Microstructural evaluation of the high-frequency induction welded joints of low carbon steel pipes

Bunsch, Adam; Krawczyk, Janusz; Matusiewicz, Piotr

doi:10.2478/adms-2021-0022

Artykuł - szczegóły

Tytuł artykułu

Microstructural evaluation of the high-frequency induction welded joints of low carbon steel pipes

Autorzy

Bunsch Adam , Krawczyk Janusz , Matusiewicz Piotr

Wybrane pełne teksty z tego czasopisma

http://content.sciendo.com/view/journals/adms/adms-overview.xml

Identyfikatory

DOI

10.2478/adms-2021-0022

Warianty tytułu

Języki publikacji

Abstrakty

The work presents the results of research on the structure of welded joints in the area of heat affected zone (HAZ). Based on precisely performed metallographic tests, the contribution of individual structural components in the area of welds of pipes welded with the induction method was assessed. The volume fraction of individual structural components in various areas of the heat affected zone, the size of the grain formed in the welding process, as well as its shape coefficients were determined. On the basis of metallographic observations, an attempt was made to describe the course of the pressure induction welding process, taking into account the structural changes, phase changes and the recovering and recrystallization processes taking place in this process.

Słowa kluczowe

welding joints heat affected zone structure changes recovering recrystallization

połączenie spawane strefa wpływu ciepła zmiany struktury odzyskiwanie rekrystalizacja

Wydawca

Politechnika Gdańska

Czasopismo

Advances in Materials Science

Rocznik

2021

Tom

Vol. 21, nr 4(70)

Strony

19--33

Opis fizyczny

Bibliogr. 30 poz., tab., fot., il., wykr.

Twórcy

autor

Bunsch Adam

abunsch@agh.edu.pl

AGH University of Science and Technology, Faculty of Metals Engineering and Industrial Computer Science, Department of Physical and Powder Metallurgy, 30-059 Cracow, Poland

autor

Krawczyk Janusz

AGH University of Science and Technology, Faculty of Metals Engineering and Industrial Computer Science, Department of Physical and Powder Metallurgy, 30-059 Cracow, Poland

autor

Matusiewicz Piotr

AGH University of Science and Technology, Faculty of Metals Engineering and Industrial Computer Science, Department of Physical and Powder Metallurgy, 30-059 Cracow, Poland

Bibliografia

1. Sajek A., Welding Thermal Cycles of Joints Made of S1100QL Steel by Saw and Hybrid Plasma-Mag Processes, Adv. Mater. Sci. 20 (2020) 75–86.
2. Ziewiec A., Tasak E., Witkowska M., Ziewiec K., Microstructure and Properties of Welds of Semi-Austenitic Precipitation Hardening Stainlees Steel after Heat Treatment, Arch. Metall. Mater. 58 (2013) 613–617.
3. Janiczak R., Pańcikiewicz K.,, Laser welding of austenitic ferrofluid container for the KRAKsat satellite, Weld. World. 65 (2021) 1347–1357.
4. Kocurek R., Adamiec J., The Repair Welding Technology of Casts Magnesium Alloy QE22, Solid State Phenom. 212 (2013) 81–86.
5. Górka J., Przybyła M., Szmul M., Chudzio A., Ładak D., Orbital TIG Welding of Titanium Tubes with Perforated Bottom Made of Titanium-Clad Steel, Adv. Mater. Sci. 19 (2019) 55–64.
6. Adamiec J., Pfeifer T., Rykała J., CMT and MIG-Pulse Robotized Welding of Thin-Walled Elements Made of 6xxx and 2xxx Series Aluminium Alloys, Solid State Phenom. 191 (2012) 45–56.
7. De Backer M., Van Minnebruggen K., De Waele W., The influence of material anisotropy and spiral welding on tensile strain capacity of spiral welded pipes, Int. J. Sustain. Constr. Des. 6 (2015) 9.
8. Simion P., Dia V., Istrate B., Hrituleac G., Hrituleac I., Munteanu C., Study of fatigue behavior of longitudinal welded pipes, IOP Conf. Ser. Mater. Sci. Eng. 145 (2016).
9. EN ISO 3183: Petroleum and natural gas industries - Steel pipe for pipeline transportation systems, 2020.
10. Liu C., Bhole S.D., Challenges and developments in pipeline weldability and mechanical properties, Sci. Technol. Weld. Join. 18 (2013) 169–181.
11. Simion P., Dia V., Istrate B., Munteanu C., Controlling and Monitoring of Welding Parameters for Micro-Alloyed Steel Pipes Produced by High Frequency Electric Welding, Adv. Mater. Res. 1036 (2014) 464–469.
12. Chen Z., Chen X., Zhou T., Microstructure and Mechanical Properties of J55ERW Steel Pipe Processed by On-Line Spray Water Cooling, Metals (Basel). 7 (2017) 150.
13. Sabzi M., Kianpour-Barjoie A., Ghobeiti-Hasab M., Mersagh Dezfuli S., Effect of High-Frequency Electric Resistance Welding (HF-ERW) Parameters on Metallurgical Transformations and Tensile Properties of API X52 Microalloy Steel Welding Joint, Arch. Metall. Mater. 63 (2018) 1693–1699.
14. Merchant V.E., Laser welding in the pipeline industry, in: D. Belforte (Ed.), Ind. Laser Handb., Springer-Verlag New York Inc., 1992, 91–88.
15. Nowacki J., Sajek A., Matkowski P., The influence of welding heat input on the microstructure of joints of S1100QL steel in one-pass welding, Arch. Civ. Mech. Eng. 16 (2016) 777–783.
16. Pańcikiewicz K., Structure and Properties of Welded Joints of 7CrMoVTiB10-10 (T24) Steel, Adv. Mater. Sci. 18 (2018) 37–47.
17. Ziewiec A., Tasak E., Zielińska-Lipiec A., Ziewiec K., Kowalska J., The influence of rapid solidification on the microstructure of the 17Cr–9Ni–3Mo precipitation hardened steel, J. Alloys Compd. 615 (2014) 627–S632.
18. Rakoczy Ł., Grudzień M., Zielińska-Lipiec A., Contribution of Microstructural Constituents on Hot Cracking of Mar-M247 Nickel Based Superalloy, Arch. Metall. Mater. 63 (2018) 181–189.
19. Pańcikiewicz K., Radomski W., Lack of tightness analysis of concealed welded radiators, Eng. Fail. Anal. 114 (2020) 104579.
20. Güngör Ö.E., Yan P., Thibaux P., Liebeherr M., Bhadeshia H.K.D.H., Quidort D., Investigations Into the Microstructure–Toughness Relation in High Frequency Induction Welded Pipes, 8th Int. Pipeline Conf. Vol. 2, ASMEDC (2010) 577–585.
21. Yan P., High frequency induction welding & post-welding heat treatment of steel pipes, University of Cambridge, 2011.
22. Yan P., Güngör Ö.E., Thibaux P., Liebeherr M., Bhadeshia H.K.D.H., Tackling the toughness of steel pipes produced by high frequency induction welding and heat-treatment, Mater. Sci. Eng. A. 528 (2011) 8492–8499.
23. Śloderbach Z., Pająk J., Determination of Ranges of Components of Heat Affected Zone Including Changes of Structure, Arch. Metall. Mater. 60 (2015) 2607–2612.
24. Udhayakumar T., Mani E., Effect of HF Welding Process Parameters and Post Heat Treatment in the Development of Micro Alloyed HSLA Steel Tubes for Torsional Applications, J. Mater. Sci. Eng. 06 (2017).
25. Zhang W., Zhao G., Fu Q., Study on the effects and mechanisms of induction heat treatment cycles on toughness of high frequency welded pipe welds, Mater. Sci. Eng. A. 736 (2018) 276–287.
26. de Santana I.J., Paulo B., Modenesi P.J., High frequency induction welding simulating on ferritic stainless steels, J. Mater. Process. Technol. 179 (2006) 225–230.
27. Matusiewicz P., Czarski A., Adrian H., Estimation of materials microstructure parameters using computer program SigmaScan Pro, Metall. Foundry Eng. 33 (2007).
28. Wojnar L., Kurzydłowski K., Szala J., Metallography and Microstructures, in: G.F. Vander Voort (Ed.), ASM Handbook, Vol. 9. Metallogr. Microstruct., ASM Int, 2004.
29. Szala J., Teoretyczne i praktyczne aspekty ilościowego opisu struktury stali ferrytyczno-perlitycznych, Hut. - Wiadomości Hut. 1 (2018) 22–28.
30. Krawczyk J., Adrian H., The kinetics of austenite grain growth in steel for wind power plant shafts, Arch. Metall. Mater. 55 (2010) 91–99.

Uwagi

The work was performed under the project No. 16.16.110.663. The authors of the work thank for graduate students Mateusz Mądry and Tomasz Kaleta for preparing microscopic documentation and participating in the preparation of some metallographic analyzes.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-010c106a-4a0f-4297-9697-d9b86f1e5cb8