New re-use applications are needed to address the relatively large quantity of waste electronic products generated in the world. Cathode-ray tubes (CRTs) from computer monitors and TV sets are a large component of such waste. The three glass components of CRTs are the funnel, panel and neck, which are produced by various manufacturers and are now collected by asset-recovery centres. In this paper, we characterize waste funnel and panel glass from dismantled cathode-ray tubes with a view to assisting the development of new re-use applications. The heavy metal (lead, barium, and strontium) content of such glass represents an acute risk to the environment. Our results of the chemical composition for different kinds of waste CRT glass including black & white and color CRTs show that CRT glass from different producers have generally similar chemical compositions. In particular, the compositions of funnel and panel black & white CRT glass are similar, but are different to those of panel and funnel color CRT glass. We also measured the following specific properties of each type of CRT glass: density, glass transition temperature, and linear coefficient of thermal expansion. It was found that the coefficients of thermal expansion of CRT glass do not vary with their composition. In contrast, the measured densities and glass transition temperatures do vary with composition. On the basis of our experimental data and data found in the literature, we outline the main properties of several waste CRT glass currently in circulation. The aim of this study was to provide the data required to determine if this kind of waste could be entirely (or partially) re-used and to aid the search for promising methods of treatment.
[1]
F Andreola,et al.
Glass-ceramics obtained by the recycling of end of life cathode ray tubes glasses.
,
2005,
Waste management.
[2]
T. Morimoto,et al.
Wet chemical functional coatings for automotive glasses and cathode ray tubes
,
2001
.
[3]
Pascal G. Yot,et al.
Elaboration and characterisation of foam glass from cathode ray tubes
,
2005
.
[4]
Timothy G. Townsend,et al.
Characterization of Lead Leachability from Cathode Ray Tubes Using the Toxicity Characteristic Leaching Procedure
,
2000
.
[5]
E. Bernardo,et al.
Mechanical properties of metal-particulate lead-silicate glass matrix composites obtained by means of powder technology
,
2003
.
[6]
Nourreddine Menad,et al.
Cathode ray tube recycling
,
1999
.
[7]
Cate Gable,et al.
Computer and Electronics Product Stewardship: Are We Ready for the Challenge?
,
2001
.
[8]
C H Lee,et al.
Management of scrap computer recycling in Taiwan.
,
2000,
Journal of hazardous materials.
[9]
M. Pham-thi.
Rare-earth calcium sulfide phosphors for cathode-ray tube displays
,
1995
.