Manutech : Jurnal Teknologi Manufaktur
Aims
Manutech adalah interdisciplinary journal yang mengajak para peneliti dari kalangan para akademisi maupun praktisi dari industri bergabung bersama dan berdiskusi dalam pengembangan keilmuan maupun penerapan teknologi manufaktur dan aspek-aspek lainnya yang terkait.
Scope
Lingkup jurnal Manutech adalah pada bidang teknologi manufaktur, mesin otomatis (automation), robotika dan elektronika, namun tidak membatasi pada hal ini saja dan dapat melingkupi bidang: Elektronika; Information and Communication Technology (ICT); Mesin dan manufaktur.
Articles
208 Documents
<![CDATA[Alat Pendeteksi Denyut Nadi Berbasis Arduino Yang Diinterfacekan Ke Komputer ]]>
<![CDATA[eko sulistyo]]>
<![CDATA[ Manutech : Jurnal Teknologi Manufaktur Vol. 8 No. 02 (2016): Manutech : Jurnal Teknologi Manufaktur ]]>
Publisher : <![CDATA[Politeknik Manufaktur Negeri Bangka Belitung ]]>
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DOI: 10.33504/manutech.v8i02.2
<![CDATA[Heartbeat/pulse is an important factor in the health sector that determines the health condition ofa person's body. The method of measuring the number of the pulses is still using the manual method bycalculating the rate of the heartbeat/pulse per minute. To know one's pulse, it needs to makemeasurements in the hospital, so not everyone can measure their own pulse. The solution of this problemis the manufacture of human pulse detection device that works automatically in real time and can beconnected with the computer. The purpose of this study is to help people or medical personnel incalculating the pulse rate digitally. The stages of this research is the pulse sensor used to detect thehuman pulse can be put on a three-site measurements, on a finger, ear and forehead, then processed bythe arduino mega 2560 as the central system. The measurement data is Beat Per Minute (BPM) will beshown to the LCD and can be also interfaced into a database using Visual Basic 6.0. The result shows thatthe average pulse measurement by using the tool is 77.3 BPM (Beat Per Minute) and manually is 76 BPM(Beat Per Minute) with the accuracy of this tool reaches 98.32% and it takes 10 seconds to display theaverage value of BPM (Beat Per Minute).]]>
<![CDATA[Rancang Bangun Mekanisme Fess Sebagai Alat Pembanding Pengaruh Geometri Flywheel Terhadap Energi Kinetik Yang Dihasilkan ]]>
<![CDATA[Adhe Anggry]]>;
<![CDATA[Yuli Dharta]]>;
<![CDATA[Andri Wiguna]]>;
<![CDATA[Armada Armada]]>;
<![CDATA[Ririn Martasari]]>
<![CDATA[ Manutech : Jurnal Teknologi Manufaktur Vol. 8 No. 02 (2016): Manutech : Jurnal Teknologi Manufaktur ]]>
Publisher : <![CDATA[Politeknik Manufaktur Negeri Bangka Belitung ]]>
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DOI: 10.33504/manutech.v8i02.3
<![CDATA[Recent days, more and more people are becoming interested in "free-energy". "Free-energy" means the energy sources used freely without to pay. The sources of "free-energy" are sunlight, rainfall, wind energy, wave power, and tidal power. There are other sources of power such as gravity, electrical charge in the atmosphere and ionosphere, and a mass. FESS (Flywheel Energy Storage System) is an attempt to store kinetic energy generated from the rotation flywheel in which the electrical power output from the generator as an input to the motor. Mass flywheel greatly affects the amount of power generated by a generator which will serve as a flywheel device or distributors of energy while at the induction generator to eventually convert mechanical energy into electrical energy and vice versa. In this system design becomes very important for the flywheel can store the kinetic energy. This research aims to design and build mechanisms as a means of comparison FESS flywheel effect of the geometry of the kinetic energy generated. The research method is done by making three different geometric design flywheels, and then analyzed with the help of FESS. From the experimental results, flywheel 1 with a ringtype web-concave generate kinetic energy of 312.30 J and specific energy of 31.23 J / kg, at the flywheel 2 which is type-straight arm kinetic energy gained by 316.73 J and energy specific of 31.67 J / kg and flywheel 3 with a ring-type web-straight kinetic energy obtained by 284.997 J and specific energy of 28.49 J / kg. From the research data we can conclude that each design geometry flywheel has a different contribution to the performance of energy storage.]]>
<![CDATA[Optimasi Multirespon Gaya Tekan Dan Momen Torsi Pada Penggurdian Material Komposit Glass Fiber Reinforce Polymer (Gfrp) yang Ditumpuk Dengan Material Stainless Steel (SS) Menggunakan Metode Algoritma Genetika ]]>
<![CDATA[Angga Sateria]]>
<![CDATA[ Manutech : Jurnal Teknologi Manufaktur Vol. 9 No. 01 (2017): Manutech : Jurnal Teknologi Manufaktur ]]>
Publisher : <![CDATA[Politeknik Manufaktur Negeri Bangka Belitung ]]>
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DOI: 10.33504/manutech.v9i01.10
<![CDATA[Glass fiber reinforced polymer (GFRP)-stainless steel stacks used in the aircraft structural components. The assembly process of this components requires mechanical joining using bolt and nut. The drilling process is commonly used for producing hole to position the bolt correctly. Thrust force and torque are responses that used to evaluate the performance of drilling process. The quality characteristic of these responses are “smaller-is-better.” The aim of this experiment is to identify the combination of process parameters for achieving required multiple performance characteristics in drilling process of GFRP-stainless steel stacks materials. The three important process parameters, i.e., point angle, spindle speed, and feed rate were used as input parameters. Point angle was set at two different levels, whilethe other two were set at three different levels. Hence, a 2 x 3 x 3 full factorial was used as designexperiments. The experiments were replicated two times. The optimization was conducted by using genetic algorithm method. The minimum thrust force and torque could be obtained by using point angle, spindle speed and feed rate of 118o, 2383 rpm, 62 mm/min respectively.]]>
<![CDATA[Rancang Bangun Mesin Penghancur Buah Kelapa Sawit Kapasitas 50 Kg/Jam ]]>
<![CDATA[Husman Husman]]>;
<![CDATA[Sugiyanto Sugiyanto]]>;
<![CDATA[Denny Saputra]]>;
<![CDATA[Ridho Rosmansyah]]>;
<![CDATA[Zulhelmi Zulhelmi]]>
<![CDATA[ Manutech : Jurnal Teknologi Manufaktur Vol. 8 No. 02 (2016): Manutech : Jurnal Teknologi Manufaktur ]]>
Publisher : <![CDATA[Politeknik Manufaktur Negeri Bangka Belitung ]]>
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DOI: 10.33504/manutech.v8i02.15
<![CDATA[The palm companies typically consist of the oil palm plantations and the palm oil mills. Besidesproduced from their own plantations, they also buy the palm oils, CPO, and the kernel (palm kernel) fromthe farmers or other processing plants. The productions of the oil palm plantations of the farmers sold tothe collectors, and the collectors sell the palm oils to a processing plant. According to the collectors, whosell the palm olis to the factory, the price is cheap though the palm oil is in a good quality. They think tocultivate oil palm themselves, but the price of oil palm processing machines cannot be reached by them.This study will make the palm fruit crushing machine capacity of 50 kg/h, which is expected to be used bythe oil palm farmers in order to increase the sales value of the plantation. The method adopted to solvethis problem is starting with the preparation of the list of requirements necessary products, manufactureand concept selection, component design, manufacturing of image detail engineering, manufacture andassembly and test tool functions. The trial results of the palm fruit crushing machine with capacity of 50kg/h can be chopping the palm fruit with a specific gravity of 0.8245kg/liter.]]>
<![CDATA[Pengaruh Jumlah Input Dan Membership Function Fuzzy Logic Control Pada Robot Keseimbangan Beroda Dua ]]>
<![CDATA[Indra Dwisaputra]]>;
<![CDATA[Tareg Mahmoud]]>;
<![CDATA[Meti Megayanti]]>;
<![CDATA[Irvan Budiawan]]>;
<![CDATA[Pranoto Hidaya R]]>
<![CDATA[ Manutech : Jurnal Teknologi Manufaktur Vol. 8 No. 02 (2016): Manutech : Jurnal Teknologi Manufaktur ]]>
Publisher : <![CDATA[Politeknik Manufaktur Negeri Bangka Belitung ]]>
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DOI: 10.33504/manutech.v8i02.16
<![CDATA[In this paper, a dynamic model of two-wheeled balancing robot has been created, and the two types of FLC has been designed. The Mamdani methods used on both FLC. The first FLC uses pendulum tilt angle theta (?) as the input and it requires the motor torque to keep the robot remains balanced as the output. The second FLC uses two inputs, the first input is theta (?) and the second input is the change in the value of theta (?) which is the output torque of the motor. The second plant model and FLC built by using Matlab Simulink. The first case is one input using 5 membership functions (mf). The second case is two inputs using the 5 and 7 mf. The characteristics and effects of the changes in the input and mf have been simulated in the Simulink and compared. By expanding the number of the inputs can reduce motor specification required in balancing robot. Meanwhile, by increasing the number mf, it can improve the performance of the controller much faster to reach the settling time.]]>
<![CDATA[Analisa Kenyamanan Kendaraan Multiguna Pedesaan Pada Kekasaran Jalan Iso 8608 ]]>
<![CDATA[Nanda Pranandita]]>
<![CDATA[ Manutech : Jurnal Teknologi Manufaktur Vol. 8 No. 02 (2016): Manutech : Jurnal Teknologi Manufaktur ]]>
Publisher : <![CDATA[Politeknik Manufaktur Negeri Bangka Belitung ]]>
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DOI: 10.33504/manutech.v8i02.18
<![CDATA[The vehicle suspension system is an important part to minimize the vibration of the vehicle caused by road unevenness. The classification of the road surface in this study is based on the classification of road roughness "Good" according to ISO 8606. The analysis of passive suspension system in this research may explain the frequency response which is received by the motorists while driving. The full car model with 1 DOF riders used in this study, simulated by using the numerical simulation software. The frequency response analysis is done on the vertical movement of the driver. Based on the analysis performed, the highest acceleration of 2.375 m / s2 at a frequency of 3.258 Hz. This value indicates the condition of "Uncomfortable" based on the table of ISO 2631. This condition will cause the rider toexperience dizziness, therefore it is strongly advised motorists to avoid frequencies below 7 Hz.]]>
<![CDATA[Rancang Bangun Mesin Pencetak Terasi Untuk Memudahkan Proses Penjualan Dengan Berat 110 Dan 250 Gram ]]>
<![CDATA[Robert Napitupulu]]>;
<![CDATA[Zaldy Kurniawan]]>;
<![CDATA[Erin Aftarini]]>;
<![CDATA[Firdi Irawan]]>;
<![CDATA[Gilang Perdana]]>
<![CDATA[ Manutech : Jurnal Teknologi Manufaktur Vol. 8 No. 02 (2016): Manutech : Jurnal Teknologi Manufaktur ]]>
Publisher : <![CDATA[Politeknik Manufaktur Negeri Bangka Belitung ]]>
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DOI: 10.33504/manutech.v8i02.19
<![CDATA[Terasi is one of the basic ingredients in the food processing, particularly in the area of the base Kep.Bangka Belitung province. The paste of the terasi in the market are generally shaped in the massive beams that make them difficult to distribute to the sellers because the market demand such varied size of 110 and 250 grams. The purpose of this study is to design and make the terasi paste printing machine which can cut to size shrimp paste with a uniform weight of 110 and 250 grams. The method used in solving this problem is based on the method design: Identification of Problems, collecting data by observation, interview, and literature, and performing data processing, Creating the design, manufacture machinery / fabricating, assembling and final testing and analyzing. The test result is that the form of paste printed measuring 61x30x45 with an average weight of 110 grams and the paste to paste the printed results of measuring 150x30x45 with an average weight of 250 grams shrimp paste.]]>
<![CDATA[Analisa Kinerja Cyclone Combustor Pada Proses Downdraft Gasifier Dengan Media Sekam Padi Untuk Kapasitas 10 Kg/Jam ]]>
<![CDATA[A Wahyu Cahyo Purnomo]]>;
<![CDATA[F X Eko Arianto]]>
<![CDATA[ Manutech : Jurnal Teknologi Manufaktur Vol. 8 No. 02 (2016): Manutech : Jurnal Teknologi Manufaktur ]]>
Publisher : <![CDATA[Politeknik Manufaktur Negeri Bangka Belitung ]]>
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DOI: 10.33504/manutech.v8i02.20
<![CDATA[Biomass potency in Indonesia is very abundant both from the animal manure or plant. Agriculture and plantations waste which are abundant can be utilized as the energy source. One of them is the rice husk. This experiment used rice husk gasification method with downdraft gasifier to turn it into a combustible gas that will be burned in the combustion chamber cyclone. The advantage of gasification compared to the method of the direct combustion is cleaner burning and particulates and contaminants can be removed before burning. The cyclone fuels can produce good mixing which is suitable for gas with low calorific value. The composition of syngas produced by gasification of rice husk are H2 13,6%, CO 14,9%, CO2 12,9% dan CH4 2,3% [1]. After leaving the reactor syngas entry cyclone separator to remove moisture and contaminants, and then go to the storage tank and eventually went to cyclone fuel to be burned after mixing with air through a different inlet. After that the different value of AFR will vary to see the changes in temperature of the flame, the fire position in the combustion chamber and the flame shape. From the experimental results in AFR = 1.59 fire in the combustion chamber air beetween 1 and 2, in the AFR = 1.14 The fire in the combustion chamber in the plane 2, in AFR = 0.69 fire in the combustion chamber 3 and in the air beetween AFR = 0.27 fire outside the combustion chamber after mixing withfresh air.]]>
<![CDATA[Identifikasi Pola Iris Menggunakan Metode Backpropagation ]]>
<![CDATA[Yoan Elviralita]]>;
<![CDATA[Asrul Hidayat]]>
<![CDATA[ Manutech : Jurnal Teknologi Manufaktur Vol. 8 No. 02 (2016): Manutech : Jurnal Teknologi Manufaktur ]]>
Publisher : <![CDATA[Politeknik Manufaktur Negeri Bangka Belitung ]]>
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DOI: 10.33504/manutech.v8i02.21
<![CDATA[In recent years, there has been a lot of research related to pattern recognition is conducted to identify various forms of patterns and controlling system. Utilizing backpropagation neural network in pattern identifying is very useful to solve problems with unknown parameter and difficult to determined. And then the data of the pattern are trained and tested. The results obtained from the recognition rate indicates a backpropagation neural network, provide excellent performance, which is an average of 98%. This neural network is expected to be developed by other researchers for the advancement of knowledge in all fields.]]>
<![CDATA[Sistem Komunikasi Jarak Jauh Alat Pengukur Kecepatan Dan Arah Angin Berbasis Mikrokontroller ]]>
<![CDATA[Yudhi Yudhi]]>;
<![CDATA[Jamalludin Jamalludin]]>
<![CDATA[ Manutech : Jurnal Teknologi Manufaktur Vol. 8 No. 02 (2016): Manutech : Jurnal Teknologi Manufaktur ]]>
Publisher : <![CDATA[Politeknik Manufaktur Negeri Bangka Belitung ]]>
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DOI: 10.33504/manutech.v8i02.22
<![CDATA[Monitoring wind speed and direction is usually performed at close range, therefore,it is necessaryto monitor remotely for time efficiencies. Making these systems start with a literature study the data relating to the technology to be used. Then the data was processed to determine the design of the system being designed. Making this system begins with a measuring instrument wind speed and wind direction. In this device for chopping round of the wind speed sensor using optocoupler. And magnetic hall sensor, constructed as a weathervane as a determinant of the wind direction sensor. RTC is used as time refference of measurement. Arduino Mega 2560 Microcontroller used to process data obtained from sensors and RTC. Then the data is the data is recorded with a cycle which can be set. After the manufacture of measuring devices and then proceed to make the data transmission system and application interface. With GSM shield Sim900a data that has been recorded is sent in the form of SMS through GSM network. Then the data is received by GSM shield servers and read by Arduino UNO. Data is read by Arduino UNO is then sent to a computer with serial communication. The data is sent to the computer will be processed by the application interface to be stored and displayed. The results of this system is able to measure and store data speed and direction of the wind from a distance. With a windspeed error of 4.56% of the measurements manually, and wind direction indicates the actual wind direction.]]>
