SCADA implementation in microhydro power plant control and monitoring systems of screw turbine type

Q4 Engineering

ARPN Journal of Engineering and Applied Sciences Pub Date : 2024-05-15 DOI:10.59018/032449

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引用次数: 0

Abstract

Screw turbine-type micro-hydro power plants are still controlled manually by humans when there is a change in the electrical load on the generator output. If there is a change in the electrical load, the generator output voltage will change, thus affecting the rotation of the turbine being used. In this case, humans are needed to manually regulate the flow of water entering the turbine to maintain the stability of the generator output voltage by controlling the sluice gate. The water discharge entering the screw turbine will rotate the generator through a belt/gearbox pulley transmission, thus producing an electrical voltage at the generator output. To maintain the stability of the generator output voltage, it is necessary to control the water discharge entering the screw turbine. The expected goal of this research is to design a control system for a screw turbine type microhydro power plant to stabilize the generator output voltage and monitor the output of a screw turbine type generator using a SCADA (Supervisory Control, and Data Aquisition) system. The method used is the research and development method, namely the system design stage based on secondary data that has been collected, where the system design includes hardware design and software design, followed by making hardware such as control panels and devices. Software, which includes display design and leader diagrams and testing, is carried out by testing the system on software, hardware, and overall system testing. From the results of the discussion and analysis, the screw turbine type microhydro power plant control design system was created, a load control system consisting of 6 groups and sluice gate opening control that uses an ultrasonic sensor to determine the water level. With the results of controlling the sluice gate at a door opening of 30 mm, the generator voltage is 18.42 Volts DC, DC current is 0.0 Ampere at a load of 0 watts, when the load is 30 watts the generator voltage decreases by 18.40 volts, current is 1.37 Ampere. Through the on-line monitoring system, electrical parameters are obtained which are displayed on the SCADA system by looking in real-time at the history of DC voltage and DC current, DC power, and DC energy generated by the screw turbine-type DC generator. The voltage read is 18. 57 volts, current 1.37 Amperes, DC electrical power is 25.4 watts with a DC light load of 30 watts.

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在螺杆涡轮机型微型水电站控制和监测系统中实施 SCADA 系统

当发电机输出的电力负荷发生变化时，螺杆涡轮机式微型水电站仍由人工控制。如果电力负荷发生变化，发电机输出电压就会发生变化，从而影响所使用水轮机的旋转。在这种情况下，需要人工通过控制水闸来调节进入水轮机的水流，以保持发电机输出电压的稳定。进入螺旋涡轮机的水流将通过皮带/齿轮箱滑轮传动装置带动发电机旋转，从而在发电机输出端产生电压。为了保持发电机输出电压的稳定，有必要控制进入螺旋水轮机的出水量。本研究的预期目标是为螺杆涡轮机型微型水电站设计一个控制系统，以稳定发电机输出电压，并使用 SCADA（监督控制和数据采集）系统监控螺杆涡轮机型发电机的输出。所采用的方法是研究和开发方法，即根据收集到的二手资料进行系统设计阶段，系统设计包括硬件设计和软件设计，然后制作控制面板和设备等硬件。软件包括显示设计和领导图以及测试，通过对软件、硬件和整个系统的测试进行系统测试。根据讨论和分析的结果，创建了螺杆水轮机型微水电站控制设计系统，该系统由 6 组负荷控制系统和使用超声波传感器确定水位的水闸开闸控制组成。水闸开度为 30 毫米时，发电机的直流电压为 18.42 伏，直流电流为 0.0 安培，当负载为 30 瓦时，发电机的电压降低了 18.40 伏，电流为 1.37 安培。通过在线监控系统，可以实时查看螺杆涡轮直流发电机产生的直流电压、直流电流、直流电功率和直流电能的历史记录，从而获得电气参数并显示在 SCADA 系统上。电压读数为 18.直流电功率为 25.4 瓦，直流轻负载为 30 瓦。

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来源期刊

ARPN Journal of Engineering and Applied Sciences Engineering-Engineering (all)

CiteScore

0.70

自引率

0.00%

发文量

期刊介绍： ARPN Journal of Engineering and Applied Sciences (ISSN 1819-6608) is an online peer-reviewed International research journal aiming at promoting and publishing original high quality research in all disciplines of engineering sciences and technology. All research articles submitted to ARPN-JEAS should be original in nature, never previously published in any journal or presented in a conference or undergoing such process across the globe. All the submissions will be peer-reviewed by the panel of experts associated with particular field. Submitted papers should meet the internationally accepted criteria and manuscripts should follow the style of the journal for the purpose of both reviewing and editing. Our mission is -In cooperation with our business partners, lower the world-wide cost of research publishing operations. -Provide an infrastructure that enriches the capacity for research facilitation and communication, among researchers, college and university teachers, students and other related stakeholders. -Reshape the means for dissemination and management of information and knowledge in ways that enhance opportunities for research and learning and improve access to scholarly resources. -Expand access to research publishing to the public. -Ensure high-quality, effective and efficient production and support good research and development activities that meet or exceed the expectations of research community. Scope of Journal of Engineering and Applied Sciences: -Engineering Mechanics -Construction Materials -Surveying -Fluid Mechanics & Hydraulics -Modeling & Simulations -Thermodynamics -Manufacturing Technologies -Refrigeration & Air-conditioning -Metallurgy -Automatic Control Systems -Electronic Communication Systems -Agricultural Machinery & Equipment -Mining & Minerals -Mechatronics -Applied Sciences -Public Health Engineering -Chemical Engineering -Hydrology -Tube Wells & Pumps -Structures

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