 Sign in
References
[2.1] Klee
S.
Das zyklische Spannungs-Dehnungs- und Bruchverhalten verschiedener Stähle
Veröffentlichungen des Instituts für Statik und Stahlbau, No. 22, 1973, TH
Darmstadt
[2.2] Traiser
H.
Verformungsverhalten und mikrostrukturelle Veränderungen normalisierter
Kohlenstoffstähle bei dynamischer Beanspruchung unter besonderer
Berücksichtigung des spannungsmechanischen und oberflächentechnischen
Größeneinflusses
PhD-Thesis, TH Darmstadt, 1981
[2.3] Sonsino
C.M., Diefenbach W.
Elasto-plastisches Schwingfestigkeitsverhalten von Ck 45 vergütet
LBF-Einzelbericht 2771-4.2 Juli 1978
[2.4] Boller
Chr., Heuler P., Seeger T.
Buxbaum O., Oppermann H., Köbler H.-G., Schütz D.
Vergleich der Lebensdauervorhersage nach dem Kerbgrundkonzept und
dem Nennspannungskonzept
Report FD 5/1983, Fachgebiet Werkstoffmechanik, TH Darmstadt,
Fraunhofer-Institut für Betriebsfestigkeit (LBF), Darmstadt
[2.5] Veith
H.
Zum Spannungs-Dehnungs-Verhalten von Baustählen bei Wechselbeanspruchung
BAM-Berichte Nr. 8, Nov. 1971, Berlin
[2.6] Reik
W., Mayr P., Macherauch E.
Untersuchungen zum Schwingfestigkeitsverhalten von Ck 45
EGKS research program, final report, part B, 1979
[2.7] Nowack
H., Trautmann K.H.
non published information
[2.8] Yoshida
S., Kanazawa K., Yamaguchi K., Kobayashi K., Sato M.,
Suzuki N., Shiohara M.
Elevated-Temperature Fatigue Properties of Engineering Materials
Part III
Transactions of the Nat. Research Inst. f. Metals, Tokyo, 1978
[2.9] NRIM
Fatigue Data Sheet No. 38
Nat. Research Inst. f. Metals, Tokyo, 1984
[2.10] NRIM
Fatigue Data Sheet No. 39
Mat. Research Inst. f, Metals, Tokyo, 1984
[2.11] NRIM
Fatigue Data Sheet No. 22
Nat. Research Inst. f. Metals, Tokyo, 1980
[2.12] Luft
G.
Zeitfestigkeitsverhalten von Stählen
Techn.-wissenschaftl. Berichte, MPA Stuttgart (1968), Heft 68-02
[2.13] Wiemann
W., Reiermann D.
non published information
[2.14] Schmalenbach
E.-W.
Wechselverformungsuntersuchungen an Kerb- und Biegeproben äquivalenter
Geometrie
PhD-Thesis, TU Karlsruhe, 1975
[2.15] Mitchel
M.R., Meyer M.E., Nguyen N.Q.
Fatigue Considerations in Use of Aluminum Alloys
Proc. of the SAE Fatigue Conference, Dearborn Mich., 1982, pp. 249 – 272
[2.16] Prowatke
G.
Zum zyklischen Werkstoffgesetz des Schiffbaustahls 09 G 2
Schiffbauforschung, 21 1/1982, pp. 29 - 34, Rostock, GDR
[2.17] Morrow
JoDean
Low Cycle Fatigue Behaviour of Quenched and Tempered SAE 1045 Steel
T.A.M. Report No. 277, Univ. of Illinois, 1955
[2.18] Mitchell
R.M.
Material Characterization of SAE 950XK; Monotonic and Cyclic Stress-Strain
Behaviour ans Strain-Life Response
FCP Report No. 25, Univ. of Illinois, 197?
[2.19] Nihei
M., Konno T., Iida K.
Prediction of Fatigue Strength under Bending by Use of Hysteresis Energy
Concept
Proc. of Nippon Zoosen Gakkai, (in Japanese), 1984, pp. 511 - 521
[2.20] Fugger
T.F. Jr.
Service Load Histories Analyzed by the Local Strain Approach
Report No. 120, Univ. of Illinois, 1985
[2.21] Richmann
R.H., Landgraf R.W.
Some Effects of Retained Austenite on the Fatigue Resistance of Carburized
Steel
Metallurgical Transactions A, Vol. 6A, 1975, pp. 955 – 964
[2.22] Polak
J., Klesnil f"., Lukas P.
High Cycle Plastic Stress-Strain Response of Metals
Mat. Science and Engineering, 15, 1974, pp. 231 – 237
[2.23] Pohl
K., Mayr Macherauch E.
Shape ans Structure of Persistent Slip Bands in Iron Carbon Alloys
Proc. of the Symp. "Defects, Fracture and Fatigue", Mount Gabriel,
Canada, 1982
[2.24] Schwab
W.
Ermüdungsverhalten von fliessgepressten bauteilähnlichen Proben
Proc. of "Werkstoffermüdung", DVM, Bad Nauheim, 1985
[2.25] Iida
K., Yamauchi T., Satoh M., Takano G.
Fatigue Strength of Electron Beam Welded Joint of Carbon Steel
IIW-Doc. XIII-1201-86, Tokyo, 1986
[2.26] Paetzold
Beurteilung der Betriebsfestigkeit von Längsspantdurchführungen auf der
Grundlage der örtlichen Dehnung
IfS-Bericht No. 455, Univ. Hamburg, 1985
[2.27] Pilo
Zum Wechselverformungsverhalten normalisierter unlegierter Stähle mit
Kohlenstoffgehalten von 0.01 bis 1.02 Gew.%
PhD-Thesis, TU Karlsruhe, 1979
[2.28] Higashida
Y.
Strain Controlled Fatigue Behaviour of Weld Metal and Heat-Affected Base Metal
in A36 and A514 Steel Welds
PhD-Thesis, Univ. of Illinois, 1976
[3.1] Klee
S.
Das zyklische Spannungs-Dehnungs- und Bruchverhalten verschiedener Stähle
Veröffentlichungen des Instituts für Statik und Stahlbau, No. 22, 1973, TH
Darmstadt
[3.2] Heuler
P., Seeger T,
Rechnerische und experimentelle Lebensdauervorhersage am Beispiel eines
geschweißten Bauteils
Konstruktion 35, 1983, H. 1, pp. 21 – 26
[3.3] Sonsino
C.M,
Einfluß von Kaltverformungen bis 5% auf das Kurzschwingfestigkeitsverhalten
metallischer Werkstoffe
PhD-Thesis, TH Darmstadt, 1982
[3.4] Boller
Chr., Seeger T.
Einfluß von Probengröße und Probenform auf das zyklische Spannungs-Dehnungs-
und Versagensverhalten der Stähle StE 460 und
30 CrNiMo 8
Report FD 12/1984, Fachgebiet Werkstoffmechanik, TH Darmstadt
[3.5] Boller
Chr., Seeger T.
Größen- und Ober flächeneinfluß bei der Lebensdauervorhersage von Kerbstäben
aus StE 460
Report FD 6/1986, Fachgebiet Werkstoffmechanik, TH Darmstadt
[3.6] Boller
Chr., Heuler P., Seeger T.
Buxbaum 0., Oppermann H., Köbler H.-G., Schütz D.
Vergleich der Lebensdauervorhersage nach dem Kerbgrundkonzept und dem
Nennspannungskonzept
Report FD 5/1983, Fachgebiet Werkstoffmechanik, TH Darmstadt, Fraunhofer-Institut
für Betriebsfestigkeit (LBF), Darmstadt
[3.7] Yoshida
S., Kanazawa K., Yamaguchi K., Kobayashi K., Sato M., Suzuki N., Shiohara M.
Elevated-Temperature Fatigue Properties of Engineering Materials Part III
Transactions of the Nat. Research Inst. f. Metals, Tokyo, 1978
[3.8] Idler
R.
Das Zeitfestigkeitsverhalten von Stählen unter Berücksichtigung der
Dehngeschwindigkeit, Oberflächenbeschaffenheit, Kerbwirkung und
des Temperaturverlaufs
Techn.-wissensehaftl. Berichte MPA Stuttgart, Heft 75-04
[3.9] Sautter
S.
Der Einfluß von Temperatur, Dehnungsgeschwindigkeit und Haltezeit auf das
Zeitfestigkeitsverhalten von Stählen
Techn.-wissenschaftl Berichte MPA Stuttgart, Heft 71-04
[3.10] NRIM
Fatigue Data Sheet No. 28
Nat. Research Inst. f. Metals, Tokyo, 1981
[3.11] NRIM
Fatigue Data Sheet No. 7
Nat. Research Inst. f. Metals, Tokyo, 1978
[3.12] Majumdar
S.
Low Cycle Fatigue Behaviour and Crack Propagation in some Steels
T.&A.M. Report No. 387, Univ. of Illinois, 1974
[3.13] Bergmann
J.W.
Zur Betriebsfestigkeitsbemessung gekerbter Bauteile auf der Grundlage der
örtlichen Beanspruchungen
Veröffentlichungen des Instituts für Stahlbau und Werkstoffmechanik d. TH
Darmstadt, Heft 37 (1983)
[3.14] Heuler,
P.
Anrißlebensdauervorhersage bei zufallsartiger Belastung auf der Grundlage der
örtlichen Beanspruchungen
Veröffentlichungen des Instituts für Stahlbau und Werkstoffmechanik d. TH
Darmstadt, Heft 40 (1983)
[3.15] Grubisic
V., Sonsino C.M.
Festigkeit von Hochdruckbehältern für neuartige Fertigungsverfahren
Fraunhofer-Institut für Betriebsfestigkeit Darmstadt, Bericht Nr. FB-148 (1979)
[3.16] Brose
W.R., Dowling N.E., Morrow JoDean
Effect of Periodic Large Strain Cycles on the Fatigue Behaviour of Steels
SAE-Report No. 740221, 1974
[3.17] Iida
K., Inoue H.
Life Distribution and Design Curve in Low Cycle Fatigue
Papers of Ship Research Institute No. 45, Univ. of Tokyo, 1973
[3.18] Krishnadev
M.R., Cutler L.R., Galibois A.
A Comparative Study of the Effect of Low Temperature on the Fracture Toughness
and Cyclic Properties of Two Candidate High-Strength Low-Alloy Steels for
Arctic Pipeline Applications
Journal of Testing and Evaluation, JTEVA, Vol. 9, No. 1, Jan. 1981, pp. 28 – 34
[3.19] Scutti
J.J, Pelloux R.M., Fuquen-Moleno R.
Fatigue Behaviour of a Rail Steel
Fatigue Engng. Struct., Vol. 7, No. 2, 1984, pp. 121 – 135
[3.20] Ronchiato
G., Castagna M., Colombo R.L.
Fracture Mechanics and Fatigue Properties of Lean Constructional Steels
Metallurgical Science and Technology, Vol. 2, 1984, PP•93 – 101
[3.21] Rieth
P.
Zur Nachbildung der betriebsähnlichen Dehnwechselbeanspruchung massiver
Bauteile aus warmfesten Stählen
PhD-Thesis, TH Darmstadt, 1982
[3.22] Soo
P., Chow J.G.Y
Development of a Procedure for Estimating the High Cycle Fatigue Strength of
Some High Temperature Structural Alloys
Journal of Engineering Materials and Technology, Vol. 103, 1981, pp. 97 – 103
[3.23] Hatanaka
K., Fujimitsu T.
The Cyclic Stress-Strain Response and Strain Life Behaviour of Metallic
Materials
Proc. of Fatigue 84 Conference, Birmingham, pp. 93 – 103
[3.24] Luft
G.
Zeitfestigkeitsverhalten von Stählen
Techn.-wiss. Ber. MPA Stuttgart, No. 68-02, 1968
[3.25] Endo
T., Morrow JoDean
Cyclic Stress-Strain and Fatigue Behaviour of Representative Aircraft Metals
Journal of Materials JMLSA, Vol. 4, No. 1, March 1969, pp. 159-175
[3.26] Dowling
N.E.
Fatigue Life and Inelastic Strain Response under Complex Histories for an Alloy
Steel
Journal of Testing and Evaluation, JTEVA, Vol. 1, No. 4, July 1973, pp. 271-287
[3.27] Smith
R.W., Hirschberg M.H., Manson S.S
Fatigue Behaviour of Materials under Strain Cycling in Low and Intermediate
Life Range
NASA Techn. Note D-1574, April 1963
[3.28] Wiemann
W., Reiermann D.
non published information
[3.29] Lefebvre
D., Ellyin F.
Cyclic Response and Inelastic Strain Energy in Low Cycle Fatigue
Int. Journal of Fatigue, Vol. 6, No. 1 , January 1984, pp. 9-15
[3.30] Eifler
D.
Inhomogene Deformationserscheinungen bei Schwingbeanspruchung eines
unterschiedlich wärmebehandelten Stahles des Typs 42 CrMo 4
PhD-Thesis, University of Karlsruhe, 1981
[3.31] Mandorini
V., Prigoni A.
Elevated Temperature Low-cycle Fatigue and Creep-fatigue Properties of a
normalized and tempered 2 1/4 Cr 1 Mo Steel
DVM, 5. Sitzung des Arbeitskreises Betriebsfestigkeit, 8./9.10.1979, Stuttgart,
pp. 39-51
[3.32] Iida
K.
Fatigue Strength Reduction Factor in Plastic Strain Cycling
IIW-Doc. XIII-427-66, Tokyo, 1966
[3.33] Leis
B.N.
Microcrack Initiation and Growth in a Pearlitic Steel - Experiments and
Analysis
ASTM STP 833, 1984, pp. 449 – 480
[3.34] Ellyin
F.
Effect of Tensile-Mean-Strain on Plastic Strain Energy and Cyclic Response
J. of Eng. Mat. and Techn., 1985, Vol. 107, pp. 119 - 125
[3.35] Ando
Y., Iida K., Sakabe K., Tsukada H.
Low and High Cycle Fatigue Strength of A302B Steel and its Welds IIW-Doc.
XIII-464-67, 1967, Tokyo
[3.36] Watson
P., Topper T.H.
An Evaluation of the Fatigue Performance of Automotive Steels
SAE-Paper No. 710597, 1971, New York
[3.37] Tomkins
B.
Fatigue Failure in High Strength Metals
Phil. Mag., 1971, pp. 687 – 703
[3.38] Kwun
S.I., Fournelle R.A. br. Low Cycle Fatigue Behaviour of a Quenched and Tempered
Niobium Bearing HSLA Steel
Metallurgical Transactions, Vol. 11A, 1980, pp. 1429 – 1437
[3.39] Ed.:
Maykuth D.J.
Aerospace Structural Metals Handbook
Dept, of Defense, Army Materials and Mechanics Research Center, Watertown,
Mass. 02172 USA
[3.40] NRIM
Fatigue Data Sheet No. 47
Nat. Research Inst. f. Metals, Tokyo, 198
[3.41] Lawrence
F.V. Jr.
private communocation
[3.42] Waraniak
J.M.
Cyclic Deformation and Fatigue Behaviour of Carburized Steel
FCP Report No. 34, Univ. of Illinois, 1980
[3.43] Dittmer
D.F., Mitchell M.R.
Material Characterization of USS-T1 Monotonic and Cyclic Stress-Strain
Behaviour and Strain-Life Response
FCP Report No. 12, Univ. of Illinois, 1974
[3.44] Deves
T.J., Kurath P., Sehitoglu H., Morrow JoDean
The Effect of Selected Subcycles in Block Loading Fatigue Histories
FCP Report No. 42, Univ. of Illinois, 1982
[3.45] Mitchell
M.R., Zweigoron R.B.
Material Characterization of a 1% Nickel Steel; Monotonie and Cyclic
Stress-Strain Behaviour and Strain-Life Response
FCP Report No. 27, Univ. of Illinois, 1977
[3.46] Berns
H., Siekmann G.
Ermüdung hochfester Vergütungsstähle bei +20 und -70°C
Arch. Eisenhüttenwes. 55, Nr. 5, 1984, pp. 235 – 240
[3.47] Higashida
Y.
Strain Controlled fatigue Behaviour of Weld Metal and Heat-Affected Base Metal
in A36 and A514 Steel Welds
PhD-Thesis, Univ. of Illinois, 1976
[3.48] Boller
Chr.
Der Einfluß von Probengröße und Oberflächenrauhigkeit auf
Lebensdauerabschätzungen bei örtlicher Betrachtung der Beanspruchungen
PhD-Thesis, TH Darmstadt, to be published 1987
[4.1] Yoshida
S., Kanazawa K., Yamaguchi K., Sasaki M., Kobayashi K., Sato M.
Elevated-Temperature Fatigue Properties of Engineering Materials Part I
Transactions of the Nat. Research Inst. f. Metals, Tokyo, Vol. 19 No. 5, 1977
[4.2] NRIM
Fatigue Data Sheet No. 15
Nat. Research Inst. f. Metals, Tokyo, 1979
[4.3] Yoshida
S., Kanazawa K., Yamaguchi K., Sato M., Kobayashi K., Suzuki N., Shiohara M.
Elevated-Temperature Fatigue Properties of Engineering Materials Part II
Transactions of the Nat. Research Inst. f. Metals, Tokyo, Vol. 20 No. 1, 1978
[4.4] Kanazawa
K., Yamaguchi K., Sato M., Kobayashi K., Suzuki N., Shiohara M., Yoshida S.
Elevated-Temperature Fatigue Properties of Engineering Materials Part IV
Transactions of the Nat. Research Inst. f. Metals, Tokyo, Vol. 20 No. 5, 1978
[4.5] Klee
S.
Das zyklische Spannungs-Dehnungs- und Bruchverhalten verschiedener Stähle
Veröffentlichungen des Instituts für Statik und Stahlbau, No. 22, 1973, TH
Darmstadt
[4.6] Jaske
C.E., Frey N.D.
Long-Life Fatigue of Type 316 Stainless Steel at Temperatures up to 593°C
J. of Eng. Mat. and Technology, April 1982, Vol. 104, pp. 137-144
[4.7] Heuler
P.
Anrißlebensdauervorhersage bei zufallsartiger Belastung auf der Grundlage
örtlicher Beanspruchungen
Veröffentlichungen des Instituts für Stahlbau und Werkstoffmechanik, Heft 40 ,
1983, TH Darmstadt
[4.8] Kanazawa
K., Yamaguchi K., Sato M., Kobayashi K., Suzuki N., Shiohara M., Yoshida S.
Elevated-Temperature Fatigue Properties of Engineering Materials Part V
Transactions of the Nat. Research Inst. f. Metals, Tokyo, Vol. 20 No. 6, 1978
[4.9] Ed.:
Maykuth D.J.
Aerospace Structural Metals Handbook
Dept, of Defense, Army Materials and Mechanics Research Center, Watertown,
Mass. 02172 USA
[4.10] Vehoff
H., Neumann P.
Automatisierung von Betriebsfestigkeitsuntersuchungen bei hohen Temperaturen
DVM-Proc. of Werkstoffprüfung 1984, Bad Nauheim, pp. 261 – 270
[4.11] Kohler
W.
Beitrag zur Wasserstoffumgebungsversprödung metallischer Werkstoffe im
Low-Cycle Fatigue Bereich
Fortschr.-Ber. VDI-Z. Reihe 18 Nr.19, 1984
[4.12] Smith
R.W., Hirschberg M.H., Manson S.S.
Fatigue Behaviour of Materials under Strain Cycling in Low and Intermediate
Life Range
NASA Techn. Note D-1574, April 1953
[4.13] Morrow
JoDean, Tuler F.R.
Low Cycle Fatigue Evaluation of Inconel 713C and Waspaloy
J, of Basic Engineering, 1965, pp. 275 – 289
[4.14] Marchand
N., Bailon J.-P., Dickson J.I.
The Cyclic Response and Strain Life Behaviour of Polycrystalline Copper and α-Brass
Proc. of the Symp. "Defects, Fracture and Fatigue", Mount Gabriel,
Canada, 1982
[4.15] Polak
J., Klesnil M, Lukas P.
High Cycle Plastic Stress-Strain Response of Metals
Mat. Science and Engineering, 15, 1974, pp. 231 – 237
[4.16] Jones
D.J.
Extension of Simple Cyclic Fatigue Damage Characteristics to Multiaxial Life
Prediction Methods
Univ. of Illinois, 1986
[4.17] Leis
B.N., Forte T.P.
Nonlinear Damage Analysis - Postulate and Evaluation
NASA CR-168171, 1983
[4.18] Soo
P., Chow J.G.Y.
Development of a Procedure for Estimating the High Cycle Fatigue Strength of
Some High Temperature Structural Alloys
J. of Eng. Mat. and Technology, 1981, pp. 97 – 103
[4.19] Rie
K.-T., Schmidt R.-M.
Frequency Effect on Low-Cycle Fatigue of Type 304 L Stainless Steel Weldments
at Elevated Temperatures
IIW-Doc. XIII-1119-84
[4.20] Majumdar
S.
Low Cycle Fatigue Behaviour and Crack Propagation in some Steels
T.&A.M. Report No. 387, Univ. of Illinois, 1974
[4.21] Kurath
P.
private communication
[4.22] Renner
E., Vehoff H.,Neumann P.
Automatisierte LCF-Prüfung in verschiedenen Umgebungen
DUM-Proc. "Werkstoffprüfung", Bad Nauheim, 1985, pp. 137 – 146
[5.1] Bergmann
J.W.
Zur Betriebsfestigkeitsbemessung gekerbter Bauteile auf der Grundlage der
örtlichen Beanspruchungen
Veröffentlichungen des Instituts für Stahlbau und Werkstoffmechanik d. TH
Darmstadt, Heft 37 (1983)
[5.2] Heuler,
P.
Anrißlebensdauervorhersage bei zufallsartiger Belastung auf der Grundlage der
örtlichen Beanspruchungen
Veröffentlichungen des Instituts für Stahlbau und Werkstoffmechanik d. TH
Darmstadt, Heft 40 (1983)
[5.3] Wellinger
K., Sautter S.
Zeitfestigkeitsverhalten von Aluminiumlegierungen bei dehnungskontrollierter
Beanspruchung
Aluminium, 1971, pp. 741 - 744
[5.4] Sonsino
C.M.
Einfluß von Kaltverformungen bis 5% auf das Kurzschwingfestigkeitsverhalten
metallischer Werkstoffe
PhD-Thesis, TH Darmstadt, 1982
[5.5] Bomas
H.
private communication
[5.6] Colon
J., Reid C.N.
The Effect of Cold Expanded Holes on the Fatigue Properties of Aluminium Alloy
6082
Proc. of "Fatigue 84", Birmingham, 1984, pp. 1683 - 1718
[5.7] Smith
R.W., Hirschberg M.H., Manson S.S
Fatigue Behaviour of Materials under Strain Cycling in Low and Intermediate
Life Range
NASA Techn. Note D-1574, April 1963
[5.8] Saleh
Y., Margolin H.
Low Cycle Fatigue Behaviour of Ti-Mn Alloys: Cyclic Stress-Strain Response
Metallurgical Transactions A, Vol. 11A, 1980, pp. 1295 - 1302
[5.9] Kohler
W.
Beitrag zur Wasserstoffumgebungsversprödung metallischer Werkstoffe im
Low-Cycle Fatigue Bereich
Fortsehr.-Ber. VDI-Z. Reihe 18 Nr.19, 1984
[5.10] Nowack
H., Trautmann K.-H.
private communication
[5.11] Endo
T., Morrow JoDean
Cyclic Stress-Strain and Fatigue Behaviour of Representative Aircraft Metals
Journal of Materials JMLSA, Vol. 4, No. 1, March 1969, pp. 159-175
[5.12] Kurath
P.
private communication
[5.13] Kurath
P.
Extension of the Local Strain Fatigue Analysis Concepts to Incorporate Time
Dependent Deformation in Ti-6A1-4V at Room Temperature
T.&A.M. Report No. 464, Univ. of Illinois
[5.14] Schmalenbach
E.-W.
Wechselverformungsuntersuchungen an Kerb- und Biegeproben äquivalenter
Geometrie
PhD-Thesis, TU Karlsruhe, 1975
[6.1] Smith
G.A., Lawrence F.V.Jr.
Fatigue Behaviour and Material Properties of Simulated Heat Affected Zone
Materials of Hi Form 60
Techn. Report, Univ. of Illinois, 1983
[6.2] Ho
N.-J., Lawrence F.V.
The Fatigue of Weldments to Subjected to Complex Loadings
FCP Report No. 45, Univ. of Illinois, 1983
[6.3] Molinaro
L.
Fatigue Behaviour and Crack Development in Compacted Graphite Cast Iron
FCP Report No. 39, Univ. of Illinois, 1981
[6.4] Nowaek
H., Trautmann K.H.
private communication
[6.5] Stephens
R.I., Chung J.H., Fatemi A., Lee H.W., Lee S.G., Vaca-Oleas C., Wang C.M.
Constant and Variable Amplitude Fatigue Behaviour of Five Cast Steels at Room
Temperature and -45°C
J, of Eng. Mat. and Technology, Vol. 106, 1984, pp. 25 - 37
[6.6] Iida
K., Yamauchi T., Satoh M., Takano G.
Fatigue Strength of Electron Beam Welded Joint of Carbon Steel
IIW-Doc. XIII-1201-86, Tokyo, 1986
[6.7] Higashida
Y.
Strain Controlled fatigue Behaviour of Weld Metal and Heat-Affected Base Metal
in A36 and A514 Steel Welds
PhD-Thesis, Univ. of Illinois, 1976
[6.8] Rie
K.-T., Schmidt R.-M.
Frequency Effect on Low-Cycle Fatigue of Type 304 L Stainless Steel Weldments
at Elevated Temperatures
IIW-Doc. XIII-1119-84
[6.9] Smith
R.W., Hirschberg M.H., Manson S.S
Fatigue Behaviour of Materials under Strain Cycling in Low and Intermediate
Life Range
NASA Techn. Note D-1574, April 1963
[6.10] Idler
R.
Das Zeitfestigkeitsverhalten von Stählen unter Berücksichtigung der
Dehngeschwindigkeit, Oberflächenbeschaffenheit, Kerbwirkung und des
Temperaturverlaufs
Techn.-wissensehaftl. Berichte MPA Stuttgart, Heft 75-04
[6.11] Sautter
S.
Der Einfluß von Temperatur, Dehnungsgeschwindigkeit und Haltezeit auf das
Zeitfestigkeitsverhalten von Stählen
Techn.-wissenschaftl Berichte MPA Stuttgart, Heft 71-04
[6.12] Bomas
H.
private communication
[6.13] Heuler
P., Seeger T.
Rechnerische und experimentelle Lebensdauervorhersage am Beispiel eines
geschweißten Bauteils
Konstruktion 35, 1983, H. 1, pp. 21 - 26
[6.14] Bergmann
J.W.
Zur Betriebsfestigkeitsbemessung gekerbter Bauteile auf der Grundlage der
örtlichen Beanspruchungen
Veröffentlichungen des Instituts für Stahlbau und Werkstoffmechanik d. TH
Darmstadt, Heft 37 (1983)
[6.15] Hück
M., Schütz W., Walter H.
Moderne Schwingfestigkeitsunterlagen für die Bemessung von Bauteilen aus
Temperguß GTS 55
ATZ Automobiltechnische Zeitschrift, Nr. 10/11, 1981, pp. 1-11
[6.16] NRIM
Fatigue Data Sheet No. 47
Nat. Research Inst. f. Metals, Tokyo, 1985
[6.17] Hück
M., Schütz W., Walter H.
Moderne Schwingfestigkeitsunterlagen für die Bemessung von Bauteilen aus
Spähroguß und Temperguß, vor allem für den Fahrzeugbau
Mitteilung aus dem Ressort F&E G. Fischer AG, Schaffhausen. CH
[6.18] Lawrence
F.V. Jr.
private communication
[6.19] Weinacht
D.J.
Fatigue Behaviour of Gray Cast Iron Under Torsional Loads
Report No. 126, Univ. of Illinois, 1986
[6.20] Dittmer
D.F., Mitchell M.R.
Material Characterization of Cast 8630 Steel: Monotonic and Stress-Strain
Behaviour and Strain-Life Response
FCP Report No. 13, Univ. of Illinois, 1974
[6.21] Hua
C.
Fatigue Crack Growth in Nodular Cast Iron
FCP Report No. 47, Univ. of Illinois, 1983
[A.1] Pickard S.M., Guiu F., Blackie A.P. Low Cycle Fatigue of Strain Aging Ferrous
Alloys. In Low Cycle Fatigue, pages 776-797, ASTM, Philadelphia, 1988. STP 942.
[A.2] Ott
W., Nowack H. Cyclic Material Properties of Steel St 00. 1987. private
communication.
[A.3] Nishijima
S. et al. Data Sheets on Fatigue Properties for Weld and HAZ Materials of SB42
(C-Si, 42ON/mmz TS) Carbon Steel Plate for Boiler and Other Pressure Vessels.
Technical Report No. 57, NRIM Fatigue Data Sheet, National Research Insitute
for Metals, December 1987.
[A.4] Bignonnet
A., Buthod-Cuan H. Strength of Metals and Alloys. In Proceedings of the 7th
International Conference on the Strength of Metals and Alloys, Pergamon Press
Oxford, New York, Toronto, Sydney, Frankfurt, Montreal, Canada, 12. - 16.
August 1985. 5. 268-310.
[A.5] Fredriksson
K., Melander A., Hedman M. Influence of Prestraining and Ageing on Fatigue
Properties of High-Strength Sheet Steels. International Journal of Fatigue,
10(No. 3):139-151, July 1988.
[A.6] Hatanaka
K., Fujimitsu T. Growth of Small Cracks and an Evaluation of Low Cycle Fatigue
Life. In Low Cycle Fatigue, pages 257-280, ASTM, Philadelphia, 1988. STP 942.
[A.7] Bäumel
A. jr., Seeger T. Thick Surface Layer Model - Life Calculations for Specimens
with Residual Stress Distribution and Different Material Zones. In
International Conference on Residual Stresses 2, Nancy, Frankreich, 1988.
[A.8] Bämnel
A. jr., Döker H., Bachmann V., Seeger T. Cyclic Material Properties of Steel Ck
15 in Vacuum Environment. 1989. private communication.
[A.9] Schwartz
M., Crespi J.C. Fracture of Pearlite under Conditions of High Deformation
Fatigue. In Low Cycle Fatigue, pages 77-93, ASTNI, Philadelphia, 1988. STP 942.
[A.10] Urashima
C. Comparison between Rotating Bending and Push-Pull Fatigue Strength in Low
Cycle Region. In Rie K.-T., editor, Proceedings of the 2nd International
Conference on Low Cycle Fatigue and Elasto-Plastic Behavior of Materials, pages
538-543, München, September 1987.
[A.11] Fatemi
A., Stephens R.I. Tensile Mean Stress Effects on Uniaxial Fatigue Behavior of
1045 HR Steel. In Fatigue `87, Third International Conference on Fatigue and
Fatigue Thresholds at the University of Virginia, pages 537-546, Engineering
Materials Advisory Services Ltd., Charlottesville, Virginia, 28. June - 3. July
1987.
[A.12] Becker
M. Das Wechselverformungsverhalten von. Ck 45 und Ck 80 im Temperaturbereich
295K ≤ T ≤ 873K. Dissertation, Universität Karlsruhe, 1987.
[A.13] Walla
J., Bomas H. Cyclic Material Properties of Steel Ck 45 N. 1988. private
communication.
[A.14] Yu
M.T., DuQuesnay D.L., Topper T.H. Notch Fatigue Behaviour of SAE 1045 Steel.
International Journal of Fatigue, 10(No. 2):109-116, April 1988.
[A.15] Bernstein
H., Loeby C. Low-Cycle Corrosion Fatigue of Three Engineering Alloys in Salt
Water. Journal of Engineering Materials and Technology, Transactions of the
ASME, 110:234-239, July 1988.
[A.16] Nishijima
S. et. al. Data Sheets on Low-Cycle Fatigue Properties of S45C (0.45C) Steel
for Machine Structural Use. Technical Report No. 44, NRIM Fatigue Data Sheet,
National Research Insitute for Metals, December 1985.
[B.1] Polàk
J., Helešic J., Klesnil M. Effect of Evaluated Temperatures on the Low Cycle
Fatigue of 2.25Cr-1Mo Steel - Part I: Constant Amplitude Straining. In Low
Cycle Fatigue, pages 43-57, ASTM, Philadelphia, 1988. STP 942.
[B.2] Rie
K.-T., Schmidt R.-M. High Temperature Low-Cycle Fatigue of Austenitic and
Ferritic Weldments. In ECF 6, Fracture control of Engineering Structures, pages
1,097-1,113, 1986.
[B.3] Kloos
K.H., Granacher J., Scholz A. Cyclic Material Properties of Steel 10 CrMo 9 10.
1989. private conxmunication.
[B.4] Zang
Y.Z. Cyclic Response of Dual-Phase Steels. In Rie K.-T., editor, Proceedings of
the 2nd International Conference on Low Cycle Fatigue and Elasto-Plastic
Behavior of Materials, pages 736-741, München, September 1987.
[B.5] Fleischer
H., Frank J. Ermüdungsverhalten des warmfesten Stahles 15 Mo 3 im
Temperaturbereich bis 500 °C. IfL-Mitteilungen, 28(Heft 2):33-39, 1989.
[B.6] Pirs
J. Some Results of Low Cycle Fatigue on Boiler Steel. In ECF 6, Fracture
control of Engineering Structures, pages 1,149-1,154, 1986.
[B.7] Mediratta
S.R., Ramaswamy V., Rama Rao P. Low Cycle Fatigue Behaviour of Dual-Phase Steel
with Different Volume Fractions of Martensite. International Journal of
Fatigue, 7(No. 2):101-106, April 1985.
[B.8] Waraniak
J.M. Cyclic Deformation and Fatigue Behaviour of Carburized Steel. Technical
Report 34, Fatigue Control Program, University of Illinois, 1980.
[B.9] Farsetti
P., Blarasin A. Fatigue Behaviour of Microalloyed Steels for Hot-Forged
Mechanical Components. International Journal of Fatigue, 10(No. 3):153-1G1,
July 1988.
[B.10] Maykuth
D.J., editor. -. Department of Defense, Army Materials and Mechanics Research
Center, .
[B.11] Sanetra
C., Zenner H. Betriebsfestigkeit bei mehraxialer Beanspruchung. In
Arbeitskreissitzung in Ottobrunn, Institut für Hüttenmaschinen und maschinelle
Anlagentechnik, Technische Universität Clausthal, 19./20. November 1987.
[B.12] Kloos
K.H., Bieker G. Cyclic Material Properties of Through Nitrided Specimens of
Steel 30 CrNiMo 8. 1989. private communication.
[B.13] Nishijima
S. et. al. Data Sheets on Elevated-Temperature, Time-Dependent Low-Cycle
Fatigue Properties of ASTM A470-8 (1 Cr-1Mo-0.25V) Steel Forging for Taurbine
Rotors and Shafts. Technical Report No. 58, NRIM Fatigue Data Shee1, National
Research Insitute for Metals, December 1987.
[B.14] Nishijima
S. et al. Data Sheets on Low-Cycle Fatigue Properties of SCM435
(0.35C-1Cr-0.2Mo) Steel for Machine Structural Use. Technical Report No. 52,
N73.IM Fatigue Data Sheet, National Research Insitute for Metals, December
1986.
[B.15] Fattorini
F., Ronchiato G, Baffigi M., Di Gianfrancesco E., Rigoni S. Mechanical
Properties of Engineering Steel Produced via Ingot and C.C. Route for
Automotive Components. Steel Research, 60(No. 1):19-24, 1989.
[B.16] Hatanaka
K., Fujimitsu T. Growth of Small Cracks and an Evaluation of Low Cycle Fatigue
Life. In Low Cycle Fatigue, pages 257-280, ASTM, Philadelphia, 1988. STP 942.
[B.17] Nishijima
S. et. al. Data Sheets on Low-Cycle Fatigue Properties of SNCM439 (0.39C-1.8Ni-0.8.Cr-0.2Mo)
Steel for Machine Structural Use. Technical Report No. 56, NRIM Fatigue Data
Sheet, National Research Insitute for Metals, December 1987.
[B.18] Ott
W., Nowack H. Cyclic Material Properties of Steel 41 Cr 4. 1987. private
communication.
[B.19] Nishijima
S. et al. Data. Sheets on Low-Cycle Fatigue Properties of SCr440 (O.4C-1Cr)
Steel for Machine Structural Use. Technical Report No. 45, NRIM Fatigue Data
Sheet, National Research Insitute for Metals, December 1985.
[B.20] Bäumel
jr. A., Seeger T. Cyclic Material Properties of Steel 50 CrMo 4. 1989. private
communication.
[B.21] Bäumel
jr. A., Döker H., Bachmann V., Seeger T. Cyclic Material Properties of Steel 50
CrMo 4 in Vacuum Environment. 1989. private conununication.
[C.1] Bernstein
H., Loeby C. Low-Cycle Corrosion Fatigue of Three Engineering Alloys in Salt
Water. Journal of Engineering Materials and Technology, Transactions of the
ASME, 110:234-239, July 1988.
[C.2] Nishijima
S. et al. Data Sheets on Elevated- Temperature, Time-Dependent Low-Cycle
Fatigue Properties of SUS304-HP (18Cr-8Ni) Hot Rolled Stainless Steel Plate.
Technical Report No. 49, NRIM Fatigue Data Sheet, National Research Insitute
for Metals, December 1985.
[C.3] Vogt
J.B., Degallaix S., Foct J. Low Cycle Fatigue Life Enhancement of 316 L
Stainless Steel by Nitrogen Alloying. International Journal of Fatigue, 6(No.
4):211-215, October 1984.
[C.4] Degallaix
S., Degallaix G., Foct J. Influence of Nitrogen Solutes and Precipitates on Low
Cycle Fatigue of 316 L Stainless Steels. In Low Cycle Fatigue, pages 798-811,
ASTM, Philadelphia, 1988. STP 942.
[C.5] Vehoff
H., Neumann P. Automatisierung von Betriebsfestigkeitsuntersuchungen bei hohen
Temperaturen. In DVM-Vortrag der Tagung Werkstoffprüfung 1984 in Bad Nauheim, pages
261-270, 6./7. Dezember 1984.
[C.6] Renner
E., Vehoff H., Neumann P. Automatisierte LCF-Prüfung in verschiedenen
Umgebungen. In DVM-Vortrag der Tagung Werkstoffprüfung 1985 in Bad Nauheim,
pages 137-146, 1985.
[C.7] Fleischer
H., Frank J. Ermüdungsverhalten des austenitischen Stahles X 8 CrNiTi 18 10 im
Temperaturbereich bis 550 °C. IfL-Mitteilungen, 27(Heft 4):109-117, 1988.
[C.8] Sonsino
C.M., Müller F. Einfluß von Kaltverformungen bis 10 % auf das
Kurzzeitschwingfestigkeitsverhalten des austenitischen Stahls X 10 CrNiTi 18 9
(1.4541). Materialwissenschaft und Werkstofftechnik, 19:335-347, 1988.
[C.9] Vogt
J.B., Degallaix G., Foct J. Low Cycle Fatigue of a 12 Cr Martensitic Stainless
Steel: The Role of Microstructure. In Rie K.-T., editor, Proceedings of the 2nd
International Conference on Low Cycle Fatigue and Elasto-Plastic Behavior of
Materials, pages 736-741, München, September 1987.
[C.10] Kloos
K.H., Granacher J., Scholz A. Cyclic Material Properties of Steel X 22 CrMoV 12
1. 1988. private communication.
[C.11] Merkling
G., Lang K.H., Eifler D. Cyclic Material Properties of Nickel-Base Alloys.
1988. private communication.
[C.12] Bui-Quoc
T., Gomuc R., Biron A., Nguyen H.L., Masounave J. Elevated Temperature
Fatigue-Creep Behaviour of Nickel-Base Superalloy IN 625. In Low Cycle Fatigue,
pages 470-486, ASTM, Philadelphia, 1988. STP 942.
[C.13] Nazmy
M.Y. High-Temperature Low Cycle Fatigue Behaviour and Lifetime Prediction of a
Nickel-Base ODS Alloy. In Low Cycle Fatigue, pages 385-398, ASTM, Philadelphia,
1988. STP 942.
[C.14] Soo
P., Chow J.G.Y. Development of a Procedure for Estimating the High Cycle
Fatigue Strength of Some High Temperature Structural Alloys. Journal of
Engineering Materials and Technology, Transactions of the ASME, 97-103, 1981.
[C.15] Chieragatti
R., Rémy L. The Low Cycle Fatigue Behaviour of MAR-M200 Single Crystals at
650ºC. In Basic Mechanisms in Fatigue of Metals, Proceedings of the
International Colloquium at Brno, Czechoslovak, pages 133-140, Institute of
Physical Metallurgy of the Czechoslovak Academy of Scienes, Brno, 12. - 14.
April 1988.
[C.16] Lukáš
P., Kunz L. Effect of Mean Stress on Cyclic Stress-Strain Response and High
Cycle Fatigue Life. International Journal of Fatigue, 11(No. 1):55-58, January
1989.
[C.17] Saxena
A., Antolovich S.D. Low Cycle Fatigue, Fatigue Crack Propagation and
Substructures in a Series of Polycrystalline Cu-Al Alloys. Metallurgical
Transactions, 6A:1809-1828, September 1975.
[C.18] Wang
G.-X., Bomas H. Cyclic Material Properties of Copper-Base Alloys. 1987. private
conununication.
[D.1] Abel
A. Comparison of Low Cycle Axial, Rotating and Bending Fatigue of Aluminium
Alloys. In Rie K.-T., editor, Proceedings of the 2nd International Conference
on Low Cycle Fatigue and Elasto-Plastic Behavior of Materials, pages 610-615,
München, September 1987.
[D.2] Chung
Y.S., Abel A. Low Cycle Fatigue of Some Aluminium Alloys. In Low Cycle Fatigue,
pages 94-106, ASTM, Philadelphia, 1988. STP 942.
[D.3] Vormwald
M, Seeger T. Zyklisches Spannungs-Dehnungs-Verhalten der Aluminiumlegierung Al
2024-FC(B) ermittelt mit Incremental-Step-Tests. Technical Report FI-9/1988,
Fachgebiet Werkstoffmechanik TH Darmstadt, 1988.
[D.4] Trautmann
K.H., Nowack H. Cyclic Material Properties of Aluminium Alloys. 1989. private
communication.
[D.5] Detert
K., Scheffel R. Low Cycle Fatigue of Al-Mg-Si Alloys. In Low Cycle Fatigue,
pages 765-775, ASTM, Philadelphia, 1988. STP 942.
[D.6] Bernstein
H., Loeby C. Low-Cycle Corrosion Fatigue of Three Engineering Alloys in Salt
Water. Journal of Engineering Materials and Technology, Transactions of the
ASME, 110:234-239, July 1988.
[D.7] Bergmann
J.W. Zur Betriebsfestigkeitsbemessung gekerbter Bauteile auf der Grundlage der
örtlichen Beanspruchungen. Institut für Stahlbau und Werkstoffmechanik TH
Darmstadt, 1983. Heft 37.
[D.8] Stephens
R.I. The Influence of Microstructure on the Fatigue Behaviour of A356-T6 Cast
Aluminium Alloy. In Basic Mechanism in Fatigue of Metals, Proceedings of the
International Colloquium at Brno, Czechoslovak, pages 185-195, Institute of
Physical Metallurgy of the Czechoslovak Academy of Scienes, Brno, 12. - 14.
April 1988.
[D.9] Srivatsan
T.S. Mechanisms of Damage in High-Temperature, Low Cycle Fatigue of an
Aluminium Alloy. International Journal of Fatigue, 10(No. 2):91-99, April 1988.
[D.10] Srivatsan
T.S., Coyne E.J. jr. Cyclic Stress Response and Deformation Behaviour of
Precipitation-Hardened Aluminium-Lithium Alloys. International Journal of
Fatigue, 8(No. 4):201-208, October 1986.
[D.11] Plumbrigde
W.J., Stanley M. Low Cycle Fatigue of a Titanium 829 Alloy. International
Journal of Fatigue, 8(No. 4):209-216, October 1986.
[E.1] Lang
K.H. Das Ermüdungsverhalten von GGG-60, GGG-40,GGV-30 und GG-30 im
Temperaturbereich 20 ºC ≤ T ≤ 500 ºC. Dissertation, Universität
Karlsruhe, 1985.
[E.2] Lang
K.H., Eifler D., Macherauch E. Cyclic Deformation Behaviour of Cast Irons with
Various Graphite Shapes in the Temperature Range 20 °C < T < 500 °C. In
Fatigue `87, Third International Conference on Fatigue and Fatigue Thresholds
at the University of Virginia, pages 627-636, Engineering Materials Advisory
Services Ltd., Charlottesville, Virginia. 28. June - 3. July 1987.
[E.3] Onodera
H, Ro Y., Yamagata T., Yamazaki M. The Effect of Tensile Strength and Ductility
on High- Temperature Low-Cycle Fatigue of Cast Ni-Base Superalloys.
Transactions of National Research Institute for Metals, 28(No. 2):112-120,
1986.
[E.4] Anton
D.L., Favrow L.H. Effect of HIP on Elevated-Temperature Low Cycle Fatigue
Properties of an Equiaxed Cast Superalloy. In Low Cycle Fatigue, pages 824-837,
ASTM, Philadelphia, 1988. STP 942.
[E.5] Nishijima
S. et al. Data Sheets on Fatigue Properties for Weld and HAZ Materials of SB42
(C-Si, 420N/mm2 TS) Carbon Steel Plate for Boiler and Other Pressure Vessels.
Technical Report No. 57, NRIM Fatigue Data Sheet, National Research Insitute
for Metals, Decemher 1987.
[E.6] Rie
K.-T., Schmidt R.-M. High Temperature Low-Cycle Fatigue of Austenitic and
Ferritic Weldments. In ECF 6, Fracture Control of Engineering Structures, pages
1,097-1,113, 1986.
[E.7] Kußmaul
K., Weiblen W. Characterization of the Cyclic Material Properties of Shape Welded
Tempered and Quenched Steels 10 MnMoNi 5 5 and 20 NiCrMoV 14 5. In Rie K.-T.,
editor, Proceedings of the 2nd International Conference on Low Cycle Fatigue
and Elasto-Plastic Behavior of Materials, pages 443-448, München, September
1987.
[F.1] Smith
R.W., Hirschberg M.H., Manson S.S. Fatigue Behavior of Materials under Strain
Cycling in Low and Intermediate Life Range. Technical Report Technical Note
D-1574, NASA National Aeronautics and Space Administration, April 1963.
[F.2] Boller
C., Heuler P., Seeger T., Buxbaum O., Oppermann H., Köbler H.-G., Schütz D.
Vergleich der Lebensdauervorhersage nach dem Kerbgrundkonzept und dem
Nennspannungskonzept. Technical Report FD-5/1983, Fachgebiet Werkstoffmechanik
TH Darmstadt, Fraunhofer-Institut für Betriebsfestigkeit (LBF), Darmstadt,
1983.
[F.3] Klee
S. Das zyklische Spannungs-Dehnungs- und Bruchverhalten verschiedener Stähle.
Technical Report No. 22, Institut für Statik und Stahlbau TH Darmstadt, 1973.
[F.4] Boller
C., Heuler P., Seeger T., Buxbaum O., Oppermann H., Köbler H.-G., Schütz D.
Vergleich der Lebe.sdauervorhersage nach dem Kerbgrundkonzept und dem
Nennspannungskonzept. Technical Report FD-5/1983, Fachgebiet Werkstoffmechanik
TH Darmstadt, Fraunhofer-Institut für Betriebsfestigkeit (LBF), Darmstadt,
1983.
[F.5] Bergmann
J.W. Zur Betriebsfestigkeitsbemessung gekerbter Bauteile auf der Grundlage der
örtlichen Beanspruchungen. Institut für Stahlbau und Werkstoffmechanik TH
Darmstadt, 1983. Heft 37.´
[F.6] Kurath
P. Cyclic Material Properties of Aluminium Alloys. private communication.
[F.7] Bergmann
J.W. Zur Betriebsfestigkeitsbernessung gekerbter Bauteile auf der Grundlage der
örtlichen Beanspruchungen. Institut für Stahlbau und Werkstoffmechanik TH
Darmstadt, 1983. Heft 37.
top | back | home
| 
