https://en.wiki.polymerservice-merseburg.de/index.php?action=history&feed=atom&title=FractographyFractography - Revision history2026-04-22T19:53:44ZRevision history for this page on the wikiMediaWiki 1.43.1https://en.wiki.polymerservice-merseburg.de/index.php?title=Fractography&diff=314&oldid=prevOluschinski: Created page with "{{Language_sel|LANG=ger|ARTIKEL=Fraktographie}} {{PSM_Infobox}} <span style="font-size:1.2em;font-weight:bold;">Fractography</span> __FORCETOC__ ==Definition of terms== The term fractography refers to the visual, macroscopic and microscopic analysis of the fracture surfaces of broken components and parts as well as test specimens. This examination method for defining the causes of fracture (see: Fracture Formati..."2025-12-02T08:23:42Z<p>Created page with "{{Language_sel|LANG=ger|ARTIKEL=Fraktographie}} {{PSM_Infobox}} <span style="font-size:1.2em;font-weight:bold;">Fractography</span> __FORCETOC__ ==Definition of terms== The term fractography refers to the visual, macroscopic and microscopic analysis of the <a href="/index.php?title=Fracture_Surface&action=edit&redlink=1" class="new" title="Fracture Surface (page does not exist)">fracture surfaces</a> of broken <a href="/index.php?title=Plastic_Component&action=edit&redlink=1" class="new" title="Plastic Component (page does not exist)">components</a> and parts as well as <a href="/index.php/Specimen" title="Specimen">test specimens</a>. This examination method for defining the causes of fracture (see: Fracture Formati..."</p>
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<span style="font-size:1.2em;font-weight:bold;">Fractography</span><br />
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==Definition of terms==<br />
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The term fractography refers to the visual, macroscopic and microscopic analysis of the [[Fracture Surface|fracture surfaces]] of broken [[Plastic Component|components]] and parts as well as [[Specimen|test specimens]]. This examination method for defining the causes of fracture (see: [[Fracture Formation|fracture formation]]) is used in particular in the context of [[Failure Analysis – Basics|damage analyses]] to evaluate the existing damage mechanism, the temporal damage kinetics and the point of origin of the failure (see also: [[Component Failure|component failure]]) [1]. Since failure is very often initiated by mechanical [[Stress|stress]] or overstress, there is also a close connection between fractography and the occurrence of [[Crack|cracks]] and [[Fracture|fractures]].<br />
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Depending on the type of stress, mechanically induced cracks or fractures can manifest themselves in all materials as macroscopically visible [[Fracture Types|brittle fractures]] or [[Fatigue|fatigue]] fractures, whereby the terms shear, cleavage and mixed fracture are primarily associated with metallic or ceramic materials. For fractography, therefore, the location of [[Crack Initiation|crack initiation]] and the direction of [[Crack Propagation|crack propagation]] are of great importance, in addition to any possible arrest lines or fracture lines (see: [[Waves and Arrest Lines|waves and arrest lines]]).<br />
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==Makroscopic and microscopic fracture characteristics==<br />
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[[Fracture Mirror|Fracture mirrors]], which are a typical feature of the [[Fracture Mirror#Formation of the fracture mirror on broken glass surfaces|fracture origin in glass]], arrest lines (see also: [[Fracture Types|Fracture types]]) and fracture propagation lines are referred to as [[Fracture Types#Macroscopic fracture features|macroscopic fracture features]] that can be detected visually with the naked eye or with the aid of magnifying glasses, but are usually characterised using light microscopy. For highly fractured fracture surfaces with complex geometry, as is often observed in metallic materials and [[Fibre-reinforced Plastics|reinforced plastics]], the use of digital microscopes with automatic [[Depth of Field Microscope|depth of field]] correction is recommended ('''Fig. 1''').<br />
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[[file:Fraktografie1.JPG]]<br />
{| <br />
|- valign="top"<br />
|width="50px"|'''Fig. 1''': <br />
|width="600px"|VHX 500D 3D digital microscope from Keyence GmbH<br />
|}<br />
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In contrast, vibration or vibration stripes, honeycombing, Wallner lines and corrosion pits are concrete examples of [[Fracture Types#Microscopic fracture features|microscopic fracture features]] that can usually only be visualised using [[Scanning Electron Microscopy|scanning electron microscopy]] and scanning [[Atomic Force Microscopy|atomic force]] and confocal microscopy at high magnifications. <br />
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Regardless of whether a brittle or ductile violent fracture or a fatigue fracture (see: [[Fatigue|fatigue]]), the macroscopic and microscopic fracture patterns depend largely on the type of [[Stress|stress]] (static or dynamic stress, [[Tensile Test|tensile]], [[Compression Test|compressive]], [[Bend Test|bending]] or torsional stress), which is why the type and temporal course of the mechanical stress must always be considered in [[Failure Analysis – Basics|damage analyses]]. The fractography carried out as part of a damage analysis therefore requires a clear evaluation and documentation of the macroscopic and microscopic fracture characteristics (see: [[Fracture Types|fracture types]]), taking into account the stress acting on the material, if possible a 3D image of the fracture surface morphology and the measurement of the [[Fracture Surface|fracture surface]] topography, as well as the determination of the [[Fracture Formation|fracture initiation]] point. The procedure for performing damage analysis on metallic and polymeric materials using fractographic characterisation methods is described in [[Failure Analysis Plastics Products, VDI Guideline 3822|VDI Guideline 3822]] for different damage patterns and types of stress.<br />
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==See also==<br />
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* [[Fibre–Matrix Adhesion|Fibre-matrix adhesion]]<br />
* [[Fracture Surface|Fracture surface]]<br />
* [[Ramps, Clods and Steps|Ramps, clods and steps]]<br />
* [[Vibration Fracture|Vibration fracture]]<br />
* [[Fracture Parables|Fracture parables]]<br />
* [[Waves and Arrest Lines|Waves and arrest lines]]<br />
* [[Scanning Electron Microscopy|Scanning electron microscopy (SEM)]]<br />
* [[In-situ Tensile Test in ESEM with AE|In-situ tensile test in ESEM with AE]]<br />
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'''References'''<br />
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* Schmitt-Thomas, K. G.: Metallkunde für das Maschinenwesen: Band 1: Aufbau und Eigenschaften metallische Werkstoffe. 2. Auflage, Springer Berlin Heidelberg (1990) (ISBN 978-3-540-51913-3)<br />
* VDI-Richtlinie: VDI 3822 (2023-12): Schadensanalyse – Grundlagen und Durchführung einer Schadensanalyse<br />
* Becker, W. T., Shipley, R. J. (Eds.): ASM Handbook: Volume 11: Failure Analysis and Prevention. Bd. 11. 10. Edition ASM International (2002) (ISBN 0-871-70704-7)<br />
* Broichhausen, J.: Analyse und Vermeidung von Schäden in Konstruktion, Fertigung und Betrieb. 1st Edition, Carl Hanser Munich (1985) (ISBN 3-446-13409-3)<br />
* [[Ehrenstein,_Gottfried_W.|Ehrenstein, G. W.]]: Kunststoff-Schadensanalyse: Methoden und Verfahren. Carl Hanser Munich (1992) (ISBN 3-446-17329-3; see [[AMK-Büchersammlung|AMK-Library]] under D 2)<br />
* Ehrenstein, G. W., Engel, L., Klingele, H., Schaper, H.: Scanning Electron Microscopy of Plastics Failure: Rasterelektronenmikroskopie von Kunststoffschäden. Carl Hanser Munich Vienna (2010) (ISBN 3-446-42242-0; see [[AMK-Büchersammlung|AMK-Library]] under D 5)<br />
* Engel, L., Ehrenstein, G. W., Klingele, H., Schaper, H.: Rasterelektronenmikroskopische Untersuchungen von Kunststoffschäden. Carl Hanser Munich Vienna (1978) (ISBN 3-446-12560-4; see [[AMK-Büchersammlung|AMK-Library]] under D 8)<br />
* Esaklul, K. A. (Ed.): Handbook of Case Histories in Failure Analysis, Vol. 2. Bd. 2. ASM International; Materials Park, OH 44073-0002 : ASM International (1993) (ISBN 0-87170-495-1)<br />
* Lampman, S. (Ed.): Characterization and Failure Analysis of Plastics. ASM International; Materials Park, OH 44073-0002 : ASM International (2003) (ISBN 978-0-87170-789-5)<br />
* Lange, G. (Ed.): Systematische Beurteilung technischer Schadensfälle. 5. Edition, Wiley-VCH (2001) (ISBN 3-527-30417-7)<br />
* Moalli, J. (Ed.): Plastics Failure Analysis and Prevention. Noyes Pubn (2001) (ISBN 978-1-884207-92-1)<br />
* Mobley, K.: Root Cause Failure Analysis. Butterworth-Heinemann (1999) (ISBN 978-0-7506-7158-3)<br />
* Mills, K. (Eds.): ASM Handbook. Bd. 12: Metals Handbook: Volume 12: Fractography. 9. Edition. ASM International (1987) (ISBN 0-871-70018-2)<br />
* Naumann, F. K.: Das Buch der Schadensfälle: Untersuchen, Beurteilen, Vermeiden. Dr. Riederer-Verlag GmbH (1976)<br />
* Neidel, A.: Handbuch Metallschäden: REM-Atlas und Fallbeispiele zur Ursachenanalyse und Vermeidung. 2nd Edition, Carl Hanser Munich Vienna (2011) (ISBN 978-3-446-42775-4)<br />
* Quinn, G. D.: NIST Recommended Practice Guide: Fractography of Ceramics and Glasses. NIST (2006) Download [http://www.nist.gov http://www.nist.gov]<br />
* Schmitt-Thomas, K. G.: Integrierte Schadenanalyse: Technikgestaltung und das System des Versagens. Springer (2005) (ISBN 3-540-20551-9)<br />
* Wendler-Kalsch, E., Gräfen, H., Isecke, B. (Eds.): Korrosionsschadenkunde. 2nd Edition, Springer (2011) (ISBN 3-540-72405-2)<br />
* [[Michler,_Goerg_Hannes|Michler, G. H.]]: Atlas of Polymer Structures, Morphology, Deformation and Fracture Surfaces. Carl Hanser, Munich Vienna (2016) (ISBN 978-1-56990-557-9; see [[AMK-Büchersammlung|AMK-Library]] under F 14)<br />
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[[category:Fracture Mechanics]]</div>Oluschinski