Construction and finite element analysis of SLM-TMF panels
The walls of combustion chambers are loaded by the high temperature of the hot gas and the pressure difference between the coolant and the chamber. This causes a failure of the wall over its repeated usage. The Finite Element analysis of a hot gas side of an actively cooled section (the so called...
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sg-ntu-dr.10356-654312023-03-11T17:01:10Z Construction and finite element analysis of SLM-TMF panels Jayaganesan Baskar Jorg Riccius School of Mechanical and Aerospace Engineering Oskar J. Haidn DRNTU::Engineering The walls of combustion chambers are loaded by the high temperature of the hot gas and the pressure difference between the coolant and the chamber. This causes a failure of the wall over its repeated usage. The Finite Element analysis of a hot gas side of an actively cooled section (the so called TMF panel) taking a real case engine as reference was studied. The need of fast and efficient production in every sector paved the way for a technique called Selective Laser Melting (SLM) which is an additive manufacturing process and combines the advantage of quick production with high design flexibilities. Thus with these advantages the TMF panel is chosen to be produced by this manufacturing process and the objective is to find the number of cycles to failure. Also, a suitable connection technology was found to connect the SLM part with standard counterpart to avoid leakage because of roughness. The unified Chaboche constitutive model's parameters for the material were identified (kinematic and isotropic hardening parameters) for the cyclic analysis for SLM-Inconel 718 at 6 different temperatures (298 K, 723 K, 773 K, 823 K, 873 K and 923 K). The accuracy of the identified parameters was demonstrated by uniaxial strain controlled cyclic analysis for different temperatures which gave good match between the test results and experimental results from literature. The SLM production of the TMF panel has the advantage of flexibility in design but at the same time production cost depends on the volume. Mass flow rate and pressure drop values across separate cooling channels produced by selective laser melting were compared. No blockage was found for 1.3*1.3 mm cooling channels. The half cooling channel + half fin coupled Finite Element analysis based on the reference case (FLPP storable engine) at the nozzle throat (where the loading is reaching its maximum) with symmetry boundary conditions on the centerline of the cooling channel and the centerline of the fin served as the reference for the 3D SLM-TMF panel FE analysis. The panel optimization was carried to match the results of the reference case (FLPP storable engine). The number of cycles to failure was calculated for the FLPP storable engine nozzle throat 2D section and also for the TMF panel before and after optimization by post processing of analysis results. Finally, a cost analysis gave the production cost of a TMF panel which was found out to be less compared with the cost of a conventional TMF panel. Master of Engineering (MAE) 2015-09-22T04:19:38Z 2015-09-22T04:19:38Z 2014 2014 Thesis http://hdl.handle.net/10356/65431 en 125 p. application/pdf |
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DRNTU::Engineering Jayaganesan Baskar Construction and finite element analysis of SLM-TMF panels |
| description |
The walls of combustion chambers are loaded by the high temperature of the hot
gas and the pressure difference between the coolant and the chamber. This causes
a failure of the wall over its repeated usage. The Finite Element analysis of a hot
gas side of an actively cooled section (the so called TMF panel) taking a real case
engine as reference was studied. The need of fast and efficient production in every
sector paved the way for a technique called Selective Laser Melting (SLM) which
is an additive manufacturing process and combines the advantage of quick
production with high design flexibilities. Thus with these advantages the TMF
panel is chosen to be produced by this manufacturing process and the objective is
to find the number of cycles to failure. Also, a suitable connection technology was
found to connect the SLM part with standard counterpart to avoid leakage because
of roughness. The unified Chaboche constitutive model's parameters for the
material were identified (kinematic and isotropic hardening parameters) for the
cyclic analysis for SLM-Inconel 718 at 6 different temperatures (298 K, 723 K,
773 K, 823 K, 873 K and 923 K). The accuracy of the identified parameters was
demonstrated by uniaxial strain controlled cyclic analysis for different
temperatures which gave good match between the test results and experimental
results from literature.
The SLM production of the TMF panel has the advantage of flexibility in design
but at the same time production cost depends on the volume. Mass flow rate and
pressure drop values across separate cooling channels produced by selective laser
melting were compared. No blockage was found for 1.3*1.3 mm cooling channels.
The half cooling channel + half fin coupled Finite Element analysis based on the
reference case (FLPP storable engine) at the nozzle throat (where the loading is
reaching its maximum) with symmetry boundary conditions on the centerline of
the cooling channel and the centerline of the fin served as the reference for the 3D
SLM-TMF panel FE analysis. The panel optimization was carried to match the
results of the reference case (FLPP storable engine). The number of cycles to
failure was calculated for the FLPP storable engine nozzle throat 2D section and
also for the TMF panel before and after optimization by post processing of
analysis results. Finally, a cost analysis gave the production cost of a TMF panel
which was found out to be less compared with the cost of a conventional TMF
panel. |
| author2 |
Jorg Riccius |
| author_facet |
Jorg Riccius Jayaganesan Baskar |
| format |
Theses and Dissertations |
| author |
Jayaganesan Baskar |
| author_sort |
Jayaganesan Baskar |
| title |
Construction and finite element analysis of SLM-TMF panels |
| title_short |
Construction and finite element analysis of SLM-TMF panels |
| title_full |
Construction and finite element analysis of SLM-TMF panels |
| title_fullStr |
Construction and finite element analysis of SLM-TMF panels |
| title_full_unstemmed |
Construction and finite element analysis of SLM-TMF panels |
| title_sort |
construction and finite element analysis of slm-tmf panels |
| publishDate |
2015 |
| url |
http://hdl.handle.net/10356/65431 |
| _version_ |
1761781938549424128 |