Construction of FEM belt models for determination of the indentation rolling resistance

Publikation: Beitrag in FachzeitschriftKonferenzaufsatz in FachzeitschriftForschungPeer-Review

Autorschaft

  • C. Schmidt
  • M. Kanus
  • L. Overmeyer

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Titel in ÜbersetzungConstruction of FEM belt models for determination of the indentation rolling resistance
OriginalspracheDeutsch
Seiten (von - bis)50-57
Seitenumfang8
FachzeitschriftCement International
Jahrgang20
Ausgabenummer2
PublikationsstatusVeröffentlicht - 2022

Abstract

The contribution (11 describes belt models based on the finite element method (FEM) for simulative determinations of the indentation rolling resistance (IRR) occurring at belt convey¬ors. As numerical solver the simulation software Abaqus is used. The investigated FEM belt model corresponds to an extended layer model, a further development of the layer model according to Oehmen (12J. Based on material param¬eters of the used elastomers, direct conclusions about the expected indentation rolling resistance are possible, which enables a greater preliminary analysis of potential mixing ratios of belt elastomers as well as general cost savings. Hereby our simulation is based on an IRR test of a steel rope conveyor belt carried out at the Institute of Transport and Automation Technology (ITA). With a conveying speed of 1 m/s at ambient temperatures of -30 °C, 0 °C, 20 °C and 40 °C as well as under the influence of wide-related superimposed loads of 5000 up to 10000 N/m, the chosen simulation conditions are identical to those of the previous practical test. Furthermore, the material properties of the simulated elastomer correspond to those of the tested con¬veyor belt and originate from a previous work. This enables a direct comparison and thus validation of the accuracy of the simulation model.

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Construction of FEM belt models for determination of the indentation rolling resistance. / Schmidt, C.; Kanus, M.; Overmeyer, L.
in: Cement International, Jahrgang 20, Nr. 2, 2022, S. 50-57.

Publikation: Beitrag in FachzeitschriftKonferenzaufsatz in FachzeitschriftForschungPeer-Review

Schmidt, C, Kanus, M & Overmeyer, L 2022, 'Construction of FEM belt models for determination of the indentation rolling resistance', Cement International, Jg. 20, Nr. 2, S. 50-57.
Schmidt, C., Kanus, M., & Overmeyer, L. (2022). Construction of FEM belt models for determination of the indentation rolling resistance. Cement International, 20(2), 50-57.
Schmidt C, Kanus M, Overmeyer L. Construction of FEM belt models for determination of the indentation rolling resistance. Cement International. 2022;20(2):50-57.
Schmidt, C. ; Kanus, M. ; Overmeyer, L. / Construction of FEM belt models for determination of the indentation rolling resistance. in: Cement International. 2022 ; Jahrgang 20, Nr. 2. S. 50-57.
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TY - JOUR

T1 - Construction of FEM belt models for determination of the indentation rolling resistance

AU - Schmidt, C.

AU - Kanus, M.

AU - Overmeyer, L.

PY - 2022

Y1 - 2022

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AB - The contribution (11 describes belt models based on the finite element method (FEM) for simulative determinations of the indentation rolling resistance (IRR) occurring at belt convey¬ors. As numerical solver the simulation software Abaqus is used. The investigated FEM belt model corresponds to an extended layer model, a further development of the layer model according to Oehmen (12J. Based on material param¬eters of the used elastomers, direct conclusions about the expected indentation rolling resistance are possible, which enables a greater preliminary analysis of potential mixing ratios of belt elastomers as well as general cost savings. Hereby our simulation is based on an IRR test of a steel rope conveyor belt carried out at the Institute of Transport and Automation Technology (ITA). With a conveying speed of 1 m/s at ambient temperatures of -30 °C, 0 °C, 20 °C and 40 °C as well as under the influence of wide-related superimposed loads of 5000 up to 10000 N/m, the chosen simulation conditions are identical to those of the previous practical test. Furthermore, the material properties of the simulated elastomer correspond to those of the tested con¬veyor belt and originate from a previous work. This enables a direct comparison and thus validation of the accuracy of the simulation model.

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JO - Cement International

JF - Cement International

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