Repository Universitas Pakuan

Detail Karya Ilmiah Dosen

Didik Notosudjono, Tatang Kukuh Wibawa, Bagus Dwi Ramadhon

Judul : Analyzing the deformation of copper conductor from a fire impact

Abstrak :
Fire is an oxidation reaction of the three elements (fuel, oxygen, heat) that can result in loss of property, injury, even death. Electricity potential that may results on fire is the short circuit current that occurs on the equipments and electrical installation cables. The remaining wires at the first fire location are subject to fire damage and can cause electrical short circuit. The purpose of this study is to analyze the short-circuit electrical deformation of copper cable using SEM EDS and MICRO XRF instrument. Based on the study result, there is a dominant change of oxygen elements in single cable and fiber sample causing fire that is 35.96% and 21.24%, those values are higher than Oxygen on a burned short circuited cable that is 19.54% and 12.1%. The microstructure of the cable that causes fire looks like irregular clumps whereas the burned cable looks like a clump of clumps.

Tahun : 2019 Media Publikasi : Jurnal Nasional Terakreditasi A

Kategori : Jurnal No/Vol/Tahun : 4 / 17 / 2019

ISSN/ISBN : 1693-6930

PTN/S : Universitas Pakuan Program Studi : TEKNIK ELEKTRO

Bibliography :
[1] WEI Mei-meia,b,c, ZHAO Zhea,b, LIANG Donga,b, Experiment of Electrical Fire Burned Copper Wire and Parameters Analysis on Metallographic Test of Melted Mark, Procedia Engineering 11 (2011) 496–503

[2] Wang Xiqing, Han Baoyu and so on. Electrical fire scene investigation and identification of technical guidelines. Shenyang: Liaoning University Press, 1996.

[3] Physics and Computer Forensics, Training material for Orbis Micro-XRF equipment. 2016. Puslabfor Bareskrim Polri, Jakarta.

[4] Yip Mao, Wang Lifen, Yang Shi groups and so on. Electrical fire in the copper wire traces of fire. Physical Testing - Part, Volume 5, 2007, 43: 226-235.

[5] Zhang Hong, Jianxin Xie, Ren Kegang and so on. Annealing temperature on the Unidirectional Fiber Microstructure and Properties of crystalline copper wire. 2003,25 (3) :237-240.

[6] Zhang post, Luo Liang, Wen Yuxiu and so on. fire shooting water on the fire wire microstructure of melt marks. Fire Safety Science, 2007,16 (2) :105-110.

[7] NFPA 921, National Fire Protection Association (NFPA). 2014, 22. “Guide for Fire and Explosion Investigations “, New York.

[8] Richard J. Roby, Ph.D., Jamie McAllister, Ph.D., 2012. “Forensic Investigation Techniques for Inspecting Electrical Conductors Involved in Fire”, Journal National Institute of Justice, Office of Justice Programs, U. S. Department of Justice.

[9] Hall Jr. JR. (2013) home electrical fires. Quincy: National Fire Protection Association.

[10] NFPA. (2004). NFPA 921 guide for fire and explosion investigations. Quincy: National Fire Protection Association.

[11] Mesrun N, Abdul Rahim MSN, Nik Hassan NF, Kah Haw Chang, Malaysian Journal of Forensic Sciences (2015) 6(1):54-62, Forensic Analysis of Copper Wire for Fire Source Determination.

[12] Suharianti Lasuda, 2010 page 2, 40 Electrical Fire occurrence analysis on Building, Electrical Engineering Department UI Thesis, Jakarta

[13] Hall Jr. JR. (2013) home electrical fires. Quincy: National Fire Protection Association.

[14] Ettling BV. (1978). Electrical wiring in building fires. Fire Technology 14(4): 317-325.

[15] ATF Fire Research Laboratory, Technical Bulletin 001, hal 7, 2012. ATF Fire Research Laboratory Technical Bulletin 001 September 28, 2012. USA.

[16] Delplace M., Vos E. (1983). Electric short circuits help the investigator determine where the fire started. Fire Technology 19(3): 185-191

[17] Liu S-J., Man D., Yu Li L., Zhao C-Z., Gao W., Liu X-L. (2011). Thermal analysis of pvc wire insulation residues in fire investigation. Procedia Engineering 11: 296-301.

[18] Levinson DW. (1977). Copper metallurgy as a diagnostic tool for analysis of the origin of building fires. Fire Technology 13(3): 211-222.

[19] Babrauskas V. (2003). Fires due to electric arcing: Can ‘cause’ beads be distinguished from ‘victim’ beads by physical or chemical testing? Fire and Materials 14: 189-201.

[20] Wright SA., Loud JD., Blanchard RA. (2015). Globules and beads: what do they indicate about smalldiameter copper conductors that have been through a fire? Fire Technology (2015), doi: 10.1007/s10694-014-0455-9.

[21] Gray, D.A.; Drysdale, D.D.; Lewis, F.A.S. Identification of electrical sources of ignition in fires. Fire Saf. J. 1983, 6, 147–150.

[22] Erlandsson, R.; Strand, G. An investigation of physical characteristics indicating primary or secondary electrical damage. Fire Saf. J. 1985, 8, 97–103.

[23] Ishibashi, Y.; Kishida, J. Research on first and second fused mark discrimination of electric wires. In Proceedings of the 1990 Annual Meeting of Japan Association for Fire Science and Engineering, 17– 18 May 1990; pp. 83–90.

[24] Lee, E.P.; Ohtani, H.; Seki, T.; Imada, S.; Yashiro, I. Discrimination between primary and secondary molten marks on electric wires by DAS. J. Appl. Fire Sci. 2000, 9, 361–379.

[25] Kuan-Heng Liu, Yung-Hui Shih, Guo-Ju Chen * and Jaw-Min Chou, Materials 2015, 8, 3776-3790; doi:10.3390/ma8063776, ISSN 1996-1944, Microstructural Study on Molten Marks of Fire-Causing Copper Wires, Published: 22 June 2015

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Detail Karya Ilmiah Dosen

Didik Notosudjono, Tatang Kukuh Wibawa, Bagus Dwi Ramadhon

Judul	:	Analyzing the deformation of copper conductor from a fire impact
Abstrak	:	Fire is an oxidation reaction of the three elements (fuel, oxygen, heat) that can result in loss of property, injury, even death. Electricity potential that may results on fire is the short circuit current that occurs on the equipments and electrical installation cables. The remaining wires at the first fire location are subject to fire damage and can cause electrical short circuit. The purpose of this study is to analyze the short-circuit electrical deformation of copper cable using SEM EDS and MICRO XRF instrument. Based on the study result, there is a dominant change of oxygen elements in single cable and fiber sample causing fire that is 35.96% and 21.24%, those values are higher than Oxygen on a burned short circuited cable that is 19.54% and 12.1%. The microstructure of the cable that causes fire looks like irregular clumps whereas the burned cable looks like a clump of clumps.
Tahun	:	2019	Media Publikasi	:	Jurnal Nasional Terakreditasi A
Kategori	:	Jurnal	No/Vol/Tahun	:	4 / 17 / 2019
ISSN/ISBN	:	1693-6930
PTN/S	:	Universitas Pakuan	Program Studi	:	TEKNIK ELEKTRO
Bibliography	:	[1] WEI Mei-meia,b,c, ZHAO Zhea,b, LIANG Donga,b, Experiment of Electrical Fire Burned Copper Wire and Parameters Analysis on Metallographic Test of Melted Mark, Procedia Engineering 11 (2011) 496–503 [2] Wang Xiqing, Han Baoyu and so on. Electrical fire scene investigation and identification of technical guidelines. Shenyang: Liaoning University Press, 1996. [3] Physics and Computer Forensics, Training material for Orbis Micro-XRF equipment. 2016. Puslabfor Bareskrim Polri, Jakarta. [4] Yip Mao, Wang Lifen, Yang Shi groups and so on. Electrical fire in the copper wire traces of fire. Physical Testing - Part, Volume 5, 2007, 43: 226-235. [5] Zhang Hong, Jianxin Xie, Ren Kegang and so on. Annealing temperature on the Unidirectional Fiber Microstructure and Properties of crystalline copper wire. 2003,25 (3) :237-240. [6] Zhang post, Luo Liang, Wen Yuxiu and so on. fire shooting water on the fire wire microstructure of melt marks. Fire Safety Science, 2007,16 (2) :105-110. [7] NFPA 921, National Fire Protection Association (NFPA). 2014, 22. “Guide for Fire and Explosion Investigations “, New York. [8] Richard J. Roby, Ph.D., Jamie McAllister, Ph.D., 2012. “Forensic Investigation Techniques for Inspecting Electrical Conductors Involved in Fire”, Journal National Institute of Justice, Office of Justice Programs, U. S. Department of Justice. [9] Hall Jr. JR. (2013) home electrical fires. Quincy: National Fire Protection Association. [10] NFPA. (2004). NFPA 921 guide for fire and explosion investigations. Quincy: National Fire Protection Association. [11] Mesrun N, Abdul Rahim MSN, Nik Hassan NF, Kah Haw Chang, Malaysian Journal of Forensic Sciences (2015) 6(1):54-62, Forensic Analysis of Copper Wire for Fire Source Determination. [12] Suharianti Lasuda, 2010 page 2, 40 Electrical Fire occurrence analysis on Building, Electrical Engineering Department UI Thesis, Jakarta [13] Hall Jr. JR. (2013) home electrical fires. Quincy: National Fire Protection Association. [14] Ettling BV. (1978). Electrical wiring in building fires. Fire Technology 14(4): 317-325. [15] ATF Fire Research Laboratory, Technical Bulletin 001, hal 7, 2012. ATF Fire Research Laboratory Technical Bulletin 001 September 28, 2012. USA. [16] Delplace M., Vos E. (1983). Electric short circuits help the investigator determine where the fire started. Fire Technology 19(3): 185-191 [17] Liu S-J., Man D., Yu Li L., Zhao C-Z., Gao W., Liu X-L. (2011). Thermal analysis of pvc wire insulation residues in fire investigation. Procedia Engineering 11: 296-301. [18] Levinson DW. (1977). Copper metallurgy as a diagnostic tool for analysis of the origin of building fires. Fire Technology 13(3): 211-222. [19] Babrauskas V. (2003). Fires due to electric arcing: Can ‘cause’ beads be distinguished from ‘victim’ beads by physical or chemical testing? Fire and Materials 14: 189-201. [20] Wright SA., Loud JD., Blanchard RA. (2015). Globules and beads: what do they indicate about smalldiameter copper conductors that have been through a fire? Fire Technology (2015), doi: 10.1007/s10694-014-0455-9. [21] Gray, D.A.; Drysdale, D.D.; Lewis, F.A.S. Identification of electrical sources of ignition in fires. Fire Saf. J. 1983, 6, 147–150. [22] Erlandsson, R.; Strand, G. An investigation of physical characteristics indicating primary or secondary electrical damage. Fire Saf. J. 1985, 8, 97–103. [23] Ishibashi, Y.; Kishida, J. Research on first and second fused mark discrimination of electric wires. In Proceedings of the 1990 Annual Meeting of Japan Association for Fire Science and Engineering, 17– 18 May 1990; pp. 83–90. [24] Lee, E.P.; Ohtani, H.; Seki, T.; Imada, S.; Yashiro, I. Discrimination between primary and secondary molten marks on electric wires by DAS. J. Appl. Fire Sci. 2000, 9, 361–379. [25] Kuan-Heng Liu, Yung-Hui Shih, Guo-Ju Chen * and Jaw-Min Chou, Materials 2015, 8, 3776-3790; doi:10.3390/ma8063776, ISSN 1996-1944, Microstructural Study on Molten Marks of Fire-Causing Copper Wires, Published: 22 June 2015
URL	: