# Page History

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The process for undertaking a life cycle costing analysis for ponds and sediment basins is the same as described in Life-Cycle Costing - Constructed Wetlands and Life-Cycle Costing - Bioretention Systems.

The origin of all of the ‘expected’ values and algorithms in MUSIC’s costing module, as well as the statistical operations used to generate ‘upper’ and ‘lower’ estimates for ponds and sediment basins are explained in Table 1.

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## Worked Example -To Manually Adjust the Estimate of V for Sediment Basins and PondsOne of the alternative algorithms in Table 7-4. allows users to estimate the typical annual maintenance cost using the size attribute V, where V is the volume of material removed from the basin / pond (in

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 m3/year). Currently,

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 MUSIC calculates V by adding the estimated volume of gross pollutants, coarse sediment and total suspended solids (TSS) that are trapped in the basin / pond per year.A worked example is given below showing how to manually calculate an estimate of V that includes TSS, coarse sediment and/or gross pollutants. For example, an estimate may be required of the volume of only trapped coarse sediment and TSS, as these materials could potentially be reused.Consider an urban catchment in Melbourne 20 ha in size with 50% impervious area that generates stormwater that is to be treated by a 194

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 m2 sediment basin (sized to trap 80% of the TSS load). The load of trapped TSS is calculated by right-clicking on the basin’s treatment node icon and examining the Statistics

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 » Mean Annual Loads section of

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 MUSIC. In this example, the inflow load is 11,700 (kg/year) and the outflow load is 2,340 kg/year, so the trapped load is 9,360 kg/year. Using a mass to volume conversion factor of 1,800 kg/

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 m3 for sediment, this equates to a volume of 5.20

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 m3/year.Using the same procedure for gross pollutants, the inflow load is 2,550 kg/year and the outflow load is 0 kg/year (as

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 MUSIC assumes 100% is captured). Using a mass to volume conversion factor of 260 kg/

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 m3 for gross pollutants, this equates to a volume of 9.81

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 m3/year.For coarse sediment, it is known that in gross pollutant traps that capture nearly all coarse sediment and gross pollutants, approximately 29% of the volume is sediment (on average). So the load of coarse sediment (m3/year) = the volume of trapped gross pollutants (i.e. 9.81

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 m3/year)

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 • 0.4085 = 4.01

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 m3/year.Now the three elements of the total trapped volume are known, the user can choose which of these should be added to estimate V.

Table 1 Summary of cost-related relationships for ponds and sediment basins.

Element of Life

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Cycle Costing Model

Default Option for Estimation in MUSIC

Alternative(s)

Notes

Life cycle

50 years

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 (From collected survey data, n = 3) No alternative in music. One could convincingly argue the life cycle is infinite for well-maintained ponds / basins, but we need to set the LC to a finite number to calculate a life cycle cost. Upper and lower estimates derived using a 84th and 16th percentile, respectively. Total acquisition cost (TAC)

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 TAC (\$2004) = 685.1

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 •(A)0.7893R2 = 0.

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 80; p

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 < 0.01; n =

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 21Where: A = surface area of

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 treatment zone in m2

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 No alternative size / cost relationships in

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 MUSIC.For literature values, see Taylor (2005b)

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 – included in Appendix H.

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 Upper and lower estimates derived using a 68% (or 1 standard deviation) prediction interval for the regression.Note that a linear equation (TAC = 96.15

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 •(A) + 16,200) produced a slightly higher R2 value, but due to the behaviour of the relationship when the treatment device size is small, the power relationship was preferred. Typical annual maintenance (TAM) cost TAM (\$2004) =

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 6

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 831•(A)0.

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 8634R2 = 0.

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 80; p

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 < 0.

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 01; n =

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 21Where: A = surface area of

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 treatment zone in m2

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TAM (\$2004) = 698.3 x (V)0.7766

R2 = 0.72; p < 0.01; n = 57.

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 No alternative size / cost relationships in MUSIC.For literature values, see Taylor (2005b)

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 Upper and lower estimates derived using a 68% (or 1 standard deviation) prediction interval for the regression

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Warning: The alternative cost / size relationship is based on an "open gross pollutant trap" data set, as these treatment devices are essentially a pond / basin with a trash rack. In addition, currently music estimates V using the combined estimated volume of gross pollutants, coarse sediment and TSS that are trapped in the basin / pond. To adjust this manually (i.e. to include only one or two of these three elements), use the procedure provided in the tip box within this section.

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 .

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 Annualised renewal / adaptation cost (RC) RC (\$2004) =

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 0

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 52% of TAC p.a.n = 4 No alternative size / cost relationships in

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 MUSIC.For literature values, see Taylor (2005b)

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 Upper and lower estimates derived using a 84th and 16th percentile, respectively. Renewal

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1 year.

(Default position due to lack of high quality data supporting an alternative period)

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10 years.

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 period 20 yearsn = 4 No alternative in music.For literature values, see Taylor (2005b). Period estimated after reviewing the CRCCH data set.There is great uncertainty surrounding this period (and the associated RC), given the lack of experience in ‘resetting’ the macrophyte zone of constructed wetlands  in Australia.  Range of data = 10 - 50 years (10 - 20 = most common range).  Note that Fletcher et al. (2005) suggested 20 – 50 years. Decommissioning cost (DC) DC (\$2004) =

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 42% of TAC

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 n =

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 4 No alternative size / cost relationships in

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 MUSIC. Upper and lower estimates derived using a 84th and 16th percentile, respectively. General caveats / notes for this type of

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 device For the purposes of costing “wetlands”, the treatment device includes an inlet zone sediment basin / pond and macrophyte zone, but no gross pollutant trap pre-treatment device.Retrofitted wetlands were excluded from the data set that was used to generate these relationships, due to limited data and unusually high total acquisition costs.