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Bolt question for an engineer.
Moderators: toaddog, TWISTY, V8Patrol, Moderators
ISO metric fastener material strength property classes (grades) is specified in ISO Standard 898-1. The 8 in 8.8 means nominal (minimum) tensile ultimate strength is 8 * 100 = 800 MPa (Megapascal); the 8 means the yield strength is 0.8 times tensile ultimate strength or 0.8 * 800 = 640 MPa.
for alloy steels, ultimate shear stress is approx .75 times the ultimate tensile stress and yield shear stress is approx .6 times the tensile yield stress.
so for ultimate shear strength of an 8.8 bolt you have 800MPa * 0.75 = 600MPa (this is the load that will break the bolt)
for yield shear strength of an 8.8 bolt you have 640MPa * .6 = 384MPa (this is the load that will start to deform the bolt.
NOTE you need to DOUBLE these for double shear.
If you know which part of the bolt (thread or shank) is loaded, and the pitch of the thread, you can work out the cross sectional area of the loaded portion, and work out the actual load in Newtons for a given bolt, with the stress = load/area formula.
(can I have a job at EA now?)
for alloy steels, ultimate shear stress is approx .75 times the ultimate tensile stress and yield shear stress is approx .6 times the tensile yield stress.
so for ultimate shear strength of an 8.8 bolt you have 800MPa * 0.75 = 600MPa (this is the load that will break the bolt)
for yield shear strength of an 8.8 bolt you have 640MPa * .6 = 384MPa (this is the load that will start to deform the bolt.
NOTE you need to DOUBLE these for double shear.
If you know which part of the bolt (thread or shank) is loaded, and the pitch of the thread, you can work out the cross sectional area of the loaded portion, and work out the actual load in Newtons for a given bolt, with the stress = load/area formula.
(can I have a job at EA now?)
Free air locker to the first 20 callers!
for a nominal 11mm diameter the cross sectional area is:Gribble wrote:Is it 5.7t? or close?
a=pi*d^2/4
a = 95mm^2
stress = load/area so load (yield) = stress (yield) * area
load (yield) = 384MPa * 95mm^2 (exponents cancel neatly)
load (yield) = 36.5kN
using our old friend force = mass * acceleration and using 9.8m/s/s for acceleration;
force = 36,500/9.8 = 3725kg
note this is for 11mm nominal diamter in single shear. a 12mm bolt has a 12.4mm or greater shank so the yield stress will be higher by proportion of the cross sectional area. note also that this is the yield stress so this load will probably not break the bolt but will start to deform it; as the bolt deforms the cross sectional area decreases so under this load the bolt may wall continue to deform to the point where it fails completely.
Free air locker to the first 20 callers!
He's an engineer.mickyd555 wrote:i cant believ a man that drew that picture on a napkin, can also say all that...........there were some big words in there. awesome stuff dumdunce, what do you do for a living...........
He opens car bonnets and says "there's an engine in 'ere"
Mechanic in other words (I think)
2005 GU3 Patrol ST Ute
Yeild is the point when a material will no longer spring back to its original shape when the load is removed. In other words, the load required to bend it. Normally around 0.7 as Dumbdunce mentioned.CJ Burns Esq wrote:Whilst we have all the right people looking,
Which is stronger fine thread or coarse thread for the opposite of shear eg pull, is that yeild?
Ultimate is the point where it will fail.
shear is where the load is applied at right angles to the shank of the bolt
tensile/compressive is when the load is applied along the axis
torsional is when the load is applied around the axis (IE twisting)
Because a course thread is deeper than a fine thread, it is marginally weaker than a fine thread.
The main difference between the 2 is their ability to tighten, maintain that load & its resistance to vibration.
2005 GU3 Patrol ST Ute
Dumbdance looses marks for incorrect use of terminology, but is good enough for this forum.
Engineers don't work it out like that though - they look in the capacity tables.
Shear capacity depends whether the shear plane is located at the shank or the thread of the bolt.
Also there is an interaction between shear and tension - they have to be reduced if both loads are present. Look at the interaction diagrams for these cases.
Anyway, minumum breaking load for class 8.8 M12 bolt in single shear, taken from the tables is - 57kN for shank and 38kN for thread.
Coarse thread bolts are generally stronger than fine thread bolts when loaded in tension, in fatigue situations - which is the common way that bolts in tension fail.
Engineers don't work it out like that though - they look in the capacity tables.
Shear capacity depends whether the shear plane is located at the shank or the thread of the bolt.
Also there is an interaction between shear and tension - they have to be reduced if both loads are present. Look at the interaction diagrams for these cases.
Anyway, minumum breaking load for class 8.8 M12 bolt in single shear, taken from the tables is - 57kN for shank and 38kN for thread.
Coarse thread bolts are generally stronger than fine thread bolts when loaded in tension, in fatigue situations - which is the common way that bolts in tension fail.
John
bolts
Would someone speak english
he asked how many tonnes is the shear strength
he asked how many tonnes is the shear strength
doh :( where specifically?Bush65 wrote:Dumbdance looses marks for incorrect use of terminology, but is good enough for this forum.
agreed - but a good engineer knows how to arrive at a similar conclusion to the table - every table has those scary letters at the bottom: 'E&OE' - so a first principles approximation is always a good idea.Engineers don't work it out like that though - they look in the capacity tables.
so at least my maths is goodAnyway, minumum breaking load for class 8.8 M12 bolt in single shear, taken from the tables is - 57kN for shank and 38kN for thread.
Coarse thread bolts are generally stronger than fine thread bolts when loaded in tension, in fatigue situations - which is the common way that bolts in tension fail.
interesting. why?
Free air locker to the first 20 callers!
Are you calling us forumites retards?Bush65 wrote:Dumbdance looses marks for incorrect use of terminology, but is good enough for this forum.
Oh, and the weight is going to be on the bolts shank, not the threads, so i was right? 5.7t?
To ask another quick one, what is the allowable "tolerance" there?
For instance, a riggers D shackle is rated at 3.5t but in reality doesn't shit itself until 14t (this is for arguments sake, ok?) so it has a saftey factor of 4.
When ISO set this standard out, what factor(s) are set into it? Or does the bolt just need to pass the standard by 1 gram?
\m/
I am basically a bum... I used to work in IT but I hated it so I quit. Now I do dodgy backyard mechanical repairs (anyone got an apprenticeship needs filling?)Mytqik wrote:He's an engineer.mickyd555 wrote:i cant believ a man that drew that picture on a napkin, can also say all that...........there were some big words in there. awesome stuff dumdunce, what do you do for a living...........
He opens car bonnets and says "there's an engine in 'ere"
Mechanic in other words (I think)
Free air locker to the first 20 callers!
If the shank of the bolt is in shear then you were almost right, it is 5.8 tonne.Gribble wrote:Are you calling us forumites retards?Bush65 wrote:Dumbdance looses marks for incorrect use of terminology, but is good enough for this forum.
Oh, and the weight is going to be on the bolts shank, not the threads, so i was right? 5.7t?
To ask another quick one, what is the allowable "tolerance" there?
For instance, a riggers D shackle is rated at 3.5t but in reality doesn't shit itself until 14t (this is for arguments sake, ok?) so it has a saftey factor of 4.
When ISO set this standard out, what factor(s) are set into it? Or does the bolt just need to pass the standard by 1 gram?
AFAIK the values given above by Bush65 give the load at which the bold will begin to yield (plastically (permanently) deform). The value you are talking about for the shackle is the SWL - safe working load - which is a long way below the yield point.
_____________________________________________________________
RUFF wrote:Beally STFU Your becoming a real PITA.
Yeh yeh, i get that, but not every single brand of bolt manufactured would break at exactly the same force. So that rating would be like a minimum.ISUZUROVER wrote:If the shank of the bolt is in shear then you were almost right, it is 5.8 tonne.Gribble wrote:Are you calling us forumites retards?Bush65 wrote:Dumbdance looses marks for incorrect use of terminology, but is good enough for this forum.
Oh, and the weight is going to be on the bolts shank, not the threads, so i was right? 5.7t?
To ask another quick one, what is the allowable "tolerance" there?
For instance, a riggers D shackle is rated at 3.5t but in reality doesn't shit itself until 14t (this is for arguments sake, ok?) so it has a saftey factor of 4.
When ISO set this standard out, what factor(s) are set into it? Or does the bolt just need to pass the standard by 1 gram?
AFAIK the values given above by Bush65 give the load at which the bold will begin to yield (plastically (permanently) deform). The value you are talking about for the shackle is the SWL - safe working load - which is a long way below the yield point.
The bolt might take twice as much before it deforms, but for saftey they say dont put anymore that 5.8 tonnes on an m12 8.8 bolt, when in their quality testing the bolt might take 7 or more, so it passes that standard easily.
Its irrelavent to my problem anyway, coz 5.7 is way more than i need. Im just curious to know if there is a saftey factor or not.
\m/
the numbers quoted for shear yield stress is nomial (ie minimum) shear yield stress for a bolt to 'make the grade' - and since adding strength adds expense, you find that bolts are pretty damn close in strength to their actual grading. in other words, there is is no safety factor involved in those figures.Gribble wrote:Yeh yeh, i get that, but not every single brand of bolt manufactured would break at exactly the same force. So that rating would be like a minimum.ISUZUROVER wrote:If the shank of the bolt is in shear then you were almost right, it is 5.8 tonne.Gribble wrote:Are you calling us forumites retards?Bush65 wrote:Dumbdance looses marks for incorrect use of terminology, but is good enough for this forum.
Oh, and the weight is going to be on the bolts shank, not the threads, so i was right? 5.7t?
To ask another quick one, what is the allowable "tolerance" there?
For instance, a riggers D shackle is rated at 3.5t but in reality doesn't shit itself until 14t (this is for arguments sake, ok?) so it has a saftey factor of 4.
When ISO set this standard out, what factor(s) are set into it? Or does the bolt just need to pass the standard by 1 gram?
AFAIK the values given above by Bush65 give the load at which the bold will begin to yield (plastically (permanently) deform). The value you are talking about for the shackle is the SWL - safe working load - which is a long way below the yield point.
The bolt might take twice as much before it deforms, but for saftey they say dont put anymore that 5.8 tonnes on an m12 8.8 bolt, when in their quality testing the bolt might take 7 or more, so it passes that standard easily.
Its irrelavent to my problem anyway, coz 5.7 is way more than i need. Im just curious to know if there is a saftey factor or not.
it might also be worth investigating how you intend to use the bolt - it might look like it's in shear when it is acutally loaded in bending and/or tension, which obviously changes the allowable stresses in the bolt.
Free air locker to the first 20 callers!
I hope no offence was taken, That comment wasn't meant to be taken seriously. I have read many of your posts and it is obvious that you know what you are talking about.dumbdunce wrote:doh :( where specifically?Bush65 wrote:Dumbdance looses marks for incorrect use of terminology, but is good enough for this forum.
You did mess up in the part about shear strength, which you correctly stated in MPa, but then incorrectly said that this was a load. In fact it is stress, but this leads to more confusion for the lay person.
Actually most design is carried out in complience with codes, which stipulate how these things are calculated.dumbdunce wrote:agreed - but a good engineer knows how to arrive at a similar conclusion to the table - every table has those scary letters at the bottom: 'E&OE' - so a first principles approximation is always a good idea.Bush65 wrote:Engineers don't work it out like that though - they look in the capacity tables.
For example, the various clauses in section 9 of AS4100 (steel structures code) for bolts and bolted connections are more involved than discussed here. But it is much simpler to use the safe load tables from the Australian Institute of Steel Construction, where most of the work has been done for you.
By the way, I did not refer to the safe load tables when I gave the minimum breaking strength for an M12 bolt - M16 is the smallest bolt permitted in a steel structure and minimum breaking strength is not a design capacity.
The thread form for external metric threads has a significant radius in the root. When fatigue is considered, the lower stress raising cooefficient at the root of coarse threads more than offsets the reduction in the cross sectional area. Published results from testing support this.dumbdunce wrote:so at least my maths is goodAnyway, minumum breaking load for class 8.8 M12 bolt in single shear, taken from the tables is - 57kN for shank and 38kN for thread.
Coarse thread bolts are generally stronger than fine thread bolts when loaded in tension, in fatigue situations - which is the common way that bolts in tension fail.
interesting. why?
John
God of Magnificant Ideas!
Re: Bolt question for an engineer.
Has any body answered this yetGribble wrote:What is the shear strength of an 8.8 grade m12 bolt?
Kingy
[color=blue][size=150][b]And your cry-baby, whinyassed opinion would be.....? [/b][/size][/color]
YES - can't you read ?V8Patrol wrote:Has any body answered this yetGribble wrote:What is the shear strength of an 8.8 grade m12 bolt?
Bush65 wrote:minumum breaking load for class 8.8 M12 bolt in single shear, taken from the tables is - 57kN for shank and 38kN for thread.
_____________________________________________________________
RUFF wrote:Beally STFU Your becoming a real PITA.
Re: Bolt question for an engineer.
Yep, all there.V8Patrol wrote:Has any body answered this yetGribble wrote:What is the shear strength of an 8.8 grade m12 bolt?
Kingy
Now how do I fit 35's under my hilux?
\m/
no, no offence taken at all - you're absolutely correct on that one. It's the sort of mistake I used to yell at other engineers for - obviously I'm getting slack in my old ageBush65 wrote:I hope no offence was taken, That comment wasn't meant to be taken seriously. I have read many of your posts and it is obvious that you know what you are talking about.dumbdunce wrote:doh :( where specifically?Bush65 wrote:Dumbdance looses marks for incorrect use of terminology, but is good enough for this forum.
You did mess up in the part about shear strength, which you correctly stated in MPa, but then incorrectly said that this was a load. In fact it is stress, but this leads to more confusion for the lay person.
that makes sense. I doubt it will ever matter to me, but it gives me a nice warm feeling just knowingThe thread form for external metric threads has a significant radius in the root. When fatigue is considered, the lower stress raising cooefficient at the root of coarse threads more than offsets the reduction in the cross sectional area. Published results from testing support this.Coarse thread bolts are generally stronger than fine thread bolts when loaded in tension, in fatigue situations - which is the common way that bolts in tension fail.
interesting. why?
Free air locker to the first 20 callers!
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