Helicopter Planet Gear Rim Crack Diagnosis and Trending Using Cepstrum Editing Enhanced with Deconvolution
Abstract
:1. Introduction
2. Materials and Methods
2.1. Experimental Setup and Data Collection Scheme
2.1.1. Helicopter Transmission Test Facility (HTTF)
2.1.2. Crack Initiation and Progression
2.1.3. Available Dataset Description
- The H-SSA data length of 405,405 was designed such that the data length was an integer multiple number of revolutions for both the planet carrier and planet gear; hence, the carrier SSA (C-SSA) or planet SSA (P-SSA) can be derived from the H-SSA.
- The H-SSA was calculated from raw vibration signals over 12 planet-ring hunting-tooth periods, and each hunting-tooth period corresponded to 99 revolutions of planet gears (99 × 4095) or 35 revolutions of the planet carrier (35 × 11,583).
- The P-SSA can be produced by reshaping H-SSA into (4095 × 99) and finding the average across the 99 columns. Similarly, C-SSA can be produced by reshaping H-SSA into (11,538 × 35) and finding the average across the 35 columns.
2.2. Gear Crack Traditional Diagnosis Approach
- Transferring P-SSA into the frequency domain (1-sided spectrum obtained by using Hilbert transform).
- Setting all GMF harmonics and the two closest sidebands around each harmonic to zero.
- Low-pass filtering the signal by zeroing all the spectral components above 3.5× GMF and, then, inverse transforming back to the time (or angle) domain and taking the real part of the signal. Note that the low-pass filtering represents a critical step, as rim cracks (compared to tooth cracks) are more likely to generate changes in relatively low frequency ranges. Low-pass filtering focuses attention on the lower-frequency-range features in the signal. This decision is based on a consideration of the expected changes in the dynamics of the gear system in the presence of a rim crack compared to, for example, a tooth crack fault, where the reverse approach may have been more appropriate.
2.3. Proposed New Signal Processing Algorithm
2.3.1. Cepstrum Editing
Cepstrum Analysis
Cepstrum-Editing Technique
Proposed Cepstrum-Editing Scheme
2.3.2. Blind Deconvolution (BD)
Minimum Entropy Deconvolution (MED)
- Assume initial values of the filter, g = f (1) = [g0, …, gL]T where L denotes the length of the filter.
- Calculate vector f (1): New filter coefficient defined as the correlation between y3(t) and the data d(t). f (1) is found by solving the system Rg = f, where R is an N × N autocorrelation matrix defined with the N as the first delay of the autocorrelation function of the data d(t).
- Calculate the error (err) using Equations (11) and (12)
3. Results
3.1. Cepstrum Editing and MED Filtration of a Typical Result (Record #522)
3.2. Trending Results
3.3. Clustering Results
4. Discussion
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Frequency of Interest | Frequency (Hz) | Frequency (×Planet Orders) | |
---|---|---|---|
Stage 1 | Input Shaft | 100 | 6.17 |
Pinion/bevel gear mesh | 1900 | 117.14 | |
Bevel gear shaft (sun gear) | 26.76 | 1.65 | |
Stage 2 | Planet gear (relative to carrier) | 16.22 | 1 |
Sun gear (relative to carrier) | 21.03 | 35/27 or 1.296 | |
Carrier (output shaft) | 5.73 | 35/99 or 0.3535 | |
Planetary gear mesh frequency (GMF) | 567.71 | 35 (or 99× carrier) | |
Planet pass frequency (Number of planets times the carrier frequency) | 3-planet 17.20 4-planet 22.94 | 3-planet 1.06 4-planet 1.41 |
Loading (%) | Load Input Torque (Nm) | Input Speed (RPM) | Duration * (Min) |
---|---|---|---|
50 | 152 | 6000 | 2 |
75 | 227 | 6000 | 2 |
100 | 303 | 6000 | 2 |
125 | 379 | 6000 | 24 |
Planet-Ring Impacts | Spatial Location of the Planet Gear with Respect to the Fixed Sensor (0 to 360°) | Carrier Rotations |
---|---|---|
1 | 127.3 | 0.35354 |
2 | 254.5 | 0.70707 |
3 | 21.8 | 1.06061 |
4 | 149.1 | 1.41414 |
5 | 276.4 | 1.76768 |
6 | 43.6 | 2.12121 |
7 | 170.9 | 2.47475 |
8 | 298.2 | 2.82828 |
9 | 65.5 | 3.18182 |
10 | 192.7 | 3.53535 |
11 | 320.0 | 3.88889 |
12 | 87.3 | 4.24242 |
13 | 214.5 | 4.59596 |
14 | 341.8 | 4.94949 |
15 | 109.1 | 5.30303 |
16 | 236.4 | 5.65657 |
17 | 3.6 | 6.01010 |
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Sawalhi, N.; Wang, W.; Blunt, D. Helicopter Planet Gear Rim Crack Diagnosis and Trending Using Cepstrum Editing Enhanced with Deconvolution. Sensors 2024, 24, 2593. https://doi.org/10.3390/s24082593
Sawalhi N, Wang W, Blunt D. Helicopter Planet Gear Rim Crack Diagnosis and Trending Using Cepstrum Editing Enhanced with Deconvolution. Sensors. 2024; 24(8):2593. https://doi.org/10.3390/s24082593
Chicago/Turabian StyleSawalhi, Nader, Wenyi Wang, and David Blunt. 2024. "Helicopter Planet Gear Rim Crack Diagnosis and Trending Using Cepstrum Editing Enhanced with Deconvolution" Sensors 24, no. 8: 2593. https://doi.org/10.3390/s24082593
APA StyleSawalhi, N., Wang, W., & Blunt, D. (2024). Helicopter Planet Gear Rim Crack Diagnosis and Trending Using Cepstrum Editing Enhanced with Deconvolution. Sensors, 24(8), 2593. https://doi.org/10.3390/s24082593