In this research, the indium dissolution properties of the waste LCD panel powders were investigated as a function of milling time fabricated by high-energy ball milling (HEBM) process. The particle morphology of waste LCD panel powders changed from sharp and irregular shape of initial cullet to spherical shape with an increase in milling time. The particle size quickly decreased to 15 until the first minute, then decreased gradually about 6 with presence of agglomerated particles after 5 minutes, which increased gradually reaching a uniform size of 13 consist of agglomerated particles after 30 minutes. The glass recovery, after dissolution, was over 99% at initial cullet, which decreased to 90.1 and 78.6% with increasing milling time of 1 and 30 minute respectively, due to a loss in remaining powder of the surface ball and jar, as well as the filter paper. The dissolution amount of indium out of the initial cullet was 208 ppm before milling, turning into 223 ppm for the mechanically milled powder after 1 minute, and nearly 146~125 ppm with further increase in milling time because of the reaction surface decrease of powders due to agglomeration. With this process, maximum dissolving indium amount (223 ppm) could be achieved at a particle size of 15 with 1 minute of milling.

The purpose of this study is to develop a durable packaging concrete using silica - based LCD waste glass. In order to verify the performance of the waste glass mixed pavement concrete, four types of concrete mixture were classified into general concrete, fly ash concrete, LCD concrete and LCD + fly ash concrete. The performance of the durable concrete pavement was tested for compressive strength, alkali - silica reaction, freezing - thawing, saltation and abrasion resistance. The purpose of this study was to develop a high - performance pavement concrete manufacturing technology using LCD waste glass powder.

Along with the increased display devices, the supply for LCD waste glass has rapidly increased. However, there is a problem for recycling. In this study, the possibility of using LCD waste glass as a substitutive material of fine aggregate is determined and compared from the test of the compressive strength and split tensile strength. Finally, it is possible to confirm the results of the failure aspect and analysis of this test.

In this research, We investigate evaluation on properties of mortars incorporated with waste LCD glass. LCD glass was grinded at 2,500, 3,500, 4,500 cm2/g blaine to replace 20% wt of cement. The compressive strength and Alkali-silica reaction test was carried out to verify effect of finess of LCD glass.

In this study, try to evaluate the basic material mechanical properties of 80 MPa class high strength concrete mixed with LCD waste glass fine powder. a high level of compressive strength is required for marine concrete mix design.