Browse > Article

Generation Rate and Content Variation of Manganese in Stainless Steel Welding  

Yoon, Chung Sik (Department of Occupational Health, Catholic University of Daegu)
Kim, Jeong Han (Korea Institute of Industrial Technology)
Publication Information
Journal of Korean Society of Occupational and Environmental Hygiene / v.16, no.3, 2006 , pp. 254-263 More about this Journal
Abstract
Manganese has a role as both toxic and essential in humans. Manganese is also an essential component in the welding because it increases the hardness and strength, prevents steel from cracking of welding part and acts as a deoxidizing agent to form a stable weld. In this study, manganese generation rate and its content was determined in flux cored arc welding on stainless steel. Domestic two products and foreign four products of flux cored wires were tested in the well designed fume generation chamber as a function of input power. Welding fume was measured by gravimetric method and metal manganese was determined by inductively coupled plasma-atomic emission spectrophotometer. The outer shell of the flux cored wire tube and inner flux were analyzed by scanning electron microscopy to determine their metal compositions. Manganese generation rate($FGR_{mn}$) was increased as the input power increased. It was 16.3 mg/min at the low input power, 38.1 mg/min at the optimal input power, and up to 55.4 mg/min at the high input power. This means that $FGR_{mn}$ is increased at the work place if welder raise the current and/or voltage for the high productivity. The slope coefficient of $FGR_{mn}$ was smaller than that of the generation rate of total fume(FGR). Also, the correlation coefficient of $FGR_{mn}$ was 0.65 whereas that of FGR is 0.91. $FGR_{mn}$ was equal or higher in the domestic products than that of the foreign products although FGR was similar. From the electron microscopic analytical data, we concluded that outer shell of the wire was composed mainly of iron, chromium, nickel and less than 1.2 % of manganese. There are many metal ingredients such as iron, silica, manganese, zirconium, titanium, nickel, potassium, and aluminum in the inner flux but they were not homogeneous. It was found that both $FGR_{mn}$ and content of manganese was higher and more varied in domestic flux cored wires than those of foreign products. To reduce worker exposure to fumes and hazardous component at the source, further research is needed to develop new welding filler materials that improve the quality of flux cored wire in respect to these points. Welder should keep in mind that the FGR, $FGR_{mn}$ and probably the generation rate of other hazardous metals were increased as the input power increase for the high productivity.
Keywords
flux cored arc welding; fume; fume generation rate; input power; manganese; stainless steel;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 세아(주). 용접재료. 서울: 세아(주). 2001. (p. 392-397, 420- 425)(available www.esab.co.kr)
2 Mena I, Horiuchi K, Lopez G. Factors enhancing entrance of manganese into brain iron deficiency age. J Nucl Med 1974;15:516
3 Tjalve H, Henriksson J. Uptake of metals in the brain via olfactory pathways. Neurotoxicology 1999;20:181-96
4 곽영순, 백남원. 모 조선소의 밀폐된 작업장에서의 공기중 용 접 흄 및 중금속 농도에 관한 조사 연구. 한국산업위생학회지 1997;7(1):107-126
5 김양호. 이지호, 윤충식. 화학물질 노출 개정연구-망간, 노동부; 2005. (85-172 쪽)
6 김현욱. 용접 근로자에서 용접작업에 따른 망간 폭로 정도, 망간에 의한 노동자의 건강장해 심포지엄 자료. 1997. (3-16 쪽)
7 박종우. 정밀 용접공학. 일진사, 1997. (15-60 쪽)
8 윤충식, 백남원. 스테인레스 강에 대한 플럭스 코어드 아크 용접공정에서의 흄 발생량 및 입자 크기 분포에 관한 연 구. 한국환경위생학회지 1999; 25(2):107-114
9 Chungsik yoon, Namwon Paik, Jeonghan Kim. Fume generation and content of total chromium and hexavalent chromium in flux-cored arc welding. Ann Occup Hyg 2003; 47(8):671-680   DOI   ScienceOn
10 한국무엽협회. 수출입 통계자료. 한국 무역협회, 2005
11 김양호. 망간폭로와 망간중독, 망간에 의한 노동자의 건강장 해 심포지엄 자료. 1997. (140-145 쪽)
12 International Agency for Research on Cancer. IARC Monographs on the evaluation of carcinogenic risks on human, chromium, nickel and welding, Vol. 49, Lyon, France; 1990
13 Voitkevich V. Chapter 2. Welding fume properties, In welding fumes-formation, properties and biological effects. England: Abington Publishing; 1995. (pp. 18-77)
14 Burgess WA. Recognition of health hazards in industry-A review of material and process. 2nd ed., John Wiley & Sons Inc; 1994
15 Antonini JM, Santamaria AB, Jenkins NT, Albini Elisa, Lucchini R. Fate of manganese associated with the inhalation of welding fumes: Potential neurological effects. NeuroToxicology 2006; 27:304-310   DOI   ScienceOn
16 노동부. 화학물질 및 물리적인자의 노출기준 개정안(노동부 고시 제2002-8호, 2006년도 노동부 회의자료 전자공청회자료. 노동부; 2006
17 Palmer WG, Eaton JC. In Effects of welding on health-XI. Miami, FL:American Welding Society; 2001
18 Hewitt PJ, Gray CN. Some difficulties in the assessment of electric arc welding fume. Am Ind Hyg Assoc J 1983; 44(10):727-732   DOI
19 Zimmer AT, Biswas P. Characterization of the aerosols resulting from arc welding processes. J Aerosol Sci 2001;32:993-1008   DOI   ScienceOn
20 신용철. 일부 망간 취급 근로자의 망간 노출실태 및 개선대 책, 망간에 의한 노동자의 건강장해 심포지엄 자료. 1997.(19-52쪽)
21 Dennis JH, Mortaxavi MSB, French J, Hewitt PJ, Redding AJ. The effect of welding parameters on ultra-violet light emissions, ozone and CrVI formation in MIG welding. Ann. Occup. Hyg 1997. 41(1):95-104
22 Koponen M, Gustafsson T, Kalliomaki P, Pyy L. Chromium and nickel aerosols in stainless steel manufacturing, grinding and welding. Am Ind Hyg Assoc J 1981;42 596-601   DOI   ScienceOn
23 National Institute for Occupational Safety and Health (NIOSH). NIOSH Method 7300 Elements. In Eller PM, editor. NIOSH Manual of analytical methods. Cincinnati, OH: US Department of Health and Human Services, Public Health Service, Centers for Disease Control and Prevention, National Institute for Occupational Safety and Health; 1994
24 Hewitt PJ, Hirstn AA. A system approach to the control of welding fumes at source. Ann. Occup. Hyg 1993; 37(3) 297-306   DOI   ScienceOn
25 Harris MK. Welding health and safety-A field guide for OEHS professionals. Fairfax, VA: American Industrial Hygiene Association Press; 2002
26 Minni E, Gustafsson TE, Koponen M, Kalliomaki P-L. A study of the chemical structure of particles in the welding fumes of mild and stainless steel. J Aerosol Sci 1984;15: 57-68   DOI   ScienceOn
27 Orr JL. Effects of welding on health VIII. Miami, Fl; American Welding Society; 1993. (pp. 1-23)
28 한국산업안전공단. 제조업체 실태조사. 2004
29 American Welding Society. Laboratory Method for Measuring Fume Generation Rates and Total Fume Emission of Welding and Allied Processes(F1.2). Miami, Fl, USA; American Welding Society(ISBN 0 87171 387 X); 1992
30 Aschner M, Aschner JL. Manganese transport across the bloodbrain barrier: relationship to iron homeostasis. Brain Res Bull 1990;24:857-60   DOI   ScienceOn
31 대한용접학회. 용접?접합 편람. 서울; 대한용접학회; 1998. (531-575, 825-829 쪽)