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Falling-head Double Ring Infiltrometer

Falling-head Double Ring Infiltrometer. Principle of how it works : The double ring infiltrometer is a way of measuring saturated hydraulic conductivity of the surface layer.

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Falling-head Double Ring Infiltrometer

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  1. Falling-head Double Ring Infiltrometer Principle of how it works: The double ring infiltrometer is a way of measuring saturated hydraulic conductivity of the surface layer. It consists of an inner and outer ring inserted into the ground. Each ring is supplied with a constant head of water either manually or from mariotte bottles. Hydraulic conductivity can be estimated for the soil when the water flow rate in the inner ring is at a steady state. It works by directing water onto a known surface area due to the parameters of the inner ring. The rate of infiltration is determined by the amount of water that infiltrates into the soils per surface area, per unit of time. Infiltration can be measured by either a single or double ring infiltrometer, with preference usually lying with the double ring because the outer ring helps in reducing the error that may result from lateral flow in the soil. The outer ring virtually turns a 3D single ringed system of looking at infiltration into a one dimensional model by allowing water in the centre ring to flow nearly exclusively straight down. This allows much easier calculation by taking out the need to account for lateral flow. This schematic diagram shows the vertical flow that is generated form the inner ring which is allowed by the outer ring accounting for all the lateral flow.

  2. Description of apparatus/method: • Before the double rings can be placed in position the ground cover must be removed without disturbing the soil surface. • The rings can be set in position and knocked into the ground about 10cm, or until the rings are set firmly in the ground. • When filling up the rings the outer ring is filled first so that the soil profile around the inner ring would be wet and only vertical flow would occur when the inner ring is filled later. • Apply the water to the centre ring, then finally measuring infiltration at certain time intervals. • When filling the inner ring water is poured in on a plastic sheet, then once the desired amount of water is in the ring on the sheet, the sheet is removed quickly. The level of the water is recorded at this point as the start of infiltration. • Water can be supplied inside the rings either by a marriotte bottle assembly, to keep a constant head or manually.

  3. Analysis of Data: Data is gained by a drop in water height, giving an infiltration of water over time. These data points are plotted in a graph of infiltration versus time. Theoretically, once the soil becomes saturated, a steady state infiltration rate will be reached, which is seen on a graph as a section of data points infiltrating showing linearality. Once this linear section is identified other outlying data points can be excluded from the analysis and a line of best fit can be fitted to the applicable data. The gradient of this fitted line gives the steady state infiltration rate for that particular soil. The steady state infiltartion rate can then be multiplied 1.45, to obtain the hydraulic conductivity (Ksat), of that soil. This is a measure of how conductive a soil is at saturation, which is a measure of permeability.  Results: Graphs show the infiltration rate over time at the pasture sites. At site 1, shows a steady state infiltration rate being reached at around 10 minutes. The infiltration rate before this is fast and the steady state infiltration rate is uniform, giving good results. Infiltration (cm) = 4.31 + 0.0058 time (Seconds) Infiltration (cm) = 2.74 + 0.0022 time (Seconds) At site 2, also has a fast initial infiltation rate, which does not settle down to give a uniform steady state infiltration rate. The pasture site had a high presence of cracks in the soil, which manipulates the infiltration rate, until the profile is totally saturated and equilibrated. unfortunately this point was not reached at site 2 as the experiment was not run for long enough, or until a uniform steady state infiltration rate was reached.

  4. Problems with method: Some draw-backs of the double ring are that 1- It is very time consuming, 2- Requiring frequent attention, either by recording measurements or by maintaining equilibrium in the height between the rings. 3- The practicality of the instrument is reduced by the fact the rings are extremely heavy to move. 4- It also requires a flat undisturbed surface which sometimes is not available. 5- The infiltration rate varies with different soil types, which can effect the accuracy of the results. 6- The soil type that the above results were obtained from is a Vertosol. These soils are known for their shrink/swell properties, which result in cracks when dried and can lead to misleading results. The double ring method is not reliable on soils with vertic properties. (McKenzie et al., 2002).

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