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International Journal of Engineering Technology and Construction, 2021, 2(1); doi: 10.38007/IJETC.2021.020102.

PLC is Used to Realize the Electrical Control of the Lotus Seed Core Breaker

Author(s)

Ming Li

Corresponding Author:
Ming Li
Affiliation(s)

North China Electric Power University, Baoding, China

Abstract

Due to the low control system of the traditional lotus seed core-shelling and shelling machine, its production efficiency, safety and work reliability are relatively low. The programmable controller PLC in the field of control system technology can better achieve the management and control goals of the control system, such as safety and efficiency. Therefore, it is necessary to carry out electrical control research based on the realization of the lotus seed core-shelling machine using PLC. The purpose of this article is to solve and improve the related problems of the electrical control system of traditional lotus seed core-shelling and hulling machine. Through PLC technology, a detailed analysis and detailed analysis of how the electrical control system of lotus seed core-shelling and hulling machine can be processed more efficiently. The research and analysis of the main problems in the electrical control system of the lotus seed core-shelling and hulling machine, and the innovative application of PLC technology to the lotus seed core-shelling and hulling machine. Feasibility of electrical control of shelling machine. The research results show that this kind of lotus seed core-piercing and shelling machine using PLC electrical control system can make the lotus seed core-piercing and shelling work easier, more convenient and efficient, and can effectively improve the shelling rate of 2.5-3.4kg / h; wear The core rate is 1.0-1.7kg / h, the clean-up rate of the lotus core reaches 1%, and the crushing rate is reduced by 1%.

Keywords

Lotus Seed Wear Core, Sheller Research, PLC System, Electrical Control System

Cite This Paper

Ming Li.  PLC is Used to Realize the Electrical Control of the Lotus Seed Core Breaker. International Journal of Engineering Technology and Construction (2021), Vol. 2, Issue 1: 16-28. https://doi.org/10.38007/IJETC.2021.020102.

References

[1] Do-Hyeong Kim, & Jae-Hoon Choi. (2019) “Analysis of the Transmission Performance of Control Pilot Signal Lines for Charging Communication in Electric Vehiclesa”, International Journal of Automotive Technology, 21(2), pp.51-52. DOI: 10.1007/s12239-020-0049-0

[2] Wei Liu, Hongzhong Qi, Xintian Liu, & Yansong Wang. (2019) “Evaluation of Regenerative Braking Based on Single-Pedal Control for Electric Vehicles”, Frontiers of Mechanical Engineering, 12(10), pp.5-7. DOI: 10.1007/s11465-019-0546-x

[3] L. Han, X.-F. Han, X.-P. Ou, & Y. Guo. (2019) “Operating Performances Analysis of Brushless Doubly-Fed Machine Using Magnetic Equivalent Circuit, Dianji yu Kongzhi Xuebao/Electric Machines and Control, 23(1), pp.27-34.

[4] Zadid Khan, Sakib Mahmud Khan, Mashrur Chowdhury, Ilya Safro, & Hayato Ushijima-Mwesigwa. (2019) “Wireless Charging Utility Maximization and Intersection Control Delay Minimization Framework for Electric Vehicles”, Computer-Aided Civil and Infrastructure Engineering, 13(1), pp.11-12.

[5] Dawei Pi, Qing Cheng, Boyuan Xie, Hongliang Wang, & Xianhui Wang. (2019) “A Novel Pneumatic Brake Pressure Control Algorithm for Regenerative Braking System of Electric Commercial Trucks”, IEEE Access, 5(99), pp.1-1. DOI: 10.1109/ACCESS.2019.2924739

[6] Alberto Cavallo, Antonio Russo, & Giacomo Canciello. (2019) “Hierarchical Control for Generator and Battery in the More Electric Aircraft”, Sciece China. Information Sciences, 62(9), pp.15-16.

[7] Magiera, A. (2017) “Control of Systematic Uncertainties in the Storage Ring Search for an Electric Dipole Moment by Measuring the Electric Quadrupole Moment, Dianji yu Kongzhi Xuebao/Electric Machines and Control, 20(9), pp.17-20. DOI: 10.1103/PhysRevAccelBeams.20.094001

[8] Diao, L., Jing, T., Loh, P. C., Yin, S. B., Lei, W., & Liu, Z. G. (2018) “An Efficient Dsp-Fpga-Based Implementation of Hybrid Pwm for Electric Rail Traction Induction Motor Control, Computer-Aided Civil and Infrastructure Engineering, 33(4), pp.32-38.

[9] Pavković, Danijel; Cipek, Mihael; Kljaić, Zdenko, Mlinarić, & Tomislav-Josip; Hrgetić. (2018) “Damping Optimum-Based Design of Control Strategy Suitable for Battery/Ultracapacitor Electric Vehicles, Energies, 21(2), pp.1-2.

[10] Guohui Zheng, San-Huang Ke, Maosheng Miao, Jinwoong Kim, & Nicholas Kioussis. (2017) “Electric Field Control of Magnetization Direction Across the Antiferromagnetic to Ferromagnetic Transition, Scientific Reports, 7(1), pp.53-66.

[11] Jinghua Guo, Yugong Luo, Jingyao Wang, Keqiang Li, & Tao Chen. (2019) “An adaptive Cascade Trajectory Tracking Control for Over-Actuated Autonomous Electric Vehicles with Input Saturation”, Science China Technological Sciences, 10(8), pp.4-6. DOI: 10.1007/s11431-018-9445-3

[12] X. Zhao, K. Peng, X. Zhang, Y. Chen, & Y. Guo. (2019) “Stability and Optimal Control of Multi-Terminal Flexible dc Distribution System Under Master-Slave Control Mode, Electric Power Automation Equipment, 2(7), pp.10-12.

[13] Osamu Yatsubo, Shota Miyake, & Nozomu Takada. (2018) “Technologies for Estimation and Forecasting of Photovoltaic Generation Output Supporting Stable Operation of Electric Power System, Ieej Transactions on Electrical & Electronic Engineering, 13(3), pp.1-2.

[14] P.-H. Tian, & J. Xu. (2018) “Design and Realization of Control System Based on Stepper Motion Driven by PLC for Limiter Displacement on hl-2a Tokamak”, Hejubian Yu Dengliziti Wuli/Nuclear Fusion and Plasma Physics, 38(4), pp.42-43.

[15] Wang, C., Liu, M., Aidong, X. U., & Zhang, J. (2017), “The Application of PLC Control System in Oil and Gas Pipeline Transportation”, 8(Supplement 1), 8(4), pp.13-17.

[16] SHI Lang-feng. (2015), “Research on the PLC Control System Based on the Multistorey Parking Garage of the Intelligent Community”, Value Engineering, 10(14), pp.3-4.

[17] Haijun Yu, Guofu Li, Liping Duo, Yuqi Jin, & Shukai Tang. (2015) “Data Acquisition and Control System with a Programmable Logic Controller (plc) for a Pulsed Chemical Oxygen-Iodine Laser”, Proceedings of SPIE - The International Society for Optical Engineering, 1(4), pp.13-14.

[18] Du, Y., Wang, C., Yang, T., & Zhang, B. (2016) “Design of Constant Tension Controlling System Based on PLC in Warping Machine”, Ieej Transactions on Electrical & Electronic Engineering, 15(8), pp.14-15.

[19] ZHANG Liang, HAN Yan-jun, WANG Yan-li, & Shijiazhuang Tiedao University. (2016) “Design of Pneumatic Deshuttering Manipulator Control System Based on PLC”, Chinese Hydraulics & Pneumatics,6(10), pp.23-24.

[20] Zhu, H., He, J., Fang, W., Ye, D., & Liang, S. (2017), “Design and Test of Small Fresh Lotus Seed Sheller”, Electric Power Automation Equipment, 33(7), pp.28-35.