Document Type : Research Article
Authors
1 Mechanics of Biosystem Department, Sari Agricultural Sciences and Natural Resources University, Sari, Iran
2 Mechanics of Biosystem Department, Tarbiat Modares University, Iran
Abstract
Introdution
Nowadays, supplying the needed food for people is one of the main global issues. Among foods, rice as the second vital crop has an important role in the world. The amount of global rice losses is about 21 percent and in Iran is reported between 16 to 30 percent that the most amount of it belongs to harvest (mowers and crushers) part. The measuring device for rice picker combine losses at lab scale is a tool which could report the losses of separating and cleaning units. One of the advantages of this device is choosing maximum speed by the operator with considering the acceptable amount of seed losses. Therefore, research about detecting and decreasing this type of losses is important. In this research, only the losses of the harvesting step, especially at the end of a combine harvester machine was addressed. Different methods included piezoelectric and acoustic sensors, load cell, and FIS controller were used as the measuring device of rice picker combine seed losses. In this research, on the contrary with other studies, the slope of meshed plate and humidity of product was measured using a piezoelectric sensor at lab scale under different conditions of the rotational speed of meshed plate. Therefore, the general purpose of this research was design, construction, and evaluation of the measuring device for rice picker combine losses based on the piezoelectric sensor at lab scale to measure the seed losses in the straws at the end of the machine at rice picking.
Materials and Methods
A meshed plate with the 100 × 60 cm2 dimension was one of the main parts of the measuring device of seed losses. The diameter of its meshes was 7 mm based on the rice seed size. It separates the rice seeds from straws. Separated seeds from this part were fallen on the other plate which is mounted under the meshed plate. The seeds through four separated routes were fallen on the sensors and output pulses from sensors were sent to the operator plus shown at a monitor. The used seeds at tests were selected from Fajr rice cultivar with a high yield and short height. The used piezoelectric sensor had the ability to convert imposed force and pressure to voltage and vice versa. After the seed falling on the sensor and its vibration, the piezoelectric sensor worked as a beam fixed at one end. The used Integrated Circuit (IC) was ATMEGA328, which receives the needed data through the sensor as a processing and action system. An electric motor was used to create the rotational speed of meshed plate. The LCD indicator was used for monitoring the obtained data from the test. The amount of seed losses at the end of rice picker combine machine was studied using the piezoelectric sensor with high sensitivity for detecting seeds to separate the seeds from straws. The tested sample in this research was 1 kg straw plus 52 g seed which was equal to 3 percent loss at the end of the harvest combine machine. The experimental design was a simple randomized complete design with three replications. The used treatments included the rotational speed of meshed plate at 3 levels (50, 75, and 100 rpm), the slope of meshed plate at 3 levels (25, 37, and 45 deg) plus humidity at 3 levels (12, 18, and 24 percent). Then the data analysis was done using the conducted test design. The GenStat software was used for data analysis.
Results and Discussion
The analysis of variance table showed that all treatments have a significant difference in the number of rice lost seeds at 1% probability level. The interaction between the rotational speed of meshed plate and seed humidity had a significant difference at the 1% level. On this base, the best separation of seed from straw recorded at 100 rpm and 12% humidity. The reason was the higher vibration of the meshed plate at high rotational speed and better separation of seeds at low humidity. Increasing the slope of meshed plate and humidity of seeds caused decreasing in the device efficiency. Because the motion speed of the sample on the meshed plate increased with increasing the slope of the meshed plate, a lower period was needed for separating the seeds from straws, and this separation at higher humidity was done hardly. The highest efficiency at this condition was obtained with 12% humidity and 25º slope. Increment of the rotational speed of meshed plate and decrement of meshed plate slope caused the best separation by the device. Its reason was high vibration at the high rotational speed and having enough time for separating the seeds from straws at a low slope of the meshed plate. The best angle for separating was 37º. Increment of the rotational speed of meshed plate, decrement of meshed plate slope, and sample humidity caused increasing the device efficiency. The reasons were high vibration at high rotational speed, having enough time for separating seeds from straws, and decreasing the compression at low humidity amounts. The results showed that the best device efficiency with 95.51% was obtained at 100 rpm rotational speed, humidity of 12%, and 25º slope of the meshed plate.
Conclusion
In this research, a measuring device for detecting the amount of seed losses combined by straws at the end of a rice picker combine machine was designed and constructed, and then was assessed. The results of lab tests showed that increment of the rotational speed of meshed plate plus decrement of meshed plate slope and sample humidity causes an increment of device efficiency. With installation and evaluation of this device on the rice picker combine machine, the needed correction at the farm will be done and the amount of losses will be decreased.
Keywords
Main Subjects
Open Access
©2022 The author(s). This article is licensed under Creative Commons Attribution 4.0 International License (CC BY 4.0), which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source.
- Bakhshandeh, A. Deputy Minister of Planning and Economic Affairs, Minister of Agriculture of Iran.
- Aghagolzadeh, H. 2005. Specifications of machinery needed for mechanized rice cultivation. 11th National Rice Conference of the country. Qazvin Agricultural Jihad Organization Agricultural Statistics 2018.
- Alimohammadzadeh, S., H. ShamsAbadi, Azadbakht, and M. H. Rezghi. 2015. Comparison of quantitative losses of different combine harvesters in rice harvesting with different moisture content. Research Findings on Improving Crop Production 1 (1): 13-28.
- Bernhardt, G., and R. Hubner. 2010. Patent No. 0199291. United States.
- Eldredge, K. W., and R. C. Blyth. 2001. Grain loss Indicator. United States Patent. Number 4,490, 964.
- Ferreira, D. B., A. Ferreira, S. Alonco, and H. Bley. 2001. Grain loss monitoring during all harvest season (gathering and processing losses), in the irrigated rice crop, and its results in reduction losses due to immediate adjustments in the combines. paper No. 011075. ASAE, Annual International Meeting, Sacramento, California, USA.
- Harisson, H. B. 1991. Rotor power and losses of an axial-flow combine. Trans. ASAE 34 (1): 60-64.
- Hedayatipour, A., and M. Rahmati. 2007. Study of drying temperature and final moisture content of rice on crop yield and conversion coefficient of high yield varieties in Mazandaran province. Journal of Agricultural Sciences and Natural Resources 13 (6).
- Karimi, H., H. Navid, A. Rostami, and A. Taheri hajivand. 2005. Design and Construction of a Grain Loss Monitor for Combine Harvester Using Load Cell. Journal of Agricultural Mechanization 1 (1).
- Lashgari, M. 2009. Implementation and evaluation of fuzzy logic controller for automated grain combine adjustment. Journal of Agricultural Engineering Research 1 (3).
- Mostofi Sarkari, M. R. 2009. Field Evaluation of grain loss monitor in different harvesting conditions on combine JD 955. In: Proceedings of 5th National Conference of Agricultural Machinery Engineering and Mechanization. Agriculture Faculty. Ferdowsi University of Mashhad. pp. 946-956. (In Persian).
- Mostofi Sarkari, M. R., M. S. Valiahdi, and I. Ranjbar. 2014. Field Assessment of End-of-Grain Combine Harvesters Equipped with a Grain Loss Monitor in JD-955 and JD-1165 Combines, Journal of Agricultural Machinery 4 (2): 335-343. (In Persian). http://dx.doi.org/10.22067/jam.v4i2.29077.
- Sharifi sangdeh, S. 2018. Investigation of the effect of grain moisture and type of 4LZ-2.5A and ICR20 combines on mortality of different rice harvesting units. Second National Conference on Harvesting and After Harvesting of Agricultural Technology, Mashhad, Khorasan Razavi Agricultural and Natural Resources Research Center.
- Strelioff, P., S. William, and J. Dale. 1977. Grain loss Monitor. United States Patent. Number 4,036,065.
- Tabatabaei, R., H. Aghagolzadeh, and B. Bakhshi. 2013. Field Testing and Evaluation of a Complete Nutrition Harvesting Combine. 7th National Congress of Agricultural Machinery and Mechanization.
- Taheri, A., H. Navid, H. Rostami, and H. Karimi. 2019. Field Assessment of Combine Seed Loss Monitoring Machine. 6th Scientific Research Congress on Development and Promotion of Agricultural Sciences and Natural Resources in Iran.
- Valiahdi, M. S., I. Rangbar, M. R. Mostofi Sarkari, and M. Majdi. 2014. Investigation of Processing Losses on a Jundir Model 1165 Combine with a Grain Loss Monitor. National Conference on Non-Agent Defense in Agriculture.
- Zhao, Z., Y. Li, J. Chen, and J. Xo. 2011. Grain separation loss monitoring system in combine harvester. Computers and Electronics in Agriculture 183-188.
)
Send comment about this article