PEMETAAN DAN MITIGASI ERROR TRAPS MENGGUNAKAN METODE WALK-THROUGH TALK-THROUGH PADA PEKERJAAN PENGECORAN LOGAM PT X
Melting is a job with the highest accident rate, reaching 50%, at the Foundry Plant of PT X during the 2022-2023 period. The interventions implemented, such as the use of HIRADC and supporting safety activities, have proven to be insufficient in preventing workplace accidents due to the presence...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/85931 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Melting is a job with the highest accident rate, reaching 50%, at the Foundry Plant of PT X
during the 2022-2023 period. The interventions implemented, such as the use of HIRADC
and supporting safety activities, have proven to be insufficient in preventing workplace
accidents due to the presence of additional contributing factors known as error traps. Three
error traps with the highest severity levels were identified and mitigated through engineering
controls. Observations and interviews using the Walk-Through Talk-Through (WTTT)
method were conducted to easily and quickly identify error traps, a method that has not been
widely used in research. Meanwhile, engineering control mitigation was carried out through
needs identification, concept generation, and concept selection. Out of a total of 18 routine
tasks involving 11 operators as sources, 56 error traps were identified with the percentage
distribution of people-related factors at 36%, task-related factors at 41%, and
organizational-related factors at 23%.. The classification results indicated that the most
frequently encountered subfactors of error traps included unclear signs or signals, work
experience, unfamiliar or rare situations, and the trust in equipment. The application of
WTTT in identifying error traps can be performed easily and yields sufficiently detailed
results. However, the classification results tend to indicate that the distribution of error traps
occurs due to task-related factors. This may be attributed to the WTTT process, which allows
for closer observation of the work being performed. The first error trap occurred during the
melting task to ensure that there was no water in the charging box when charged into the
furnace. The second error trap occurred during the washing ladle task when the crane
operator placed the ladle into a safe parking jig. The third error trap was identified during
the pouring task when the operator aligned the nozzle with the pouring cup using the molten
metal's flame for guidance. The mitigation for the highest-ranking error trap involved the
design of drainage in the scrap charging box; the second error trap involved a mechanical
signal to ensure the parking jig's safety; and the third error trap involved a mechanical
scoop to ensure precision in the molten metal's flame.
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