Legionella species: A potential problem associated with rain water harvesting systems?

The risk of Legionella transmission from rain water harvesting (RWH)-fed water toilet flushing was investigated. Experiments monitored RWH tanks to determine Legionella spp. presence which was successfully isolated from three of four of RWH tanks (site 1: 3600 CFU/dm3 in February and 3600 CFU/dm3 in May; site 2: not detected; site 3: <940 GU/dm3; site 4: 44,000 GU/dm3), and to determine whether toilets could generate aerosol droplets capable of harbouring bacteria. The concentrations of particles measuring 10 µm or less in diameter (PM10, capable of reaching the alveolar region of the lungs and causing disease) were monitored following flushes. Aerosols were detectable in an enclosed toilet cubicle (PM10 concentration increased in one experiment from 0.038 mg/m3 when t = 1–600 s to 0.057 mg/m3 when t = 600–800 s). Recovery of Lactobacillus plantarum (surrogate for Legionella) from a seeded toilet cistern (108 CFU ml/dm3) indicated that bacteria were expelled, as demonstrated by recovery on MRS plates placed around the toilet unit. Legionella could be dispersed via aerosols from a toilet flushed with water from an RWH system and the effect would be more pronounced in smaller, enclosed areas, but this is unlikely to pose a risk to human health.

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Oasis of Resilience? An Empirical Investigation of Rain Water Harvesting Systems in a High Poverty, Peripheral Community

Economics of Disasters and Climate Change ◽

10.1007/s41885-019-00050-2 ◽

2019 ◽

Vol 4 (1) ◽

pp. 129-144

Author(s):

Daniel P. Aldrich ◽

Courtney Page-Tan

Keyword(s):

Empirical Investigation ◽

Rain Water ◽

Water Harvesting ◽

High Poverty ◽

Rain Water Harvesting ◽

Harvesting Systems

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Life cycle cost assessment of a rain water harvesting system for toilet flushing

Water Science & Technology Water Supply ◽

10.2166/ws.2011.135 ◽

2012 ◽

Vol 12 (3) ◽

pp. 309-320 ◽

Cited By ~ 8

Author(s):

S. R. Ghimire ◽

D. W. Watkins ◽

K. Li

Keyword(s):

Sensitivity Analysis ◽

Life Cycle ◽

System Design ◽

Life Cycle Cost ◽

Rain Water ◽

Cost Assessment ◽

Water Harvesting ◽

Toilet Flushing ◽

Rain Water Harvesting ◽

Years Of Service

Rain water harvesting (RWH) has gained popularity as a way of supplementing water supplies for various purposes, including drinking, sanitation and irrigation. This paper presents a methodology of life cycle cost assessment (LCCA) of a unit RWH system (hereafter RWH system) for toilet flushing in an industrial site. The life cycle cost and net present value benefits (NPVB) were estimated for the RWH system and compared with those of a conventional system. For the current system design, the analysis of the life cycle cost of the RWH system indicates negative NPVB for all plausible service lives up to 55 years, mainly because of the initial infrastructure investment costs, operation and maintenance (O&M) costs, and pumping costs for the system. However, sensitivity analysis concluded that an alternative design with no pump, low O&M costs (5%) and 1% tank refill volume may be economically viable given 7 years of service life. The sensitivity analysis also revealed that higher hypothetical water prices ($5/m3) may lead to positive NPVB after only 5 years of service. Full cost pricing for rainwater harvesting is important for the promotion of sustainable practices and life cycle based system design is critical to make RWH systems economically attractive.

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