Pil Hong Jeong, Beom Jin Kim, Yeong Jin Kim, Dong Gyu Jeon, Hyo Min Kim, Jae Hyeon Kim, Hyeong Min Kim, Gyu Seong Lee, Kawan Anil, Eung Ryul Park, Soon Jae Yu, Min Jun Ann, Do Won Hwang
J Electr Electron Mater 2024;37(4):394-399. Published online July 1, 2024
An irradiator is developed using two UVA wavelength ranges of SMD LEDs as a curing light source. This module has dimensions of 545×111×300 mm3 and is equipped with a TIR bar-shaped lens made of PDMS silicone resin. The developed irradiator offers high uniformity, with 89% in the centerline of the horizontal axis direction, for two different wavelength ranges of 365 nm and 385 nm. The radiation intensity from the light source module shows highly directional characteristics, and the irradiator provides a maximum irradiance of 1,634 mW/cm2 at a working distance of 50 mm. During the initial 5 minutes of operation, the irradiance experiences a rapid decrease. However, this issue is addressed by optimizing the LED’s current reduction characteristics and managing the Transistor’s temperature rise in the constant current circuit. After continuous operation for approximately 60 minutes. The highest temperature, near the central part of the irradiating surface, reaches 69.7℃, while the lowest temperature, near the edges, is 41.1℃.
A high directivity TIR (total internal reflection) lens in the UV-A region was designed using a silicone resin, and a UV light source module with a maximum irradiation density of 150 mW/cm2 was fabricated. The beam angle of the TIR lens was designed to be 8.04° and the maximum diameter of the TIR lens was ø13.5. A silicone resin having a UV transmittance of 93% and a refractive index of 1.4 at a wavelength of 365 nm was used, and the lens was manufactured using an aluminum mold, from which silicone could be easily released. The module was fabricated in a metal printed circuit board of COB (chip on board) type using a 0.75×0.75 mm2 UV chip. A jig was used to adjust the focal length between lens and chip and to fix the position of the lens. The optical characteristics such as illumination distributions of the lens and module were designed using ‘LightTools’ optical simulation software. The heat dissipation system was designed to use a forced-air cooling method using a heat-sink and fan.