DEVELOPMENT OF EQUIPMENT MAINTENANCE SYSTEM MODEL WHICH IS CAPABLE OF IDENTIFYING COMPONENT USAGE USING FORCE FLOW MODEL APPROACH
Production equipment in the manufacturing industry consists of various types. Machine tools are production equipment in the machining industry that are used for working on metal or non-metal materials to produce products as needed. The decrease of machine tools performance is strongly influenced...
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| Format: | Dissertations |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/56939 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Production equipment in the manufacturing industry consists of various types.
Machine tools are production equipment in the machining industry that are used
for working on metal or non-metal materials to produce products as needed. The
decrease of machine tools performance is strongly influenced by the functioning
condition of its constituent components. This study aims to develop a model of a
machining equipment maintenance system that is capable to produce maintenance
information down to the component level in the form of remaining service life and
maintenance schedules for used components. This study applied a force flow model
to represent the connection of the force flow propagation between the components
used. The force flow model requires anatomy of the constituent components which
are represented in the structural model of the equipment components. In order to
make the model to function properly, the component nodes in the force flow model
have several attributes, namely: identity, force flow component nodes, moving
status and power flow percentage factor values. The developed system model has
some functions, those are the ability to: tracing sources of driving components,
tracing being-used components subjected to a force, tracing components whose
remaining life is to be calculated, determining components status whose power flow
values are calculated, calculating power values of components subjected to a force,
calculating components remaining service life and generating maintenance
schedules. The developed model has been verified in several case studies upon
equipment objects, including turning machine gearboxes, Aciera F3 milling
machines and hand-driven drill tools. The results showed that the used component
that is subjected to a force on the test object could be identified, and the value of
the power on the component subjected to a force could be calculated. Furthermore,
with the assumed service life (mean time between failure) of each component and
the total duration of usage during for a certain period, the model could define the
reduction value of the components remaining service life and maintenance
schedules, such as remaining service life and prediction of bearing maintenance
schedules in the case study. The novelty of this research is the development of a
new model of the maintenance system that can produce maintenance information
down to the component level through the application of the force flow model to the
developed model.
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