Effect of internal pressure on springback during low pressure tube hydroforming

Chu, Guannan; Lin, Chuang; Wei, Li

doi:10.1007/s12289-017-1395-y

Cited by 21 publications

(9 citation statements)

References 14 publications

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“…They analytically obtained springback in bulge forming and validated the analytical model using both experimental tests and numerical simulations. Chu et al [14] proposed an analytical model for springback in low-pressure tube hydroforming (LPTH) based on classical elasticity theory. The classical theory of elasticity assumes a direct correlation between springback and the bending moment in the forming of tubes.…”

Section: Introductionmentioning

confidence: 99%

Analytical approach to investigate the effects of through-thickness stress on springback in bending of isotropic sheet metal

Movahedi,

Gerdooei

2024

Int J Adv Manuf Technol

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Within contemporary sheet metal forming processes like electromagnetic forming, the sheet experiences pronounced out-of-plane compression stress. This study focuses on the predicting the springback in the bending of an isotropic sheet metal in the presence of through-thickness compressive normal stress. In the analytical method, the longitudinal stress distribution across sheet thickness was calculated via equilibrium equations and the associated ow rule in incremental plasticity based on the power law hardening model, obtaining the reverse bending moment. During the unloading phase, the external load was lifted, and the springback angle was estimated by assuming linear elastic behavior and neglecting the Bauschinger effect, employing the superposition method. A case study was conducted on an aluminum alloy sheet for different compressive stresses and bend curvatures. Subsequently, the reverse bending moments and springback angles obtained for each case were compared to the numerical outcomes from nite element (FE) modeling. Analytical results indicate that elevating the compressive normal stress on the sheet surface to 75% and 100% of the yield stress will lead to a reduction in springback by 17.4% and 32%, respectively. At the compressive normal stress of 75% of the yield stress, the numerical model exhibited a 4.4% difference from the analytical model. For the validation of the analytical model, a four-point bending test was conducted with varying initial bend curvatures and angles. This involved comparing the experimental springback angle and curvature with both numerical and analytical predictions. In comparison, both the numerical and analytical models demonstrated strong agreement with the experimental results.

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Section: Introductionmentioning

confidence: 99%

Analytical approach to investigate the effects of through-thickness stress on springback in bending of isotropic sheet metal

Movahedi,

Gerdooei

2024

Int J Adv Manuf Technol

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“…Chu et alstudied the springback of rectangular component in LPTH process. And proposed a forming process, tube hydro-forging(THFG), for forming variable cross-section at low hydraulic pressure[8] [9].…”

Section: Introductionmentioning

confidence: 99%

Research on hydro-pressing of aluminum alloy double cavity profile components

Han,

Wang,

Zhuang

2023

Preprint

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In this paper, double-cavity profiles with variable cross-section characteristics formed by hydro-pressing are studied. The hydro-pressing forming law of aluminum alloy double-cavity profiles is investigated by numerical simulation and experimental methods, and the effects of process parameters on corner filling, height and width dimensions, flatness of rib plate and wall thickness distribution are analyzed. The results show that the lower corner radius of the middle section increases first and then decreases with the increase of the supporting pressure. The upper corner radius of the middle section and the upper and lower corner radius near the two ends of the section increase with the increase of the supporting pressure. With the increase of the clamping force, the size deviation of the component height decreases and the size deviation of the width increases. The double-cavity profiles formed under pressure within 0.25ps had the worst flatness of the rib plate. The use of teflon as lubricant has the best effect on the improvement of thickness distribution. The component with good dimensional accuracy and wall thickness distribution can be formed by using 0.5ps supporting pressure and teflon lubricant. The forming characteristics of double-cavity profiles are summarized, which provides reference for the selection of actual production process parameters.

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“…The results confirmed that the required internal pressure and die closing force for low pressure tube hydroforming is much less than that of high pressure tube hydroforming. Chu et al [5] predicted the effect of internal pressure on the springback during low pressure tube hydroforming. However, the hydroforming process leads to rupture or folding defects for low-ductility materials such as high strength steel tubes.…”

Section: Introductionmentioning

confidence: 99%

Integration of Hot Tube Gas Forming and Die Quenching of Ultra-High Strength Steel Hollow Parts Using Low Pressure Sealed-Air

et al. 2022

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A low pressure sealed-air hot tube gas forming process of ultra-high strength steel tubes was developed not only to change the cross-section of the hollow products by bulging but also to increase the strength of components. Gas-formed components are typically formed by a controlled-gas pressure with extremely high internal pressure, which leads to affected production costs and safety. Moreover, compressing the gas with high pressure requires high energy during its preparation. Therefore, to simplify the internal pressure controlling system and improve the safety factor in gas forming processes, the sealed-air tubes are formed with a quite low initial pressure. The pressure of the sealed air increased with increasing temperature of the air inside the resistance-heated tube, and the bulging deformation was controlled only by axial feeding. The effects of the initial pressure and heating temperature on the bulging deformation and quenchability of the tubes, and the effect of the starting time of axial feeding on the bulging behavior were examined. Consequently, ultra-high strength steel bulged parts were produced even in low initial internal pressure and with the rapid heating of the tubes.

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Effect of internal pressure on springback during low pressure tube hydroforming

Cited by 21 publications

References 14 publications

Analytical approach to investigate the effects of through-thickness stress on springback in bending of isotropic sheet metal

Analytical approach to investigate the effects of through-thickness stress on springback in bending of isotropic sheet metal

Research on hydro-pressing of aluminum alloy double cavity profile components

Integration of Hot Tube Gas Forming and Die Quenching of Ultra-High Strength Steel Hollow Parts Using Low Pressure Sealed-Air

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