Sensing Technologies for Measuring Grain Loss during Harvest in Paddy Field: A Review
Abstract
:1. Introduction
2. Major Losses in Combine Harvester Operation
2.1. Header Losses
2.2. Threshing Losses
2.3. Separation Losses
2.4. Cleaning Loss
2.5. Parameters That Contributes to Grain Losses on Combine Harvester
3. Conventional Methods of Grain Loss Measurement
4. Grain Loss Sensing Method
5. Related Studies on Grain Loss Sensor Monitoring
6. Principle of Grain Loss Monitoring System
7. Limitations of the Existing Grain Loss Sensor Monitoring Systems
- The grain loss sensor has a low resolution. It should be upgraded to meet rice harvesting requirements, which indicate that total grain loss must be less than 3% [50].
- Due to the dense and concurrent collisions of the materials, the impact signals overlap [53]. The sensor’s integration and protection are required to withstand the rigorous operating conditions encountered in field applications.
- The amplifier’s output signal was still irregular due to interference signals caused by external mechanical vibration. To process the signals, it is necessary to improve the filtering module [20].
- The separation of grains from materials other than grains (MOG) must be improved because grains are identified as residues in some of the developed grain sensor monitoring systems, and residues are also identified as grains [56].
- Interference between signals generated during field harvesting is unavoidable due to machine vibration disturbance, the low recognition accuracy of grain impact signals from materials other than grains (MOG), and grain moisture content change [7].
- Finally, it is illustrated that most currently developed grain loss monitoring systems have been tested in the laboratory, but only a few were implemented in field harvesting.
8. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Authors | Type of Losses | Sensor Used | Sensor Position | Measurement Error (%) |
---|---|---|---|---|
[7] | Cleaning loss | PVDF film sensor | Under the concave screen of the lab test | 0.7 highest error, 1.3 lowest |
[21] | Separation/cleaning | Piezoelectric ceramic | Under the sieve | ≤3.46% |
[29] | Separation loss | Piezoelectric ceramic | End of the walker | 4.63 |
[48] | Cleaning loss | Piezoelectric ceramic | Under the cleaning sieve | 4.48 |
[50] | Separation loss | Piezoelectric ceramic | Under the threshing sieve | 3.83 |
[51] | Separation/Cleaning | PVDF film sensor | Under the cleaning/separation sieve | Rice 2.5, Wheat 4.8 |
[52] | Cleaning loss | PVDF film sensor | Below the threshing and cleaning sieve | 1.8–3.15 |
[53] | Grain losses | Two crossed PVDF film | Test bench in the laboratory | Not specified |
[54] | Cleaning loss | Displacement sensor | Under the cleaning sieve | Not specified |
[56] | Cleaning loss | PVDF film sensor | Test bench in the laboratory | Reduced from 12 to 3 |
[57] | Cleaning loss | PVDF film sensor | Rear of the vibrating cleaning sieve | Not specified |
[58] | Separation loss | PVDF film sensor | Under threshing/separation rotor | 3.40 |
S/N | Type of Sensor | Critical Point (Comments) | Photo |
---|---|---|---|
1 | Piezoelectric ceramic sensor | Because of the brittleness of the sensor material, it is susceptible to breakage due to vibration and has a lower level of reliability than the other materials. The vibration interference of the combine reduces the sensor’s measurement accuracy [48]. | |
2 | Acoustic sensor | The sensor’s sensitivity severely diminished due to the mechanical vibration of the machine [56]. It has a limited degree of precision [57]. | |
3 | PVDF piezoelectric | It is the most commonly utilized grain loss sensor. It has a negligible effect on the structure of the testing system. It also offers a considerable advantage in terms of sensing components [57]. | |
4 | Force sensor | The sensor can only detect a fraction of the discharge grain and the surface of the sensor is very small to be installed on the combine harvester [59]. | |
5 | Pressure sensor | The conventional pressure sensor is incapable of distinguishing between grain and residue. Additionally, the sensor’s response time is very lengthy [60]. | |
6 | Piezoelectric crystal sensor | This type of sensor increase not only the signals of the grain cleaning loss but also provide consistent sensitivity for the sensitive element stable performance, and high signal to noise ratio were the key characteristics of the sensor [61]. |
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Bomoi, M.I.; Nawi, N.M.; Abd Aziz, S.; Mohd Kassim, M.S. Sensing Technologies for Measuring Grain Loss during Harvest in Paddy Field: A Review. AgriEngineering 2022, 4, 292-310. https://doi.org/10.3390/agriengineering4010020
Bomoi MI, Nawi NM, Abd Aziz S, Mohd Kassim MS. Sensing Technologies for Measuring Grain Loss during Harvest in Paddy Field: A Review. AgriEngineering. 2022; 4(1):292-310. https://doi.org/10.3390/agriengineering4010020
Chicago/Turabian StyleBomoi, Muhammad Isa, Nazmi Mat Nawi, Samsuzana Abd Aziz, and Muhamad Saufi Mohd Kassim. 2022. "Sensing Technologies for Measuring Grain Loss during Harvest in Paddy Field: A Review" AgriEngineering 4, no. 1: 292-310. https://doi.org/10.3390/agriengineering4010020
APA StyleBomoi, M. I., Nawi, N. M., Abd Aziz, S., & Mohd Kassim, M. S. (2022). Sensing Technologies for Measuring Grain Loss during Harvest in Paddy Field: A Review. AgriEngineering, 4(1), 292-310. https://doi.org/10.3390/agriengineering4010020