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Journal of Industrial Automation and Electrical Engineering

jiaee
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Published by Universitas Negeri Padang

ISSN : - EISSN : 30891159 DOI : -

Core Subject : Science, Engineering,

Control & Systems Engineering Electrical & Electronics Engineering Energy Engineering

Journal of Industrial Automation and Electrical Engineering (JIAEE) is an open-access peer-reviewed journal which is providing a platform to researchers, scientists, engineers, and practitioners/professionals throughout the world to publish the latest creations and achievement, future challenges and exciting applications of manufacture and applications of instrumentation and control engineering, industrial automation, control system, robotics, power electronic and drive, renewable energy, SCADA and Internet of Things (IoT), power quality, electrical machine and drive, artificial intelligence (AI), circuits & electronics, electrical engineering materials, protection system, power system analysis etc. This journal is published periodically twice a year, namely in June and December.

Arjuna Subject : Teknik (semua kategori) - Teknik Kontrol dan Sistem

Articles 125 Documents

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Realization of Single Phase Full Bridge Boost Inverter Using Arduino Farahilla, Wahyu; Faradina, Nevi; Yuhendri, Muldi
Journal of Industrial Automation and Electrical Engineering Vol. 1 No. 1 (2024): Vol 1 No 1 (2024): June 2024
Publisher : Department of Electrical Engineering Universitas Negeri Padang

Show Abstract | Download Original | Original Source | Check in Google Scholar

This paper discusses a single-phase boost inverter that functions to increase and convert DC voltage to AC. A boost inverter is a combination of two DC-DC boost converters that can be operated as an inverter with a load connected in an opposite direction between the two converters. The boost inverter in this final project is implemented with an Arduino UNO328 microcontroller using the sinusoidal pulse width method (SPWM) as a trigger. The output frequency value given varies from 50Hz to 70Hz. In the design of this single-phase boost inverter, it consists of several main components, namely the Arduino microcontroller, which functions as a pulse width modulation signal generator; a MOSFET gate driver using the IR2841S IC functions to switch the IRFP260N MOSFET, where the MOSFET is switched with a constant frequency of 30 kHz and a 5V power supply as a voltage supply for Arduino and a 12V supply voltage for the gate driver; as well as capacitors and inductors. The test results in the design of this single-phase boost inverter run according to the design because the circuit has been able to increase and convert the voltage, namely from an input voltage of 12VDC to 31.59Vac with an output frequency of 50Hz. The selection of component quality in the circuit also affects getting more accurate results

Internet of Things (IoT) implementation through Node-RED to control and monitoring induction motors Bahri, Faisal; Ta ali; Hendra, Ayu
Journal of Industrial Automation and Electrical Engineering Vol. 1 No. 1 (2024): Vol 1 No 1 (2024): June 2024
Publisher : Department of Electrical Engineering Universitas Negeri Padang

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.24036/

The Internet of Things (IoT) is a technology that plays an important role in the contemporary era, especially in the industrial sector. The Internet of Things allows remote access of physical objects at any time and from any location, simply by establishing an internet connection. Thus, in the control and monitoring of motors remotely, IoT allows adjusting the speed and direction of rotor rotation. The motor used is a 0.75 kW Siemens induction motor. To adjust the speed and direction of rotor rotation of the motor, a Sinamic G120 programmable logic controller S7-1200 VSD is programmed via TIA Portal to serve as the central controller for all induction motor control. A multi-interface system consisting of a KTP 700 Comfort HMI, a PC server, and clients in the form of PC and smartphone clients was used for control and monitoring of the induction motor. The visual interface of the HMI interface was designed using TIA Portal, while the visual interface of the server and client was designed using Node-RED. The PC server, PLC, HMI, and VSD are all connected via Ethernet. At the same time, the connection of the Internet of Things (IoT) client, which is integrated with the server, is connected via the Internet network. Research on IoT-based control and monitoring of induction motors through the Node-RED proposal has been successful and works as intended

Design and implementation of buck-boost converter using Atmega 8535 microcontroller Aslimeri; Anggraini, Widya; Yuhendri, Muldi
Journal of Industrial Automation and Electrical Engineering Vol. 1 No. 1 (2024): Vol 1 No 1 (2024): June 2024
Publisher : Department of Electrical Engineering Universitas Negeri Padang

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To achieve the desired DC voltage, a variety of DC-DC converter types are employed, including buck converters, which can generate output voltages lower than the input voltage, boost converters, which can generate output voltages higher than the input voltage, and buck-boost converters, which can raise and lower the output voltage value based on the input voltage value. MOSFET is used in this study's buck-boost converter design because to its lower cost. The Pulse Widening Technique, commonly known as the Pulse Width Modulation (PWM) approach, is one way to control the MOSFET modulation pulse. In designing the buck-boost converter using the ATMega8535 microcontroller, it consists of several main components, namely: The ATMega8535 microcontroller functions as a PWM signal generator, the MOSFET gate drive consists of an optocoupler 4N25 IC, which is used for switching the IRFP 250N MOSFET. In this study, a buck-boost converter will be made that can increase and decrease DC voltage. The output voltage setting of the buck-boost converter can be done by adjusting the power switch modulation pulse used in the buck-boost converter. The test results of the buck-boost converter circuit show that the converter can work well to increase and decrease the voltage according to the desired set point. Both in testing the tool with different loads and constant voltage, the tool is able to work as desired

Enhance the voltage drop in the end costumer of PT. PLN ULP 50 Kota using insertion transformer arif, Syafwanil; Habibullah
Journal of Industrial Automation and Electrical Engineering Vol. 1 No. 1 (2024): Vol 1 No 1 (2024): June 2024
Publisher : Department of Electrical Engineering Universitas Negeri Padang

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Loading that exceeds the capacity of the transformer if left unchecked will damage the transformer itself; apart from that, it can also cause drop voltage along the conductor, which causes electricity services to customers to be disrupted, especially at the customer end. The results of research at PT PLN (Persero) ULP 50 Kota Suliki Service Office revealed that of the 108 existing transformers, the GD 175 Kasiak Rampung transformer experienced overload with a percentage of 99%, and the end voltage measurement was 177 volts. This figure does not comply with the standards set by PLN. An insert transformer was built as an improvement effort so that the loading percentage decreased to 45% and the end voltage became 277 volts. This effort provides benefits, namely improving the quality of customer service, increasing electricity sales, reducing ENS if there are maintenance efforts, and improving the company's image.

Backpropagation neural network for DC-DC boost converter control using arduino microcontroller Dwi Saputra, Robi; Yuhendri, Muldi
Journal of Industrial Automation and Electrical Engineering Vol. 1 No. 1 (2024): Vol 1 No 1 (2024): June 2024
Publisher : Department of Electrical Engineering Universitas Negeri Padang

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One kind of power converter that is frequently found in devices that employ a DC voltage source to produce a voltage output higher than the input voltage is the boost converter. The boost converter output voltage converter must be adjusted in order to produce the desired voltage output. This research suggests utilizing an Arduino Mega 2560 microcontroller implemented backpropagation-type artificial neural network to manage the boost converter output voltage. The highest output voltage of the boost converter is 24 volts, and its input voltage is 12 volts. Laboratory tests using different reference voltages and loads are used to validate the boost converter voltage control system based on a backpropagation neural network. Experiments conducted under a variety of test conditions demonstrate that the backpropagation neural network-based boost converter output voltage control system used in this study has effectively controlled the boost converter output voltage in accordance with the reference output voltage value, both when the load and the reference voltage are varied.

Smart trolley based on client server and computer vision habiby, Gusvito; Muskhir, Mukhlidi; Mukhaiyar, Riki; Habibullah; Luthfi, Afdal
Journal of Industrial Automation and Electrical Engineering Vol. 1 No. 1 (2024): Vol 1 No 1 (2024): June 2024
Publisher : Department of Electrical Engineering Universitas Negeri Padang

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Technological advances have significantly changed many aspects of human life, including shopping activity. The modern retail environment must provide extraordinary customer satisfaction in order to remain competitive. With the Smart Trolley, an automated shopping cart integrated with a payment and pricing system, offers solutions to a shopping challenge that can scan the price of goods. The study explores the development and implementation of Smart Trolley based on client-server architecture and computer vision technology. The Smart Trolley is equipped with a mini PC (Raspberry Pi), a barcode scanner, and an LCD display to display the total cost of goods when they are added to the cart. In addition, it supports non-cash payments and can reduce waiting time at the cashier. Server connections allow real-time monitoring by store staff and prevent fraud. The results of the implementation show that Smart Trolley effectively helps consumers to see the prices of goods, imitate the quarters at the cashier, and improve the security of transactions. This innovative solution aims to simplify the shopping experience, providing a more efficient and comfortable process for consumers in a modern market shopping experience

Real-time protection and monitoring of three phase induction motor using arduino Masely, Fahrul; Tri Putra Yanto, Doni; Yelfianhar, Ichwan; Elvanny Myori, Dwiprima
Journal of Industrial Automation and Electrical Engineering Vol. 1 No. 1 (2024): Vol 1 No 1 (2024): June 2024
Publisher : Department of Electrical Engineering Universitas Negeri Padang

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Electric motor protection in modern industry is increasingly important along with technological developments and the need to maintain operational reliability and prevent unwanted disturbances. This research develops an Arduino Mega-based three-phase induction motor protection system that uses PZEM-004T sensors to monitor current and voltage, and MAX6675 sensors to accurately measure motor temperature. The monitoring data is displayed in real-time on the ILI9341 TFT LCD screen, enabling early detection of abnormal conditions such as overheat, over current, and voltage imbalance. The system provides a quick response to protect motors from potential damage, ultimately preventing significant losses and ensuring operational continuity and energy efficiency in increasingly complex industrial environments

Sorting objects based on weight using the Internet of Things (IoT) Muhammad Habibi Alfajri, Muhammad; Sukardi
Journal of Industrial Automation and Electrical Engineering Vol. 1 No. 1 (2024): Vol 1 No 1 (2024): June 2024
Publisher : Department of Electrical Engineering Universitas Negeri Padang

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This research aims to design and implement a goods sorter based on weight using Arduino Nano, equipped with a web-based monitoring system. The system uses a load cell sensor to detect the weight of items and classify them into three different categories. The Internet of Things (IoT) concept is applied to enable real-time monitoring through Google Sheets, where the sorting data is automatically sent and stored on the web. The test results show that this tool successfully improves efficiency and accuracy in the process of sorting goods in the industry. Additionally, this tool can reduce costs typically incurred for procuring checkweigher devices and ensure compliance with quality standards regulated by consumer protection laws. Based on the analysis of the test data, this system can function well according to the specified requirements, with several recommendations for improving accuracy and further developing monitoring features

Design and implementation of quadratic boost converter employing arduino microcontroller Kurnia Deca Nevil, Prayoga; Yuhendri, Muldi
Journal of Industrial Automation and Electrical Engineering Vol. 1 No. 1 (2024): Vol 1 No 1 (2024): June 2024
Publisher : Department of Electrical Engineering Universitas Negeri Padang

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In modern power conversion applications, efficiency and the ability to significantly boost the voltage are two important aspects to consider. This article discusses the design and analysis of the Quadratic Boost Converter (QBC), a power converter that offers a higher voltage boost ratio compared to conventional boost converters. The Quadratic Boost Converter uses two inductors and two capacitors arranged in such a way as to boost the input voltage to a higher level with better efficiency. This study includes simulations and laboratory experiments to measure the performance of the Quadratic Boost Converter under various load and input voltage conditions. The results show that the Quadratic Boost Converter is not only able to achieve a higher voltage boost ratio but also has better efficiency under various operating conditions. This study also highlights the advantages of the Quadratic Boost Converter in solar power systems and electric vehicle applications, where significant voltage boost and high efficiency are highly required. Thus, the Quadratic Boost Converter is a potential solution for the need for more efficient and effective power conversion in various modern electronic applications

Supervisory control and data acquisition system for solar panel based on Internet of things (IoT) Raihan Alfiansyah, Muhammad; Ta ali; Yuhendri, Muldi; Sardi, Juli
Journal of Industrial Automation and Electrical Engineering Vol. 1 No. 1 (2024): Vol 1 No 1 (2024): June 2024
Publisher : Department of Electrical Engineering Universitas Negeri Padang

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Supervisory control and data acquisition (SCADA) system on IoT-based solar power plant using HMI, PC, and Smartphone interfaces. HMI uses KTP 700 Comfrot, Siemens S7-1200 PLC connected to the internet via Ngrok, using Siemens TIA Portal V17. The purpose of monitoring the realtime state of the PLTS such as the condition of batteries, solar panels, inverters and loads used and maintaining from troubleshooting. This research designs hardware and software devices to develop a SCADA system. including PLC, HMI, PC, battery, SCC, inverter, solar panel and sensor devices and other actuators are arranged in such a way. software design is carried out in TIA Portal to program PLC and HMI, Node Red as an implementation of the internet of things. in the research it can be concluded that the application of ngrok on the localhost system is very easy, because it does not require a homebase to connect with an external network. and the output of solar panels is not always monitored by the temperature and solar radiation of the SCADA system on solar power plants based on the internet of things. the implementation of the internet of things uses Node Red and Ngrok software as a link between localhost and external networks. So the internet of things in this test can be controlled and monitored remotely with a cacatan must always be connected to the internet. Monitoring, control and data access systems work well

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Home Page

OAI Link

Editorial Team

Contact

Reviewer

Google Scholar

Contact Name
Muldi Yuhendri

Contact Email
muldiy@ft.unp.ac.id

Phone
+6281332008021

Journal Mail Official
jiaee@ppj.unp.ac.id

Editorial Address
Departement Teknik Elektro, Universitas Negeri Padang Jl. Prof. Hamka Air Tawar Padang, 25131

Location
Kota padang,

Sumatera barat

INDONESIA

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Home Page

OAI Link

Editorial Team

Contact

Reviewer

Google Scholar

Contact Name Muldi Yuhendri

Contact Email muldiy@ft.unp.ac.id

Phone +6281332008021

Journal Mail Official jiaee@ppj.unp.ac.id

Editorial Address Departement Teknik Elektro, Universitas Negeri Padang Jl. Prof. Hamka Air Tawar Padang, 25131

Location Kota padang, Sumatera barat INDONESIA

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

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Abstract

Contact Name
Muldi Yuhendri

Contact Email
muldiy@ft.unp.ac.id

Phone
+6281332008021

Journal Mail Official
jiaee@ppj.unp.ac.id

Editorial Address
Departement Teknik Elektro, Universitas Negeri Padang Jl. Prof. Hamka Air Tawar Padang, 25131

Location
Kota padang,

Sumatera barat

INDONESIA