Time-optimal feedback system with identifier to control induction heating process

Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

Authors

  • Yuliya Pleshivtseva
  • I. Levin
  • Bernard Nacke
  • Martin Ennen
  • Alexandre Nikanorov

Research Organisations

External Research Organisations

  • Samara State Technical University
View graph of relations

Details

Original languageEnglish
Title of host publicationProceeding of XIX International UIE-Congress on Electrotechnologies for Material Processing
Subtitle of host publicationPlzen (Czech Republic), September 2-3
Pages197-202
Publication statusPublished - Sept 2021

Abstract

This paper deals with numerical modeling of longitudinal high-frequency (HF) induction welding of cladded pipes using double frequency approach. Solutions are proposed to reach the required temperature distribution at the welding edge for the cladding composite of S355 and Alloy 625 with single and double frequencies. An advanced consideration of magnetic and other material properties was performed to simulate the dominating physical effects of HF welding. By the use of FEM analysis, the theoretical capability of an inductive longitudinal welding process for cladded pipes has been demonstrated. Despite some simplifications, the dominating effects of the longitudinal welding were considered by the presented model. In the context of the research, a correlation for welding speed, welding frequency and temperature distribution with industrial relevance was found for the cladded pipe welding. Industrial scale process windows for both, single frequency and simultaneous double frequency is presented in this work.

Keywords

    cladded pipes, induction high-frequency welding, numerical modeling

ASJC Scopus subject areas

Cite this

Time-optimal feedback system with identifier to control induction heating process. / Pleshivtseva, Yuliya; Levin, I.; Nacke, Bernard et al.
Proceeding of XIX International UIE-Congress on Electrotechnologies for Material Processing: Plzen (Czech Republic), September 2-3. 2021. p. 197-202.

Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

Pleshivtseva, Y, Levin, I, Nacke, B, Ennen, M & Nikanorov, A 2021, Time-optimal feedback system with identifier to control induction heating process. in Proceeding of XIX International UIE-Congress on Electrotechnologies for Material Processing: Plzen (Czech Republic), September 2-3. pp. 197-202. <http://hdl.handle.net/11025/45770>
Pleshivtseva, Y., Levin, I., Nacke, B., Ennen, M., & Nikanorov, A. (2021). Time-optimal feedback system with identifier to control induction heating process. In Proceeding of XIX International UIE-Congress on Electrotechnologies for Material Processing: Plzen (Czech Republic), September 2-3 (pp. 197-202) http://hdl.handle.net/11025/45770
Pleshivtseva Y, Levin I, Nacke B, Ennen M, Nikanorov A. Time-optimal feedback system with identifier to control induction heating process. In Proceeding of XIX International UIE-Congress on Electrotechnologies for Material Processing: Plzen (Czech Republic), September 2-3. 2021. p. 197-202
Pleshivtseva, Yuliya ; Levin, I. ; Nacke, Bernard et al. / Time-optimal feedback system with identifier to control induction heating process. Proceeding of XIX International UIE-Congress on Electrotechnologies for Material Processing: Plzen (Czech Republic), September 2-3. 2021. pp. 197-202
Download
@inproceedings{1f65570e12c54eba84ffa2d39c81a5ac,
title = "Time-optimal feedback system with identifier to control induction heating process",
abstract = "This paper deals with numerical modeling of longitudinal high-frequency (HF) induction welding of cladded pipes using double frequency approach. Solutions are proposed to reach the required temperature distribution at the welding edge for the cladding composite of S355 and Alloy 625 with single and double frequencies. An advanced consideration of magnetic and other material properties was performed to simulate the dominating physical effects of HF welding. By the use of FEM analysis, the theoretical capability of an inductive longitudinal welding process for cladded pipes has been demonstrated. Despite some simplifications, the dominating effects of the longitudinal welding were considered by the presented model. In the context of the research, a correlation for welding speed, welding frequency and temperature distribution with industrial relevance was found for the cladded pipe welding. Industrial scale process windows for both, single frequency and simultaneous double frequency is presented in this work.",
keywords = "cladded pipes, induction high-frequency welding, numerical modeling",
author = "Yuliya Pleshivtseva and I. Levin and Bernard Nacke and Martin Ennen and Alexandre Nikanorov",
note = "Funding Information: The work is partly supported by Russian Foundation for Basic Researches (project №19-08-00232).",
year = "2021",
month = sep,
language = "English",
pages = "197--202",
booktitle = "Proceeding of XIX International UIE-Congress on Electrotechnologies for Material Processing",

}

Download

TY - GEN

T1 - Time-optimal feedback system with identifier to control induction heating process

AU - Pleshivtseva, Yuliya

AU - Levin, I.

AU - Nacke, Bernard

AU - Ennen, Martin

AU - Nikanorov, Alexandre

N1 - Funding Information: The work is partly supported by Russian Foundation for Basic Researches (project №19-08-00232).

PY - 2021/9

Y1 - 2021/9

N2 - This paper deals with numerical modeling of longitudinal high-frequency (HF) induction welding of cladded pipes using double frequency approach. Solutions are proposed to reach the required temperature distribution at the welding edge for the cladding composite of S355 and Alloy 625 with single and double frequencies. An advanced consideration of magnetic and other material properties was performed to simulate the dominating physical effects of HF welding. By the use of FEM analysis, the theoretical capability of an inductive longitudinal welding process for cladded pipes has been demonstrated. Despite some simplifications, the dominating effects of the longitudinal welding were considered by the presented model. In the context of the research, a correlation for welding speed, welding frequency and temperature distribution with industrial relevance was found for the cladded pipe welding. Industrial scale process windows for both, single frequency and simultaneous double frequency is presented in this work.

AB - This paper deals with numerical modeling of longitudinal high-frequency (HF) induction welding of cladded pipes using double frequency approach. Solutions are proposed to reach the required temperature distribution at the welding edge for the cladding composite of S355 and Alloy 625 with single and double frequencies. An advanced consideration of magnetic and other material properties was performed to simulate the dominating physical effects of HF welding. By the use of FEM analysis, the theoretical capability of an inductive longitudinal welding process for cladded pipes has been demonstrated. Despite some simplifications, the dominating effects of the longitudinal welding were considered by the presented model. In the context of the research, a correlation for welding speed, welding frequency and temperature distribution with industrial relevance was found for the cladded pipe welding. Industrial scale process windows for both, single frequency and simultaneous double frequency is presented in this work.

KW - cladded pipes

KW - induction high-frequency welding

KW - numerical modeling

M3 - Conference contribution

SP - 197

EP - 202

BT - Proceeding of XIX International UIE-Congress on Electrotechnologies for Material Processing

ER -

By the same author(s)

  1. Induction tempering of surface hardenend components

    Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

  2. Optimal programmed control of mass induction heating with guaranteed quality

    Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

  3. Magnetic Properties Identification by Using a Bi-Objective Optimal Multi-Fidelity Neural Network

    Research output: Contribution to journalArticleResearchpeer review

  4. Solving 1D non-linear magneto quasi-static Maxwell's equations using neural networks

    Research output: Contribution to journalArticleResearchpeer review

  5. Dynamische Querfelderwärmung: Erzeugung maßgeschneiderter Temperaturfelder in Flachstählen

    Research output: Chapter in book/report/conference proceedingConference contributionResearch