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All Journal Jurnal Teknik Mesin, Industri, Elektro dan Informatika Clean Energy and Smart Technology
Danu Prasetyo
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Civil Engineering, Building, Construction & Architecture Computer Science & IT Control & Systems Engineering Decision Sciences, Operations Research & Management Electrical & Electronics Engineering Industrial & Manufacturing Engineering Mechanical Engineering

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ANALISIS MEKANIK DAN TERMAL PISTON MESIN PEMBAKARAN DALAM MENGGUNAKAN SOFTWARE ANSYS 2023 Muhammad Taufiqurrahman; Agung Raharjo; Auzan Faizdaffa Hakim; Danu Prasetyo; Trisma Jaya Saputra
Jurnal Teknik Mesin, Industri, Elektro dan Informatika Vol. 2 No. 3 (2023): September : JURNAL TEKNIK MESIN, INDUSTRI, ELEKTRO DAN INFORMATIKA
Publisher : Pusat Riset dan Inovasi Nasional

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.55606/jtmei.v2i3.2127

Abstract

Sebagai bagian utama dari mesin pembakaran dalam, piston berfungsi sebagai penggerak utama pada mesin pembakaran dalam, yaitu memindahkan tenaga yang dihasilkan oleh pembakaran bahan bakar di dalam ruang bakar menuju mekanisme penggerak lainnya seperti crankshaft. Penelitian ini bertujuan untuk mengukur kekuatan dan ketahanan material piston tertentu, serta untuk mengetahui faktor-faktor yang mempengaruhi keausan piston. Selain itu, analisis termal dilakukan untuk mengetahui distribusi suhu pada piston dan mengukur pengaruh suhu pada kinerja mesin. Dalam penelitian ini, kami akan menggunakan metode elemen hingga untuk melakukan simulasi numerik terhadap piston mesin pembakaran dalam. Simulasi pengujian yang dilakukan pada piston menggunakan software Ansys 2021 R3 dan pembuatan model tiga dimensi CAD dari piston kepala datar menggunakan perangkat lunak SOLIDWORKS tahun 2022. Material yang digunakan pada piston adalah paduan aluminium AlSi10Mg. Dilakukan dua simulasi Steady State Thermal, dan Static Structural. Simulasi Steady State Thermal menghasilkan distribusi temperatur dan total heat flux. Sedangkan simulasi Static Structural menghasilkan total deformasi, equivalent (von-mises) stress, tegangan geser, dan tegangan normal.
OPTIMIZATION OF THE STRUCTURAL DESIGN OF THE CHASSIS OF AN AUTOMATED GUIDE VEHICLE USING EXPERIMENTAL AND NUMERICAL METHODS Danu Prasetyo; Sunaryo; Heru Nugroho; Budi Santoso
Clean Energy and Smart Technology Vol. 4 No. 2 (2026): April
Publisher : Nacreva Publisher

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58641/cest.v4i2.204

Abstract

Automated Guided Vehicles (AGVs) are a smart transportation solution that is increasingly being used in industry. The stability and strength of the chassis are critical factors in ensuring AGV performance when carrying loads. This study examines the effects of load variations and material types on the structural performance of AGV chassis through an experimental approach and numerical simulation based on Finite Element Analysis (FEA). The materials used were ASTM A36 and ASTM A500, with loads of 5 kg, 10 kg, and 15 kg. A chassis design with dimensions of 400 × 300 × 80 mm was modeled and analyzed using Computational Fluid Dynamics (CFD) software. Validation was performed through experimental testing using a dial indicator. The results show that at a 15 kg load, ASTM A500 experienced a maximum stress of 60.15 MPa and a deflection of 0.00078 m, lower than ASTM A36, which reached 68.06 MPa and a deflection of 0.00089 m. The difference between the simulation and experimental results was well below 10%. Similarly, regarding the safety factor, ASTM A500 has a value of 2.7145 at maximum load, indicating that this material has a higher safety margin compared to ASTM A36. Based on these results, ASTM A500 is considered more efficient and stable, and is more recommended for AGV chassis applications. This study highlights the importance of integrating numerical and experimental methods to produce optimal structural designs.
Co-Authors Auzan Faizdaffa Hakim Budi Santoso Heru Nugroho Muhammad Taufiqurrahman RR. Ella Evrita Hestiandari Sunaryo Trisma Jaya Saputra