Analysis And Evaluation Of The Performance Of A Low-Pressure Boiler Feed Pump Induction Motor Based On Temperature Increase
Article Sidebar
Main Article Content
Abstract
The induction motor in the Low Pressure Boiler Feed Pump (LP BFP) system plays a crucial role in ensuring the smooth operation of the power generation process at the combined cycle power plant. An increase in motor temperature is a key indicator for evaluating performance and detecting potential operational issues at an early stage. This study aims to analyze and evaluate the performance of the LP BFP induction motor based on temperature rise and motor vibration conditions at PT PLN Nusantara Power UP Gresik. The research method employs a descriptive quantitative approach through field observations, temperature measurements, vibration analysis, and the collection of motor operational data. The results show that the motor temperature on the Drive End (DE) side is 56.8°C and on the Non-Drive End (NDE) side is 47.6°C, which are still within normal operating limits. However, the vibration analysis results indicate bearing damage with an ALARM status based on ISO 10816-3. Therefore, regular temperature monitoring and preventive maintenance are crucial to maintaining the motor’s operational reliability.
Downloads
Article Details
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
References
Ashfahandika, M., Slamet, P., & Sarwo, R. (2025). Evaluasi Kinerja Motor Induksi 3 Fasa Menggunakan Parameter Listrik terhadap Variasi Kerusakan pada Komponen Bearing
Ayankoso, S., Dutta, A., He, Y., Gu, F., Ball, A., & Pal, S. K. (2026). Performance of vibration and current signals in the fault diagnosis of induction motors using deep learning and machine learning techniques.
Chen, L., Chernousko, F., & Song, G. (2015). JVE AU TH RS ON. 17(8).
Filho, D. P. S., Ginu, Y. F., & Jr, K. M. D. A. (2025). Induction Motor Fault Diagnosis Based on the Machine Temperature , Vibration Analysis and Sensors Fusion. 1–10.
Habetler, T. G., & Ran, L. (2023). BEARING FAULT DETECTION IN INDUCTION MOTORS USING VIBRATION ANALYSIS FOR CONDITION MONITORING.
Kurang, B., Hp, D., & Dilakukan, Y. (2018). EVALUASI EFISIENSI MOTOR INDUKSI SATU FASE. 10(1), 14–20.
Motor, E., Tiga, I., Menggunakan, F., & Simulink, M. (2024). Analisa pengaruh perubahan frekuensi dan tegangan terhadap efisiensi motor induksi tiga fasa menggunakan matlab
Narayanasamy, S. (2021). Condition monitoring of 3-phase induction motor. 5(3).
Nova, D., & Hardani, K. (2018). Analisis Torsi dan Efisiensi pada Motor Induksi Tiga Fasa Rotor Sangkar. 19(2).
Pengajar, S., Studi, P., & Elektro, T. (n.d.). Pengujian dan analisis motor asinkron tiga fasa pada laboratorium elektro.
Pratama, A. K., Zondra, E., & Yuvendius, H. (2020). Analisis Efisiensi Motor Induksi Tiga Phasa Akibat Perubahan Tegangan. 5(1), 35–43.
Rahyadi, S., Desmira, D., Vokasional, P., Elektro, T., & Keguruan, F. (2025). Analisis Preventive Maintenance Motor Condensate Extraction Pump 10 , 5kv Unit 6 di PT PLN Indonesia Power UBP Suralaya. 12(2), 354–362.
Setiono, A. M., Rijanto, A., & Zulfika, D. N. (2020). ANALISIS AMPLITUDO GETARAN TERHADAP JENIS KERUSAKAN UNBALANCE , LOOSENESS , DAN KERUSAKAN BEARING PADA MOTOR INDUKSI 3 PHASE
Suhu, B. N., & Arus, K. (2025). Desain Sistem Monitoring Gangguan Motor Induksi. 6(2), 207–216.
Zaini, Z., & Natasha, L. (2023). Monitoring for Temperature of Three Phase Induction Motor at Chemical Industry Using Internet of Things. 1(1), 140–161.