In recent years, the braking noise of disc brakes has remained a focal point in research. However, there is a paucity of discussion regarding the improvement of the heat-dissipation rib structure of brake discs through topology optimization methods. This study aims to mitigate the braking noise of disc brakes by constructing a thermo-mechanical coupling and complex eigenvalue analysis model for the brake friction pair. Topology optimization was performed on the heat-dissipation ribs of the brake disc, culminating in a Y-shaped heat-dissipation rib structure. The findings reveal that the Y-shaped structure can augment the heat-dissipation area, enhancing heat dissipation, and substantially reduce the temperature at various key nodes. Moreover, the alteration in the stiffness distribution of the brake disc results in an average increase of 4.9% in the first four-order modal frequencies. This enables the vibrations of the brake disc to evade sensitive noise frequency bands, and renders the distribution of the instability coefficient more concentrated and smoothly. The maximum deformations of the first four modes decrease by 8.9%, 8.1%, 6.9%, and 9.7% respectively, effectively modifying the vibration characteristics.
ShenMLiHDuJH, et al. New insights into reducing airborne particle emissions from brake materials: grooved textures on brake disc surface. Tribol Int2022; 174: 107721.
2.
ManojASaurabhANaralaSKR, et al. Surface modification of grey cast iron by laser cladding for automotive brake disc application. Wear2023; 532: 205099.
3.
HuiYLiuGZhangQ, et al. Fading behavior and wear mechanisms of C/C-SiC brake disc during cyclic braking. Wear2023; 526: 204930.
4.
LuCShenJFuQ, et al. Research on radial crack propagation of railway brake disc under emergency braking conditions. Eng Fail Anal2023; 143: 106877.
5.
AhnSSohnCChoiS, et al. Study on reduction of squeal noise of disc brake system considering braking temperature of urban railway vehicle. J Mech Sci Technol2023; 37(5): 2253–2262.
6.
PanGYJiangZWYangZJ, et al. Study on contribution of back plate shape of brake pad to disc brake system noise. In Proc., 2015 4th International Conference on Sustainable Energy and Environmental Engineering (ICSEEE 2015), Shenzhen, China, 2015.
7.
KimSK.Improvements for reduction of the brake squeal noise at Seoul metro rolling stock on tracks. J Mech Sci Technol2009; 23: 2206–2214.
8.
GuYLiuYLuC, et al. Effect of compressive strain of brake pads on brake noise. Shock Vib2020; 2020(1): 8832363.
9.
KhuntiptongATangchaichitKPolnumtiangS, et al. Study of brake pad shim modification to improve stability against high frequency squeal noise by finite element analysis. Eng J2022; 26(9): 25–34.
10.
ZhangSYinJLiuY, et al. Multiobjective structure topology optimization of wind turbine brake pads considering thermal-structural coupling and brake vibration. Math Probl Eng2018; 2018(1): 7625273.
11.
HongHKimGLeeH, et al. Optimal location of brake pad for reduction of temperature deviation on brake disc during high-energy braking. J Mech Sci Technol2021; 35: 1109–1120.
12.
BouaziziMSoulaMLazghabT.Numerical analysis of brake squeal noise–application to the disk brake systems. Noise Vib Worldw2024; 55(3): 117–122.
13.
KalelNBhattBDarpeA, et al. Role of binder in controlling the noise and vibration performance of brake-pads. Proc IMechE, Part D: J Automobile Engineering2023; 237(13): 3200–3213.
14.
CascettaFCaputoFDe LucaA.Squeal frequency of a railway disc brake evaluation by FE analyses. Adv Acoust Vib2018; 2018(1): 4692570.
15.
DuYWangY.Squeal analysis of a modal-parameter-based rotating disc brake model. Int J Mech Sci2017; 131: 1049–1060.
16.
ParkSLeeKKimS, et al. Brake-disc holes and slit shape design to improve heat dissipation performance and structural stability. Appl Sci2022; 12(3): 1171.
17.
ZhangSZhangJ.Effect of heat transfer optimization on brake noise characteristics of automotive disc brake. J Vibroeng2019; 21(3): 792–802.
18.
ZhuDYuXSaiQ, et al. Noise and vibration performance of automotive disk brakes with laser-machined M-shaped grooves. Proc IMechE, Part D: J Automobile Engineering2023; 237(5): 978–990.
19.
NoubyMSrinivasanK.Simulation of the structural modifications of a disc brake system to reduce brake squeal. Proc IMechE, Part D: J Automobile Engineering2011; 225(5): 653–672.
20.
PanGLiuZXuQ, et al. Optimal design of brake disc structures for brake squeal suppression. J Phys Conf Ser2021; 2101(1): 012026.
21.
YinJHaoQLiuY, et al. Multi objective optimization of internal and surface structure of high-speed and heavy-duty brake disc. Adv Mech Eng2022; 14(1): 16878140211070459.
22.
WagnerASpelsbergKGHagedornP.Structural optimization of an asymmetric automotive brake disc with cooling channels to avoid squeal. J Sound Vib2014; 333(7): 1888–1898.
23.
StojanovicNGhazalyNMGrujicI, et al. Determination of noise caused by ventilated brake disc with respect to the rib shape and material properties using Taguchi method. Trans FAMENA2022; 46(4): 19–30.
24.
WuGZhangD.Thermal-mechanical coupling analysis of disc brake based on ANSYS Workbench. Lubr Eng2022; 47(10): 126–133.
25.
KimSW. Thermophysical properties of automotive brake disk materials. In: 2006 international forum on strategic technology, Ulsan, Korea (South), 18–20 October 2006, pp.163–166. New York: IEEE.
26.
MackinTJNoeSCBallKJ, et al. Thermal cracking in disc brakes. Eng Fail Anal2002; 9(1): 63–76.
27.
MahmoudiTParviziAPoursaeidiE, et al. Thermo-mechanical analysis of functionally graded wheel-mounted brake disk. J Mech Sci Technol2015; 29: 4197–4204.
28.
BelhocineABouchetaraM.Thermo-mechanical coupled analysis of automotive brake disc. Int J Precis Eng Manuf2013; 14(9): 1591–1600.
29.
McPheeADJohnsonDA.Experimental heat transfer and flow analysis of a vented brake rotor. Int J Therm Sci2008; 47(4): 458–467.
30.
LimpertR.Brake design and safety. Warrendale, PA: SAE International, 2011.
31.
ChenSHuangQLiangM, et al. Numerical study on the heat transfer characteristics of oscillating flow in cryogenic regenerators. Cryogenics2018; 96: 99–107.
32.
DowsonD.A generalized Reynolds equation for fluid-film lubrication. Int J Mech Sci1962; 4(2): 159–170.
33.
LiuPZhengHCaiC, et al. Analysis of disc brake squeal using the complex eigenvalue method. Appl Acoust2007; 68(6): 603–615.
34.
FepponF.Density-based topology optimization with the Null Space Optimizer: a tutorial and a comparison. Struct Multidiscipl Optim2024; 67(1): 4.
35.
CuiYTakahashiTMatsumotoT.An exact volume constraint method for topology optimization via reaction-diffusion equation. Comput Struct2023; 280: 106986.
36.
StojanovicNGlisovicJGrujicI, et al. Experimental and numerical modal analysis of brake squeal noise. Mobil Veh Mech2018; 44(4): 73–85.
