Siphon-aided backwash
The goal of our research is to evaluate the feasibility of a siphon-aided backwash design to be used for a sand or mixed-media down-flow filter. The benefits of siphon-aided backwash are:
1) The height of the clear-well does not need to be equal to the the head pressure required to attain 30%-50% expansion.
2) The filter bed can be right next to the clear-well, connected via an open pipe without a valve. Flow of water into and out of the clear-well will be controlled by valves on the influent and backwash manifolds.
3) Using 55 gallon HDPE barrels, we will create a system of parallel filters surrounding a shared clear-well. By backwashing the filters out of phase, we will reduce the demand for a large clear-well. Additionally, the downflow filters will be filling the clear-well while the other filters being backwashed draw from it. This allows faster clear-well recharge rates and shortens the time between consecutive backwash cycles.
The inspiration for our design
An example of a patented siphon-aided backwash design (Automatic Valveless Gravity Filter)
The filter bed rests inside an air-tight container. The influent enters through a port above the sand bed. The siphon is also connected through a separate port, connected to the container, above the sand bed. The clean water exits the container below the sand bed, which leads to clear-well storage.
Flow scheme in regular down-flow mode:
Raw water enters from the top>sand bed>out to clear-well
In backwash mode: The siphon is "primed" by the headloss generated in the clogging filter, which causes the raw water to flow up the siphon tube. Eventually the water begins to flow over the bend of the siphon and as it fills the tube, a negative pressure gradient is established, diverting all flow out the siphon.
Water from clear-well flows in reverse>sand bed (from bottom)>siphon>waste
Designs
Concentric well screen filter design
Offset filter bed design
55 Gallon Barrel Filters with Shared Clear Well
Single 55 gallon barrel filter schematic
Height required to attain backwash velocity (with headloss calculations)
Factors to consider for operation:
1)Sand level monitoring
-Plexi-glass viewing strip on barrel side
2)Pressure across filters-when do the filters need to be back-washed?
-piezometer
3)Backwash Velocity- achieve bed expansion without losing sand
-Gate valve on siphon tube
4)Flow distribution during backwash-avoiding shocks to the system
5)Bypass -for seasons when filtration is unnecessary
Discussion topics
1)8 parallel filters: where 7 down-flow filters backwash 1 filter
-Problem: not flexible for variable plant flow rates
-If multiple filters are dirty, can not achieve desired backwash velocity
2)Clear well might be necessary
-Constant backwash velocity
-If multiple filters are dirty, filters can still be back-washed
3)Backwash from sedimentation tank
-Is using raw water for backwash okay?
-At end of backwash ~6 inches of dirty water is retained in bed, so the first distribution of water after backwash will have high turbidity
Future work
Bench top model:
-Test how changing the height difference (between the water level in the clear well to the bottom of the siphon) influences backwash velocities.
-Fine-tune the backwash velocity using a gate valve on the siphon tube.