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Open Access
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nThis is an unedited manuscript accepted for publication and provided as an Article in Press for early access at the author’s request. The article will undergo copyediting, typesetting, and galley proof review before final publication. Please be aware that errors may be identified during production that could affect the content. All legal disclaimers of the journal apply.n
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A. Y. Chaudhari, R. U. Waghmare, P. V. Wagh, H. D. Badgujar, A. S. Sul,
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- Assistant Professor, Student, Student, Student, Student, Department of Mechanical engineering , MET’s Institute of Engineering, Nashik, Department of Mechanical engineering , MET’s Institute of Engineering, Nashik, Department of Mechanical engineering , MET’s Institute of Engineering, Nashik, Department of Mechanical engineering , MET’s Institute of Engineering, Nashik, Department of Mechanical engineering , MET’s Institute of Engineering, Nashik, Maharashtra, Maharashtra, Maharashtra, Maharashtra, Maharashtra, India, India, India, India, India
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Abstract
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nThe braking system represents one of its most important components of any vehicle, as a failure can result in devastating accidents. This study describes the design and development of an Air Brake Hose Failure Detection and Safety Braking System to address the problem of brake failure in big vehicles. The system monitors the condition of air brake hoses in real-time and provides audio-visual alerts to the driver in case of any abnormalities. A secondary braking system is integrated into the design to activate automatically upon detecting brake hose failure, ensuring continuous vehicle control and safety. The proposed system integrates pneumatic cylinders, solenoid valves, pressure switches, and a sensor-based monitoring mechanism to effectively prevent fluid leakage and ensure reliable braking performance. Designed for heavy vehicles such as buses and trucks, the system continuously monitors pressure levels and responds in real time to any abnormalities. This proactive approach helps maintain consistent braking functionality, reducing the risk of accidents caused by brake failure. Initial testing demonstrates the system’s efficiency, showing it to be both cost-effective and space- saving. Its modular design allows for easy integration into existing vehicle systems without major modifications. Overall, the solution offers a robust and adaptable safety enhancement for commercial transportation, supporting both operational reliability and improved road safety.nn
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Keywords: Brakes, fluid leakage, detection, secondary brakes line, safety.
n[if 424 equals=”Regular Issue”][This article belongs to Recent Trends in Fluid Mechanics ]
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nA. Y. Chaudhari, R. U. Waghmare, P. V. Wagh, H. D. Badgujar, A. S. Sul. [if 2584 equals=”][226 wpautop=0 striphtml=1][else]Safety braking system to avoid the failure in air brake Hoses[/if 2584]. Recent Trends in Fluid Mechanics. 08/10/2025; 12(03):-.
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nA. Y. Chaudhari, R. U. Waghmare, P. V. Wagh, H. D. Badgujar, A. S. Sul. [if 2584 equals=”][226 striphtml=1][else]Safety braking system to avoid the failure in air brake Hoses[/if 2584]. Recent Trends in Fluid Mechanics. 08/10/2025; 12(03):-. Available from: https://journals.stmjournals.com/rtfm/article=08/10/2025/view=0
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| Volume | 12 | |
| [if 424 equals=”Regular Issue”]Issue[/if 424][if 424 equals=”Special Issue”]Special Issue[/if 424] [if 424 equals=”Conference”][/if 424] | 03 | |
| Received | 14/05/2025 | |
| Accepted | 13/08/2025 | |
| Published | 08/10/2025 | |
| Retracted | ||
| Publication Time | 147 Days |
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