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http://dx.doi.org/10.17702/jai.2012.13.4.171

Study on the Demand Characteristics of Epoxy Resins Applied to the Restoration of Ceramics  

Nam, Byeongjik (Restoration Technology Division, National Research Institute of Cultural Heritage)
Jeong, Seri (Restoration Technology Division, National Research Institute of Cultural Heritage)
Jang, Sungyoon (Restoration Technology Division, National Research Institute of Cultural Heritage)
Publication Information
Journal of Adhesion and Interface / v.13, no.4, 2012 , pp. 171-181 More about this Journal
Abstract
The demand characteristics of the conventional 12 kinds of epoxy resins which have been used for restoration of the ceramic relics were investigated to provide standards of the effective materials in this study. The result of durability analysis showed that a liquid type is more effective in ceramic relics (low damage, high strength), and a paste type is more effective in earthenware relics (high damage, low strength). The result of workability analysis appears that the liquid type is higher than the paste type, and a slow curing type is higher than a fast curing type in surface hardness. Therefore, in the case of the liquid type which is hard to reprocess due to high surface hardness, it is necessary to conduct a study on improving physical properties by adding filler. The result of the gloss analysis on epoxy resins showed that the liquid type (colorless) has higher gloss than the paste type, and the slow curing type has higher gloss than the fast curing type in liquid types. CDK-520A/520B and Araldite SV 427-2/HV 427-1 showed the most similar gloss to $700^{\circ}C$ earthenware, Devcon 5 minute, EPO-TEK 301-2, and Quik Wood showed the most similar gloss to celadon and whiteware, Quik Wood, EPO-TEK 301-2, and Devcon 5 minute showed the most similar gloss to buncheongware. It is necessary for conservator to decide the range of the restoration surface by predicting the increase and decrease of the restoration surface because most of the epoxy resins caused the volume change in curing process.
Keywords
ceramic; epoxy resin; mechanical property; shrinkage-expansion characteristics; gloss;
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  • Reference
1 한국표준협회, KS M 3821 (에폭시수지 및 경화제의 비중 시험방법), 한국산업규격 (2008).
2 한국표준협회, KS L 4008 (도자기의 흡수율, 부피 비중, 겉보기비중 및 겉기공률의 측정방법), 한국산업규격 (1996).
3 S. Kalpakjian, Manufacturing Processes for Engineering Materials, 3rd Edition, PEARSON EDUCATION KOREA LTD., pp.51-54 (2004).
4 김박윤 譯, 플라스틱材料講座 1 -에폭시樹脂, 대광서림, 13 (2000).
5 김재구, TTT경화도표에 의한 에폭시시스템의 경화 반응 메카니즘과 반응속도 규명, 충남대학교, 석사학위논문, pp.20-26 (1999).
6 안춘기, 엘라스토머, 31, 133 (1996).
7 박기정, 권오영, 안송이, 문화재보존연구, 7, 16 (2010).
8 이해순, 윤은영, 박물관보존과학, 8, 31 (2007).
9 N. Tennent, Studies in Conservation, 24, 153 (1979).   DOI
10 S. Bradley, Strength testing of adhesives and consolidants for conservation purposes, In Preprints of the Contributions to the International Institute for Conservation Parts Congress on Adhesives and Consolidants, N. S. Brommelle, E. M. Pye, P. Smith and G. Thomson Ed., London: International Institute for Conservation (1984).
11 J. L. Down, Studies in Conservation, 29, 63 (1984).   DOI
12 J. L. Down, Studies in Conservation, 31, 159 (1986).
13 S. Bradley, Evaluation of Hxtal NYL-1 and Loctite 350 adhesives for glass conservation, In Preprints of International Council of Museums Committee for Conservation 9th Triennial Meeting, Dresden, K. Grimstad Ed., pp. 675-679, Los Angeles: Getty Conservation institute (1990a).
14 S. Bradley, Evaluation of Hxtal NYL-1 adhesives for glass conservation, British Museum Conservation Research Report, no. 3, (1990b).
15 N. Tennent, An Epoxy Resin Update, Text of lecture delivered to UKIC Ceramics and Glass Conservation Group Meeting on Adhesives and Consolidant, Available from author at Department of Chemistry, University of Glasgow, Glasgow G12 8QQ, UK (1991).
16 Araldite Rapid-Technical and Material Safety Data Sheet, BOSTIK FINDLEY (2002).
17 Devcon 5 minute-Technical and Material Safety Data Sheet, ITW Polymers and Fluids (2002).
18 Araldite AW106/HV953U-Technical and Material Safety Data Sheet, HUNTSMAN (2009).
19 Araldite AY103-1/HY956-Technical and Material Safety Data Sheet, HUNTSMAN (2009).
20 Araldite 2020-Technical and Material Safety Data Sheet, HUNTSMAN (2004).
21 EPO-TEK 301-1-Product Information Sheet, EPOXY TECHNOLOGY (2006).
22 EPO-TEK 301-2-Product Information Sheet, EPOXY TECHNOLOGY (2006).
23 Hxtal NYL-1-Technical and Material Safety Data Sheet, HXTAL Adhesive (2010).
24 Fynebond-Safety Data Sheet, Fyne Conservation Services.
25 한국표준협회, KS M ISO 604 (플라스틱-압축성의 측정 시험), 한국산업규격 (2008).
26 CDK-520A/520B-Material Safety Data Sheet.
27 Araldite SV 427-2/HV 427-1-Technical and Material Safety Data Sheet, KREMER.
28 Quik Wood-Technical and Material Safety Data Sheet, ECOLINE INDUSTRIAL SUPPLY, INC.
29 한국표준협회, KS M ISO 178 (플라스틱-굴곡성의 측정 시험), 한국산업규격 (2007).
30 한국표준협회, KS M ISO 2039-2 (플라스틱-경도의 측정-제2부 : 로크웰 경도), 한국산업규격 (2008).
31 한국표준협회, KS M 3832 (플라스틱의 광학적 특성 시험 방법), 한국산업규격 (2011).
32 한국표준협회, KS M ISO 3521 (플라스틱-불포화 폴리에스테르 및 에폭시 수지-전체 부피 수축률 측정), 한국산업규격 (2010).
33 양필승, 서정호, 보존과학회지, 27, 49 (2011).
34 국립중앙박물관, 보존과 복원의 세계 토기.자기, pp. 72-77 (2007).
35 황현성, 이해순, 강형태, 박물관보존과학, 7, 33 (2006).
36 황현성, 이해순, 박물관보존과학, 5, 5 (2004).
37 박기정, 이정하, 김순관, 문화재보존연구, 2, 58 (2005).
38 박기정, 문화재보존연구, 4, 15 (2007).