Robotic Nondestructive Testing Technology

Cover
Half Title
Title Page
Copyright Page
Table of Contents
Preface,
Author,
Chapter 1 Introduction
1.1 BACKGROUND
1.1.1 Automatic NDT Methods of Complex Components
1.1.2 Development Trend of Robotic NDT Technique
1.2 BASIS OF MANIPULATOR
1.2.1 Type and Structure of Manipulators
1.2.2 Working Mode of Manipulators
1.3 MATHEMATICAL RELATIONSHIP BETWEEN THE COORDINATE SYSTEM AND EULER ANGLE
1.3.1 Definition of a Manipulator Coordinate System
1.3.2 Relationship between Position & Attitude and Coordinate System
1.3.2.1 Position Description
1.3.2.2 Attitude Description
1.3.2.3 Spatial Homogeneous Coordinate Transformation
1.3.3 Quaternion and Coordinate Transformation
REFERENCES
Chapter 2 Method of Acoustic Waveguide UT
2.1 WAVE EQUATION AND PLANE WAVE SOLUTION
2.1.1 Acoustic Wave Equation for an Ideal Fluid Medium
2.1.2 Plane Wave and Solutions of Wave Equations
2.2 ULTRASONIC REFLECTION AND TRANSMISSION AT THE INTERFACE
2.3 ANALYSIS OF SOUND FIELD IN AN ACOUSTIC WAVEGUIDE TUBE
2.4 MEASUREMENT OF SOUND FIELD IN AN ACOUSTIC WAVEGUIDE TUBE
REFERENCES
Chapter 3 Planning Method of Scanning Trajectory on Free-Form Surface
3.1 MAPPING RELATIONS BETWEEN MULTIPLE COORDINATE SYSTEMS
3.1.1 Translation, Rotation and Transformation Operators
3.1.1.1 Translation Operator
3.1.1.2 Rotation Operator
3.1.1.3 Transformation Operator
3.1.2 Equivalent Rotation and Quaternion Equation
3.1.2.1 Representation in an Angular Coordinate System
3.1.2.2 Representation in an Equivalent Axial Angular Coordinate System
3.2 SURFACE SPLIT AND RECONSTRUCTION BASED ON NUBRS
3.2.1 Parametric Spline Curve and Surface Split Method
3.2.2 Scanning of Non-uniform Rational B-Splines (NURBS)
3.2.3 Surface Construction Based on Differential Equation and Interpolation Algorithm
3.3 SURFACE SCANNING TRAJECTORY ALGORITHM BASED ON CAD/CAM
3.3.1 Generation of Discrete Point Data of Free-Form Surface
3.3.2 Coordinate Transformation under the Constraint of Ultrasonic Testing (UT) Principle
3.4 SCANNING TRAJECTORY SMOOTHNESS JUDGMENT AND DATA DISCRETIZATION PROCESSING
3.4.1 Wavelet Processing Method of Surface Data
3.4.2 Handling and Judgment of Surface Smoothness
REFERENCES
Chapter 4 Single-Manipulator Testing Technique
4.1 COMPOSITION OF A SINGLE-MANIPULATOR TESTING SYSTEM
4.1.1 Workflow of a Testing System
4.1.2 Principle of Equipment Composition
4.2 PLANNING OF SCANNING TRAJECTORY
4.2.1 Ultrasonic/Electromagnetic Testing Parameters
4.2.2 Trajectory Planning Parameters
4.3 CALIBRATION AND ALIGNMENT OF ASSEMBLY ERROR
4.3.1 Method of Coordinate System Alignment
4.3.2 Alignment Method Based on Ultrasonic A-Scan Signal
4.3.3 Error Compensation Strategy and Gauss-Seidel Iteration
4.3.4 Positioning Error Compensation
4.4 MANIPULATOR POSITION/ATTITUDE CONTROL AND COMPENSATION
4.4.1 Kinematics Analysis
4.4.2 End-Effector Position Error and Compensation Strategy
4.4.3 Method of Joint Position/Attitude Feedback
4.5 METHOD OF SYNCHRONIZATION BETWEEN POSITION AND ULTRASONIC SIGNAL
REFERENCES
Chapter 5 Dual-Manipulator Testing Technique
5.1 BASIC PRINCIPLE OF ULTRASONIC TRANSMISSION DETECTION
5.1.1 Basic Principles of Ultrasonic Reflection and Ultrasonic Transmission
5.1.1.1 Basic Principle of Ultrasonic Reflection Detection
5.1.1.2 Basic Principle of Ultrasonic Transmission Detection
5.1.1.3 Comparison between the Elements of an Ultrasonic Reflection Method and Those of an Ultrasonic Transmission Method
5.1.2 Ultrasonic Transmission Testing of Curved Workpieces
5.1.2.1 Principle of Reflection and Transmission of Ultrasonic Wave Incident on Curved Workpieces
5.1.2.2 Principle of Refraction of Ultrasonic Wave Incident on a Curved Surface
5.2 COMPOSITION OF A DUAL-MANIPULATOR TESTING SYSTEM
5.2.1 Hardware Structures in a Dual-Manipulator Testing System
5.2.1.1 Six-DOF Articulated Manipulator
5.2.1.2 Manipulator Controller
5.2.1.3 Data Acquisition Card
5.2.1.4 Ultrasonic Signal Transceiver System
5.2.1.5 Water-Coupled Circulation System
5.2.2 Upper Computer Software of a Dual-Manipulator Testing System
5.2.2.1 Overall Design of Upper Computer Software
5.2.2.2 Data Acquisition
5.2.2.3 Synchronous Control of Dual Manipulator
5.2.2.4 Automatic Scanning Imaging Module
5.2.3 Lower Computer Software of a Dual-Manipulator Testing System
5.3 MAPPING RELATION BETWEEN DUAL-MANIPULATOR BASE COORDINATE SYSTEMS
5.3.1 Transformation Relationship between Base Coordinate Systems
5.3.1.1 Definition of Parameters of a Manipulator Coordinate System
5.3.1.2 Solution of an Unified Variable Method
5.3.1.3 Solving with a Homogeneous Matrix Method
5.3.2 Orthogonal Normalization of Rotation Matrix
5.3.2.1 Basis of Lie Group and Lie Algebra
5.3.2.2 Orthogonalization of Rotation Matrix Identity
5.3.3 Experiment of Dual-Manipulator Base Coordinate Transformation Relationship
5.3.4 Analysis of Transformation Relation Error
5.4 DUAL-MANIPULATOR MOTION CONSTRAINTS DURING TESTING
5.4.1 Constraints on the Position and Attitude of Dual-Manipulator End-Effectors in the Testing of Equi-Thickness Workpiece
5.4.2 Constraints on the Position and Attitude of Dual-Manipulator End-Effectors in the Testing of Variable-Thickness Workpiece
REFERENCES
Chapter 6 Error Analysis in Robotic NDT
6.1 KINEMATICS ANALYSIS FOR ROBOTIC TESTING PROCESS
6.1.1 Establishment of the Coordinate System in a Moving Device
6.1.2 Matrix Representation of the Position/Attitude Relationship between Coordinate Systems
6.1.3 Coordinated Motion Relation between Manipulator and Turntable
6.1.4 Matrix Representation of Coordinated Motion Relation
6.2 PLANNING OF MOTION PATH IN THE TESTING PROCESS
6.2.1 Algorithm of Detection Path Generation
6.2.2 Resolving of Manipulator Motion Path
6.3 ERROR SOURCES IN ROBOTIC UT PROCESS
6.3.1 Geometric Error in Path Copying
6.3.2 Localization Error in Manipulator Motion
6.3.3 Clamping Error of Tested Component
REFERENCES
Chapter 7 Error and Correction in Robotic Ultrasonic Testing
7.1 ULTRASONIC PROPAGATION MODEL
7.1.1 Fluctuation of Sound Pressure in an Ideal Fluid Medium
7.1.2 Expression of Sound Pressure Amplitude
7.1.3 Superposition of Multiple Gaussian Beams
7.1.4 Influence of the Curved Surface on Ultrasonic Propagation
7.2 3D POINT CLOUD MATCHING ALGORITHM BASED ON NORMAL VECTOR ANGLE
7.2.1 Matching Features of 3D Point Clouds
7.2.2 Calculation of the Normal Vector on a Curved Surface
7.2.3 Identification and Elimination of Surface Boundary Points
7.2.4 Calculation of Spatial Position/Attitude Deviation of 3D Point Cloud
7.3 CORRECTION EXPERIMENT FOR 3D POINT CLOUD COLLECTION AND INSTALLATION DEVIATION
7.3.1 Steps of 3D Point Cloud Matching
7.3.2 Simulation Verification of Position/Attitude Deviation Correction Algorithm
7.3.3 Experiment and Detection Verification of Curved-Component Deviation Correction
REFERENCES
Chapter 8 Kinematic Error and Compensation in Robotic Ultrasonic Testing
8.1 THREE-DIMENSIONAL SPATIAL DISTRIBUTION MODEL OF ROBOTIC UT ERROR
8.1.1 Model of Manipulator Localization Error
8.1.2 Relationship between Distance Error and Kinematic Parameter Error
8.1.3 Three-Dimensional Spatial Distribution of Errors
8.2 FEEDBACK COMPENSATION MODEL OF ROBOTIC UT ERROR
8.2.1 Principle of Error Feedback Compensation
8.2.2 Calculation of Kinematic Parameter Errors
8.2.3 Step of Feedback Compensation of Kinematic Parameter Error
8.3 DESIGN AND APPLICATION OF BI-HEMISPHERIC CALIBRATION BLOCK
8.3.1 Design of Bi-hemispheric Calibration Block
8.3.2 Method of UT System Compensation with Bi-hemispheric Calibration Error
8.3.3 Application of Calibration Block in Kinematic Parameter Error Compensation
REFERENCES
Chapter 9 Dual-Manipulator Ultrasonic Testing Method for Semi-Closed Components
9.1 PROBLEMS FACED BY THE ULTRASONIC AUTOMATIC TESTING OF SEMI-CLOSED CURVED COMPOSITE COMPONENTS
9.2 METHOD OF PLANNING THE DUAL-MANIPULATOR TRAJECTORY IN THE ULTRASONIC TESTING OF SEMI-CLOSED COMPONENTS
9.2.1 Coordinate Systems in Dual-Manipulator and Their Relations
9.2.2 Method of Planning the X-Axis Constrained Trajectory in the Ultrasonic Testing of Semi-Closed Component
9.2.3 Experimental Verification of the Trajectory Planning Method with X-Axis Constraint
9.3 ANALYSIS AND OPTIMIZATION OF VIBRATION CHARACTERISTICS OF SPECIAL-SHAPED EXTENSION ARM TOOL
9.3.1 Calibration of Static Characteristics of Special-Shaped Extension Arm Tool
9.3.2 Improved S-Curve Acceleration Control Algorithm
9.3.3 Trajectory Interpolation Based on Improved S-Curve Acceleration Control
REFERENCES
Chapter 10 Calibration Method of Tool Center Frame on Manipulator
10.1 REPRESENTATION METHOD OF TOOL PARAMETERS
10.2 FOUR-ATTITUDE CALIBRATION METHOD IN TCF
10.2.1 Calibration of the Position of Tool-End Center Point
10.2.2 Calibration of the Attitude of End Center Point of Special-Shaped Tool
10.3 CORRECTION OF FOUR-ATTITUDE CALIBRATION ERROR OF TOOL CENTER FRAME
10.4 FOUR-ATTITUDE TCF CALIBRATION EXPERIMENT
10.4.1 TCF Calibration Experiment of Special-Shaped Tip Tool
10.4.2 Verivcation Experiment of TCF Calibration Result of Special-Shaped Tip Tool
10.5 FOUR-ATTITUDE TCF CALIBRATION EXPERIMENT OF SPECIAL-SHAPED EXTENSION ARM
REFERENCES
Chapter 11 Robotic Radiographic Testing Technique
11.1 BASIC PRINCIPLE OF X-RAY CT TESTING
11.1.1 Theory of X-ray Attenuation
11.1.2 Mathematical Basis of Industrial CT Imaging
11.2 COMPOSITION OF A ROBOTIC X-RAY CT TESTING SYSTEM
11.3 ACQUISITION, DISPLAY AND CORRECTION OF X-RAY PROJECTION DATA
11.3.1 Principle and Working Mode of a Flat Panel Detector
11.3.2 Implementation of X-ray Image Acquisition and Real-Time Display Software
11.3.3 Analysis of the Factors Affecting the Quality of X-ray Projection Images
11.4 COOPERATIVE CONTROL OF X-RAY DETECTION DATA AND MANIPULATOR POSITION AND ATTITUDE
11.4.1 Design of Collaborative Control Concept
11.4.2 Method of Manipulator Motion Control Programming in Lower Computer
11.4.3 Modes of Communication and Control of Upper and Lower Computers
11.4.4 Implementation Method of Cooperative Control Software
11.5 AN EXAMPLE OF HOLLOW COMPLEX COMPONENT UNDER TEST
REFERENCES
Chapter 12 Robotic Electromagnetic Eddy Current Testing Technique
12.1 BASIC PRINCIPLE OF ELECTROMAGNETIC EDDY CURRENT TESTING
12.1.1 Characteristics of Electromagnetic Eddy Current Testing
12.1.2 Principle of Electromagnetic Eddy Current Testing
12.1.2.1 Electromagnetism Induction Phenomenon
12.1.2.2 Faraday’s Law of Electromagnetic Induction
12.1.2.3 Self-Inductance
12.1.2.4 Mutual Inductance
12.1.3 Eddy Current and Its Skin Effect
12.1.4 Impedance Analysis Method
12.1.4.1 Impedance Normalization
12.1.4.2 Effective Magnetic Conductivity and Characteristic Frequency
12.1.5 Electromagnetic Eddy Current Testing Setup
12.2 COMPOSITION OF A ROBOTIC ELECTROMAGNETIC EDDY CURRENT TESTING SYSTEM
12.2.1 Hardware Composition
12.2.2 Software Composition
12.3 METHOD OF ELECTROMAGNETIC EDDY CURRENT DETECTION IMAGING
12.3.1 Display Method of Eddy Current Signals
12.3.2 Method of Eddy Current C-Scan Imaging
REFERENCES
Chapter 13 Manipulator Measurement Method for the Liquid Sound Field of an Ultrasonic Transducer
13.1 MODEL OF AN ULTRASONIC TRANSDUCTION SYSTEM
13.1.1 Equivalent Circuit Model of an Ultrasonic Transducer
13.1.2 Ultrasonic Excitation and Propagation Medium
13.2 SOUND FIELD MODEL OF AN ULTRASONIC TRANSDUCER BASED ON SPATIAL PULSE RESPONSE
13.2.1 Theory of Sound Field in an Ultrasonic Transducer
13.2.2 Sound Field of a Planar Transducer
13.2.3 Sound Field of a Focusing Transducer
13.3 MEASUREMENT MODEL AND METHOD OF SOUND FIELD OF AN ULTRASONIC TRANSDUCER
13.3.1 Ball Measurement Method of Sound Field of an Ultrasonic Transducer
13.3.2 Hydrophone Measurement Method of Sound Field of an Ultrasonic Transducer
13.4 SOUND-FIELD MEASUREMENT SYSTEM OF ROBOTIC ULTRASONIC TRANSDUCER
13.4.1 Composition of a Hardware System
13.4.2 Composition of a Software System
13.5 MEASUREMENT VERIFICATION OF SOUND FIELD OF MANIPULATOR TRANSDUCER
13.5.1 Measurement of Sound Field of a Planar Transducer
13.5.2 Measurement of Sound Field of Focusing Transducer
REFERENCES
Chapter 14 Robotic Laser Measurement Technique for Solid Sound Field Intensity
14.1 SOLID SOUND FIELD AND ITS MEASUREMENT METHOD
14.1.1 Definition, Role and Measurement Significance of Solid Sound Field
14.1.2 Current Domestic and Overseas Measurement Methods and Their Problems
14.2 SOUND SOURCE CHARACTERISTICS OF SOLID SOUND FIELD AND ITS CHARACTERIZATION PARAMETERS
14.2.1 Structure and Characteristics of Exciter Sound Source
14.2.2 Characterization Method of Solid Sound Field
14.2.2.1 Analytical Method
14.2.2.2 Semi-Analytical Method
14.2.2.3 Numerical Method
14.2.2.4 Measurement Method of Ultrasonic Intensity in Solids
14.3 COMPOSITION OF A ROBOTIC MEASUREMENT SYSTEM FOR SOUND FIELD INTENSITY
14.3.1 Hardware Composition
14.3.2 Software Function
14.4 PRINCIPLE OF LASER MEASUREMENT FOR SOUND FIELD INTENSITY DISTRIBUTION
14.4.1 Measurement Principle of Laser Displacement Interferometer
14.4.2 Measurement Principle of Normal Displacement of Sound Wave
14.5 MEASUREMENT METHOD FOR TRANSVERSE WAVE AND LONGITUDINAL WAVE BY A DUAL-LASER VIBROMETER
14.6 APPLICATION OF A SOUND FIELD INTENSITY MEASUREMENT METHOD
REFERENCES
Chapter 15 Typical Applications of Single-Manipulator NDT Technique
15.1 CONFIGURATION OF A SINGLE-MANIPULATOR NDT SYSTEM
15.2 AN APPLICATION EXAMPLE OF ROBOTIC NDT TO ROTARY COMPONENTS
15.2.1 Structure of Clamping Device
15.2.2 Correction of Perpendicularity and Eccentricity of Principal Axis
15.2.3 Generation and Morphological Analysis of Defects in Rotary Components
15.2.4 Analysis of Error and Uncertainty in the Ultrasonic Detection of Defects inside Rotary Components
15.2.5 Application Examples of Robotic NDT of Rotary Components
15.3 ROBOTIC NDT METHOD FOR BLADE DEFECTS
15.3.1 Robotic Ultrasonic NDT of Blades
15.3.2 Detection by Ultrasonic Vertical Incidence
15.3.3 Ultrasonic Surface-Wave Detection Method
15.4 ROBOTIC NDT METHOD FOR BLADE DEFECTS
15.4.1 Principle of Ultrasonic Thickness Measurement
15.4.2 Calculation Method of Echo Sound Interval Difference
15.4.3 Thickness Measurement Method with Autocorrelation Analysis
REFERENCES
Chapter 16 Typical Applications of Dual-Manipulator NDT Technique
16.1 CONFIGURATION OF A DUAL-MANIPULATOR NDT SYSTEM
16.1.1 NDT Method for Large Components: Dual-Manipulator Synchronous-Motion Ultrasonic Testing
16.1.2 NDT Method for Small Complex Components: Dual-Manipulator Synergic-Motion Ultrasonic Testing
16.2 AN APPLICATION EXAMPLE OF DUAL-MANIPULATOR ULTRASONIC TRANSMISSION DETECTION
16.2.1 Ultrasonic C-Scan Detection of a Large-Diameter Semi-closed Rotary Component
16.2.2 Ultrasonic C-Scan Detection of a Small-Diameter Semi-closed Rotary Component
16.2.3 Ultrasonic C-Scan Detection of a Rectangular Semi-closed Box Component
16.2.4 Ultrasonic Testing of an Acoustic Waveguide Tube
REFERENCES