Frank W. DelRio, Todd Huber, Rex K. Jaramillo, E. David Reedy Jr., Scott J. Grutzik
{"title":"通过时间-温度叠加法解读试验温度和加载速率对聚合物-金属界面断裂韧性的影响","authors":"Frank W. DelRio, Todd Huber, Rex K. Jaramillo, E. David Reedy Jr., Scott J. Grutzik","doi":"10.1007/s10704-024-00790-7","DOIUrl":null,"url":null,"abstract":"<div><p>In this letter, we present interfacial fracture toughness data for a polymer-metal interface where tests were conducted at various test temperatures <i>T</i> and loading rates <span>\\(\\dot{\\delta }\\)</span>. An adhesively bonded asymmetric double cantilever beam (ADCB) specimen was utilized to measure toughness. ADCB specimens were created by bonding a thinner, upper adherend to a thicker, lower adherend (both 6061 T6 aluminum) using a thin layer of epoxy adhesive, such that the crack propagated along the interface between the thinner adherend and the epoxy layer. The specimens were tested at <i>T</i> from 25 to 65 °C and <span>\\(\\dot{\\delta }\\)</span> from 0.002 to 0.2 mm/s. The measured interfacial toughness Γ increased as both <i>T</i> and <span>\\(\\dot{\\delta }\\)</span> increased. For an ADCB specimen loaded at a constant <span>\\(\\dot{\\delta }\\)</span>, the energy release rate <i>G</i> increases as the crack length <i>a</i> increases. For this reason, we defined rate effects in terms of the rate of change in the energy release rate <span>\\(\\dot{G}\\)</span>. Although not rigorously correct, a formal application of time–temperature superposition (TTS) analysis to the Γ data provided useful insights on the observed dependencies. In the TTS-shifted data, Γ decreased and then increased for monotonically increasing <span>\\(\\dot{G}\\)</span><i>.</i> Thus, the TTS analysis suggests that there is a minimum value of Γ<i>.</i> This minimum value could be used to define a lower bound in Γ when designing critical engineering applications that are subjected to <i>T</i> and <span>\\(\\dot{\\delta }\\)</span> excursions.</p></div>","PeriodicalId":590,"journal":{"name":"International Journal of Fracture","volume":"247 3","pages":"361 - 367"},"PeriodicalIF":2.2000,"publicationDate":"2024-05-04","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Interpreting test temperature and loading rate effects on the fracture toughness of polymer-metal interfaces via time–temperature superposition\",\"authors\":\"Frank W. DelRio, Todd Huber, Rex K. Jaramillo, E. David Reedy Jr., Scott J. Grutzik\",\"doi\":\"10.1007/s10704-024-00790-7\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>In this letter, we present interfacial fracture toughness data for a polymer-metal interface where tests were conducted at various test temperatures <i>T</i> and loading rates <span>\\\\(\\\\dot{\\\\delta }\\\\)</span>. An adhesively bonded asymmetric double cantilever beam (ADCB) specimen was utilized to measure toughness. ADCB specimens were created by bonding a thinner, upper adherend to a thicker, lower adherend (both 6061 T6 aluminum) using a thin layer of epoxy adhesive, such that the crack propagated along the interface between the thinner adherend and the epoxy layer. The specimens were tested at <i>T</i> from 25 to 65 °C and <span>\\\\(\\\\dot{\\\\delta }\\\\)</span> from 0.002 to 0.2 mm/s. The measured interfacial toughness Γ increased as both <i>T</i> and <span>\\\\(\\\\dot{\\\\delta }\\\\)</span> increased. For an ADCB specimen loaded at a constant <span>\\\\(\\\\dot{\\\\delta }\\\\)</span>, the energy release rate <i>G</i> increases as the crack length <i>a</i> increases. For this reason, we defined rate effects in terms of the rate of change in the energy release rate <span>\\\\(\\\\dot{G}\\\\)</span>. Although not rigorously correct, a formal application of time–temperature superposition (TTS) analysis to the Γ data provided useful insights on the observed dependencies. 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Interpreting test temperature and loading rate effects on the fracture toughness of polymer-metal interfaces via time–temperature superposition
In this letter, we present interfacial fracture toughness data for a polymer-metal interface where tests were conducted at various test temperatures T and loading rates \(\dot{\delta }\). An adhesively bonded asymmetric double cantilever beam (ADCB) specimen was utilized to measure toughness. ADCB specimens were created by bonding a thinner, upper adherend to a thicker, lower adherend (both 6061 T6 aluminum) using a thin layer of epoxy adhesive, such that the crack propagated along the interface between the thinner adherend and the epoxy layer. The specimens were tested at T from 25 to 65 °C and \(\dot{\delta }\) from 0.002 to 0.2 mm/s. The measured interfacial toughness Γ increased as both T and \(\dot{\delta }\) increased. For an ADCB specimen loaded at a constant \(\dot{\delta }\), the energy release rate G increases as the crack length a increases. For this reason, we defined rate effects in terms of the rate of change in the energy release rate \(\dot{G}\). Although not rigorously correct, a formal application of time–temperature superposition (TTS) analysis to the Γ data provided useful insights on the observed dependencies. In the TTS-shifted data, Γ decreased and then increased for monotonically increasing \(\dot{G}\). Thus, the TTS analysis suggests that there is a minimum value of Γ. This minimum value could be used to define a lower bound in Γ when designing critical engineering applications that are subjected to T and \(\dot{\delta }\) excursions.
期刊介绍:
The International Journal of Fracture is an outlet for original analytical, numerical and experimental contributions which provide improved understanding of the mechanisms of micro and macro fracture in all materials, and their engineering implications.
The Journal is pleased to receive papers from engineers and scientists working in various aspects of fracture. Contributions emphasizing empirical correlations, unanalyzed experimental results or routine numerical computations, while representing important necessary aspects of certain fatigue, strength, and fracture analyses, will normally be discouraged; occasional review papers in these as well as other areas are welcomed. Innovative and in-depth engineering applications of fracture theory are also encouraged.
In addition, the Journal welcomes, for rapid publication, Brief Notes in Fracture and Micromechanics which serve the Journal''s Objective. Brief Notes include: Brief presentation of a new idea, concept or method; new experimental observations or methods of significance; short notes of quality that do not amount to full length papers; discussion of previously published work in the Journal, and Brief Notes Errata.