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The orifice between the rapid mix and flocculation tanks is designed to produce a difference in water level high that can then be sensed by a float which would then change the flow rate of aluminum sulfate:
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{latex}$$ \Delta H = K_{_{orifice} } {{V_{jet} ^2 } \over {2*g}} $$ {latex} |
where
is the difference in head loss between the rapid mix and flocculation tankLatex Wiki Markup {latex}$$ \Delta H $${latex}
- K orifice is the required minor loss coefficient through the orifice
- V jet is the velocity in the dosing tube
This head loss was then used to determine the velocity of the water through the orifice and the residence time. Using the following equations:
Velocity of Jets:
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{latex} $$V_{jet} = {Q \over {C_d *A_{orifice} }} $${latex} |
where
- V jet is the velocity of the jet
- Q is the flow rate through the system
- C d is the vena contracta coefficient for exit condition in orifice
- A orifice is the area of the orifice
Residence time :
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{latex}$$ \theta = {{d_{orifice} } \over {V_{jet} }} $${latex} |
where
is the residence timeLatex Wiki Markup {latex} $$ \theta $$ {latex}
- d orifice is the diameter of the orifice
- V jet is the velocity of the jet
Once these values were determined, we were able to calculate the energy dissipation rate using the following equation:
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{latex}$$ \varepsilon = {{g*\Delta H} \over \theta } $${latex} |
where
is the energy dissipation rateLatex Wiki Markup {latex}$$ \varepsilon $${latex}
- g is gravity
is the head lossLatex Wiki Markup {latex}$$ \Delta H $${latex}
is the residence timeLatex Wiki Markup {latex}$$ \theta $${latex}
We sought to keep the energy dissipation rate between .5 and 1 W/kg so that molecular scale diffusion works and in order for small scale turbulent mixing to be effective.
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We first must determine the size of the counterweight on the doser arm in order to ensure that the dosage will only be a function of the difference in water height in the flocculation and rapid mix tanks. The mass of the weight is calculated by determining the mass of the doser when full.
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{latex}$$ m_{doserful} = [({{.375in} \over 2})^2 *\pi *25cm + ({{D_{actual} } \over 2})^2 *\pi *1m]\rho _{water} + m_{doser} $${latex} |
where
- D actual is the difference between the given diameter of the dosing tube and the measured diameter of the dosing tube
is the density of waterLatex Wiki Markup {latex}$$ \rho _{water} $${latex}
is the mass of the doser emptyLatex Wiki Markup {latex}$$ m_{doser} $${latex}
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