On the Characteristics of Fatigue Fracture with Rapid Frequency Change
Abstract
:1. Introduction
2. Theory and Formulation
- a.
- First and Second Laws of Thermodynamics
- b.
- Internal heat generation
- c.
- Generalization of governing equations for variable frequency
- d.
- Internal Friction and Fatigue Limit
3. Material and Specifications
4. Bending Test Rig, Sensors, and Experimental Process
5. Results and Discussion
6. Validation and Application
7. Summary and Conclusions
- There is a relationship between the frequency of testing and the life of CS 1018 in the range of testing frequencies. An improvement in fatigue life is observed for higher frequencies compared to lower frequencies, due to the time for damage accumulation in lower frequencies.
- The material fails when the accumulated generated entropy reaches a nearly constant value of 23 MJm−3 K−1, with a narrow band range of ±3 MJm−3 K−1.
- The results show that, in the tested frequency range, fatigue life improves when the material experiences variable working frequencies. This is attributed to the distribution of stress in variable frequencies as opposed to the concentration of stress at the same frequency for constant frequencies. It should be noted that the results are valid for CS 1018 at the range of tested frequency for both low- and high-cycle fatigue. It is shown that the current model is able to accurately predict the life of a material under rapid frequency variations. However, the material’s fatigue behavior may be subject to change for frequencies at ranges of kHz. Therefore, the application of this method for very-high-cycle fatigue (VHCF) needs further investigations.
- The life trends also show a dependency on the order of applied frequency in which the life is higher for H–L–H compared to L–H–L. Moreover, for L–H, a higher number of cycles that fail are observed than in H–L tests. Generally, it is discovered that the higher number of changes in frequency (for the tested frequency range for CS 1018) improves life more.
- Internal friction for 30 Hz and 10 Hz testing frequencies are extracted, and it is shown there is not a significant change in line equations for the tested frequencies. However, a larger slope at 30 Hz is observed due to the higher energy rate given to the system, which activates more half-planes to travel to their neighboring energy levels.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Carbon | Manganese | Silicon | Phosphorus | Sulfur | Iron | |
---|---|---|---|---|---|---|
CS 1018 | 0.13–0.20% | 0.30–0.90% | 0.15–0.30% | 0.04% Max | 0.5% Max | 98.06–99.42% |
UTS (MPa) | YS (MPa) | Modulus of Elasticity (GPa) | Density (g/cm3) | Poisson’s Ratio | Hardness, Brinell | |
---|---|---|---|---|---|---|
CS 1018 | 440 | 370 | 205 | 7.86 | 0.29 | 126 |
Displacement (mm) | Corresponding Stress Level (MPa) | Frequency Sequencing | Frequency (Hz) | Life (Cycles) | Life Change (% Increase with Respect to Low Frequency) |
---|---|---|---|---|---|
3.81 | 211 | High | 26 | 489,200 | |
211 | Low–High | 9–26 | 493,100 | 0.79 | |
5.08 | 254 | Low | 9 | 46,300 | |
254 | High | 26 | 46,800 | 1.07 | |
254 | Low–high | 9–26 | 47,700 | 3.02 | |
254 | High–low | 25–9 | 47,300 | 2.15 | |
254 | Low–high–low | 8–24–9 | 48,510 | 4.77 | |
254 | High–low–high | 24–10–24 | 50,120 | 8.25 | |
7.62 | 316 | Low | 9 | 14,200 | |
316 | High | 26 | 14,900 | 4.9 | |
316 | Low–high | 9–26 | 15,600 | 9.85 | |
316 | High–low | 25–9 | 15,350 | 8.09 | |
316 | Low–high–low | 8–24–9 | 15,890 | 11.90 | |
316 | High–low–high | 24–10–24 | 17,100 | 20.42 | |
10.16 | 345 | Low | 9 | 5400 | |
345 | High | 26 | 5700 | 5.55 | |
345 | Low–high | 9–26 | 6240 | 15.55 | |
345 | High–low | 25–9 | 6000 | 11.11 | |
345 | Low–high–low | 8–24–9 | 7100 | 31.48 | |
345 | High–low–high | 24–10–24 | 8060 | 49.25 |
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Amooie, M.A.; Lijesh, K.P.; Mahmoudi, A.; Azizian-Farsani, E.; Khonsari, M.M. On the Characteristics of Fatigue Fracture with Rapid Frequency Change. Entropy 2023, 25, 840. https://doi.org/10.3390/e25060840
Amooie MA, Lijesh KP, Mahmoudi A, Azizian-Farsani E, Khonsari MM. On the Characteristics of Fatigue Fracture with Rapid Frequency Change. Entropy. 2023; 25(6):840. https://doi.org/10.3390/e25060840
Chicago/Turabian StyleAmooie, Mohammad A., K. P. Lijesh, Ali Mahmoudi, Elaheh Azizian-Farsani, and Michael M. Khonsari. 2023. "On the Characteristics of Fatigue Fracture with Rapid Frequency Change" Entropy 25, no. 6: 840. https://doi.org/10.3390/e25060840
APA StyleAmooie, M. A., Lijesh, K. P., Mahmoudi, A., Azizian-Farsani, E., & Khonsari, M. M. (2023). On the Characteristics of Fatigue Fracture with Rapid Frequency Change. Entropy, 25(6), 840. https://doi.org/10.3390/e25060840