Marine valves; play a critical role in the fluid systems of ships and offshore structures, ensuring the safe and efficient control of liquid and gas flow. This article reviews the acoustic performance of marine valves, focusing on flow-induced noise and its mitigation strategies. By leveraging numerical simulations and comparative analysis, we evaluate the sound characteristics of different valve types (e.g., ball valves, globe valves, and butterfly valves). Additionally, we discuss recent advancements in AI-driven tools, such as Google Scholar’s integration of the Gemini model, to enhance research accessibility and data interpretation in marine engineering.

Marine valves play a critical role in the fluid systems of ships, ensuring the safe and efficient operation of vessels. This study investigates the acoustic performance of different types of marine valves under various operational conditions using numerical simulations. By analyzing flow-induced noise (FAN) and its relationship with valve geometry, the research aims to provide theoretical support for optimizing valve design and selection in maritime engineering. The results indicate that ball valves exhibit superior acoustic performance compared to gate and globe valves, offering significant implications for noise reduction in shipboard systems.

Marine valves are indispensable components in the maritime industry, designed to control fluid flow, regulate pressure, and ensure operational safety in the harsh marine environment. These valves are engineered to withstand corrosion, high pressure, and extreme weather conditions, making them vital for ships, offshore platforms, and underwater infrastructure.

Marine valves ;are critical components in the design and operation of maritime systems, ensuring the safe and efficient control of fluid flow in ships, offshore platforms, and subsea infrastructure. These specialized valves are engineered to withstand harsh marine environments, including exposure to saltwater corrosion, high-pressure conditions, and dynamic mechanical stresses. Their reliability and performance are paramount to the functionality of propulsion systems, ballast control, fuel management, and safety-critical operations such as fire suppression and emergency shutdowns.

Marine valves; are critical components in the fluid control systems of ships, offshore platforms, and other marine vessels. They regulate the flow of liquids, gases, and slurries, ensuring the safe and efficient operation of propulsion systems, fuel delivery, ballast management, and HVAC (heating, ventilation, and air conditioning) systems. Given the harsh maritime environment—characterized by high pressure, corrosion, and mechanical stress—marine valves must meet stringent design and performance standards to ensure reliability and longevity.