Friction welding (FWR) is a solid-state welding and bonding process that generates heat through mechanical friction between workpieces in relative motion to one another. The process is used with the addition of a lateral force called "upset" to plastically displace and fuse the materials.[1] Friction welding is a solid-state welding technique similar to forge welding. Instead of a fusion welding process, Friction welding is used with metals and thermoplastics in a wide variety of aviation and automotive applications.

The ISO norm of friction welding is EN ISO 15620:2019,[2] which contains information about the basic terms, definitions, and tables of the weldability of metals and alloys.

History

edit
 
Historical photo of a double spindle machine for rotary friction welding

Some applications and patents connected with friction welding dates back to the turn of the 20th century,[3] and rotary friction welding is the oldest of the methods.[4] W. Richter patented the method of linear friction welding (LFW) process in 1924[5] in England and 1929[5] in the Weimar Republic. The description of the process was vague[4] and H. Klopstock patented the process in the Soviet Union in 1924.[5] The first description and experiments related to rotary friction welding took place in the Soviet Union in 1956,[3][5] when a machinist named A. I. Chudikov researched scientific studies and suggested the use of the welding method as a commercial process.[5] The process was introduced to the United States in 1960.[3] The American companies Caterpillar Tractor Company (Caterpillar - CAT), Rockwell International, and American Manufacturing Foundry all developed machines for the process. Patents were also issued throughout Europe and the Soviet Union. The first studies of friction welding in England were carried out by the Welding Institute in 1961.[5]

In the United States, Caterpillar Inc. and Manufacturing Technology Inc. (MTI) developed an inertia process in 1962.[3][5] In Europe, KUKA AG and Thompson launched rotary friction welding for industrial applications in 1966,[6] developed a direct-drive process, and in 1974,[6] built the rRS6 double spindle machine for heavy truck axles.[6] Another method was invented in the Soviet Union by Yu. Klimenko in the mid-1960s and patented in 1967,[7] experimentally proven and developed into a commercial technology at The Welding Institute (TWI) in the United Kingdom and patented again in 1991: the friction stir welding (FSW) process,[8] is a solid-state joining process that uses a non-consumable tool to join two facing workpieces without melting the workpiece material.

An improved modification of the standard friction welding technique is low force friction welding, a hybrid technology developed by EWI and MTI, which "uses an external energy source to raise the interface temperature of the two parts being joined, thereby reducing the process forces required to make a solid-state weld compared to traditional friction welding".[9] The process applies to both linear and rotary friction welding.[10]

Metal techniques

edit

Friction welding takes many forms but the following are the most popular methods used.[11]

Rotary friction welding

edit
 
Rotary friction welding

Rotary friction welding (RFW) is one of the main methods of friction welding. One welded element is rotated relative to the other and pressed down. The heating of the material is caused by friction work and creates a non-separable weld.[12]

Linear friction welding

edit

Linear friction welding (LFW) is the act of moving a single component in a linear reciprocating motion across the face of a stationary component.[13][14]

Friction stir welding

edit
 
Friction stir welding

Friction stir welding (FSW) is a solid-state joining process that uses a non-consumable tool to join two facing workpieces without melting the workpiece material. Heat is generated by friction between the rotating tool and the workpiece material, which leads to a softened region near the FSW tool. While the tool is traversed along the joint line, it mechanically intermixes the two pieces of metal and forges the hot and softened metal by the mechanical pressure which is applied by the tool.

Friction surfacing

edit

Friction surfacing is a process derived from friction welding where a coating material is applied to a substrate. A rod composed of the coating material (called a mechtrode) is rotated under pressure, generating a plasticized layer in the rod at the interface with the substrate.

Thermoplastic technique

edit

Linear vibration welding

edit

In linear vibration welding, the materials are placed in contact and put under pressure. An external vibration force is then applied to slip the pieces relative to each other, perpendicular to the pressure being applied.

Orbital friction welding

edit

Orbital friction welding is similar to spin welding, but uses a more complex machine to produce an orbital motion in which the moving part rotates in a small circle, much smaller than the size of the joint as a whole.

Method list connected to friction welding

edit

Other information

edit

Welds tests for friction welding and description of zones

edit

Quality requirements of welded joints depend on the form of application, e.g. in the space or flight industry, weld errors are not allowed.[21] Weld quality tests assurance is performed, with measurements and numerical methods.

For example, an ultra-fine grain structure of alloy or metal which is obtained by techniques such as severe plastic deformation[22] is desirable, and not changed by the high temperature, a large heat affected zone is unnecessary.[23][17]

In addition to changing the grain structure during metal joining cycles, by methods where high temperature affected zone was occur, are phase transformations structure. For example, in steel between austenite, ferrite, pearlite, bainite,[24] cementite, and martensite, (See: Iron-carbon phase diagram).[citation needed] In order to avoid changes, solid state welding may be desired and large heat affected zone is not needed if weakens the material properties.

Heat and mechanical affected zones in friction weld

edit
 
Picture shows weld zones in friction welding.[16]

Individual thermomechanical zones can be described by citing an example article:

Anthony R. McAndrew, Paul A. Colegrove, Clement Bühr, Bertrand C.D., Flipo Achilleas Vairis, "A literature review of Ti-6Al-4V linear friction welding", 2018.[16]

Technically, the WCZ and the TMAZ are both "thermo-mechanically affected zones"; due to the different microstructures they possess, they are often considered separately. The WCZ experiences significant dynamic recrystallisation (DRX), the TMAZ does not. The material in HAZ is not deformed mechanically but is affected by the heat. The region from one TMAZ/HAZ boundary to the other is often referred to as the "TMAZ thickness" or the plastically affected zone (PAZ).[25]

Zones:

  • WCZ– weld center zone
  • HAZ – heat affected zone
  • TMAZ – Thermo-mechanically affected zone
  • BM – base material, parent material
  • Flash

Similar terms are used in welding.

Seizure resistance

edit

Friction welding may unintentionally occur at sliding surfaces like bearings. This happens in particular if the lubricating oil film between sliding surfaces becomes thinner than the surface roughness, which may be due to low speed, low temperature, oil starvation, excessive clearance, low viscosity of the oil, high roughness of the surfaces, or a combination thereof.[26]

The seizure resistance is the ability of a material to resist friction welding. It is a fundamental property of bearing surfaces and in general of sliding surfaces under load.

Curiosities

edit

Terms and definitions, name shortcuts

edit

From ISO's (the International Organization for Standardization) - ISO 15620:2019(en) Welding — Friction welding of metallic materials:

axial force - force in axial direction between components to be welded,

burn-off length - loss of length during the friction phase,

burn-off rate - rate of shortening of the components during the friction welding process,

component - single item before welding,

component induced braking - reduction in rotational speed resulting from friction between the interfaces,

external braking - braking located externally reducing the rotational speed,

faying surface - surface of one component that is to be in contact with a surface of another component to form a joint,

forge force - force applied normal to the faying surfaces at the time when relative movement between the components is ceasing or has ceased,

forge burn-off length - amount by which the overall length of the components is reduced during the application of the forge force,

forge phase - interval time in the friction welding cycle between the start and finish of application of the forge force,

forge pressure - pressure (force per unit area) on the faying surfaces resulting from the axial forge force,

forge time - time for which the forge force is applied to the components,

friction force - force applied perpendicularly to the faying surfaces during the time that there is relative movement between the components,

friction phase - interval time in the friction welding cycle in which the heat necessary for making a weld is generated by relative motion and the friction forces between the components i.e. from contact of components to the start of deceleration,

friction pressure - pressure (force per unit area) on the faying surfaces resulting from the axial friction force,

friction time - time during which relative movement between the components takes place at rotational speed and under application of the friction forces,

interface - contact area developed between the faying surfaces after completion of the welding operation,

rotational speed - number of revolutions per minute of rotating component

stick-out - distance a component sticks out from the fixture, or chuck in the direction of the mating component,

deceleration phase - interval in the friction welding cycle in which the relative motion of the components is decelerated to zero,

deceleration time - time required by the moving component to decelerate from friction speed to zero speed,

total length loss (upset) - loss of length that occurs as a result of friction welding, i.e. the sum of the burn-off length and the forge burn-off length,

total weld time - time elapsed between component contact and end of forging phase,

welding cycle - succession of operations carried out by the machine to make a weldment and return to the initial position, excluding component-handling operations,

weldment - two or more components joined by welding.[2]

References

edit
  1. ^ "Friction Welding - an overview | ScienceDirect Topics". www.sciencedirect.com. Retrieved 2023-05-10.
  2. ^ a b "EN ISO 15620:2019". www.iso.org. Retrieved 2020-12-28.
  3. ^ a b c d Wen Lin, K. K. Wang (1974). "Flywheel Friction Welding Research" (PDF). Supplement to the Welding Journal.
  4. ^ a b J. LOPERA, K. MUCIC, F. FUCHS, N. ENZINGER (October 2012). "Linear Friction Welding Of High Strength Chains: Modelling And Validation". Mathematical Modelling of Weld Phenomena. 10.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  5. ^ a b c d e f g Mehmet UZKUT, Bekir Sadık ÜNLÜ, Selim Sarper YILMAZ, Mustafa AKDAĞ. "Friction Welding And Its Applications In Today's World" (PDF).{{cite web}}: CS1 maint: multiple names: authors list (link)
  6. ^ a b c "Rotary friction welding machines". KUKA AG. Retrieved 2020-12-27.
  7. ^ "SU195846A1 - Method of welding metal by Friction". Google Patents. 20 April 2006. Retrieved 22 May 2023.
  8. ^ a b Thomas, W.M., Nicholas, E.D., Needham, J.C., Murch, M.G., Templesmith, P., Dawes, C. J., 1991. Improvements to Friction Welding. GB Patent Application No. 91259788.
  9. ^ a b Jones, Simon. "Low Force Friction Welding -- What is it?". blog.mtiwelding.com. Retrieved 2020-12-28.
  10. ^ Zurawski, Pawel (January 7, 2022). "Analysis of low force friction welding process in the industrial environment" (PDF). International Journal of Engineering and Innovative Technology. 11 (7): 1–9. doi:10.51456/IJEIT.2022.v11i07.001. S2CID 247075337.
  11. ^ "Friction Welding 101: Whiteboard Wednesday". blog.mtiwelding.com. Retrieved 2023-07-06.
  12. ^ "Rotary Friction Welding - Job Knowledge". www.twi-global.com. Retrieved 2023-07-06.
  13. ^ "What is Friction Stir Welding (FSW)? - Process and Applications". www.twi-global.com. Retrieved 2023-07-06.
  14. ^ "What is Linear Friction Welding?". www.twi-global.com. Retrieved 2023-07-06.
  15. ^ Lacki, P.; Kucharczyk, Z.; Śliwa, R.E.; Gałaczyński, T. (2013-06-01). "Effect of Tool Shape on Temperature Field in Friction Stir Spot Welding". Archives of Metallurgy and Materials. 58 (2): 595–599. doi:10.2478/amm-2013-0043. ISSN 1733-3490.
  16. ^ a b c McAndrew, Anthony R.; Colegrove, Paul A.; Bühr, Clement; Flipo, Bertrand C.D.; Vairis, Achilleas (2018-10-03). "A literature review of Ti-6Al-4V linear friction welding". Progress in Materials Science. 92: 225–257. doi:10.1016/j.pmatsci.2017.10.003. ISSN 0079-6425.
  17. ^ a b Orłowska, Marta; Olejnik, Lech; Campanella, Davide; Buffa, Gianluca; Morawiński, Łukasz; Fratini, Livan; Lewandowska, Małgorzata (2020). "Application of linear friction welding for joining ultrafine grained aluminium". Journal of Manufacturing Processes. 56. Elsevier BV: 540–549. doi:10.1016/j.jmapro.2020.05.012. hdl:10447/421431. ISSN 1526-6125.
  18. ^ Pissanti, Daniela Ramminger; Scheid, Adriano; Kanan, Luis Fernando; Dalpiaz, Giovani; Kwietniewski, Carlos Eduardo Fortis (January 2019). "Pipeline girth friction welding of the UNS S32205 duplex stainless steel". Materials & Design. 162: 198–209. doi:10.1016/j.matdes.2018.11.046. ISSN 0264-1275.
  19. ^ Buzzatti, Diogo Trento; Chludzinki, Mariane; Santos, Rafael Eugenio dos; Buzzatti, Jonas Trento; Lemos, Guilherme Vieira Braga; Mattei, Fabiano; Marinho, Ricardo Reppold; Paes, Marcelo Torres Piza; Reguly, Afonso (2019). "Toughness properties of a friction hydro pillar processed offshore mooring chain steel". Journal of Materials Research and Technology. 8 (3): 2625–2637. doi:10.1016/j.jmrt.2019.04.002. ISSN 2238-7854.
  20. ^ Buzzatti, Diogo Trento; Buzzatti, Jonas Trento; Santos, Rafael Eugenio dos; Mattei, Fabiano; Chludzinski, Mariane; Strohaecker, Telmo Roberto (2015). "Friction Hydro Pillar Processing: Characteristics and Applications". Soldagem & Inspeção. 20 (3): 287–299. doi:10.1590/0104-9224/si2003.04. hdl:10183/132809. ISSN 0104-9224.
  21. ^ Pilarczyk, J.; Piotr, A. (2013). Poradnik inżyniera 1 – spawalnictwo (in Polish). Warszawa: Wydawnictwo WNT.
  22. ^ Rosochowski, Andrzej (2013). Severe plastic deformation technology. Whittles Publishing. ISBN 9781849951197. OCLC 968912427.
  23. ^ T. Chmielewski, W. Pachla, M. Kulczyk, J. Skiba, W. Presz, B. Skowrońska (2019). "Friction Weldability Of UFG 316L Stainless Steel" (PDF). Arch. Metall. Mater. 64: 1051–1058. doi:10.24425/amm.2019.129494.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  24. ^ Parzych, S.; Krawczyk, J. (2012-01-01). "The Influence of Heat Treatment on Microstructure and Tribological Properties of Resistance Butt Welds Made of a Cast Bainitic Steel". Archives of Metallurgy and Materials. 57 (1). doi:10.2478/v10172-012-0020-9. ISSN 1733-3490.
  25. ^ Clement Bühr, Paul A.Colegrove, Bertrand C.D.Flipo, Achilleas Vairis, Anthony R.McAndrew (2018-03-01). "A literature review of Ti-6Al-4V linear friction welding". Progress in Materials Science. 92: 225–257. doi:10.1016/j.pmatsci.2017.10.003. ISSN 0079-6425.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  26. ^ Requirements to engine bearing materials, SubsTech
  27. ^ Wang, Kaifeng; Khan, Haris Ali; Li, Zhiyi; Lyu, Sinuo; Li, Jingjing (October 2018). "Micro friction stir welding of multilayer aluminum alloy sheets". Journal of Materials Processing Technology. 260: 137–145. doi:10.1016/j.jmatprotec.2018.05.029. ISSN 0924-0136. S2CID 140028992.
  28. ^ Wood Welding, How is it possible? Youtube link, archived from the original on 2021-12-12, retrieved 2021-04-06
  29. ^ "TWI Develops Wood Welding Process". www.twi-global.com. Retrieved 2021-04-06.
  30. ^ Li, Suxia; Zhang, Haiyang; Shu, Biqing; Cheng, Liangsong; Ju, Zehui; Lu, Xiaoning (2021). "Study on the Bonding Performance of the Moso Bamboo Dowel Welded to a Poplar Substrate Joint by High-Speed Rotation". Journal of Renewable Materials. 9 (7): 1225–1237. doi:10.32604/jrm.2021.014364. ISSN 2164-6341.