Effect of Lubrication on Friction in Bending under Tension Test-Experimental and Numerical Approach
Abstract
:1. Introduction
2. Experimental
2.1. Material
2.2. Friction Simulator
- Machine oil LAN-46 (Orlen Oil): kinematic viscosity 43.9 mm2·s−1 (at 40 °C), viscosity index 94, flow temperature −10 °C and ignition temperature 232 °C,
- Deep-drawing oil L (Orlen Oil): kinematic viscosity 330 mm2·s−1 (at 40 °C), freezing point −29 °C, flash point 238 °C and weld point 500 daN,
- Heavy-Draw 1150 oil (Lamson Oil): density 975 kg·m−3 (at 20 °C); viscosity 1157 mm2·s−1 (at 40 °C) and flash point 277 °C.
3. Numerical Modeling
3.1. Description of the FE-Based Model
3.2. FE Mesh
3.3. Material Model
3.4. Contact Conditions
3.5. Mesh Sensitivity Analysis
4. Results and Discussion
4.1. Experimental
4.1.1. Effect of Surface Roughness of Tools
4.1.2. Effectiveness of Lubrication
4.2. Results of Numerical Modeling
4.2.1. Distribution of Specimen Elongation
4.2.2. Flexuring of the Specimen
4.2.3. Normal and Friction Forces
5. Conclusions
- The normal pressure in the BUT test continuously increased with increasing specimen elongation, and this was due to the strain hardening phenomenon. However, the COF was very stable during the tests realized in all friction conditions. This conclusion is in contrast to the recent investigations of authors [2,3] on the friction determination in a strip drawing test when the nonlinear relation between friction and normal force was found.
- The effectiveness of the lubrication depended on the balance between two mechanisms accompanied with friction: (1) adhesion of the surfaces in contact and (2) roughening of workpiece asperities by the tool surface. High surface roughness of tool released the dominant share of ploughing in total frictional resistance. In these conditions, all of the lubricants used were not able to decrease the COF in to sufficient extent.
- Lubricants destined for application in SMF operations were able to reduce a value of friction coefficient approximately by 3–52% in relation to the surface roughness of rolls.
- Friction in the sheet–tool interface caused flexuring of the strip during flowing the sheet through the BUT test. This effect results in the non-uniformity of the contact normal force and depended on the value of COF.
- The lubricated conditions, by making the sample to move over the tool surface more easily, reduced the mean normal stress value on the sample surface in the contact area. Moreover, in the case of the most effective lubricant, i.e., HDO, the higher the deformation value, the more uniform the stress distribution in the contact zone was observed.
- The distribution of contact friction force and contact normal forces was non-uniform along the width and length of the strip material being in contact with the roll surface. This could be associated with the local flexuring of the strip sheet over the countersample surface.
Author Contributions
Funding
Conflicts of Interest
References
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C | Mn | P | S | Fe |
---|---|---|---|---|
≤0.08 | ≤0.4 | ≤0.03 | ≤0.03 | remainder |
Specimen Orientation | Rp0.2 (MPa) | Rm (MPa) | K (MPa) | n | r |
---|---|---|---|---|---|
0° | 172 | 306 | 513 | 0.17 | 1.49 |
45° | 179 | 319 | 502 | 0.19 | 1.32 |
90° | 184 | 210 | 524 | 0.20 | 1.58 |
Sa (μm) | Sq (μm) | Sv (μm) | Sz (μm) | St (μm) | Sp (μm) |
---|---|---|---|---|---|
1.46 | 1.72 | 5.89 | 12.42 | 11.39 | 8.87 |
Model No. | Element Size, mm | Number of Elements | Number of Nodes | Tensile Front Force, N at Specimen Elongation | Computation Time, s | ||
---|---|---|---|---|---|---|---|
5% | 10% | 15% | |||||
N1 | 1 × 1 × 1 | 1380 | 3058 | 2709 | 2979 | 3096 | 220 |
N2 | 0.5 × 0.5 × 0.5 | 11,040 | 17,451 | 2697 | 2976 | 3089 | 2008 |
N3 | 0.25 × 0.25 × 0.25 | 88,320 | 113,365 | 2695 | 2976 | 3086 | 24,547 |
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Trzepiecinski, T.; Lemu, H.G. Effect of Lubrication on Friction in Bending under Tension Test-Experimental and Numerical Approach. Metals 2020, 10, 544. https://doi.org/10.3390/met10040544
Trzepiecinski T, Lemu HG. Effect of Lubrication on Friction in Bending under Tension Test-Experimental and Numerical Approach. Metals. 2020; 10(4):544. https://doi.org/10.3390/met10040544
Chicago/Turabian StyleTrzepiecinski, Tomasz, and Hirpa G. Lemu. 2020. "Effect of Lubrication on Friction in Bending under Tension Test-Experimental and Numerical Approach" Metals 10, no. 4: 544. https://doi.org/10.3390/met10040544
APA StyleTrzepiecinski, T., & Lemu, H. G. (2020). Effect of Lubrication on Friction in Bending under Tension Test-Experimental and Numerical Approach. Metals, 10(4), 544. https://doi.org/10.3390/met10040544