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Piezoelectric Driven Testing Facilities to Research the Very High Cycle Fatigue Regime *

Fischer, Christian ; Wagener, Rainer ; Friedmann, Andreas ; [weitere]

Walter de Gruyter GmbH ; 2012

In: Materials Testing Vol. 54, No. 11-12 ( 2012-11-01), p. 746-749

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In: Materials Testing, Walter de Gruyter GmbH, Vol. 54, No. 11-12 ( 2012-11-01), p. 746-749

Kurzfassung: Cyclic low amplitude loading and a huge number of cycles characterizes the Very High Cycle Fatigue (VHCF) regime. The challenge in research of the Very High Cycle Fatigue regime is to apply this large number of cycles to fracture in an acceptable time frame. For this reason, it is essential to use a machine, which is able to operate at high frequencies of cycles. Two testing machine concepts with piezo actuators are presented in this study. In the first concept, a high performance piezo stack actuator is presented, in which the specimen and the load cell are mechanically assembled in series. This set-up applies forces up to 10 kN and testing frequencies up to 1000 Hz. The second testing facility is a hybrid testing system, which consists of an inertial mass actuator and a servo hydraulic actuator connected in parallel. Both systems are capable of testing normal specimen dimensions and provide the possibility to work with variable as well as constant amplitude loading.

Materialart: Online-Ressource

ISSN: 2195-8572 , 0025-5300

URL: Article

DOI: 10.3139/120.110388

RVK:

ZG 1100

Sprache: Englisch

Verlag: Walter de Gruyter GmbH

Publikationsdatum: 2012

ZDB Id: 2280363-4

ZDB Id: 206395-5

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Fatigue life and cyclic material behavior of butt-welded high-strength steels in the LCF regime*

Möller, Benjamin ; Wagener, Rainer ; Kaufmann, Heinz ; [weitere]

Walter de Gruyter GmbH ; 2015

In: Materials Testing Vol. 57, No. 2 ( 2015-02-02), p. 141-148

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In: Materials Testing, Walter de Gruyter GmbH, Vol. 57, No. 2 ( 2015-02-02), p. 141-148

Kurzfassung: Fatigue life approach methods based on general local concepts for welded joints assign universal material properties to geometrically well-defined weld toes or weld roots, in order to evaluate local stresses and strains, ignoring any metallurgical discrepancies. In this study, analysis of the main influences on these concepts, linear damage accumulation and cyclic material behavior, of the high-strength and ultra-high-strength steels S960QL, S960M and S1100QL was performed for the base material and for butt-welded specimens. Results of stress-controlled tests under constant amplitude loading (CAL) and variable amplitude loading (VAL) show that a linear damage accumulation with a damage sum of D al = 0.5 is conservative. Effects of the geometrical and metallurgical notch on the cyclic material behavior are shown by strain controlled testing of both base material and welded specimens. Cycles to crack initiation, presented in strain-life curves, are consequently reduced in the as-welded state. Cyclic stress-strain curves show a cyclic softening of the base material as well as of the welded joints. Furthermore, the advantages of the ultra-high-strength steel S1100QL disappear in welded connections.

Materialart: Online-Ressource

ISSN: 2195-8572 , 0025-5300

URL: Article

DOI: 10.3139/120.110691

RVK:

ZG 1100

Sprache: Englisch

Verlag: Walter de Gruyter GmbH

Publikationsdatum: 2015

ZDB Id: 2280363-4

ZDB Id: 206395-5

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Fatigue strength of nodular cast iron with regard to heavy-wall applications

Bleicher, Christoph ; Wagener, Rainer ; Kaufmann, Heinz ; [weitere]

Walter de Gruyter GmbH ; 2015

In: Materials Testing Vol. 57, No. 9 ( 2015-09-01), p. 723-731

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In: Materials Testing, Walter de Gruyter GmbH, Vol. 57, No. 9 ( 2015-09-01), p. 723-731

Kurzfassung: For a proper estimation of the fatigue life of a heavy-walled cast component made of nodular cast iron, sufficient knowledge regarding the cyclic properties of the material is necessary. Based on the material parameters at hand for component design, different fatigue analysis procedures can be used. Elastic and elastic-plastic approaches can be adopted, with the latter being reserved only for local approaches. The present publication summarizes the cyclic material parameters gained during a research project by extensive material tests under stress and strain controlled cyclic loading at different load ratios for three nodular cast iron grades. In addition to an improved knowledge of the cyclic material behavior, the notch, the size effects and the mean stress sensitivity were of special concern during the investigations in order to provide an entire overview of the tested materials and thus input information for both stress and strain based design approaches. Tests were performed for specimens taken from large cast blocks of the nodular cast iron grades EN-GJS-400-18U-LT and EN-GJS-450-18, both with ferritic matrices, and EN-GJS-700-2 with a pearlitic matrix. For some of these materials, mean stress sensitivities above 0.5 were obtained during the investigations. These values are not covered by the common standards, which calculate lower values for the mean stress sensitivity. Cyclic material parameters for stress and strain controlled tests are given in this paper as well as values for the size effect, based on the concept of the highly stressed volume. The effect of different specimen sizes could be shown not only by stress but also by strain controlled tests.

Materialart: Online-Ressource

ISSN: 2195-8572 , 0025-5300

URL: Article

DOI: 10.3139/120.110782

RVK:

ZG 1100

Sprache: Englisch

Verlag: Walter de Gruyter GmbH

Publikationsdatum: 2015

ZDB Id: 2280363-4

ZDB Id: 206395-5

Permalink

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