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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
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[2.6] Reik
W., Mayr P., Macherauch E.
Untersuchungen zum Schwingfestigkeitsverhalten von Ck 45
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[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
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Proc. of Nippon Zoosen Gakkai, (in Japanese), 1984, pp. 511 - 521
[2.20] Fugger
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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
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[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
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