Sage, I am fascinated by your instruments. I hope you will share your pedal steel with us in the near future.
Karlis<FONT SIZE=1 COLOR="#8e236b"><p align=CENTER>[This message was edited by Karlis Abolins on 27 June 2002 at 12:03 PM.]</p></FONT>
Kyle, your solution about carbon composite necks will shortly be seen on your new guitars. I wish you the best.
Carl and Andy, Thank you for your kind words of encouragement.
Jim, I agree that the changer axle deflection on most current guitars is not a factor.
Sage, I am fascinated by your instruments. I hope you will share your pedal steel with us in the near future.
Karlis<FONT SIZE=1 COLOR="#8e236b"><p align=CENTER>[This message was edited by Karlis Abolins on 27 June 2002 at 12:03 PM.]</p></FONT>
The new MSA bodies are carbon composite, but the necks are aluminum.<SMALL>Kyle, your solution about carbon composite necks will shortly be seen on your new guitars.</SMALL>
I believe one of the reasons my D-12 Dekley has little to no cabinet drop is that the massive, almost solid, Pakkawood necks are bolted firmly to the body, keeping the body from flexing. I'm hoping to do some work on this guitar over the next two weeks and will be able to report my findings at that time.
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Jim Smith jimsmith94@attbi.com
-=Dekley D-12 10&12=-
-=Fessenden Ext. E9/U-13 8&8=-
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Carl, (likewise...no disrespect intended), I don't worry about "numbers"...just the "sound". I, personally, (in the context of playing in a band), cannot "hear" a 2-cent discrepancy, therefore, I choose not to concern myself with it. It is my own feeling that the time spent on these tiny intricacies of tone and tuning (that seem to seriously trouble so many players) would be better spent on learning to just play the thing! Your own feelings, however, are just as valid.
Neither of us is right or wrong, we just have different priorities!
Neither of us is right or wrong, we just have different priorities!
'Tis true that on a 10 string PSG, you have somewhere in the neighborhood of 250-300# of stress on the cabinet.
However, one must realize that this stress, once the open strings are tuned, is "ZERO" stress in relation to a given pedal(s) and/or knee lever(s)) additional stress.
In other words, WHEN the A pedal is engaged, and another string drops, it is NOT due to the 300# of static pull. That pull is already there!! And the opening tuning has NO strings that are in a dropped state. UNTIL some additonal pull(s) occurs.
Rather, it is ONLY the two pulls on the A pedal (in this instance) that has an affect on a string or strings dropping. So 300#'s suddenly becomes 50 pounds of pull. NOT 300.
Something that MOST cabinets can easily handle with OUT the problem we all face more or less.
So what we are looking at here in the case of the A pedal and the 6th string dropping as an example is: The root cause is promulgated by the two B strings ONLY being raised.
Now the 64 million dollar question is; WHAT is allowing that 6th string to drop?
WHEN you find this, the solution should be quite easy. The Problem is and has been all along, I have found NO one that can satisfy me that it is in fact the cabinet bowing that is causing MOST of the drop.
Ron Lashley said it was NOT! His words to me on 2 different occasions were,
"I KNOW what is causing it. AND, it is more than one thing".
I tried my best to get him to tell me. But that was never to be.
God rest his precious soul,
carl
However, one must realize that this stress, once the open strings are tuned, is "ZERO" stress in relation to a given pedal(s) and/or knee lever(s)) additional stress.
In other words, WHEN the A pedal is engaged, and another string drops, it is NOT due to the 300# of static pull. That pull is already there!! And the opening tuning has NO strings that are in a dropped state. UNTIL some additonal pull(s) occurs.
Rather, it is ONLY the two pulls on the A pedal (in this instance) that has an affect on a string or strings dropping. So 300#'s suddenly becomes 50 pounds of pull. NOT 300.
Something that MOST cabinets can easily handle with OUT the problem we all face more or less.
So what we are looking at here in the case of the A pedal and the 6th string dropping as an example is: The root cause is promulgated by the two B strings ONLY being raised.
Now the 64 million dollar question is; WHAT is allowing that 6th string to drop?
WHEN you find this, the solution should be quite easy. The Problem is and has been all along, I have found NO one that can satisfy me that it is in fact the cabinet bowing that is causing MOST of the drop.
Ron Lashley said it was NOT! His words to me on 2 different occasions were,
"I KNOW what is causing it. AND, it is more than one thing".
I tried my best to get him to tell me. But that was never to be.
God rest his precious soul,
carl
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- Henry Matthews
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CARL, I'M GOING TO HAVE TO AGREE WITH YOU. I THINK THAT IT IS SIMPLY THE BOWING OF THE CABINET THAT CAUSES CABINET DROP. THERE MIGHT BE ANOTHER SMALL FACTOR INVOLVED BUT THE MAIN CAUSE IS THE BOWING OF THE CABINET. TRY TWO THINGS. PUT A GOOD TUNING METER ON THE STEEL OF YOUR CHOICE AND MASH THE A&B PEDALS AND OBSERVE THE DROP. NOW MASH TWO OF YOUR C6TH PEDALS AND YOU WILL SEE THE SAME DROP OR REALLY CLOSE. THE CLOSER YOU GET TO THE MIDDLE OF THE GUITAR AND THE HARDER YOU MASH THE PEDALS, THE MORE DROP YOU HAVE ON THE E 9TH NECK. DAY SETUP GUITARS HAVE MORE DROP THAN EMMONS SET UP BECAUSE YOUR MAIN A&B PEDALS ARE CLOSER TO THE MIDDLE OR CENTER OF THE GUITAR. THE L-LEGRAND III CABINET DROP ELIMINATOR AS INGENIUS AS IT IS, IS NOTHING MORE THAN A ADJUSTIBLE PRY DEVICE THAT BOWS THE CABINET THE OTHER WAY BY PUTTING TENSION ON THE CHANGER BAR AND IT WORKS VERY WELL, IN FACT GREAT.
I DON'T WORRY ABOUT DROP BECAUSE MY EARS CAN'T HEAR A 2 CENT DROP AND I ENVY YOU GUYS THAT CAN HEAR THAT.
TO ME IT ALL BOILS DOWN TO ONE THING. THE STRONGER YOUR GUITAR CABINET THE LESS DETUNING YOU HAVE.
I DON'T WORRY ABOUT DROP BECAUSE MY EARS CAN'T HEAR A 2 CENT DROP AND I ENVY YOU GUYS THAT CAN HEAR THAT.
TO ME IT ALL BOILS DOWN TO ONE THING. THE STRONGER YOUR GUITAR CABINET THE LESS DETUNING YOU HAVE.
You know, this is an interesting subject. And I have been thinking - maybe this is why one set of "numbers" for tuning pulls cannot work - for example, if on one guitar the 8th string drops 5 cents when AB is engaged, then the A and B pulls need to be LOWER so that the 3-4-5-6-8 strings would be more in tune with EACH OTHER. This would mean you would have to cheat a little in distance with the bar when going from open to AB, for example. (All this compared to a guitar with "zero" cabinet drop.) Since it seems EVERY guitar has a different drop, then the amount of raise (for A & B) would be different for the main groups to still be in tune WITH EACH OTHER with pedals engaged. Maybe this is why the real "pros" often tune only their open strings with a tuner and tune pedal pulls by ear?????
Gil,
You are correct.
The reason that the "Jeff Newman" tuning guideline* is so popular, is it takes into consideration just what you speak of.
Jeff would be the last player on earth to recommend we shapen our E's by a full two and one half cycles IF, it were NOT for cabinet drop. His ears are just too good for that. Few players on earth play MORE in tune than Jeff. Along with his awesome teaching attributes.
The reason the 442.5 works is because MOST players are always pulling toward the A chord rather than pulling toward the E chord. This is because that is what A and B do!!
Cabinet drop is creating an almost "false" situation. We WANT The 4th string to be 440. But dang it, when ya go down on A and/or B it aint 440 no MO!!! (If you are from SHY-Cargo that means it is LESS than 440 hoss. )
So we purposely raise the E's so that as one engages these pedals cabinet drop lowers the E's back to 440 where it belongs! (Or there abouts.)
*Note: NOT all guitars need 442.5. Some need less. Rarley do they need more. Experiment with yours, using Jeff's chart as a starting point, until you find one that will allow you to play OVER the fret. You will be suprised.
May Jesus bless you in your quest(s)
carl
You are correct.
The reason that the "Jeff Newman" tuning guideline* is so popular, is it takes into consideration just what you speak of.
Jeff would be the last player on earth to recommend we shapen our E's by a full two and one half cycles IF, it were NOT for cabinet drop. His ears are just too good for that. Few players on earth play MORE in tune than Jeff. Along with his awesome teaching attributes.
The reason the 442.5 works is because MOST players are always pulling toward the A chord rather than pulling toward the E chord. This is because that is what A and B do!!
Cabinet drop is creating an almost "false" situation. We WANT The 4th string to be 440. But dang it, when ya go down on A and/or B it aint 440 no MO!!! (If you are from SHY-Cargo that means it is LESS than 440 hoss. )
So we purposely raise the E's so that as one engages these pedals cabinet drop lowers the E's back to 440 where it belongs! (Or there abouts.)
*Note: NOT all guitars need 442.5. Some need less. Rarley do they need more. Experiment with yours, using Jeff's chart as a starting point, until you find one that will allow you to play OVER the fret. You will be suprised.
May Jesus bless you in your quest(s)
carl