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Machine learning-based rapid forecasting method for dynamic response of hull grillage structure under underwater explosion load

A technology of underwater explosion and machine learning, which is applied in the field of ship damage under underwater explosion load, can solve the problems of difficult models and high test costs, and achieve the effects of improved accuracy, rapid prediction, and saving calculation time

Active Publication Date: 2021-08-27
HARBIN ENG UNIV
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

There are scale effects in the small-scale scale model experiment, and the boundary conditions are difficult to keep consistent with the actual working conditions. It is difficult to reverse the original model, and it can only be used as a preliminary mechanism study.
Large-scale experiments and actual ship tests are costly, and are limited by conditions such as feasibility and safety

Method used

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  • Machine learning-based rapid forecasting method for dynamic response of hull grillage structure under underwater explosion load
  • Machine learning-based rapid forecasting method for dynamic response of hull grillage structure under underwater explosion load
  • Machine learning-based rapid forecasting method for dynamic response of hull grillage structure under underwater explosion load

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specific Embodiment 1

[0050] according to Figure 1 to Figure 5 As shown, the present invention provides a method for fast prediction of the dynamic response of the hull grillage structure under the underwater explosion load based on machine learning, comprising the following steps:

[0051] A machine learning-based rapid prediction method for the dynamic response of hull grille structures under underwater explosion loads, comprising the following steps:

[0052] Step 1: Use any Euler-Lagrangian method to numerically calculate the response of the hull grille structure under underwater explosion loads to obtain data samples;

[0053] The step 1 is specifically:

[0054] Step 1.1: Determine the size of the water area according to the radius of the largest bubble produced by the underwater explosion of a certain equivalent explosive. The size of the water area should be 2 to 4 times the maximum diameter of the bubble produced by a certain equivalent explosive at the corresponding water depth;

[005...

specific Embodiment 2

[0087] The size of the water area in step 1 should be 2 to 4 times the maximum diameter of the air bubbles produced by the cartridge at the corresponding water depth, and the maximum diameter of the air bubbles is calculated using the Geers-Hunter model:

[0088]

[0089] In the formula: m c is the quality of the drug pack, a c is the radius of drug inclusion, ρ f is fluid density, K, k, A, B are explosive material parameters.

[0090] By time-integrating equation (1), the volume change rate and the volume change law with time can be obtained respectively:

[0091]

[0092]

[0093] Then solve the bubble radius a and the vertical migration u of the bubble produced by the underwater explosion:

[0094]

[0095]

[0096]

[0097]

[0098]

[0099] In the formula: g is the acceleration due to gravity, K c and r are explosive material parameters, C D is the fluid resistance coefficient, ρ c is the explosive density, p I is the hydrostatic press...

specific Embodiment 3

[0133] Determine the size of the water area according to the radius of the largest bubble produced by the underwater explosion of a certain equivalent explosive. The size of the water area should be 2 to 4 times the maximum diameter of the bubble produced by a certain equivalent explosive at the corresponding water depth; grid size, and the S-ALE method is used to discretize the water area and air, so that the grid size within the maximum diameter range of the bubble is smaller, and the grid size in other areas is twice the grid size within the maximum diameter range; then, the hull plate The frame structure is modeled and the structure is consistent with the minimum grid size of the water area to complete the model establishment. Such as figure 2 with image 3 As shown, the arbitrary Euler-Lagrangian method (ALE) is used to calculate the dynamic response of the hull grille structure under the underwater explosion load, and the coordinates of each node of the structure and t...

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Abstract

The invention relates to a machine learning-based rapid forecasting method for dynamic response of a hull grillage structure under an underwater explosion load. According to the method, any Euler-Lagrange method is adopted to carry out numerical calculation on ship body grillage structure response under the underwater explosion load to obtain a data sample; according to a hull grillage structure, dimension reduction is performed on the sample database so as to shorten the deep neural network training time; a deep neural network is adopted to learn the sample database after dimension reduction, and the learning effect is verified; the ant colony algorithm is adopted to optimize the structure and hyper-parameters of the deep neural network, the training efficiency and forecasting precision of the deep neural network are improved, and the deep neural network with the optimal generalization effect is output; and post-processing the dynamic response forecast result of the hull grillage structure under the underwater explosion load by using the deep neural network.

Description

technical field [0001] The invention relates to the technical field of ship damage under underwater explosive loads, and relates to a machine learning-based rapid prediction method for the dynamic response of hull plate structures under underwater explosive loads. Background technique [0002] Surface ships are the main force of naval equipment, and the damage caused by underwater explosions will pose a serious threat to the combat effectiveness and vitality of ships. Rapidly and accurately evaluating the damage characteristics of ships under underwater explosive loads in the battlefield environment has extremely important military value. For the research of underwater explosion, at present, it is mainly based on numerical simulation and model test. The published experimental data are basically limited to simple frame structures and experiments with small scale ratios. Small-scale scale model experiments have scale effects, and the boundary conditions are difficult to keep...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G06F30/27G06N3/00G06N3/08G06F111/06G06F111/10G06F113/08
CPCG06F30/27G06N3/006G06N3/08G06F2111/10G06F2113/08G06F2111/06
Inventor 任少飞刘永泽张阿漫王诗平刘云龙明付仁李帅崔璞
Owner HARBIN ENG UNIV
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