GEARLESS MILL DRIVE MAINTENANCE PLANNING RISK ANALYSIS USING FAILURE MODE AND EFFECT ANALYSIS AND ANALYTIC HIERARCHY PROCESS
The Gearless Mill Drive (GMD) is a critical production equipment in copper concentrator mill processing plants, playing an integral role in the overall production process. The GMD utilizes a synchronous motor, with the rotor coil forming an integral part of the mill's construction. The risin...
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| Format: | Theses |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/81924 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The Gearless Mill Drive (GMD) is a critical production equipment in copper
concentrator mill processing plants, playing an integral role in the overall
production process. The GMD utilizes a synchronous motor, with the rotor coil
forming an integral part of the mill's construction. The rising demand for copper
due to electrification programs has prompted stakeholders to demand high
availability and utilization for this production unit. However, optimizing the GMD
maintenance system presents complex challenges and requires thorough
preparation. This is because processing plants and mines located in remote areas
face significant geographical and operational challenges. Maintenance efforts have
been implemented to extend the machine's intended operating life. However, the
effectiveness of these maintenance activities needs to be re-evaluated. Risk-cost
analysis can be utilized to assess the effectiveness of maintenance work in
mitigating machine failure risks and balancing cost components, including
maintenance costs and opportunity costs arising from maintenance activities.
Failure Mode and Effect Analysis (FMEA), a Six Sigma tool, can be employed to
evaluate potential risks and their impact on machinery or production units, as well
as the effectiveness of damage detection and prevention systems, including
maintenance programs. FMEA does have certain limitations, one of which is the
subjectivity of the assessment by the source. To address the challenges and
limitations of FMEA, the Analytic Hierarchy Process (AHP), a Multi Criteria
Decision Making (MCDM) tool, can be utilized. In this study, AHP is employed
for Risk-Cost analysis, where: 1) Risk factors of each failure mode are compared
pairwisely; 2) Risk factors are compared with cost factors to determine the criteria
that prioritize decision-making in an aggregate manner; 3) Maintenance solution
alternatives with a work scheduling framework are used as alternatives in AHP.
Five maintenance work scheduling alternatives have been identified in the
formulation process. The decision-makers perceived the need to critically review
maintenance work scheduling and understand the importance of maintenance
activities. As a result, the implementation of a run-to-failure strategy was
considered the least desirable alternative. Risk-cost analysis in the maintenance
domain facilitates the optimization of maintenance activities with a
correspondingly quantifiable risk level. This optimization can maximize the
availability and utilization of production units to achieve production targets. It is
crucial for all stakeholders to ensure that production units can operate productively
and safely beyond their intended operating lifetime. |
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