한국융합학회논문지 (Journal of the Korea Convergence Society)

  • 제9권4호
  • /
  • Pages.93-98
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  • 2018
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  • 2233-4890(pISSN)
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  • 2713-6353(eISSN)
한국융합학회 (Korea Convergence Society)
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시력교정용 안경렌즈의 융복합적 기술개발을 위한 UV차단 성능 평가

Assessment of UV Blocking Performance for Development of Converged Technologies of Vision Correcting Spectacle Lenses

  • 김흥수 (대전보건대학교 안경광학과)
  • Kim, Heung-Soo (Dept. of Optometry, Daejeon Health Institute of Technology)
  • 투고 : 2018.02.13
  • 심사 : 2018.04.20
  • 발행 : 2018.04.28
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초록

본 연구는 시력교정용 안경렌즈의 재질에 따른 자외선 차단 성능을 확인하고자 하였다. 안경렌즈 Acryl, CR-39, NK-55, MR-8 재질의 렌즈에 대하여 흠집 방지와 반사방지 코팅을 한 렌즈 Group A와 여기에 자외선 차단 코팅을 추가한 렌즈 Group B, 그리고 자외선 차단 전용렌즈 Group C에 대하여 자외선 투과율을 측정하였다. 그 결과, UV-A 파장에서 Group A는 CR-39 렌즈가 7.726 %, NK-55 렌즈, 0.043 %, MR-8과 Acryl 렌즈, 0.007 % 순 이었으며 Group B는 CR-39 렌즈가 0.038 %, NK-55 렌즈, 0.037 %, MR-8과 Acryl 렌즈, 0.007 % 순으로 나타나 CR-39 렌즈의 자외선 차단 성능이 크게 개선되었다. Group C는 굴절률이 1.60과 1.67에서 각각 0.005 %, 0.004 %로 나타나 자외선 차단 성능이 가장 우수하였다. 저 도수의 렌즈와 썬글라스의 경우, CR-39 렌즈를 가장 많이 사용하는 현실에서 자외선 차단을 위한 새로운 재질 또는 자외선 흡수제, 자외선 차단코팅 기술 등의 융 복합적 기술개발이 요구된다고 하겠다.

This study was wanted to confirm ability for UV blocking according to its material. The lenses materials were Acryl, CR-39, NK-55, and MR-8. It was grouped: Group A consisting of anti-scratch hard coated lenses and anti-refractive multi coated lenses, Group B added UV blocking coating on the group A, and Group C consisting of only UV blocking lenses. The results measured UV transmittance, On the UV-A wavelength, Group A showed the UV transmittance of 7.726%, 0.043%, 0.007%, and 0.007% respectively. Group B showed 0.038%, 0.037%, 0.007%, and 0.007%, respectively. The UV-blocking performance of CR-39 has been greatly improved. Group C has shown the best UV blocking function; only 0.005% and 0.004% of UV transmittances.(1.60 and 1.67 index of refraction respectively). For the low power of lenses and sunglasses, the CR-39 lens is the most used. Therefore, to UV blocking from the lens, new materials or UV absorbers or UV coating technology and development of Converged Technologies are required.

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참고문헌

  1. R. P. Gallagher & T. K. Lee. (2006). Adverse effects of ultraviolet radiation: a brief review. Prog Biophys Mol Biol. 92(1), 119-131. https://doi.org/10.1016/j.pbiomolbio.2006.02.011
  2. P. J. Sung. (2012). Optometry Goods, 3th ed. Seoul : Daehakseorim Pub.
  3. H. Y. Byun, E. J. Lee, D. H. Oh, S. R. Kim & M. J. Park. (2015). Denaturation and Inactivation of Antioxidative Enzymes due to Repeated Exposure to UV-B and Inhibitory Effect of RGP Lens. J Korean Ophthalmic Opt Soc., 20(2), 237-246. DOI: 10.14479/jkoos.2015.20.2.237
  4. D. S. Yu & J. S. Yoo. (2008). Evaluation of Ultraviolet Blocking of Ophthalmic Lenses. J. Korean Oph. Opt. Soc., 13(3), 7-128.
  5. J. Y. Yeon, et al. (2014). A Study on the Factors that Influence the Sun Protection Factor(SPF) and Protection Factor of UV-A(PA) in Sunscreen. J. of Korean Oil Chemists' Soc., 31(3), 422-439. DOI: 10.12925/jkocs.2014.31.3.422
  6. H. Yoo. E. H. Lee. (2016) The Relationship between Use of Sunblocks and Dry Eye. Journal of Digital Convergence, 14(6), 347-353. DOI: 10.14400/JDC.2016.14.6.347
  7. D. H. Kim & A. Y. Sung. (2015). Application of hydroxy-substituted benzophenone group for UV-block soft contact lens. Korean J. Vis. Sci., 17(1), 57-68.
  8. H. S. Kang. (2017). Glasses materials, 7th ed. Seoul : Shinkwang Pub.
  9. D. H. Han. (2018) A study on the polarized spectacle lens with photochromic UV blocking function of refractive index 1.60. Journal of Convergence for Information Technology, 8(1) 147-152. DOI: 10.22156/CS4SMB.2018.8.1.147
  10. T. H. Kim & A. Y. Sung. (2010). Study on the Hydroxy/Fluoro Benzophenone Group for UV- Block Effect of Contact Lens. Korean J. Vis. Sci., 12(3), 199-208.
  11. K. G. Wakefield, & A. G. Bennett. (2000) Bennett's ophthalmic prescription work, 4th Ed., Oxford. UK : Butterworth-Heinemann.
  12. K. C. Kim. (2016). Anti-Reflection Coating Technology Based High Refractive Index Lens with Ultra-Violet Rays Blocking Function. Journal of the Korea Academia-Industrial cooperation Society. 17(12), 482-487. DOI: 10.5762/kais.2016.17.12.482
  13. Y. G. Kim. (2001). Dippy time dependence of transmittance edge and half point in UV cut lens' manufacture. J. Korean Oph. Opt. Soc., 6(1), 101-105.
  14. J. Y. Yeon, et al. (2015). Stability and Sun Protection Efficacy of Sunscreens Based on the Solubility and a Combination of Organic UV Absorbers. J. Soc. Cosmet. Sci. Korea., 41(3), 189-199. DOI: 10.15230/scsk.2015.41.3.189
  15. D. S. Yu, J. H. Lee, & J. W. Ha. (2006). UV Blocking Coatings by Combination of Organic- inorganic Hybrid Materials and UV absorbers. Journal of the Korea Academia- Industrial cooperation Society, 7(6), 1296-1301.