跨介质航行体高速出水破冰实验及其教学应用OA
High-speed water-breaking icebreaking experiment and its teaching application for cross-medium navigating bodies
跨介质冲击动力学是船舶与海洋工程专业必修课,航行体高速出水破冰是其重点研究方向之一,该过程涉及复杂多相流动与冰-流-固耦合现象.本研究采用水下弹射实验装置,结合高速摄像技术,系统观测航行体高速出水破冰全过程,重点分析速度变化、尾空泡形态演化及冰层破碎断裂规律,并将实验结果用于该课程实验教学.结果表明,模型实验能真实再现航行体水下运动、撞碎冰层及穿越水-空界面的动态过程;可视化手段有助于学生对复杂物理现象的理解.该研究为船舶与海洋工程、航空航天工程等专业实验教学提供了创新案例,有效解决了传统理论教学直观性不足的问题.
[Objective]Cross-medium impact dynamics is a core compulsory course for ship and ocean engineering,aerospace engineering,and related majors.It deals with complex physical phenomena such as underwater ejection of navigating bodies,cavitating multiphase flow,and water-exit impact.Traditional theoretical teaching relies primarily on formula derivation and lacks effective visualization tools,making it difficult for students to understand the intricate ice-flow-solid coupling mechanisms and cavitation evolution laws involved in the process.Although cross-medium experimental teaching has been explored domestically and internationally,research on experimental teaching with a focus on cavitation morphology evolution during the high-speed water-exit icebreaking process of a navigating body is lacking.This study aims to fill this gap by integrating the high-speed water-exit icebreaking experiment of navigating bodies with course teaching:systematically observing the entire experimental process;analyzing key characteristics,including changes in the velocity of the navigating body,wake cavitation morphology evolution,and ice layer fragmentation rules;and developing an intuitive experimental teaching case to overcome the insufficiency of intuitiveness of traditional teaching and improve the experimental operation skills and scientific thinking ability of students.[Methods]An integrated experimental and teaching system was constructed.The experimental system comprised a high-speed water-exit icebreaking system,a data acquisition system,and an ice-making device.A transparent acrylic water tank(80×80×120 cm)was filled with tap water to a depth of 80 cm;prefabricated ice layers(8 layers in all,each 40×40×1.5 cm,prepared 2 days in advance)were placed on the water surface.The navigating body(length:257 mm,diameter:38 mm)was ejected by 150 kPa high-pressure air from a gas tank(controlled by a PLC panel and solenoid valve).Two Phantom VEO 710L high-speed cameras(10,000 frames/s,448×800 resolution,and 50 μs exposure)and two 2000 W thermal headlamps captured images at horizontal and oblique overhead angles;the data were processed by PCC software.The experiment followed 10 standardized steps,and teaching adopted a three-stage model:pre-class preparation(teachers prepared equipment/outlines;students previewed),in-class group experiments(role rotation for camera operation,PLC control,and phenomenon observation),and post-class assignments.Velocity was calculated as displacement divided by the time interval using high-speed camera frame data.[Results]The experiment accurately reproduced the underwater movement,ice collision,penetration,and water-air interface crossing of the navigating body.Velocity increased initially and then decreased,rising from 7.41 m/s(head exit)to 8.15 m/s(tail exit),then dropping to 7.41 m/s(ice collision),5.13 m/s(ice penetration,a 31%decrease),and finally 4.76 m/s(tail water-exit).Cavitation evolved in five stages:stable aggregation(pre-collision),irregular mushroom-shaped disturbance(collision),intense fragmentation with vacuum zones(icebreaking),asymmetric elongation/shedding(penetration),and gradual dissipation(water-exit).Ice cracks developed from intact surfaces(pre-collision)to microcracks(initial collision),reticulated main cracks(icebreaking),expanded networks with shedding(penetration),and complete fragmentation into small pieces(post-water-exit).In the teaching process,visualization substantially improved students'understanding,and group rotation ensured mastery of all key equipment operations.[Conclusions]This study successfully established an innovative experimental teaching method for the free-ejection high-speed water-exit icebreaking movement of navigating bodies.Experimental results revealed complex multiphase flow coupling characteristics,providing important data for polar underwater vehicle design.Integrating experiments with teaching overcomes the poor intuitiveness of traditional theoretical teaching,improves students'grasp of cross-medium dynamics principles(e.g.,cavitation evolution and ice-flow-solid coupling),and cultivates practical skills in equipment operation,data processing,and error analysis.Standardized procedures and interactive design make the teaching method applicable to ship and ocean engineering,aerospace engineering,and other majors.Post-class open questions stimulate students'innovative thinking,enrich cross-medium experimental teaching resources,and lay a solid foundation for talent cultivation in related disciplines.
于志超;李志鹏;张淼;王玉娟;方明
哈尔滨工程大学 船舶工程学院,黑龙江 哈尔滨 150001哈尔滨工程大学 船舶工程学院,黑龙江 哈尔滨 150001哈尔滨工程大学 船舶工程学院,黑龙江 哈尔滨 150001哈尔滨工程大学 船舶工程学院,黑龙江 哈尔滨 150001哈尔滨工程大学 船舶工程学院,黑龙江 哈尔滨 150001
社会科学
跨介质冲击空泡流动出水破冰实验教学高速摄像
cross-medium impactcavity flowwater exit ice breakingexperimental teachinghigh-speed photography
《实验技术与管理》 2026 (3)
222-229,8
黑龙江省教学改革项目一般项目(SJGYB2024123)哈尔滨工程大学本科教育教学改革研究项目(JG2023B0104)
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