4. Bolted joint design (e-learning) – Bulten Polska S.A.

About Course

It is crucial that the bolted joints are strong enough to withstand the axial loads and the shear loads to which they are exposed. This is a short and simplified guide to the design of different bolted joints, including correct tightening techniques to secure your application of the joint.

Bolt joint design.
The bolt's mission.
How to design a bolted joint.
Design to handle axial load.
Why the bolt should always break first?
Hexagon with / without flange.
Design to handle shear loads.
Coefficient of friction.
Clamping force.
Loss in clamping force due to settling/relaxation.
How can we reduce the amount of bolts needed?
Optimize the assembly process.
Bolted joint design - Summary

Course Content

Bolted joint design (e-learning)

Before you begin, make sure to
Welcome to this e-learning module!
Bolted joint design
The bolt’s mission
How to design a bolted joint
Design to handle axial load
BuProx – calculation tool
The bolt must be able to handle the load
The bolt should always break first (part 1)
The bolt should always break first (part 2)
Thread engagement (video)
The bolt should always break first (part 3)
The bolt should always break first (part 4)
The surface under the bolt head needs to be strong enough to handle the pressure
Hexagon with flange
Hexagon head without flange
Design to handle shear loads
Coefficient of friction
Interface friction
Clamping force (part 1)
Clamping force (part 2)
Loss in clamping force due to settling/relaxation
How can we reduce the amount of bolts needed?
Optimize the assembly process (part 1)
Optimize the assembly process (part 2)
Change to a ultra-high tensile strength bolt
How many bolts do we need? (part 1)
How many bolts do we need? (part 2)
How many bolts do we need? (part 3)
How many bolts do we need? (part 4)
How many bolts do we need? (part 5)
How many bolts do we need? (part 6)
How many bolts do we need? (part 7)
Summary – How many bolts do we need?
Bolted joint design – Summary
Congratulation !
Bolted joint design quiz

About Course

What Will You Learn?

Course Content

Bolted joint design (e-learning)

Before you begin, make sure to

Welcome to this e-learning module!

Bolted joint design

The bolt’s mission

How to design a bolted joint

Design to handle axial load

BuProx – calculation tool

The bolt must be able to handle the load

The bolt should always break first (part 1)

The bolt should always break first (part 2)

Thread engagement (video)

The bolt should always break first (part 3)

The bolt should always break first (part 4)

The surface under the bolt head needs to be strong enough to handle the pressure

Hexagon with flange

Hexagon head without flange

Design to handle shear loads

Coefficient of friction

Interface friction

Clamping force (part 1)

Clamping force (part 2)

Loss in clamping force due to settling/relaxation

How can we reduce the amount of bolts needed?

Optimize the assembly process (part 1)

Optimize the assembly process (part 2)

Change to a ultra-high tensile strength bolt

How many bolts do we need? (part 1)

How many bolts do we need? (part 2)

How many bolts do we need? (part 3)

How many bolts do we need? (part 4)

How many bolts do we need? (part 5)

How many bolts do we need? (part 6)

How many bolts do we need? (part 7)

Summary – How many bolts do we need?

Bolted joint design – Summary

Congratulation !

Bolted joint design quiz