钝体倾斜和垂直冲击入水时引起的超空泡流动特性实验研究

施红辉; 胡青青; 陈波; 贾会霞

doi:10.11883/1001-1455(2015)05-0617-08

钝体倾斜和垂直冲击入水时引起的超空泡流动特性实验研究

doi: 10.11883/1001-1455(2015)05-0617-08

浙江理工大学机械与自动控制学院, 浙江杭州 310018

基金项目: 浙江省自然科学基金项目(LQ13A020005, LQ13A020006, Z1110123)

详细信息

作者简介:
施红辉(1962—), 男, 博士, 教授, 博士生导师, hhshi@zstu.edu.cn

中图分类号: O382.1
计量
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- 被引次数: 0
出版历程
- 收稿日期: 2014-03-19
- 修回日期: 2014-06-05
- 刊出日期: 2015-10-10

Experimental study of supercavitating flows induced by oblique and vertical water entry of blunt bodies

School of Mechanical Engineering and Automation, Zhejiang Sci-Tech University, Hangzhou 310018, Zhejiang, China

摘要

摘要: 对4种不同头型的钝体、以不同初始速度在小倾斜角度和垂直状态下入水，所产生的空泡流进行了的实验观察，分析了不同工况下空泡产生和发展的特性。实验结果表明：对于倾斜入水及垂直入水，圆台头和平头(即空化器均为圆盘)实验体均能形成较稳定的入水弹道；初始入水速度较低时，空泡的闭合方式为深闭合；初始入水速度较高时，空泡的闭合方式为表面闭合，且运动速度衰减得更快。测量得知，钝体倾斜入水产生的空泡的前部外形轮廓与Logvinovich的半经验公式给出的结果相吻合。在垂直入水的情况下，调查了物体头部对空泡的起始点位置及其形态的影响。
- 爆炸力学 /
- 空泡形态 /
- 倾斜入水 /
- 钝体 /
- 速度 /
- 自由液面
Abstract: Small-angle oblique and vertical water entry experiments were carried out to observe the supercavitation generated by the blunt bodies with different initial velocities. The development features of the supercavitation in different cases were analyzed. Experimental results show that for small-angle oblique and vertical water entry, the the round-head and flat-head (disc cavitator) blunt bodies can form stable trajectories. When the initial water-entry velocity is lower, the closure mode of the cavity is deep closure. When the initial water-entry velocity is higher, the closure mode of the cavity is surface closure, and its speed decay rate is larger. For the supercavity generated by the small-angle oblique water entry of the blunt bodies, the front part of the supercavity contour is in agreement with the result by G.V. Logvinovich's semi-empirical formula. For the vertical water entry of the blunt bodies, the influences of the head shapes were discussed on the beginning points and morphologies of the supercavities.
- mechanics of explosion /
- supercavity morphology /
- oblique water entry /
- blunt body /
- velocity /
- free surface

HTML全文

图 1 弹体发射系统的结构示意图

Figure 1. Schematic of the experimental setup

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图 2 钝体外形尺寸

Figure 2. Geometry of the blunt body shapes

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图 3 工况1中的钝体倾斜入水

Figure 3. Oblique water entry of the blunt body in case 1

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图 4 工况2中的钝体倾斜入水

Figure 4. Oblique water entry of the blunt body in case 2

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图 5 工况4中的钝体倾斜入水

Figure 5. Oblique water entry of the blunt body in case 4

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图 6 工况7中的钝体倾斜入水

Figure 6. Oblique water entry of the blunt body in case 7

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图 7 工况8中的钝体垂直入水

Figure 7. Vertical water entry of the blunt body in case 8

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图 8 工况9中的钝体垂直入水

Figure 8. Vertical water entry of the blunt body in case 9

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图 9 工况10的钝体垂直入水

Figure 9. Vertical water entry of the blunt body in case 10

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图 10 工况6中的钝体高速入水

Figure 10. High-speed water entry of the blunt body in case 6

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图 11 工况3中的钝体低速入水

Figure 11. Low-speed water entry of the blunt body in case 3

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图 12 典型的空泡深度闭合和表面闭合

Figure 12. Deep closure and surface closure of the cavity

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图 13 不同初速度下钝体入水后的位移和速度对比

Figure 13. Comparison of displacement and velocity after water entry among the blunt bodies with different initial velocities

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图 14 空泡外形轮廓的测量方法

Figure 14. The measuring method of the cavity contour

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图 15 工况3实验和Logvinovich理论确定的超空泡外形轮廓位置

Figure 15. The cavity contours by current experiment in case 3 and Logvinovich's theory

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图 16 垂直冲击入水时钝体头部形状对超空泡发生位置的影响

Figure 16. The dependence of the supercavitation beginning points on the head shapse of blunt bodies in the case of vertical water entry

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表 1 不同工况下的实验参数

Table 1. Experimental parameters in different cases

工况	头型	p₀/MPa	α/(°)	m/g	v₀/(m·s^-1)
1	平头	0.3	18	3.569 9	14.64
2	圆头	0.3	18	3.445 8	9.58
3	圆台头	0.2	18	2.992 8	6.29
4	圆台头	0.3	18	2.992 8	12.24
5	圆台头	0.5	18	2.992 8	35.35
6	圆台头	1.0	18	2.992 8	82.76
7	尖头	0.3	18	3.305 9	14.19
8	平头	重力加速	90	18.131 3	4.425
9	圆头	重力加速	90	17.580 8	4.560
10	尖头	重力加速	90	17.050 3	4.545

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