Centrifugal Pump Vibration Analysis In The Belt Clutch Connection System With A Variation Of The Dimensions Of The Thickness Of The Belt And Width Of The Belt

Introduction

The centrifugal pump plays a vital role in the clean water supply system, ensuring the availability of water for the needs of the community. However, in reality, the pump is not always able to convert electrical energy into complete motion energy. The remaining wasted energy can produce vibrations and unwanted sounds. Excessive vibrations can cause damage to the engine components, such as bearings, shaft, and flames. One of the reasons is disobedience to the motor flame connection and pump, so it cannot be connected rigidly.

Understanding the Problem

The centrifugal pump is a critical component in the clean water supply system, and its performance is directly related to the availability of water for the community. However, the pump's inability to convert electrical energy into complete motion energy can lead to vibrations and unwanted sounds. These vibrations can cause damage to the engine components, resulting in costly repairs and downtime.

The Role of the Belt Clutch System

To overcome the problem of vibrations and damage to the engine components, a common solution is to use a belt clutch system. The belt clutch connects the two flexible and elastic materials, namely the belt. The belt is tied to Flensa with the help of bolts and nuts in the upper and left and left positions of Flensa.

The Analysis Methodology

This analysis uses a mass model with a multiple degree of freedom (3 DOF). This model uses 3 masses analyzed in a free object diagram. Variations in the thickness of the belt used in this analysis are 4.5 mm, 6 mm, and 7.5 mm, while the width is 98 mm, 120 mm, and 145 mm.

The Effect of Belt Thickness and Width on Performance

The analysis shows that the thickness of the thickness and width of the belt affect the performance of the motor pump system, especially at the acceleration, speed, transfer, and natural frequency. Belts with a width dimension of 145 mm and a thickness of 7.5 mm have the smallest acceleration, speed, and displacement value, which is 8.53 m/s², 0.42 m/s, and 0.24 mm. This belt also has the largest mass, stiffness, and damping value, which is 1.52 kg, 133 N/M, and 937,76 N/(m/s). Natural frequency in a thickness of 7.5 mm shows the best performance and is able to withstand all variations of the thickness and width of the belt tested.

The Results of the Analysis

Based on the results of the analysis, the use of belts with a thickness of 7.5 mm and a width of 145 mm is recommended to be applied to the centrifugal pump system in the PDAM. This is because the configuration can minimize vibrations, thereby increasing the performance of the pump and extending the life of the engine components.

The Importance of Vibration Analysis

In addition, vibration analysis can be an effective tool for early detecting potential damage to the pump system. By monitoring vibration regularly, the PDAM can detect and overcome problems before more serious damage occurs. This is very important to ensure the continuity of the clean water supply system for the community.

Conclusion

In conclusion, the centrifugal pump is a critical component in the clean water supply system, and its performance is directly related to the availability of water for the community. The use of a belt clutch system can help to minimize vibrations and increase the performance of the pump. The analysis shows that belts with a thickness of 7.5 mm and a width of 145 mm have the best performance and are recommended to be applied to the centrifugal pump system in the PDAM.

Recommendations

Based on the results of the analysis, the following recommendations are made:

• The use of belts with a thickness of 7.5 mm and a width of 145 mm is recommended to be applied to the centrifugal pump system in the PDAM.
• Regular monitoring of vibration is necessary to detect and overcome problems before more serious damage occurs.
• The PDAM should consider implementing a vibration analysis program to ensure the continuity of the clean water supply system for the community.

Future Work

Future work should focus on:

• Conducting further analysis to determine the optimal belt thickness and width for different types of centrifugal pumps.
• Developing a vibration analysis program to detect and overcome problems before more serious damage occurs.
• Implementing a maintenance program to ensure the continuity of the clean water supply system for the community.
  Frequently Asked Questions (FAQs) about Centrifugal Pump Vibration Analysis ====================================================================

Q: What is centrifugal pump vibration analysis?

A: Centrifugal pump vibration analysis is a method used to analyze the vibrations of a centrifugal pump and its components, such as the shaft, bearings, and impeller. The analysis helps to identify potential problems and optimize the performance of the pump.

Q: Why is vibration analysis important for centrifugal pumps?

A: Vibration analysis is important for centrifugal pumps because excessive vibrations can cause damage to the engine components, such as bearings, shaft, and flames. Regular vibration analysis can help to detect and overcome problems before more serious damage occurs.

Q: What are the benefits of using a belt clutch system in centrifugal pumps?

A: The belt clutch system helps to minimize vibrations and increase the performance of the pump. It also allows for easier maintenance and repair of the pump.

Q: What are the recommended belt thickness and width for centrifugal pumps?

A: The analysis shows that belts with a thickness of 7.5 mm and a width of 145 mm have the best performance and are recommended to be applied to the centrifugal pump system in the PDAM.

Q: How often should vibration analysis be performed on centrifugal pumps?

A: Regular vibration analysis should be performed on centrifugal pumps to detect and overcome problems before more serious damage occurs. The frequency of vibration analysis depends on the type of pump, operating conditions, and maintenance history.

Q: What are the consequences of neglecting vibration analysis on centrifugal pumps?

A: Neglecting vibration analysis on centrifugal pumps can lead to costly repairs, downtime, and even complete failure of the pump. It can also affect the quality of water supplied to the community.

Q: Can vibration analysis be used to predict the lifespan of centrifugal pumps?

A: Yes, vibration analysis can be used to predict the lifespan of centrifugal pumps. By monitoring vibration regularly, the PDAM can detect and overcome problems before more serious damage occurs, which can help to extend the lifespan of the pump.

Q: What are the future directions for centrifugal pump vibration analysis?

A: Future work should focus on conducting further analysis to determine the optimal belt thickness and width for different types of centrifugal pumps, developing a vibration analysis program to detect and overcome problems before more serious damage occurs, and implementing a maintenance program to ensure the continuity of the clean water supply system for the community.

Q: Who should perform vibration analysis on centrifugal pumps?

A: Vibration analysis on centrifugal pumps should be performed by trained and experienced personnel, such as mechanical engineers or vibration analysts. They should have the necessary knowledge and skills to interpret the results of the analysis and make recommendations for maintenance and repair.

Q: What are the costs associated with vibration analysis on centrifugal pumps?

A: The costs associated with vibration analysis on centrifugal pumps depend on the type of analysis, the frequency of analysis, and the personnel performing the analysis. However, the costs are typically lower than the costs of repairing or replacing a damaged pump.

Q: Can vibration analysis be used to optimize the performance of other types of pumps?

A: Yes, vibration analysis can be used to optimize the performance of other types of pumps, such as positive displacement pumps, reciprocating pumps, and screw pumps. The analysis can help to identify potential problems and optimize the performance of the pump.