Filler material (concrete or mortar) has been used for shielding radioactive waste, however, it is proceeded out evaluation for radiation shielding performance. So, it is needed to check the property in the shielding performance. Therefore, in this paper, mechanical properties of concrete was evaluated for the applicability using heavyweight waste glass as fine aggregate of filler material. From the test results, compressive and elasticity modulus were significantly affected by substitution of heavyweight waste glass, however, it could be improved the performance by using mineral admixture as binder.

Electrical waste, such as heavy weight waste glass, has become a global concern in terms of resource recycling. At the same time, aggregate is one of the most widely used infrastructure materials, and it is being exhausted. So, in this paper, the heavy weight waste glass is considered as aggregate due to its physical characteristics and chemical composition. From the results, when the heavy weight waste glass substitution ratio increase, the compressive strength and flexural strength decreased.

국내 태양광 시장은 정부의 주도하에 2006년 이후 연평균 50% 이상의 성장률을 보이며 급성장 하였다. 2006년에 22MW였던 태양광 시장은 2012년, 그보다 10배 이상인 279MW의 규모에 이르렀고 2013년에는 330MW가 설치되었다. 그 결과 2006년 36MW에 불과하였던 국내 태양광 누적 설치용량은 6년만인 2012년에 1GW를 돌파하였다. 기존 연구결과를 통해 유추한 결과 폐 태양광 모듈의 발생 시기는 태양광 모듈 수명이 2000년 이전의 생산제품은 10년, 2001년∼2010까지의 생산제품은 15년, 2011년 이후의 생산제품에 대해서는 20년이라고 가정할 때에 대략 2020년 정도가 될 것으로 추측된다. 생산과정에서 발생한 폐 모듈은 물론 기존에 설치된 모듈의 효율저하, 제조시의 불량 및 새로이 개발된 고효율(발전효율 18%이상)패널로의 교체로 모듈의 평균수명이 낮아져 매년 폐기되는 모듈의 양은 기하급수적으로 증가할 것으로 예상된다. 현재까지 처리된 폐 모듈의 양도 최소 5MW으로 추측되며, 2020년부터 처리해야 할 폐 모듈의 양은 백MW단위로, 많은 양의 폐기물이 배출될 것이라 본다. 아직까지 우리나라는 자원 재생에 대한 인식이 부족하여 여러 가지 문제에 당면해 있는 실정이다. 우리나라는 전국적인 회수 체계가 미흡하고 재활용 인식이 낮아 수거자체가 어려울 뿐만 아니라, 도시 광산은 서비스업으로 분류되어 있어 산업단지 내 공장설립이 제한되어 있고, 그 절차 또한 복잡하고 오랜 시간 기다려야하기 때문에 접근이 쉽지 않다. 이에 본 연구는 폐 PV모듈(Photovoltaic module)에서 추출한 저 철분 강화유리 분말을 이용한 콘크리트용 혼화재로서의 활용가능성 알아보고, 최근 환경문제로 대두되어 있는 산업폐기물의 건설 순환자원으로의 재활용방안을 제시하고자 함이 목적이다.

In this paper, the sulfate resistance of concrete substituted the crushed heavy weight waste glass as fine aggregate are compared and evaluated. From the results, when heavy weight waste glass substituted ratio increase, the reduction rate of compressive strength is decreased. So, the sulfate resistance is improved by using heavy weight waste glass in concrete.

It is necessary to investigate the possibility of high density material as an ingredient in the manufacturing of radiation shielding material. In this study, the suitability of heavy weight waste glass as a shielding material is considered. From the results, it was found that when the heavy weight waste glass substitution ratio increases, radiation shielding performance also increase.

In this paper, the flexural behavior of RC member recycled heavy weight waste glass as fine aggregate was evaluated by finite element analysis. From the results, yield point and maximum load decreased with decreasing concrete strength and elastic modulus. Also, the finite element analysis program does not reflect the ductility loss of RC members using heavy weight waste glass as fine aggregate.

In this paper, the sulfate resistance of concrete substituted the crushed heavy weight waste glass as fine aggregate are compared and evaluated. From the results, when heavy weight waste glass substituted ratio increase, the reduction rate of compressive strength is decreased. So, the sulfate resistance is improved by using heavy weight waste glass in concrete.

It is necessary to investigate the possibility of high density material as an ingredient in the manufacturing of radiation shielding material. In this study, the suitability of heavy weight waste glass as a shielding material is considered. From the results, it was found that when the heavy weight waste glass substitution ratio increases, radiation shielding performance also increase

Insulation materials used for building save energy and can be classified into inorganic and organic materials. Organic insulation emits toxic gases in a fire annd has lower water resistance. Inorganic insulation is heavy and has poorer thermal performance than that of organic material. This study evaluated the physical properties and fire resistance of lightweight inorganic insulation foaming material made of waste glass powder. The test results showed that the inorganic material performed well with low density and low thermal conductivity for an insulation material. Foam insulation material manufactured from glass powder was sufficient as a fire-resistant product.

As the industrialization is rapidly growing, the quantities of industrial waste glass have been quickly increased. However the most of them are not recycled. Therefore, it is needed to investigate the possibility of industrial waste glass as concrete material ingredient. In this paper, it is compared and evaluated that the characteristics of freeze-thaw resistance according to industrial waste glass substitution ratio in concrete specimens. From the results, the weight change was not affected by the waste glass substitution ratio. And, the relative dynamic modulus of elasticity was increased slightly with the waste glass substitution ratio. The relative dynamic modulus of elasticity was above 80% up to 300cycles in all of the mixes.

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 carried out the compressive strength, modulus of rupture and scaling resistance tests in order to evaluate the durability of concrete pavement containing waste glass powder. As a results of this research, the concretes incorporating 20% waste glass powder had higher compressive strengths and modulus of ruptures than the concretes with 20% fly-ash. Also, they had a better scaling resistance than ordinary portland cement concretes and fly ash concretes.

In this paper, the heavy metal leaching of mortar substituted the crushed waste glass as fine aggregate are evaluated. From the results, when the heavy weight waste glass substitution ratio increase, leching quantities of heavy metal is increased. Therefore, it is needed that the characteristics of heavy metal leching according to waste glass substitution ratio in mortar specimens.

In this paper, we investigate the pozzolanic reaction of the waste glass sludge incorporating precipitation additives experimentally. The consumption of calcium hydroxide, and the compressive strength were tested for two different types of the waste glass sludge depending on whether precipitation additives were used.

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.

급격한 산업화와 삶의 질의 변화로 인해 생산된 고밀도 폐유리의 양은 꾸준히 증가하고 있으나 대부분 재활용되지 못하고 있다. 특히 고밀도 폐유리의 경우 불법적으로 처리되거나 매립되는 실정이다. 한편, 원전구조물의 안전성 확보를 위해 차폐 성능이 우수한 재료가 사회적으로 요구되고 있다. 콘크리트는 가장 많이 사용되고 있는 건설재료이며, 많은 양의 자원들이 콘크리트를 생산하기 위해 사용되고 있다. 따라서 고밀도 폐유리를 차폐 콘크리트 재료로 재활용할 수 있는 방안에 대한 연구가 요구되어진다. 본 연구에서는 고밀도 폐유리를 차폐 콘크리트 잔골재로의 적용가능성을 평가하였다. 결과에 따르면, 폐유리를 혼입한 모르타르의 경우, 일반 모르타르에 비하여 단위용적질량이 증가하여 차폐 성능 개선이 가능할 것으로 판단된다. 폐유리 혼입에 의해 강도는 감소하는 것으로 나타났으며, 세척의 경우보다 비세척의 경우에 강도 발현이 유리한 것으로 나타났다.

Due to strong binding, optical clarity, adhesion to many surfaces, toughness and flexibility polyvinyl butyral(PVB) resin films are commonly used in the automotive and architectural application as a protective interlayer in the laminated glass. Worldwide million tons of PVB waste generated from end-of-life automotive associated with various environmental issues. Stringent environmental directive, higher land costs eliminate landfilling option, need a sustainable, environment-friendly technology to recycle these solid wastes. In our current study, we have developed a mechano-chemical separation process to separate PVB resins from glass and have characterized the separated PVB through various techniques, i.e., scanning electron microscope (SEM), energy-dispersive X-ray spectroscopy (EDS), infrared spectroscopy (IR) and nuclear magnetic resonance spectroscopy (NMR). Feasibility for reuse of these recycled PVB has been investigated. The technology developed in our laboratory is sustainable, environment-friendly, techno-economical feasible process, and capable of mass production (recycling).

As the industrialization is rapidly growing and the quantities of heavy weight waste glass have been quickly increased but the most of them are not recycled. The heavy weight waste glass have been treated by illegal dumping or being buried in landfills. And, it is caused some problem such as the environmental pollution. So, it is needed to investigate the possibility of recycling of heavy weight waste glass as concrete material ingredient. In this paper, the mechanical properties of mortar substituted the crushed waste glass as fine aggregate are evaluated. From the results, when waste glass substitution ratio increase, fluidity and specific gravity increase. However, the compressive strength and flexural strength decrease. So, the mechanical properties of mortar are significantly affected by waste glass substitution ratio.

In this paper, the length change of mortar substituted the crushed heavy weight waste glass as fine aggregate are evaluated. From the results, when waste glass substitution ratio increase, ASR expansion increase. However, the dry shrinkage decrease. So, the length change of mortar are significantly affected by waste glass substitution ratio.