Validation Case: Flange Under Bolt Preload

This validation case belongs to structural analysis, with the case of a pipe flange under the effect of bolt preload. The aim of this test case is to validate the following parameters:

Bolt preload boundary condition

The simulation results from SimScale were compared to test case results presented in [SSNV228]$^1$.

View Project

Geometry

The geometry used for the case is shown below:

It represents a quarter section of a pipe bolted flange pair. The bolt shaft is simplified as a cylinder, as well as the nut. The model includes the pipe sections, flanges, a bolt, nuts, washers, and a gasket.

Analysis Type and Mesh

Tool Type: Code Aster

Analysis Type: Non-linear Static

Mesh and Element Types:

Mesh Type	Number of Cells	Number of Nodes	Element Type
Standard (structured)	50210	62344	1st Order Hexahedrals and Pyramids

Table 1: Mesh details

The mesh was computed using SimScale’s Standard Mesher algorithm. To optimize the performance of the FEA model, Sweep meshing refinement was used on the different parts, resulting in a structured mesh. Such a mesh consists of mapped hexahedral and pyramid elements, as can be seen in the figure:

structured mesh flange bolt preload validation case — Figure 2: Finite elements structured mesh used for the simulation generated with the standard algorithm

Simulation Setup

Material:

Elastic Modulus $E = $ 200 $GPa$
Poison’s ratio $\nu = $ 0.3

Boundary Conditions:

Constraints:
- Symmetry plane on the XZ plane faces
- Symmetry plane on the YZ plane faces
- Symmetry plane on pipe end faces
Contacts:
- Bonded contact between the pipes and flange necks
- Bonded contact between the flange faces and washers
- Bonded contact between the washers and nuts
- Bonded contact between the nuts and bolt shaft
- Physical contact between the flanges and seal ring
Load:
- Bolt preload of 3393 $N$
- Pressure on internal pipe, flange and seal faces $P = $ 1e-6 $Pa$, automatically ramped from zero to the maximum value.

Reference Solution

The reference solution is of the numerical type, as presented in [SSNV228]$^1$. It is given in terms of the mean stress on the bolt shaft:

$$ \sigma_{bolt} = 30\ MPa $$

Result Comparison

Comparison of the axial bolt stress $\sigma_{ZZ}$ at a point data result control item located on the bolt shaft with the theoretical solution is presented below:

FIELD	COMPUTED	REF	ERROR
$\sigma_{ZZ}$ $(SIZZ)$ $[MPa]$	30.3135	30.0	1.05 %

Table 2: Results comparison and computed errors

Illustration of the deformed shape and stress distribution on the flange under bolt preload condition is presented in Figure 3, while the overall distribution of the axial stress on the bolt $\sigma_{ZZ}$ is presented in Figure 4:

stress contours developed due to bolt preload flange — Figure 3: Deformed shape and stress contour on the bolted flange

stress on bolt in preload — Figure 4: Stress contour plot for $\sigma_{ZZ}$ $(SIZZ)$, showing the distribution of the axial stress in the bolt. Stress concentrations can be seen varying from the reference value of 30 MPa.

References

SSNV228 – “Mise en pré-tension d’un goujon” – Code_Aster validation case.

Note

If you still encounter problems validating you simulation, then please post the issue on our forum or contact us.

Last updated: March 1st, 2023

Did this article solve your issue?

How can we do better?

We appreciate and value your feedback.