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The active length of the tank is the total length of the sedimentation tank minus the inactive length of the sedimentation tank found below.

{latex}
\large
$$
L.Inactive = L.SedPlate \cdot \cos (AN.SedPlate) + W.InletChannel + W.ExitChannel + 2 \cdot T.ChannelWall
$$
{latex}

The upward velocity through the lamella:

{latex}
\large
$$
V.SedUpActiveBelow = {{Q.Sed} \over {W.Sed \cdot \left( {L.Sed - L.SedInactive} \right)}}
$$
{latex}

Length of the Lamella:

{latex}
\large
$$
L.SedPlateEst = {{B.SedPlateMin \cdot \left( {{{V.SedUpActiveBelow} \over {V.SedCBod}} - 1} \right) + T.SedPlate} \over {\sin \left( {AN.SedPlate} \right) \cdot \cos \left( {AN.SedPlate} \right)}}
$$
{latex}

The length found in the above loop is an estimated length, The actual lamella length is dependent on the length of the plastic sheeting material that available. Typically this sheeting length is either 8 or 12 feet.

{latex}
\large
$$
L.SedPlate = {{L.SedPlateSheet} \over {floor\left( {{{L.SedPlateSheet} \over {L.SedPlateEst}}} \right)}}
$$
{latex}

From this number the actual upward velocity (V.SedUpActiveBelow) under the lamella and the actual space needed between the lamella are recalculated. The equation for V.SedUpActiveBelow is the same was used above.
The perpendicular, center to center, space between lamella:

{latex}
\large
$$
B.SedPlate = {{L.SedPlate \cdot \sin \left( {AN.SedPlate} \right) \cdot \cos \left( {AN.SedPlate} \right) - T.SedPlate} \over {{{V.SedUpActiveBelow} \over {V.SedCBod}} - 1}}
$$
{latex}

Perpendicular open space between lamella (does not include material thickness):

...

The horizontal distance between lamella; this accounts for the angle of the lamella in the tank:

{latex}
\large
$$
B.SedPlateHorizontal = {{B.SedPlate} \over {\sin \left( {AN.SedPlate} \right)}}
$$
{latex}

Using the available active length in the sedimentation tank and the known length of the lamella, the number of lamella that can fit in the tank can be calculated as follows.
The Number of Lamella:

{latex}
\large
$$
N.SedPlates = ceil\left( {{{L.SedActiveMax} \over {B.SedPlateHorizontal}}} \right)
$$
{latex}

The vertical height taken up by the lamella is simply a function of the lamella length and angle.

{latex}
\large
$$
H.SedPlate = L.SedPlate \cdot \cos \left( {AN.SedPlate} \right)
$$
{latex}

The thickness of the lamella contributes a small but significant dead zone to the tank. Now that the exact number of lamella has been calculated, more accurate values of active tank length, upward velocity, and critical velocity can be found. Calculations for these values are shown below.

...

The height of the water in the sedimentation tank can now be determined. The inletchannel and the lamella and launders coexist in the same top portion the tank. Therefore the water height is the maximum of these two pieces plus space needed for the elements in the bottom of the tank, which include the inlet manifold and drain.

{latex}
\large
$$
HW.Sed = \max \left( {\left( {Z.SedSlopes + H.SedFrameWall + H.SedBetween + 2 \cdot outerdiameter(ND.SedPlateFrame) + H.SedPlate + H.SedAbove} \right),\left( {H.SedManifoldPort + H.SedBetween + T.ChannelWall + H.InletChannel} \right)} \right)
$$
{latex}

where

For tanks where there are more than one bay per tank, a wall is constructed to separate bays. This wall has height that comes up to the top of ledge that supports the lamella frame. This was done so that the wall can lend support to the center section of the lamella. The equation used is as follows.

{latex}
\large
$$
H.SedBayDivider = Z.SedSlopes + H.SedFrameWall
$$
{latex}

The inlet manifold is formed by laying concrete plates next to each other. The width of each slope plate is defined by the user. If the length of the sedimentation tank is not equally divided by the width of the plate, there is a leftover space that needs to be filled by a fraction of a plate. This is used for construction purposes. More details of about the inlet manifold can be found on the inlet manifold design page. It should be noted that this calculation could not be done in the inlet manifold program because the size of the inlet channel was needed, and the inlet channel is not defined until after the inlet manifold program.

{latex}
\large
$$
{\rm{W}}_{{\rm{SedSlopePlateRemaining}}}  = L_{Sed}  - N_{SedPorts}  \cdot W_{SedSlopePlate}
$$
{latex}