Optimization and Analysis of Pulsation Dampener

Authors

  • Harshal Kotkar Department of Mechanical Engineering, Saraswati College of Engineering, Kharghar, Maharashtra, India
  • Hrishikesh Pawar Department of Mechanical Engineering, Saraswati College of Engineering, Kharghar, Maharashtra, India
  • Shubham Patil Department of Mechanical Engineering, Saraswati College of Engineering, Kharghar, Maharashtra, India
  • Sagar Chavan Department of Mechanical Engineering, Saraswati College of Engineering, Kharghar, Maharashtra, India
  • Madhukar Sorte Associate Professor and Head, Department of Mechanical Engineering, Saraswati College of Engineering, Kharghar, Maharashtra, India

DOI:

https://doi.org/10.37628/jcam.v6i1.1063

Keywords:

pulsation, power pumps, dampener, pump, vibration

Abstract

This paper presents a new method for generating computer-aided models and analysis of pulsation dampeners used in fluid power systems to reduce vibration. Pulsation dampeners are widely used in different energy systems to measure the backlash that is driven by power pumps. The vibrations caused by the power pumps in the water system can be strong enough to cause structural damage to the pipes if the pulsation dampener is not installed. However, current methods used by industry in planning and analyzing dampeners are procedures designed to understand themselves. Adaptable to new technologies. The new modeling approach will work well and improve the current analytics and analytics process for marketers who are moving in different ways with user effort. The proposed method is the result of using a simulation between the electrical and hydraulic circuits. In the new method, a circular dampener is usually the same as a pure hydraulic circuit installed during the system of the diffuse diffuser pipes. In short, the new method will run some hurdles and introduce new strategies for using computer- based models and design of dampeners for reducing the vibration of electrical systems. 

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Published

2020-08-06

Issue

Section

Articles