SCADA-Based Heliostat Control System with a Fuzzy Logic Controller for the Heliostat Orientation

Salgado-Plasencia Salgado-Plasencia,Rivas-Araiza Rivas-Araiza,Carrillo-Serrano Carrillo-Serrano,Toledano-Ayala Toledano-Ayala

doi:10.3390/app9152966

Salgado-Plasencia Salgado-Plasencia, Rivas-Araiza Rivas-Araiza + Show 2 more

Open Access

https://doi.org/10.3390/app9152966

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Journal: Applied sciences	Publication Date: Jul 24, 2019
Citations: 7	License type: CC BY 4.0

Affiliation: Autonomous University of Queretaro

Abstract

In central receiver systems, there are local controls that modify the position of the heliostats, where the trend is to increase the intelligence of the local controls in order to give them greater autonomy from the central control. This document describes the design and construction of a SCADA (Supervisory Control and Data Acquisition)-based heliostat control system (HCS) with a fuzzy logic controller (FLC) for the orientation control. The HCS includes a supervisory unit with a graphical user interface, a wireless communication network, and a stand-alone remote terminal unit (RTU) implemented on a low-cost microcontroller (MCU). The MCU uses a solar position algorithm with a maximal error of 0.0027° in order to compute the position of the sun and the desired angles of the heliostat, according to a control command sent by the supervisory unit. Afterwards, the FLC orients the heliostat to the desired position. The results show that the RTU can perform all the tasks and calculations for the orientation control by using only one low-cost microcontroller with a mean squared error less than 0.1°. Besides, the FLC orients the heliostat by using the same controller parameters in both axes. Therefore, it is not necessary to tune the controller parameters, as in the traditional PID (Proportional-Integral-Derivative) controllers. The system can be adapted in order to control other two-axis solar-tracking systems.

Highlights

The use of renewable energy resources has grown as a result of the concerns about CO2 emissions, dependence on fossil fuels, as well as climate change
It is powered by a 24 V power supply for the motor driver circuits, and it is regulated at 5 V and 3.3 V in order to provide the power to the remote terminal unit (RTU) components
The mobile app consists of the buttons for the Bluetooth connection, labels that show the operation status (OS) of the RTU, and the control buttons

Summary

Introduction

The use of renewable energy resources has grown as a result of the concerns about CO2 emissions, dependence on fossil fuels, as well as climate change. In order to collect solar energy, it is necessary to know the position of the sun throughout the day. This can be achieved by using a solar tracker, which combines a mechanical structure with electronic feedback devices. Solar trackers are divided into single-axis or two-axis trackers. In single-axis solar trackers, the tracking system drives the rotation axis until the normal component of the mechanical structure and the solar vector are coplanar, whereas the double-axis solar trackers follow the sun in the horizontal and the vertical plane [2]. The solar tracking systems are divided into three classifications: the sensor driver systems (SDS), which determine the position of the sun using solar

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