DETERMINING THE DAMPING FACTOR OF THE RULER IN WATER USING LOGGER PRO
Abstract
This study aims to determine the value of the damping coefficient in water for a ruler using three types of materials and two different oscillation directions. The research problem is how the damping coefficient of several types of solids oscillates in water. The type of oscillating solid is a ruler whose materials are made of aluminum, iron, and stainless steel with varying lengths and widths . The research method used is an experiment with a water sample at a temperature of 200C with a viscosity value of 1,00 mPa.s found in the faucet of the physics laboratory of the University of Sanata Dharma Yogyakarta. The data collection tool used is Video Logger Pro, which is considered to be accurate in measuring attenuation for each time it makes observations on each type of solid. Based on the results of the study by swinging the ruler in different oscillation modes at a declination angle of < 10 0, with variations in length being cut 9,5 cm, then each of them was cut back twice with the next 2 cm in length, creating three variations in length. Cut the width variation from the initial 2,6cm wide, then cut the next 0,3cm width twice so there are three width variations. Based on the results of the study, it was found that the smaller the moment of inertia, the smaller the value of the damping coefficient
Downloads
References
Fowles, and cassiday. (2005). Analytical mechanics seventh edition. United States of America: Thomson brooks/cole.
Giancoli, Douglas C. (2014). Fisika: Jilid 2 Edisi 7. Jakarta: Erlangga.
Ishaq, Mohammad. (2007). Fisika Dasar Edisi 2. Yogyakarta: Graha Ilmu.
Khanafiyah, S. (2010). Percobaan Osilasi Bandul Fisis Bentuk Sederhana Sebagai Tugas Proyek Penelitian Pada Materi Momen Inersia Di SMA. Jurnal Pendidikan Fisika Indonesia, 5 (2009), 47-53. https://doi.org/10.15294/jpfi.v5i1.1000.
Leme, J. C., & Oliveira, A. (2017). Pendulum Underwater – An Approach for Quantifying Viscosity. The Physics Teacher 55 (9), 555–557. https://doi.org/10.1119/1.5011833.
Limiansih K, Santosa IE. (2013). Redaman pada Pendulum Sederhana. Jurnal Fisika Indonesia, 17(51), 17-20. https://doi.org/10.22146/jfi.24428.
Manggala, R. W., & Panuluh, A. H. (2021). Analisis Redaman pada Osilasi Balok Kayu. Jurnal Fisika Indonesia, 25(1), 7-10. https://doi.org/10.22146/jfi.v1i1.57939.
Oktova R, Diana N. (2013). Penentuan koefisien viskositas air menggunakan metode osilasi pegas dengan koreksi kedalaman penetrasi dan koreksi efek dinding. Berkala Fisika Indonesia, 5(1), 25–34. https://doi.org/10.12928/bfi-jifpa.v5i1.247.
Rada, M.K.D. & Panuluh, A.H. (2021). Penggunaan Aplikasi Logger Pro untuk Menentukan Nilai Viskositas Air. Jurnal Ilmu Fisika dan Pembelajarannya, 5(1), 28-35. https://doi.org/10.19109/jifp.v5i1.8553.
Serway, R.A. dan Jewitt, Jr. J.W, (2014). Physics for Scientist and Engineer with Modern Physics Ninth Edition. Boston: Brooks/Cole.
Shamim, Sohaib, dkk. (2010). Investigating viscous damping using webcam. American Journal of Physics, 78, 433-436. https://doi.org/10.1119/1.3298370.
Sutarno, dkk. (2017). Keterampilan pemecahan masalah mahasiswa dalam pembelajaran bandul fisis menggunakan model problem solving virtual laboratory. Jurnal Pendidikan Fisika dan Teknologi, 3(2), 164-172. https://doi.org/10.29303/jpft.v3i2.396.
Tipler, P. A. (1998). Fisika untuk Sains dan Teknik Jilid ke-1. Jakarta: Erlangga.
Vogt P, Kuhn J. (2012). Analyzing simple pendulum phenomena with a smartphone acceleration sensor. Physics Teacher, 50(7), 439–40. https://doi.org/10.1119/1.4752056.
Ciptaan disebarluaskan di bawah Lisensi Creative Commons Atribusi 4.0 Internasional.