Finite-element simulation of pressure profile and 3D deformation of breasts wearing adjustable bras

Abstract

Adjustable bras should be well designed with scientific analysis of pressure distribution to maintain a balance between the multidimensional considerations of comfort, function, and safety. A contact mechanics model of a body-adjustable brassiere was developed, with the aim of investigating the interaction between these considerations, and of further scientifically optimizing the pattern design and fabric selection. Point cloud data were obtained through 3D body scanning, and the torso surface was reconstructed using a detection contour method. A geometric model of the torso was divided into soft tissue, thorax, and breast by reverse engineering; the brassiere geometric model, in the semi-dressed state, was divided into eight parts and constructed using forward–reverse methods. The breast and soft tissue were considered as linear elastic entities with different material parameters, the thorax was taken to be a rigid body, and the brassiere was modeled as a linear elastic shell with variable components and material parameters. The simulation was validated by pressure measurement and shaping evaluation in vivo. Results show that the model could be used to predict the contact pressure and 3D deformation with reasonable accuracy. The contact pressure at the top of the shoulder is 4.9–7.8 kPa, that at the underband is 1.9–4.9 kPa, and that at the upper band is 1.0–2.9 kPa. The pressure on the breasts is mainly concentrated in the lower half of the breasts, and ranges from 0.1 to 1.5 kPa. The finite-element model developed in this study helps to provide a better understanding of the complex interactions between the body and an adjustable brassiere, and can be used to analyze different bra design features (fabric parameter, pattern, etc.) for predicting the pressure distribution and deformation of breast shapes.

Keywords

Finite-element model numerical simulation brassiere contact pressure breast 3D deformation

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References

Zuo

Wang

Wen

, et al. Research progress of the brassiere–chest contact simulation based on the finite element mechanical model. J Silk 2022; 59: 71–80.

Ramzann

Imran

Zaman

, et al. Design and development of auxetic structures for enhancing ergonomic comfort in women’s intimate apparel (brassiere). J Eng Fiber Fabr 2023; 18: 15589250231219760.

Zhang

Guo

, et al. Extraction and recognition of breast morphological feature parameters based on machine learning models. Text Res J 2024; 94: 1851–1865.

Guo

Chen

, et al. Optimized design of sports bras with pressure comfort, thermal comfort, and shaping support. Text Res J 2024; 94: 180–191.

Zhou

, and Ng

SP.

Methods of studying breast motion in sports bras: A review. Text Res J 2011; 1234–1248.

McGhee

Steele

JR.

Changes to breast structure and function across a woman’s lifespan: Implications for managing and modeling female breast injuries. Clin Biomech 2023; 107: 106031.

McGhee

Steele

JR.

Biomechanics of breast support for active women. Exercise Sport Sci Rev 2020; 48: 99–109.

Liu

Miao

Dong

, et al. Enhancing pressure comfort of a bra’s under-band. Text Res J 2018; 88: 2250–2257.

Shi

Liu

, et al. Biomedical therapeutic compression textiles: Physical-mechanical property analysis to precise pressure management. J Mech Behav Biomed Mater 2024; 151: 106392.

10.

Liu

Lao

, et al. Determination of leg cross-sectional curvatures and application in pressure prediction for lower body compression garments. Text Res J 2019; 89: 1835–1852.

11.

Zhang

Fan

, et al. Establishment of finite element model for human thorax. J Army Med Univ 2009; 31: 535–537.

12.

Xu YY. The research of bra cup fitness based on finite element analysis. Master’s Thesis. Zhejiang Sci-Tech University, China, 2015.

13.

Qiu JY. Simulation of a breast and a sports bra interaction during exercise. Master’s Thesis, Soochow University, China, 2016.

14.

Qiu

Simulation of a breast and a sports brassiere interaction during exercise. Master’s Thesis, Suzhou University, China, 2017.

15.

Sun Y, Yick KL, Cai YQ, et al. Finite element analysis on contact pressure and 3D breast deformation for application in women’s bras. Fibers Polym 2021; 22: 2910–2921.

16.

Ruiter

Müller

Stotzka

, et al. Automatic image matching for breast cancer diagnostics by a 3D deformation model of the mamma. Biomed Tech (Berl) 2002; 47: 644–647.

17.

Dempsey

SCH

O’Hagan

Samani

Measurement of the hyperelastic properties of 72 normal homogeneous and heterogeneous ex vivo breast tissue samples. J Mech Behav Biomed Mater 2021; 124: 104794.

18.

Liang

Yip

, et al. Computational modelling methods for sports bra–body interactions. Int J Clothing Sci Technol 2020; 32: 921–934.

19.

Liang

Yip

, et al. Numerical simulation of nonlinear material behaviour: Application to sports bra design. Mater Des 2019; 183: 108177.

20.

GB/T 23698-2023. General requirements for 3D scanning anthropometric methodologies.

21.

GB/T 3923.1:2013. Textiles. Tensile properties of fabrics. Part 1: Determination of maximum force and elongation at maximum force using the strip method.

22.

Yao Y. Research on Multi-Material bra wires design by finite element analysis. Master’s Thesis, 2015, Zhejiang Sci-Tech University, China.

23.

Ma DD. Research on pressure delivery and co-couple deformation of “Compression stockings-Lower limb” based on finite element. Master’s Thesis,2018, Donghua University, China.

24.

Dong DW. Prediction of Different Postural Morphology for Reconstructing Elastic Soft Tissue of Human Body. Master’s Thesis, 2017, Hangzhou Danzi University, China.