| dc.description.abstract | The burning rate of coconut oil droplets has been investigated experimentally by adding bio-additives of clove oil and eucalyptus oil. Tests were carried out with single droplets suspended on thermocouples at room atmospheric pressure, and room temperature and ignited with a hot wire. The addition of clove oil and eucalyptus oil as bio-additives into coconut oil was 100 ppm and 300 ppm, respectively. The droplet combustion method was chosen to increase the contact area between the air and fuel so that the reactivity of the fuel molecules increases. The results showed that the eugenol compounds contained in clove oil and cineol compounds in eucalyptus oil were both aromatic, and had an unsymmetrical carbon chain geometry structure. Furthermore, this factor can potentially accelerate the occurrence of effective collisions between fuel molecules. Therefore the fuel is combustible, as evidenced by the increased burning rate, where the results show that without bio-additives, the burning rate of crude coconut oil (CCO) is about 0.7 seconds. These results are 0.15 to 0.2 seconds slower than CCO with bio-additive, which is around 0.55 to 0.6 seconds. Moreover, from the observations, it was found that the highest burning rate was achieved in both bio-additives with a concentration of 300 ppm. © Helen Riupassa et al. | en_US |
| dc.description.sponsorship | This article is one of the output of the National Competitive Basic Research (PDKN) grant funded by the Ministry of Education, Culture, Research, and Technology of the Republic of Indonesia with research contract number 057/LPPM-USTJ/P/VI/2022. The authors thank the fuel and combustion engineering laboratory of Jayapura University of Science and Technology for its research equipment, students, and laboratory assistants who have assisted in the data collection process. We also appreciate the laboratory assistants from the Integrated Laboratory of the State University of Malang for their assistance in collecting data on the composition of CCO, CvO, and EO. ___________________________________________ | en_US |
| dc.department-temp | Riupassa, H., Department of Mechanical Engineering, Jayapura University of Science and Technology, Jayapura, 99351, Indonesia; Suyatno, Department of Mechanical Engineering, Jayapura University of Science and Technology, Jayapura, 99351, Indonesia; Nanlohy, H.Y., Department of Mechanical Engineering, Jayapura University of Science and Technology, Jayapura, 99351, Indonesia; Trismawati, Department of Industrial Engineering, Panca Marga University, Probolinggo, 67271, Indonesia; Sanata, A., Department of Mechanical Engineering, University of Jember, East Java68121, Indonesia; Subagyo, R., Department of Mechanical Engineering, Lambung Mangkurat University, Banjarmasin, 70123, Indonesia; Adiwidodo, S., Department of Mechanical Engineering, State Polytechnic of Malang, East Java65141, Indonesia; Rizza, M.A., Department of Mechanical Engineering, State Polytechnic of Malang, East Java65141, Indonesia; Yamaguchi, M., Department of Mechanical Engineering, Keio University, Tokyo, 108-8345, Japan; Tomidokoro, T., Department of Mechanical Engineering, Keio University, Tokyo, 108-8345, Japan; Sarikoc, S., Department of Mechanical Engineering, Amasya University, Amasya, 05100, Turkey | en_US |
