振声学

PREFACE

Chapter 9 HAMILTON—S PRINCIPLE AND SOME OTHER VARIATIONAL METHODS

9.1 Hamilton's principle

9.2 Flexural vibrations of slender beams

9.3 Equation of motion for honeycomb beams in flexure

9.4 Plates with constrained viscoelastic layer

9.5 Timoshenko beams

9.6 Mindlin plates

9.7 Cylindrical shells

9.8 Lagrange's equation

9.9 Garlekin's method

9.10 An example using Garlekin's method

Chapter 10 STRUCTURAL COUPLING BETWEEN SIMPLE SYSTEMS

10.1 Introduction

10.2 Coupled mass—spring systems

10.3 Coupled systems with losses

10.4 Example

10.5 Rubber mounts， some material parameters

10.6 Wave propagation in rubber mountsj approximate solutions

10.7 Equivalent stiffness of simple mounts—approximate methods

10.8 Static deflection of cylindrical rubber mounts

10.9 Wave propagation in circular rods， exact solutions

10.10 Measurements of effective stiffness of mounts

10.11 Structural coupling via resilient mounts

10.12 Simple transmission model

10.13 Multi—point coupling

10.14 Multi—point coupling， low and high frequency limits

10.15 Source strength

Chapter 11 WAVES IN FLUIDS

11.1 Wave equation

11.2 Energy and intensity

11.3 Losses

11.4 Basic solutions to wave equation

11.5 Green's function

11.6 Dipole and other multipole sources

11.7 Additional sources and solutions

11.8 Moving monopole sources

11.9 Reflection from a plane surface

11.10 Reflection from a water surface

11.11 Influence of temperature and velocity gradients

11.12 Acoustic fields in closed rooms

11.13 Geometrical acoustics

11.14 Near and reverberant acoustic fields in a room

11.15 Measurement of the sound transmission loss of a wall

Problems

Chapter 12 FLUID STRUCTURE INTERACTION AND RADIATION OF SOUND

12.1 Radiation and fluid loading of infinite plates

12.2 Radiation—general formulation

12.3 Green's function—rigid plane boundary

12.4 Spatial Fourier transforms—several variables

12.5 Radiation from infinite point excited plates

12.6 Mobilities of fluid loaded infinite plates

12.7 Discussion of results—infinite fluid loaded plates

12.8 Radiation from finite baffled plates

12.9 Radiation ratios—finite baffled plates

12.10 Radiation from point excited plates

12.11 Sound radiation ratios—cylinders

12.12 Losses due to radiation

12.13 Radiation from fiuid loaded finite plates

Problems

Chapter 13 SOUND TRANSMISSION LOSS OF PANELS

13.1 Sound transmission through infinite fiat panels

13.2 Plate velocity induced by an acoustic field

13.3 Sound transmission between rooms separated by a smgle

13.4 Sound transmission between equal rooms

13.5 Sound transmission between irregular rooms

13.6 Effect of boundary conditions of plate on sound transmission

13.7 Effect of a baffle on sound transmission loss

13.10 Sound transmission through complex structures

13.12 Sound transmission through fluid loaded plates

Problems

Chapter 14 WAVEGUIDES

14.2 Structural waveguides

14.3 Coupled structural waveguides

14.4 Measurements and predictions

14.5 Composite， sandwich and honeycomb plates

14.6 Flexural vibrations of honeycomb／sandwich beams

14.7 Wavenumbers， sandwich／honeycomb beams

14.9 Dynamic properties of sandwich beams

14.10 Bending stiffness of sandwich plates

14.11 Response of sandwich beams

14.12 Energy flow in sandwich beams

14.13 Energy fiow across pinned junctions

14.14 Wave propagation on infinite cylinders

14.15 Vibratiop of open circular cylindrical shells

14.16 Sound transmission loss of shallow shell segments

14.17 Comparison between measured and predicted TL

Problems

Chapter 15 RANDOM EXCITATION OF STRUCTURES

15.1 Introduction

15.2 Excitation of plates

15.3 Rain on the roof excitation of plates

15.4 urbulent boundary layers

15.5 TBL models

15.6 Plate response due to TBL excitation

15.7 Measurements of TBL induced vibrations

15.8 Comparison between measured and predicted velocity levels

15.9 Parameter study

15.10 Flow noise induced in ships

Problems

Chapter 16 TRANSMISSION OF SOUND IN BUILT—UP STRUCTURES

16.1 Introduction

16.2 Statistical energy analysis， SEA

16.3 Energy flow between continuous systems

16.4 Coupling between acoustic fields and vibrating structures

16.5 Prediction of sound transmission through a panel using SEA

16.6 Sound transmission through double walls

16.7 Limitation of SEA derived sound transmission loss

16.8 Coupling between vibrating structures

16.9 Energy flow in large structures， SEA

16.10 SEA parameters

16.11 Ship noise

16.12 Waveguide model

16.13 Noise levels in accommodation spaces

16.15 Measured and predicted results

16.16 Conclusions—noise prediction on ships

REFERENCES

Appendix A SOUND TRANSMISSION LOSS OF SINGLE LEAF PANELS

Appendix B VELOCITY LEVEL OF SINGLE LEAF PANELS EXCITED BY AN ACOUSTIC FIELD

Appendix C INPUT DATA FOR NOISE PREDICTION ON SHIPS

INDEX

《振声学(第2卷)(英文版)》由科学出版社出版。振声学主要研究典型结构在各种激励下的振动响应、振动能量传递和声辐射的一般性规律。分两卷，本书是第一卷。第一卷的内容简介是：首先回顾了单自由度系统和频域分析，接着重点讨论了固体中的波传播、纵波和横波的耦合关系、结构阻尼和连接方式引起的波衰减、以及梁和板的弯曲振动等。【作者简介】作者：（瑞典）尼尔森A.C. 刘碧龙