https://vikis.lt/pamokos/api.php?action=feedcontributions&feedformat=atom&user=VvolkovasAktyvios pamokos - Naudotojo indėlis [lt]2026-04-23T22:03:14ZNaudotojo indėlisMediaWiki 1.38.6https://vikis.lt/pamokos/index.php?title=Diagnostika&diff=44Diagnostika2023-03-21T10:05:31Z<p>Vvolkovas: </p>
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<div>Čia pateikiama KTU profesoriaus Vitalijaus Volkovo paruošta monografija<br />
'''Diagnostics and Monitoring of Technical Systems:'''<br />
''Methods and Application''<br />
Kaunas, 2021<br />
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Visą knygą atskirais skyriais pagal toliau pateiktą turinį galima atsisiųsti '''[https://ktuedu-my.sharepoint.com/:f:/g/personal/eimkarc_ktu_lt/Ev6sqUjOn5pKvByuf-ZPWssBsEGK8smv98nJADqAzs5qLg?e=owKeju čia]'''<br />
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Autorius dirbo KTU Mechanikos fakulteto Mechanikos inžinerijos [https://midf.ktu.edu/mechanikos-inzinerijos-katedra/ katedroje]<br />
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Visuotinė lietuvių enciklopedija apie [https://www.vle.lt/straipsnis/vitalijus-volkovas/ autorių]<br />
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KTU bibliotekoje yra šios Vitalijaus Volkovo paruoštos [https://biblioteka.ktu.edu/galleries/volkovas/ knygos]<br />
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Informacija anglų kalba yra čia [[Diagnostics]]<br />
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TABLE OF CONTENTS.<br><br />
FOREWORD.<br><br />
INTRODUCTION.<br><br />
'''1. PROBLEMS OF RELEVANCE.<br>'''<br />
1.1. Energy and concentration of power, failures and mistakes – reasons of the potential accidents.<br><br />
1.2. Industrial facilities and product safety, quality requirements.<br><br />
1.3. The methodology of evaluation of system’s technical state.<br><br />
1.4. System monitoring and diagnostics symbiosis.<br><br />
REFERENCES 1.<br><br />
'''2. MODELS OF DAMAGED MECHANICAL SYSTEMS.<br>'''<br />
2.1. Technological system decomposition into elements and analysis of defective states.<br><br />
2.2. Models of technical system structural elements.<br><br />
2.2.1. Linear dynamics challenges.<br><br />
2.2.2. Nonlinear dynamics challenges.<br><br />
2.3. Model of damaged structure’s parameters changing.<br><br />
REFERENCES 2.<br><br />
'''3. DYNAMICS AND STATE IDENTIFICATION OF HETEROGENEOUS SYSTEMS.<br>'''<br />
3.1. Systems with lumped parameters.<br><br />
3.2 Systems with distributed parameters.<br><br />
3.2.1. The transfer function identification.<br><br />
3.2.2. Dynamics of oblong constructive element and defect identification.<br><br />
3.2.3. Defect identification in the axis - symmetrical constructive elements.<br><br />
3.2.3.1. FEM analysis and state parameters identification.<br><br />
3.2.3.2. Reaction of the mechanical system to impact load and state determination.<br><br />
3.2.4. Dynamics and identification of flexible constructive elements.<br><br />
3.2.4.1. Model of transverse oscillations of a defective belt free span between pulleys.<br><br />
3.2.4.2. FEM analysis of the defective belt interaction with the pulley.<br><br />
3.2.4.3. A method of belt drives malfunction diagnosis.<br><br />
3.2.4.4. Procedure of measuring.<br><br />
3.3. Damaged system’s quazi-harmonic process model.<br><br />
REFERENCES 3.<br><br />
'''4. THEORY OF MODERN DIAGNOSTIC METHODS AND MEANS.<br>'''<br />
4.1. Controlled dynamic elements in structure’s diagnostics.<br><br />
4.1.1. The qualitative estimation of defectness of the beam type structures.<br><br />
4.1.2. Experimental investigation of the technical state change and defect localization in beam type structures.<br><br />
4.1.3. The diagnostic methods, based on the dynamics of structure with additional mass.<br><br />
4.2. Inspection using mechanical energy converting elements.<br><br />
4.2.1. The mechanical energy conversion into electricity model.<br><br />
4.2.2. Practical aspect of application and new devices.<br><br />
4.3. Some aspects of vibration and impact analysis in systems diagnostics.<br><br />
4.3.1. Evaluation of quality of heterogeneous mechanical systems using impedance method.<br><br />
4.3.2. Vibro shock signals in rotating system<br><br />
4.3.3. Simulation of vibro shock signals in rotating system.<br><br />
4.4. Multi-layer cylindrical structures diagnostics based on Lamb’s wave’s interference.<br><br />
4.4.1. Waves propagating within the cylindrical structure and interference phenomenon.<br><br />
4.4.2. A technique of signal processing for interferometric estimation of the amount of deposit in pipes<br><br />
4.5. Acoustic emission (AE): research and new aspects.<br><br />
4.5.1. AE method in the rotating machine elements.<br><br />
4.5.2. AE testing of pressurized vessels and cylinders.<br><br />
REFERENCES 4.<br><br />
'''5. DEVELOPMENT AND APPLICATION OF MONITORING AND DIAGNOSTICS.<br>'''<br />
5.1. Permanent vibration monitoring and diagnostics of unique machines (UM).<br><br />
5.1.1. Vibration monitoring and diagnostic systems of turboagregate.<br><br />
5.1.2. Monitoring the technical condition of hydroelectric power plants.<br><br />
5.1.3. Vibroacoustic diagnostics of rolling bearings using stationary system.<br><br />
5.2. Periodic vibration diagnostics of rotor systems with portable devices.<br><br />
5.3. Adaptable vibration monitoring in rotor systems.<br><br />
5.3.1. Concept and principles of adaptive monitoring.<br><br />
5.3.2. Realization of adaptive bearing defect detection.<br><br />
5.3.3. Adaptive monitoring algorithm.<br><br />
5.4. Vibrodiagnostics problem in small hydroelectric power plants (SHPP).<br><br />
5.5. The concept of buildings stability monitoring and damage diagnostics.<br><br />
5.5.1. Concept of building’s stability.<br><br />
5.5.2. Models of building and defects.<br><br />
5.5.3. Building’s stability monitoring system (BSMS).<br><br />
5.5.4. Results of laboratory experiment and practices.<br><br />
5.5.4.1. Analysis of frequencies of FE models and MA experiments.<br><br />
5.5.4.2. STFT method for floor damage diagnostics.<br><br />
5.5.4.3. Application of CWT to defect detection.<br><br />
5.5.4.4. ANN application to defect detection.<br><br />
5.5.4.5. Practical use of building monitoring concept.<br> <br />
5.6. Development of new measurement elements for vibration monitoring systems.<br><br />
5.6.1. Low frequency vibration measurement device: creation and investigation.<br><br />
5.6.2. Air gap measuring system for purpose of diagnostics and condition monitoring.<br><br />
REFERENCES 5.<br><br />
'''6. UNCERTAINTY IN MONITORING AND DIAGNOSTIC SYSTEMS.<br>'''<br />
6.1 Uncertainty in vibration monitoring systems of rotating machinery .<br><br />
6.2. Uncertainty sources in vibration monitoring and diagnostic systems.<br><br />
6.2.1. Calculating measurement uncertainty in vibromonitoring systems.<br><br />
6.2.2. Increase of mean and variance estimates reliability for limited data size.<br><br />
6.2.2.1. Theory of the method.<br><br />
6.2.2.2. The results of statistical simulation.<br><br />
6.2.2.3. Practical application of the method.<br><br />
6.2.3. The measurement uncertainty with random or systematic errors.<br><br />
6.2.3.1. Rotating machinery as a measurement object.<br><br />
6.2.3.2. Vibromonitoring system as a measurement medium.<br><br />
6.2.3.3. Analysis of experimental data.<br><br />
6.2.4. Uncertainty of decision making.<br><br />
6.3. Investigation of vibration monitoring uncertainty including transient modes of rotating systems.<br><br />
REFERENCIES 6.<br><br />
CONCLUSSION.<br></div>Vvolkovas