Research on a Ship Deflection Anti-Collision Method Based on a Water-Jet Interference Flow Field

Abstract: Currently, water jets are mainly used in the fields of mechanical processing and mining collection. This paper creatively introduces them to the field of safety assurance for inland navigation. Compared with the traditional bridge anti-striking methods such as intelligent early warning and passive anti-striking, this method can form an “interference zone” by changing the water flow conditions in the local bridge water areas, causing the yawing moment of the yaw ship to change, thereby causing the ship’s course… Show more

“…However, these intelligent warning systems only have an effect on ship yaw resulting from specific factors. If the intelligent warning system fails to warn a ship effectively, passive collision avoidance devices are still needed to ensure the safety of the bridge [20]. Once a ship bridge collision occurs, it affects the normal navigation of the waterway and can even cause major bridge damage and negative societal impacts.…”

“…This reduced the risk of the ship hitting the collision avoidance devices and causing damage to the ship, enhancing the safety of the navigable sections of the river and the bridge [19] In this study, a bridge in the Jialing River basin was taken as the engineering background, and a typical ship in a navigable river section was taken as the research object. To prove the effectiveness of the device [20], numerical simulations and generalized model tests were carried out using a Fluent overset grid [22,23] technology and RNG k-ε turbulence model [24,25] to explore the reasonable deployment angle of the device and clarify the optimal jet ratio of the device, R. Finally, by comparing the optimal jet ratio and the difference of the ship's motion and response state at the reasonable deployment angle, we area, a hydraulic high-energy beam device in the intervention zone was set on the side of the bow of the vessel to change the shipʹs direction and ensure active collision avoidance. This reduced the risk of the ship hitting the collision avoidance devices and causing damage to the ship, enhancing the safety of the navigable sections of the river and the bridge [19] In this study, a bridge in the Jialing River basin was taken as the engineering background, and a typical ship in a navigable river section was taken as the research object.…”

“…This reduced the risk of the ship hitting the collision avoidance devices and causing damage to the ship, enhancing the safety of the navigable sections of the river and the bridge [19] In this study, a bridge in the Jialing River basin was taken as the engineering background, and a typical ship in a navigable river section was taken as the research object. To prove the effectiveness of the device [20], numerical simulations and generalized model tests were carried out using a Fluent overset grid [22,23] technology and RNG k-ε turbulence model [24,25] to explore the reasonable deployment angle of the device and clarify the optimal jet ratio of the device, R. Finally, by comparing the optimal jet ratio and the difference of the ship's motion and response state at the reasonable deployment angle, we In this study, a bridge in the Jialing River basin was taken as the engineering background, and a typical ship in a navigable river section was taken as the research object. To prove the effectiveness of the device [20], numerical simulations and generalized model tests were carried out using a Fluent overset grid [22,23] technology and RNG k-ε turbulence model [24,25] to explore the reasonable deployment angle of the device and clarify the optimal jet ratio of the device, R. Finally, by comparing the optimal jet ratio and the difference of the ship's motion and response state at the reasonable deployment angle, we provided a basis for the research and development of safe, efficient, and green collision avoidance technology and equipment for ships and bridges.…”

Research on the Hydraulic Characteristics of Active Ship Collision Avoidance Devices for Hydrodynamic High-Energy Beam Bridges under Relatively Optimum Deployment Conditions

“…However, these intelligent warning systems only have an effect on ship yaw resulting from specific factors. If the intelligent warning system fails to warn a ship effectively, passive collision avoidance devices are still needed to ensure the safety of the bridge [20]. Once a ship bridge collision occurs, it affects the normal navigation of the waterway and can even cause major bridge damage and negative societal impacts.…”

“…This reduced the risk of the ship hitting the collision avoidance devices and causing damage to the ship, enhancing the safety of the navigable sections of the river and the bridge [19] In this study, a bridge in the Jialing River basin was taken as the engineering background, and a typical ship in a navigable river section was taken as the research object. To prove the effectiveness of the device [20], numerical simulations and generalized model tests were carried out using a Fluent overset grid [22,23] technology and RNG k-ε turbulence model [24,25] to explore the reasonable deployment angle of the device and clarify the optimal jet ratio of the device, R. Finally, by comparing the optimal jet ratio and the difference of the ship's motion and response state at the reasonable deployment angle, we area, a hydraulic high-energy beam device in the intervention zone was set on the side of the bow of the vessel to change the shipʹs direction and ensure active collision avoidance. This reduced the risk of the ship hitting the collision avoidance devices and causing damage to the ship, enhancing the safety of the navigable sections of the river and the bridge [19] In this study, a bridge in the Jialing River basin was taken as the engineering background, and a typical ship in a navigable river section was taken as the research object.…”

“…This reduced the risk of the ship hitting the collision avoidance devices and causing damage to the ship, enhancing the safety of the navigable sections of the river and the bridge [19] In this study, a bridge in the Jialing River basin was taken as the engineering background, and a typical ship in a navigable river section was taken as the research object. To prove the effectiveness of the device [20], numerical simulations and generalized model tests were carried out using a Fluent overset grid [22,23] technology and RNG k-ε turbulence model [24,25] to explore the reasonable deployment angle of the device and clarify the optimal jet ratio of the device, R. Finally, by comparing the optimal jet ratio and the difference of the ship's motion and response state at the reasonable deployment angle, we In this study, a bridge in the Jialing River basin was taken as the engineering background, and a typical ship in a navigable river section was taken as the research object. To prove the effectiveness of the device [20], numerical simulations and generalized model tests were carried out using a Fluent overset grid [22,23] technology and RNG k-ε turbulence model [24,25] to explore the reasonable deployment angle of the device and clarify the optimal jet ratio of the device, R. Finally, by comparing the optimal jet ratio and the difference of the ship's motion and response state at the reasonable deployment angle, we provided a basis for the research and development of safe, efficient, and green collision avoidance technology and equipment for ships and bridges.…”

Research on the Hydraulic Characteristics of Active Ship Collision Avoidance Devices for Hydrodynamic High-Energy Beam Bridges under Relatively Optimum Deployment Conditions