Reusing of sodium silicate as a raw material in glass industry: byproduct of sodium borohydride production

Authors

  • Aysel Kanturk Yildiz Technical University, Department of Chemical Engineering, Turkey
  • Muge Sari Yildiz Technical University, Department of Chemical Engineering, Turkey
  • Özgul Dere Yildiz Technical University, Department of Chemical Engineering, Turkey
  • Sabriye Piskin Yildiz Technical University, Department of Chemical Engineering, Turkey

DOI:

https://doi.org/10.15626/Eco-Tech.2007.011

Keywords:

Sodium silicate; Reusing; Vitrification; Sodium borohydride; clean energy.

Abstract

Global energy and ecology problems continue to grow because of burning of fossil fuels,
environmental pollution, decrease of energy sources and difficulties in storing electricity.
Hydrogen has great potential to solve these problems as an environmentally clean energy
carrier and as a way to reduce reliance on imported energy sources. Hydrogen can be stored
and transported safely in the form of sodium borohydride (NaBH4) due to its high theoretical
hydrogen yield by weight (10.6%) in applications where H2 gas is used, e.g., proton exchange
membrane (PEM) fuel cells. NaBH4 is synthesized from boron minerals (borax, ulexite,
colemanite ... ) by the thermal-chemical reactions.
The main aim of this paper is the investigation of reusing of Na2SiO3, obtained from Na8H4
production based on the conversion reaction of borosilicate glass, as a raw material in glass
industry. The by-product, was defined as Na2SiO3 (PDF number: 00-016 -0818) by XRD (XRay Diffractometer) technique, was then vitrificated into a glass for utilization. The obtained
glass was characterized by scanning electron microscopy with energy dispersive spectroscopy
(SEM/EDS) analysis and FT-IR (Fourier Transformer-Infrared spectroscopy) techniques. The
results show that by-product Na2SiO3 can be reused as a raw material in glass industry.

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References

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Kantiirk, A., Piskin, S, Innovation in sodium borohydride production process from borosilicate glass with sodium under hydrogen atmosphere: high hydrogen process, International Journal of Hydrogen Energy. In Press https://doi.org/10.1016/j.ijhydene.2007.04.047

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Published

2007-12-12

Issue

2007: Proceedings from Kalmar ECO-TECH'07: Technologies for waste and wastewater treatment, energy from wast, remediation of contaminated sited, emissions related to climate

Section

Solid waste: waste storage recycling and reuse

License

Copyright (c) 2007 Aysel Kanturk , Muge Sari, Özgul Dere, Sabriye Piskin

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

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