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Sedimentation Tank Dimensions Design Program

The design of the sedimentation tank is a critical piece of the design of the entire plant. Its properties, such as depth and critical velocity, are important in determining the dimensions and lamella spacing, among other things. This program requires inputs from the user and from our basis of design in order to determine the design and dimensions necessary to generate the AutoCAD drawing and design report.

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Sedimentation Tank Design Program Algorithm

Sedimentation Tank Inputs
Sedimentation Tank Outputs
Sedimentation Tank AutoCAD Drawing Program

Algorithm

The sedimentation program calculates the dimensions of one sedimentation tank and considering the break down of what portion of the tank is allotted for the inlet slopes versus the lamella. The details of the inlet slopes, drain pipe, launders and lamella to be in the tank are calculated in separate programs. All sedimentation tanks in the plant are designed to be identical.
The number of tanks is specified by the user. Based on the number of tanks given by the user the flow rate through one tank must be calculated first.

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This flow rate will then determine the cross sectional area of the tank given the desired upflow velocity. The upflow velocity is set to allow for possible sludge blanket formation (70m/day). The width of the tank is a user input determined by the width of the material used for the plate settlers (42in = 1.07m). The specified width allows for the tank length to be calculated.

dimensions of inlet slopes, sed plate frame, lamella, sed launder, as well as dimensions of the inlet channel.

Firstly, the design of sedimentation tanks for a given flowrate Q, involves a selection of the number of sedimentation tanks from a user input. Based on the user input, the flowrate in one sedimentation tank and length of the sed tank are calculated:

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Q.Sed
Q.Sed

and

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L.Sed
L.Sed

where the width of the sedimentation tank was set to 42.5 inches, which represents the width of available lamella material, and the upflow velocity was set to 70m/day to allow for possible sludge blanket formation.

The wall height of the sedimentation tank was set to be equal to the height of the water level plus the height of the

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The height or depth of the tank is simply the water height in the tank plus the plant freeboard of 10cm. This plant freeboard is a design assumption used through out the design algorithms to give a buffer to allow for possible variation in water levels without resulting in tank overflow. The water height is set in the basis of design. It should be noted that this value will have to be higher if larger plants are designed.

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AGUACLARA:H.SedAGUACLARA:
H.Sed

Within the given waterdepth the tank is divided into sections. The user is asks to give a ratio (Pi.SedBottomHWSed)of how the sedimentation tank should be divided, this fraction represents the portion of the tank devoted to the inlet slopes below the lamella, this includes the drain pipe at the bottom of the tank. The rest of the tank is aportioned to lamella and effluent launders. The user given fraction is multiplied by the design water depth to give a vertical height of the tank occupied by the inlet slopes and the drain pipe.

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The water level height is calculated as the sum of elevation of the sed slopes, 2*outerdiameter of the pipe used for the sed plate frame, height of the lamella, height of the water above lamella, and the distance between the top of the slopes and the bottom of the lamella. Two other factors also taken into consideration are the thickness of the concrete ledge used to hold up the launder on the inlet channel side and the extra space between the top of the lamella and the launder to offset any error during construction. Because of these two variables there is significant space between the top of the lamella and the launders, which results in an increase in the height of the water in the sedimentation tank, leading to a taller sedimentation tank.

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Latex

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$$
HW_{Sed} = Z_{SedSlopes} + H_{SedBetween} + 2*outerdiameter(ND_{SedPlateFrame} ) + H_{SedPlate} + H_{SedAbove} + T_{ConcreteMin} + S_{LamellaLaunder}
$$

where, the elevation of the sed slopes is defined as:

Latex

\large
$$
Z_{SedSlopes} = Z_{SedSludge} + H_{SedTopSlope} + H_{SlopeThickness}
$$

The calculations of the lamella height can be found here.

The launders leaving the sedimentation tanks were designed in a similar manner as the sedimentation sludge drain manifold. The height of water above plate settlers has been defined as:

Latex

\large
$$
H_{SedAboveW} = outerdiameter(ND_{SedLaunder} ) + HL_{SedLaunder}
$$

The calculations of dimensions of the inlet channel can be found here.

Finally, therefore:

Latex

\large
$$
H_{Sed} = HW_{Sed} + H_{PlantFreeboard}
$$

and

Latex

\large
$$
Z_{MP} = HW_{Sed} - HW_{InletChannel}
$$

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In this current design the top of the slopes are designed to meet the bottom of the lamella. The bottom of the slopes are designed to slope down to the top of the drain pipe. If the depth of the water is increased to the point where the angle of the slopes is greater than 60deg the angle of the slopes will be set to 60 deg and the rest of the height to the bottom of the lamella will be straight vertical wall.

For deeper plants the height of the platform is calculated based on the bottom of the platform being even with the bottom of the inlet channel.

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