BLASTWORTHINESS ANALYSIS OF AUXETIC PANEL ON HULL STRUCTURE OF COMBAT VEHICLE TO MEET STANAG 4569 LEVEL III STANDARD
APC Anoa is a combat vehicle currently mass-produced in Indonesia for military purposes. Anoa is an Armored Personnel Carrier (APC) type combat vehicle which functions to transport soldiers to the battlefield safely. The Anoa currently in production able to withstand the 7.62 mm caliber bullets f...
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| Format: | Final Project |
| Language: | Indonesia |
| Subjects: | |
| Online Access: | https://digilib.itb.ac.id/gdl/view/53852 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | APC Anoa is a combat vehicle currently mass-produced in Indonesia for military
purposes. Anoa is an Armored Personnel Carrier (APC) type combat vehicle which
functions to transport soldiers to the battlefield safely. The Anoa currently in
production able to withstand the 7.62 mm caliber bullets fired by infantry. As for
its blast resistance, APC Anoa has reached the STANAG 4569 level II standard.
However, with a larger spectrum of threats, it is necessary to increase the level of
protection in APC Anoa. Especially from bomb and mine threats. Research to
increase the level of protection to STANAG 4569 level III has been done before.
This research focuses on the use of additional sandwich panels with aluminum foam
cores. However, there is no industry in Indonesia that can reliably supply aluminum
foam needs. Alternatively, an auxetic structure can be used as the core of a sandwich
panel. The auxetic material and structure itself has been in the spotlight to make it
a ballistic armor, as well as a blast-proof structure. With their arrangement, auxetic
materials can have high strength and resistance but still with a minimum weight.
In doing this undergraduate assignment, the author wants to compare the energy
absorption of sandwich panel specimens using aluminum foam cores with auxetic
cores. The type of auxetic structure used in this study is the reentrant honeycomb
open cell structure. The first stage is carried out to verify whether the modeling
made is of good enough quality by conducting a numerical drop weight impact test.
Similar testing is also carried out on foam core sandwich panels. From the modeling
carried out in the first stage, it was found that in the wall thickness of 0.5 mm the
auxetic core panel had an inferior total and specific energy absorption value
compared to foam core. Then, the authors increased the thickness to 1 mm. Then
do the drop weight impact test again. It was found that the total energy absorption
by auxetic core specimens with a wall thickness of 1 mm was lower than that of
foam. However, the 1 mm wall auxetic specimen had a higher specific energy
absorption than the foam core specimen.
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In the next stage, blast test was carried out referring to STANAG 4569 level III on
foam core and auxetic specimens. As a comparison, the authors also modeled the
blast test on a single plate. From these tests, it was found that the foam and auxetic
core panels were able to significantly reduce deformation and acceleration due to
blast in the APC Anoa passenger cabin compared to single plates. Auxetic core
specimens at wall thicknesses of 0.5 mm and 1 mm have higher energy absorption
values than foam cores. However, specimens with a wall thickness of 0.5 mm have
a better absorption than 1 mm |
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