Sage Journals: Discover world-class research

Abstract

Interference-fit joints are widely used in lightweight and high-speed transmission systems due to their ability to transmit high torque, resist fatigue and maintain compact geometry. However, most prior studies focused on solid shafts and similar materials overlooking the combined influence of torsion, friction and geometry in hollow shaft shrink-fits with dissimilar materials. This limitation restricts their applicability to modern engineering systems. This work presents a generalized analytical model for optimizing shrink-fit joints under torsional loading. Closed-form solutions are derived for the optimal hub and shaft aspect ratios, interference value, contact pressure as well as torque capacity ensuring balanced effective stress in both shaft and hub while minimizing material usage. A main contribution of the model is the identification of threshold conditions: (i) a lower limit of the joint strength factor, below which no feasible solution exists, and (ii) upper and lower bounds for the shaft aspect ratio depending on design scenarios. These thresholds provide clear criteria for determining whether a given material combination and geometry can support the required torque transmission. The results showed that increasing friction will reduce the necessary interference while demanding a thicker hub to withstand shear stresses, whereas the contact pressure remains unaffected and depends only on geometry and material properties. Case studies with steel, aluminum, and brass demonstrated the differences between high-strength homogenous joints and low-strength or dissimilar material pairings, with the latter requiring more significant geometric adjustments. Three-dimensional finite element analysis validated analytical predictions within deviations ranging from $3 %$ to $10 %$ . This work provides direct design formulas useful for aerospace and automotive lightweight transmission systems. It provides theoretical understanding and practical tools, including closed-form formulas and design charts for efficient, reliable shrink-fit joint design without iterative simulations.

Keywords

shrink-fit joints interference fit optimization torsional loading finite element analysis (FEA)

Get full access to this article

View all access options for this article.

References

Madej

Śliwka

. Analysis of interference-fit joints. Appl Sci 2021; 11: 11428.

Wang

, et al. Automatic measurement of contact stress and connection force of interference components by ultrasound. Appl Sci 2023; 13: 12461.

Budynas

Nisbett

Shigley

. Shigley’s mechanical engineering design. 11th ed. McGraw-Hill, 2021.

Bataineh

Al-Hawari

. Computation of the release force in a gear shrink-fitted over a solid shaft. Int J Mech Eng Robot Res 2021; 10(11): 592–600.

Castagnetti

Dragoni

. Optimal aspect ratio of interference fits for maximum load transfer capacity. J Strain Anal Eng Des 2005; 40: 177–184.

Croccolo

De Agostinis

. Analytical solution of stress and strain distributions in press fitted orthotropic cylinders. Int J Mech Sci 2013; 71: 21–29.

Izard

García-Martín

Rodríguez-Martín

, et al. Finite element analysis of the influence of chamfer hub geometry on the stress concentrations of shrink fits. Appl Sci 2023; 13: 3606.

Izard

Garcia

Rodriguez-Martín

, et al. Finite element analysis of the reduction in stress concentration factors in shrink fits by using contact rings. Appl Sci 2022; 12: 10037.

Zou

Zeng

Wang

, et al. Effect of plastic deformation and fretting wear on the fretting fatigue of scaled railway axles. Int J Fatigue 2020; 132: 105371.

10.

Sharifi

Arghavani

Hematiyan

. An analytical solution for optimum design of shrink-fit multi-layer compound cylinders. Int J Appl Mech 2012; 04: 1250043.

11.

Qiu

Zhou

. Analytical solution for interference fit for multi-layer thick-walled cylinders and the application in crankshaft bearing design. Appl Sci 2016; 6: 167.

12.

Bai

Wang

Ning

, et al. Contact pressure algorithm of multi-layer interference fit considering centrifugal force and temperature gradient. Appl Sci 2018; 8: 726.

13.

Wang

Zhang

, et al. Press-fit analysis of multilayer interference fit. Proc Inst Mech Eng Part C: J Mech Eng Sci 2023; 237: 903–918.

14.

Es-saheb

Alsubaie

Fouad

. Advance optimum design of multi-layer compound cylinders. AIP Adv 2024; 14: 035129.

15.

Abdelsalam

Sedaghati

. Design optimization of compound cylinders subjected to autofrettage and shrink-fitting processes. J Press Vessel Technol 2013; 135: 021209.

16.

Pedersen

. On optimization of interference fit assembly. Struct Multidiscipl Optim 2016; 54: 349–359.

17.

Saeed

Falter

Dausch

, et al. Artificial intelligence techniques for improving cylindrical shrink-fit shaft-hub couplings. In: 2021 Proceedings of the design society, 2021, pp. 645–656. Bordeaux, France: Cambridge University Press.

18.

Kazemzadeh Azad

Akış

. A study of shrink-fitting for optimal design of multi-layer composite tubes subjected to internal and external pressure. Iran J Sci Technol Trans Mech Eng 2019; 43: 451–467.

19.

Salehi Kolahi

Karamooz

Rahmani

. Elastic analysis of shrink-fitted thick FGM cylinders based on linear plane elasticity theory. Mech Adv Compos Struct 2020; 7: 121–127.

20.

Zrinej

Nor-Eddine

Bouzid

. Elastic stress analysis of shrink-fit thick-wall FGM cylinders. In: 2024 4th international conference on innovative research in applied science, engineering and technology (IRASET), 2024, pp. 1–6.

21.

Norton

. Machine design: an integrated approach. 5th ed. Prentice Hall, 2014.

22.

Croccolo

Vincenzi

. A generalized theory for shaft—hub couplings. Proc Inst Mech Eng Part C: J Mech Eng Sci 2009; 223: 2231–2239.

23.

Croccolo

Vincenzi

. Stress concentration factors in compression—fit couplings. Proc Inst Mech Eng Part C: J Mech Eng Sci 2010; 224: 1143–1152.

24.

Smith

. ABAQUS/Standard User’s Manual. Version 6.9. Dassault Systèmes Simulia Corp, 2009.

Generalized analytical model for optimal design of hollow shaft–hub shrink-fit joints under torsional loading

Abstract

Keywords

Get full access to this article

References