https://semarakilmu.com.my/journals/index.php/sjotfe/issue/feed 2024-12-18T00:00:00+07:00 Open Journal Systems <p>The <strong>Semarak Journal of Thermal Fluid Engineering (SJOTFE)</strong> aims to advance scientific knowledge by publishing original research that significantly enhances the understanding and application of thermal and fluid dynamics principles in engineering. The journal seeks to showcase innovative experimental, theoretical, and computational solutions to complex problems, encourage interdisciplinary research, and highlight technological developments in energy systems, aerospace, automotive, and chemical processes. It promotes research focused on improving energy efficiency and sustainability and serves as an educational resource for engineers, researchers, and students. By fostering international collaboration and contributing to the establishment of standards and best practices, the journal aims to be a leading platform for the global thermal fluid engineering community.</p> <h3><strong>EVENTS UPDATE</strong><br /><br /><strong>Semarak International Research Article Competition 2024 III </strong>(SIRAC 2024 III)</h3> <p><a href="https://submit.confbay.com/conf/sirac2024_3"><strong><img src="https://akademiabaru.com/submit/public/site/images/nurulain/sirac-iii.png" alt="" width="931" height="470" /></strong></a></p> <div class="tribe-events-schedule tribe-clearfix">Welcome to our esteemed research article competition! We’re thrilled to invite scholars, researchers, and practitioners worldwide to showcase their groundbreaking [...] <a href="https://submit.confbay.com/conf/sirac2024_3"><strong>READ MORE &gt;&gt;</strong></a></div> https://semarakilmu.com.my/journals/index.php/sjotfe/article/view/13596 2024-11-27T12:02:34+07:00 Muhammad Zariq Imran Abdul Manap zariqimran92@gmail.com Hanani Abd Wahab nani@uthm.edu.my Winda Astuti Astuti wastuti@binus.edu

<p>Solar Photovoltaic (PV) technology, which converts solar radiation into electrical energy, is increasingly used in agriculture to power farm appliances. However, maintaining optimal environmental conditions for crop cultivation remains challenging. This study addresses this issue by integrating PV technology with an environmental monitoring and control unit to create a self-sustainable greenhouse, enhancing crop breeders’ efficiency. The primary problem addressed is the difficulty in maintaining stable temperature and humidity levels in mushroom cultivation environments. The research aims to develop and simulate a PV-powered temperature control system for an oyster mushroom house, chosen due to its high market demand. Using Matlab/Simulink, a working model simulation was created to analyze the system’s performance in maintaining optimal temperature and humidity levels. The simulation, based on energy balance equations, connects a mushroom house subsystem to Simscape electrical components and a solar panel. Simulation results indicate that the system can maintain a stable temperature around 25.7℃ throughout the day, regardless of ambient temperature variations. In conclusion, the study successfully developed a solar-powered temperature control system for oyster mushroom cultivation, demonstrating its potential to enhance the efficiency and sustainability of agricultural practices.</p>

2024-12-18T00:00:00+07:00 Copyright (c) 2024 Semarak Journal of Thermal-Fluid Engineering https://semarakilmu.com.my/journals/index.php/sjotfe/article/view/13631 2024-12-03T14:18:08+07:00 Md.Nor Anuar Mohamad anuarm@uthm.edu.my Wan Nur Azrina Wan Muhammad wazrina@uthm.edu.my Tuan Nurul Ain Tuan Kamaruddin ad200088@student.uthm.edu.my

<p>The process of powder metallurgy milling, which reduces solid metal to fine particles to improve its properties, is the subject of this study. The objective is to determine the RPM and time relationship for efficient grinding and to fabricate a small milling machine for powder applications. Particle size, time, and homogeneity requirements are examined. The milling machine is designed in SolidWorks. Aluminium chips are used for test runs. Particle sizes are evaluated at different times using an optical microscope. The Arduino control system and a 12 V DC motor are used. Longer grinding times consistently result in smaller chips. Based on the result, the average of the 5.79 mm chip size measurements made before milling was determined. Following the milling process, the sizes were 0.75 mm at two hours, 0.51 mm at four hours, and 0.27 mm at six hours. The study shows that the efficiency and particle size distribution of powder metallurgy milling can be improved using a small machine with a fixed bar and different types of grinding media. For effective milling, it is crucial to maximize mill rotation, as shown by critical speed analysis. To sum up, the study effectively creates a small milling machine for use in powder metallurgy procedures.</p>

2024-12-18T00:00:00+07:00 Copyright (c) 2024 Semarak Journal of Thermal-Fluid Engineering