Detailed Bolted Joint Calculations.xls
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 Description:

A video accompanies this calculation.
Purpose of calculation:
Determine force distribution in a bolted joint.
Calculation Reference
Machine Design Juvinall
Scahum's Machine Design
http://www.mech.uwa.edu.au/DANotes/threads/mechanics/mechanics.html
http://emntserver.unl.edu/Negahban/em223/note16/note16.htm
http://en.wikipedia.org/wiki/Bolted_joint
http://www.boltscience.com/
Use 'Torque Pretension' worksheet also consult with the following references
http://www.roymech.co.uk/Useful_Tables/Screws/Preloading.html#Initial_Bolt_Tension
http://www.roymech.co.uk/Useful_Tables/Screws/Screw_loads.html
Calculation Validation
http://ocw.mit.edu/OcwWeb/MechanicalEngineering/2007Spring2005/Tools/detail/spreadsheet.htm
1) Material and basic geometry geometry
Young's modulus of bolt
Poisson ratio of bolt
Young's modulus of clamped plate
Poisson ratio of clamped plate
upper clamped plate thickness
lower clamped plate thickness
total clamped plate thickness
2) Bolting details
bolt diameter
bolt thread root diameter
bolt clearance hole
bolt head diameter
(note: could be increased using a flanged headed bolt or a washer)
thickness of bolt head
nut thickness
(note: enter 0 if threaded into flange)
bolt length assumed equal total clamped plate thickness + hnut
3) Torque Tightening and Bolt PreLoad Calculation
Method of torque tightening determines accuracy of bolt preload obtained.
It is not unusual to increase bolt size because the torque tightening method cannot guarentee a minimum preload.
The effects of the torque tightening method are shown on the joint diagram below.
Variation in preload (+ and )
Tightening Torque (to yield bolt see Eqn. 37)
Bolt head dimension across flats
Thread pitch
outer thread radius
inner thread radius
mean thread radius
Effective radius of rubbing surface against which head/nut bears
Coefficient of friction between screw and nut thread
Coefficient of friction at head/nut bearing collar
Thread Lead (equals thread pitch for single thread screws)
Angle of thread at mean radius
Thread angle at bearing surface
Angle between tangent to tooth profile (on the loaded side) and a radial line
Thread Constant
Bolt preload (load parallel to screw axis)
Efficiency of the screw mechanism (ratio of useful work out to work in)
Torque to stretch Bolt
Thread Torque (torsional load in the bolt to stretch the bolt and overcome thread friction)
Torque to overcome thread friction
Torque to overcome collar friction
Joint pretension constants to compare with other threads
Typical K factors for comparison purposes
Steel Thread Condition
0.30 as received, stainless on mild or alloy
0.20 as received, mild or alloy on same
0.16 cadmium plated
0.14 molybdenumdisulphide grease
0.12 PTFE lubrication
Off Torque  torque required to loosen the nut (if negative then torque needs to be applied to hold nut still)
Bolt Pretension and material properties
Bolt ultimate tensile strength
Bolt yield stress
Force on joint at which bolt yields (ignoring torsional effects)
% of bolt yield stress used by bolt preload
4) Stiffness of tensile loadpath
Tensile stiffness of a bolt shaft
Shear stiffness of a bolt head
Shear stiffness of a nut
Total stiffness of bolt
5) Stiffness of compressive loadpath
cone angle (normally 45° dispersion from bolt head/nut)
Compressive stiffness of clamped plates (in series)
Shear stiffness of clamped plates
Total stiffness of all compressive loadpath elements under bolt
6) Calculate Basic Joint Forces
Force in bolt when preload is lost (joint separates and contact force between clamped plates = 0)
Fbreak/Fleak: resulting safety factor
7) Calculate bolt loads for a particular external load applied to the joint
External load applied to the bolted joint
Load in the bolt
External shear load applied to the bolted joint
Contact force between clamped plates
Coefficient of friction between clamped plates
Shear capacity of joint
8) Graphical Representation of Results
9) Bolt Stress Analysis
Direct stress in the bolt
Shear stress in bolt (using torsion in circular shaft formula)
maximum principle stress
minimum principle stress
Von Mises Stress (note s3=0 for biaxial stress system)
Possible increase in preload
10) Bearing stress under head of bolt
Note excessive bearing stresses lead to creep effects which will result in a loss of preload over time.
This relaxation is a function of:
Typically the bearing stress should not exceed the clamped plate yield stress.
Maximum bearing Stress
11) Joint deflections and nut rotation.
Bolt extension
Flange compression
Angle turned to extend the bolt
12) Losses at Clamped Surfaces
Paint compression factor
Maximum paint thickness (specification)
Number of painted surfaces
Preload after paint compression
Maximum paint thickness (specification)
Preload after paint compressionA simpler version of this calculation is available here.
Calculation Reference
Handbook of bolts and bolted joints
American Machinists' Handbook and Dictionary of Shop Terms
Basic Principles for Construction, Cengage Learning
Machinery's Handbook
 Submitted By:
 John Doyle (JohnDoyle[Admin])
 Submitted On:
 25 May 2012
 File Size:
 519.00 Kb
 Downloads:
 572
 File Version:
 1.2
 File Author:
 John Doyle
 Rating:
A separate calc for d1 and d2 with hf1 and hf2 in the equations and with the initial 2 deleted in each equation. A separate calc for kf1 and kf2 based on d1 and d2 ( and possible using separate E values (Ef2 and Ef2 ) although I do not think this is important.
kf = kf1+kf2 /(kf1.kf2).
I have created a modified version of the spreadsheet if John Doyle wants a copy.
1) Add fine thread sizes.
2) Add screw joint, that is, bolt through clearance material into tapped hole.
[img]http://www.excelcalcs.com/images/stories/WebLog/boltstiff.png[/img]
However I was unsure of the derivation of the formula and decided to include simpler terms. Now that I have taken a look at the [url=http://www.roymech.co.uk/Useful_Tables/Screws/Joint_Stiffness.html]stiffness derivation on your site[/url] I feel much more confortable using your formulae.
Thank you very much for the comment and I update the calculation shortly.
uses the stiffness of a cylinder with OD = dia of bottom of cone frustrum. Other
sources including roymech,co.uk use the actual stiffness of the frustrum.
The method used may be acceptable from a practical point of view but the resulting stiffness factors are very low compared to the other sources.
Please could John comment on this.
Note this is an excellent highly visible set of calcs.
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