Environmental assessment of air to water machines-triangulation to manage scope uncertainty
Artikel i vetenskaplig tidskrift, 2013

Devices that condense and disinfect water vapour to provide chilled drinking water in office environments, so-called 'air water generators' (AWGs), are being marketed as environmentally friendly alternatives to the traditional bottled water cooler. We sought to examine this claim. The approach adopted was a preliminary life cycle assessment with performance indicators for the use of energy and water and the emission of greenhouse gases. We compared an AWG with its main market competitor, the traditional bottled water cooler and a simple refrigerator containing a jug of water. Modelling was based on Australian conditions and energy supply. To manage possible scope uncertainty, we borrowed the idea of 'triangulation' as defined in the social sciences. We found that without a renewable energy supply, the claim of environmental superiority is not supported by quantitative analysis. For each indicator, the AWG's score was typically two to four times higher than the alternatives. Energy consumption was the key issue driving all three indicators. Considering the principal environmental issues related to these systems, air-to-water machines significantly underperform bottled water coolers. A simple refrigerator has the capacity to perform multiple functions and therefore outperform both the bottled and atmospheric water options once allocation of burdens is considered. These conclusions are supported by all three perspectives examined to manage uncertainty.

Bottled water cooler

Atmospheric water generator

Carbon tax

Simplified life cycle assessment

Uncertainty analysis

Författare

Gregory Peters

Chalmers, Kemi- och bioteknik, Kemisk miljövetenskap

N. J. Blackburn

Monash University

M. Armedion

SMEC Australia Pty Ltd.

International Journal of Life Cycle Assessment

0948-3349 (ISSN) 1614-7502 (eISSN)

Vol. 18 5 1149-1157

Ämneskategorier

Annan teknik

DOI

10.1007/s11367-013-0568-2

Mer information

Senast uppdaterat

2018-02-26