Abstract:
Devices, apparatus, systems and methods of using baffle boxes with turbulence deflectors and flow spreaders. Turbulence deflectors are added about the inlet port of a baffle box, and a flow spreader is added centrally beneath an outlet port to increase removal efficiency of pollutants and prevent the conveyance of pollutants down stream. The turbulence deflectors and the flow spreader will increase the removal efficiency of particles, especially fine and ultra fine particles without impeding the water flow. The turbulence deflectors will significantly reduce the turbulence within the sediment chambers which will lead to better settling and less re-suspension. The flow spreader spreads the flow wide sooner within the baffle box to reduce the linear velocity of the water current, and directs water flow away from the area of greatest turbulence adjacent to the inflow, and will increase the settling of particles and minimize re-suspension. By increasing the removal efficiency of the first sediment chamber the shielding will prevent the re-suspension of fine and ultra fine particles.

Description:
This invention claims the benefit of priority to U.S. Provisional Patent Application No. 61/119,095 filed Dec. 2, 2008. 
    
    
     FIELD OF INVENTION 
     This invention relates to storm water baffle boxes, in particular to devices, apparatus, systems and methods of using baffle boxes with turbulence deflectors and flow spreaders. 
     BACKGROUND AND PRIOR ART 
     Storm water pollution is often conveyed into our environments from various sources such as from storm water entering lakes and rivers. This type of pollution can threaten the stability of our ecosystems, and the water resources that man&#39;s society depends on. Storm water pollution is often referred to a non-point source pollution because its source is everywhere that rain falls. However, storm water is often concentrated in storm drain pipes for conveyance which is a convenient point of applied treatment. Sediments are heavier than water and many of the targeted chemical pollutants readily attach to sediments. Storm water pipes are used for sediment transport as well as water. Sediments that are smaller in size have a higher concentration of these chemical pollutants than larger particles. 
     A storm water treatment system that can capture very fine sediments such as silt and clay will be more effective than a treatment system that is limited to medium and coarse size sediments. In modern day permitting practices of water sheds, requirements for more demanding pollutant removal efficiencies, and technology that increases the efficiency of storm water treatment will more than likely be required and an important part of the solution. Currently, capturing very fine sediment particles is not able to be easily achieved in current storm water treatment systems. 
       FIG. 1  is an upper perspective view of a conventional baffle box  10 .  FIG. 2  is another perspective view of the baffle box  10  of  FIG. 1  with cut-away face wall.  FIG. 3  is a top view of the conventional baffle box  10  of  FIGS. 1-2  with water flow lines.  FIG. 4  is a side sectional view of the conventional baffle box  10  of  FIG. 3  along arrows  4 A with flow lines over the baffles and circulating loop currents within the sediment chambers. 
     Referring to  FIGS. 1-4 , a conventional baffle box  10  can include an inlet pipe  20  entering into one end of a baffle box case  40 , and an outflow pipe  30  exiting out the opposite end of the box case  40 . Inside of the case  40  can be one or more baffles  50  that divide up various sediment chambers  60 ,  70  and  80 . 
     Referring to  FIGS. 3-4 , water flows into the box  10  in the direction of arrow  90 , and circulates in loops  110  inside of first sediment chamber  60 , and flows over baffle  50  in the direction of arrow  120  into second chamber  70 . The water then circulates again in loops  110  inside of second sediment chamber  70 , and over another baffle  50  in the direction of arrow  120  into third sediment chamber  80  where it again circulates in loops  110 , and then exits the box  10  through outflow pipe  30  in the direction of arrow  100 . From the first sediment chamber  60  to the third sediment chamber  80 , a gradual widening of the flow occurs while sediment  130  is at the bottom of box  10  below water level  140   
     Baffle boxes are treatment structures that can treat the entire flow of a pipe and has the capability to capture particles that are heavier than water such as sediments. Baffle boxes are used to reduce the velocity of the water flow and reduces turbulence to calm the water which is conducive for the settling of suspended particles. Creating calm water and maximizing retention time within the baffle box will increase the removal efficiency. Although there many different configurations of baffle boxes, laboratory and field testing has yielded data that suggests an optimum configuration for a baffle box. A typical well designed conventional baffle box can have the following general characteristics: 
     1. Three equally size sediment chambers 
     2. The length of the vault will be approximately twice the width. 
     3. The inflow pipe, top of baffles and outfall pipe will be at the same elevation. 
     4. The inflow pipe size will not exceed half the width of the vault. 
     Referring to  FIGS. 1-4 , a majority of the captured sediments in a baffle box  10  will be in the first sediment chamber  60 . The average sediment size in the second sediment chamber  70  will be smaller than in the first sediment chamber  60 , and average sediment size in the third chamber  80  will be smaller than the sediment in the second sediment chamber  70 . Smaller particles take longer to settle than larger particles. The greater the flow volume moving through a baffle box  10  the less the removal efficiency because there will greater turbulence and less retention time. During medium and large flows there is significant turbulence within the sediment chambers  60 - 80 , which can prevent sediments from settling and re-suspend sediments that had been captured in a previous rain event. In larger flows rectangular current can form within the sediment chambers  60 - 80  and possibly flush most of the previously captured sediments out the end of the baffle box  10 . 
     As water flow enters the baffle box  10  through the inflow pipe  20  the water current gradually spreads wide and down into the first chamber  60 . As the current impacts against the first baffle  50  the current turns and flows down the face of the baffle  50 . When the current reaches the bottom of the sediment chamber it impacts the sediment  130 , agitating it, and then turns back toward the inflow flowing across the captured sediments  130  scouring and re-suspending these sediments. When the current reaches the wall just under the inflow it impacts the wall and turns flowing up the wall toward the inflow pipe  20  and carrying with it scoured sediments. 
     Finally, as the current merges into the inflowing water from the inflow pipe  20 , sediments that had been previously settled across the bottom of the sediment chamber  60  are re-suspended into the highly turbulent inflowing water and are flushed further down the length of the baffle box. The sediments may settle again in the second sediment chamber  70  or third sediment chamber  80 , or flush completely out the end of the baffle box  10  through the outflow pipe  30 . This rectangular current is also present in the second chamber  70  and third chamber  80 . However, the first chamber  60  has significantly greater turbulence than the other chambers  70 ,  80 . This process repeats continuously during the rain event and will dramatically reduce the removal efficiency of the baffle box  10 . Thus, the need exists for solutions to the above problems with the prior art. 
     SUMMARY OF THE INVENTION 
     A primary objective of the present invention is to provide enhanced baffle box apparatus, devices, systems and methods that use turbulence deflectors and flow spreaders to increase the removal efficiency of pollutants and reduce and prevent the conveyance of the pollutants downstream. 
     A secondary objective of the present invention is to provide enhanced baffle box apparatus, devices, systems and methods that use turbulence deflectors and flow spreaders to significantly reduce the turbulence within the sediment chambers which will lead to better settling and less re-suspension. 
     A third objective of the present invention is to provide enhanced baffle box apparatus, devices, systems and methods that use turbulence deflectors and flow spreaders to spread the flow wide sooner within the baffle box to reduce the linear velocity of the water current. It will also direct water flow away from the area of greatest turbulence adjacent to the inflow, and in doing so, function to increase the settling of particles and minimize re-suspension. 
     A fourth objective of the present invention is to provide enhanced baffle box apparatus, devices, systems and methods that use turbulence deflectors and flow spreaders to increase removal efficiency of in the sediment chamber(s) to prevent the re-suspension of fine and ultra fine particles. 
     By enhancing a conventional baffle box with turbulence deflectors and a flow spreader the removal efficiency of pollutants will increase and prevent the conveyance of pollutants down stream. Turbulence deflectors and a flow spreader will increase the removal efficiency of particles, especially fine and ultra fine particles without impeding the water flow. 
     The turbulence deflectors will significantly reduce the turbulence within the sediment chambers which will lead to better settling and less re-suspension. 
     The flow spreader will function to spread the flow wide sooner within the baffle box to reduce the linear velocity of the water current. It will also direct water flow away from the area of greatest turbulence adjacent to the inflow, and in doing so, function to increase the settling of particles and minimize re-suspension. By increasing the removal efficiency of the first sediment chamber the process of shielding will function to prevent the re-suspension of fine and ultra fine particles. 
     A preferred system for increasing efficiencies of storm water baffle boxes to remove pollutants, can include a baffle box having at least one sediment settling chamber with a baffle, with a raised inlet port for allowing storm water to pass into the baffle box, and a raised outlet port for passing flow from the storm water to pass out of the baffle box, an inflow deflector adjacent to the inlet portion of the baffle box beneath the inlet port for reducing turbulence of the storm water passing into the sediment chamber to allow for increased settling and less suspension of pollutant particulates, and a flow spreader in the at least one sediment chamber on the baffle for spreading the flow wide sooner within the baffle box to reduce linear velocity of the flow of the storm water. 
     The inflow deflector can include a pair of angled down deflectors on both sides of the inlet port. The flow spreader can include a funnel positioned adjacent a rear wall of the baffle box centrally located on the upstream of the baffle. The funnel flow spreader can have a triangular configuration. 
     The system can further include a second sediment chamber having a second baffle, the with tops of the baffles approximately even in elevation to the inflow and outflow pipes, for allowing storm water to pass from the inflow pipe and flow across and into the first sediment chamber, then across the top to the first baffle and then into the second sediment collection chamber, a second inflow deflector adjacent to the top of the first baffle on the downstream side of the first baffle for reducing turbulence of the storm water passing into the second sediment chamber to allow for increased settling and less suspension of pollutant particulates. 
     The system can further include a third sediment settling chamber between the second baffle and the outflow end of the baffle box for allowing storm water to pass from the second sediment collection chamber, then across the top of the second baffle box and then into the third sediment collection chamber, and a third inflow turbulence deflector adjacent to the top of the second baffle and within the third sediment settling chamber with the baffle box for reducing turbulence of the storm water passing into the third sediment chamber to allow for increased settling and less suspension of pollutant particulates. 
     The first inflow deflector can include two separate deflectors with a space separating the two deflectors, so that the space is below the inlet port, and the second inflow turbulence deflector and the third inflow turbulence deflectors are each a single elongated deflector. 
     Furthermore, each of the first inflow deflector and the second inflow deflector and the third inflow deflector are each a single elongated deflector. 
     The flow spreader can be the same height as the first baffle. The flow spreader can be higher than the height of the first baffle. 
     A method of increasing pollutant removal efficiencies of a baffle box to prevent further conveyance of the pollutants down stream, can include the steps of deflecting incoming storm water passing into an inlet port of a first sediment chamber of the baffle box with a first inflow deflector in order to block sediment from becoming resuspended in the baffle box, spreading water current wide adjacent to a rear wall of the first sediment chamber of the baffle box to reduce linear velocity of water current, and increasing deposit amounts of the sediment and the particulates being held in a bottom of the first sediment chamber of the baffle box with a first baffle. 
     The deflecting step can include the step of attaching at least one angled down deflector to an inside wall beneath the inlet port, wherein the angled down deflector increases back pressure within the sediment chamber to reduce volumes of the storm water passing into the baffle box. 
     The spreading step can include the step of placing a flow spreader onto a central portion of a rear wall of the baffle box beneath the outlet port in order to spread the water current and deflect the water current toward corners where the inflow wall and sides of the baffle box meet. 
     The method can include the steps of deflecting the incoming storm water passing into a second sediment chamber with a second inflow deflector in order to block the sediment from becoming resuspended in the second chamber, and increasing the deposit amounts of the sediment and the particulates being held in a bottom of the second sediment chamber. 
     The method can include the steps of deflecting the incoming storm water passing into a third sediment chamber with a third inflow deflector in order to block the sediment from becoming resuspended in the third chamber, and increasing the deposit amounts of the sediment and the particulates being held in a bottom of the third sediment chamber. 
     The first inflow deflector can be two separate deflectors with a space separating the two deflectors, so that the space is below the inlet port, and the second inflow turbulence deflector and the third inflow turbulence deflectors are each a single elongated deflector. Furthermore, each of the first inflow deflector and the second inflow deflector and the third inflow deflector can each be a single elongated deflector. 
     The flow spreader can be the same height as the first baffle. The flow spreader can be higher than the height of the first baffle. 
     Further objects and advantages of this invention will be apparent from the following detailed description of the presently preferred embodiments which are illustrated schematically in the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE FIGURES 
         FIG. 1  is an upper perspective view of a conventional baffle box. 
         FIG. 2  is another perspective view of the baffle box of  FIG. 1  with cut-away face wall. 
         FIG. 3  is a top view of the conventional baffle box of  FIGS. 1-2  with water flow lines. 
         FIG. 4  is a side sectional view of the conventional baffle box  10  of  FIG. 3  along arrows  4 A with flow lines over baffles and circulating loop currents in the sediment chambers. 
         FIG. 5  is a perspective view of a baffle box with separate inflow turbulence deflectors, baffle turbulence deflector and flow spreader ready to be installed in the baffle box. 
         FIG. 6  is a perspective view of the baffle box of  FIG. 5  with the novel deflectors and flow spreader installed inside the baffle box. 
         FIG. 7  is a top view of the baffle box with deflectors and flow spreader of  FIG. 6  showing water flow through the box and over the baffles. 
         FIG. 8  is a side cross-sectional view of the baffle box with deflectors and flow spreader along arrows  8 A of  FIG. 7  showing water flow through the box and the baffles. 
         FIG. 9  is a top front perspective view of a left inflow turbulence deflector of  FIGS. 5-8 . 
         FIG. 10  is a top rear perspective view of the left inflow turbulence deflector of  FIG. 9 . 
         FIG. 11  is a top front perspective view of a right inflow turbulence deflector of  FIGS. 5-8 . 
         FIG. 12  is a top rear perspective view of the right inflow turbulence deflector of  FIG. 11 . 
         FIG. 13  is a top view of the baffle turbulence deflector of  FIGS. 5-8 . 
         FIG. 14  is a side view of the baffle turbulence deflector of  FIGS. 5-8 . 
         FIG. 15  is a top rear perspective view of the flow spreader of  FIGS. 5-8 . 
         FIG. 16  is a top front perspective view of the flow spreader of  FIG. 15 . 
         FIG. 17  is a perspective view of baffle box with deflectors and an optional elongated flow spreader. 
         FIG. 18  is a cross-sectional view of the baffle box of  FIG. 17 . 
         FIG. 19  is a perspective view of the baffle box with deflectors and the standard flow Spreader  180 , and single baffle turbulence deflectors in all the chambers. 
     
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Before explaining the disclosed embodiments of the present invention in detail it is to be understood that the invention is not limited in its applications to the details of the particular arrangements shown since the invention is capable of other embodiments. Also, the terminology used herein is for the purpose of description and not of limitation. 
     The components in the figures will now be described.
       10 . Conventional baffle box. Prior art.     20 . Inflow pipe.     30 . Outflow pipe.     40 . Baffle box case.     50 . Baffle.     60 . Sediment chamber  1 .     70 . Sediment chamber  2 .     80 . Sediment chamber  3 .     90 . Water flow into the box.     100 . Water flow out of box.     110 . Circulating loop currents in sediment chambers.     120 . Flow over baffle.     130 . Sediment.     140 . Possible water level.     150 . Right inflow turbulence deflector.     155 . Downwardly sloping top surface.     158 . Frame     159 . Openings for fasteners     160 . Left inflow turbulence deflector.     165 . Downwardly sloping top surface.     168 . Frame     169 . Openings for fasteners.     170 . Baffle turbulence deflector.     172 . Upper flange edge     173 . Openings for fasteners     174 . Planar rectangular sheet.     176 . Lower flange edge adds strength to deflector     180 . Flow spreader.     181 . Flange end     182 . Inwardly bent panel     183 . Openings for fasteners     184 . Outwardly bent panel     185 . Rounded apex top     186 . Outwardly bent panel     187 . Openings for fasteners     188 . Inwardly bent panel     189 . Flange end     190 . Baffle box with deflectors and flow spreader.     200 . Water flow into chamber  1  redirected by flow spreader.     220 . Circulating loop currents in sediment chambers  1  &amp;  2  dead-heading into baffle turbulence deflector.     240 . Sediment.     250 . Closed end of turbulence deflector.     260 . Open end of turbulence deflector.     270 . Baffle Box with deflectors and optional elongated flow spreader.     280 . Elongated flow spreader.     290 . Baffle box with standard flow spreader and alternate chamber # 1  deflector configuration.   

       FIG. 5  is a perspective view of a baffle box  10  with separate inflow turbulence deflectors  150 ,  160  (shown in  FIGS. 9-11 ), baffle turbulence deflector  170  (shown in  FIGS. 13-14 ) and flow spreader  180  (shown in  FIGS. 15-16 ) ready to be installed in the baffle box  10 .  FIG. 6  is a perspective view of the baffle box  10  of  FIG. 5  with the novel deflectors  150 ,  160  and flow spreader  180  installed inside the baffle box  10 . 
       FIG. 9  is a top front perspective view of a left inflow turbulence deflector  160  of  FIGS. 5-8 .  FIG. 10  is a top rear perspective view of the left inflow turbulence deflector  160  of  FIG. 9 .  FIG. 11  is a top front perspective view of a right inflow turbulence deflector  150  of  FIGS. 5-8 .  FIG. 12  is a top rear perspective view of the right inflow turbulence deflector  150  of  FIG. 11 . Each of the deflectors  150 ,  160  can have downwardly sloping top surfaces  155 ,  165  with lower flange edge  154 ,  164  closed ends  250  and open bottom ends  260 , and have a triangular appearing side profile. 
     Referring to  FIGS. 5 ,  6  and  9 - 12 , the right inflow turbulence deflector  150  and the left inflow turbulence deflector  160  can be installed against the front inner wall of the baffle box below and the right and left of the inflow pipe  20 . Each deflector  150 ,  160  can be installed by attaching fasteners (not shown) such as bolts, screws and the like, through openings  159 ,  169  in the frames  158 ,  168  about the respective deflectors  150 ,  160 . 
       FIG. 13  is a top view of the baffle turbulence deflector  170  of  FIGS. 5-8 .  FIG. 14  is a side view of the baffle turbulence deflector  170  of  FIGS. 5-8 . Referring to  FIGS. 5 ,  6  and  13 - 14 , the baffle turbulence deflector  170  can have a rectangular planar shape  174  with angled flat opposite flange edges  172 ,  176 , and openings in an upper flange edge  172  for allowing fasteners, such as but not limited to bolts and screws to attach, the deflector to outflow sides of baffles  50  inside of the box  10 . 
       FIG. 15  is a top rear perspective view of the flow spreader  180  of  FIGS. 5-8 .  FIG. 16  is a top front perspective view of the flow spreader  180  of  FIG. 15 . Referring to  FIGS. 5 ,  6 , and  15 - 16 , the flow spreader(s)  180  can have flat flange ends  181 ,  189  each with openings  183 ,  187  for allowing fasteners, such as but not limited to bolts and screws to attach the spreader to the inlet side of the first baffle  50  in the first sediment chamber  60 . The spreader(s)  180  can have inwardly bent flat panels  182 ,  188  that extend up from the flange ends  181 ,  189 , and have upper flat panels  184 ,  186  that outwardly bend out from panels  182 ,  188 , and meet at a rounded apex  185 . 
       FIG. 7  is a top view of the baffle box  190  with deflectors  150 ,  160 ,  170 , and flow spreader  180  of  FIG. 6  showing water flow through the box and over the baffles  50 .  FIG. 8  is a side cross-sectional view of the baffle box  190  with deflectors  150 ,  160 ,  170  and flow spreader  180  along arrows  8 A of  FIG. 7  showing water flow through the box and over the baffles  50 . 
       FIG. 7  shows water flow through the box  190  and over the baffles. The flow into first sediment chamber  60  is immediately redirected to flow  200  to the sides of the chamber by the flow spreader  180 . The left and right turbulence deflectors  150 ,  160  break up the circulating loop currents that were previously shown in the conventional baffle box of prior art  FIGS. 1-4 . In  FIG. 7 , backpressure  210  created by the turbulence deflectors  150 ,  160  helps to spread the flow the full width of the chamber  60 , reduces turbulence, and reduces the overall velocity of the flow all of which improves sediment settling  240 .  220 . Circulating loop currents  220  in sediment chambers  60 ,  70  dead-heading into respective baffle turbulence deflectors  170  in each respective chamber. Flow into the chambers is shown as non-filled arrows  120 . 
       FIG. 8  further shows the flow of water through the chambers  60 ,  70 ,  80  and over the baffles  50 .  FIG. 8  shows the function of the deflectors  150 ,  160 ,  170  in breaking up the loop currents. Again, flow into the chambers is illustrated as non-filled arrows and backpressure is illustrated as hatched arrows. 
     Referring to  FIGS. 7-8 , backpressure can be created by redirected flow dead-heading into turbulence deflectors  150 ,  160  in the first chamber  60 . The backpressure spreads the flow across the width of the chamber  60 , reduces turbulence, and reduces the velocity of the flow, all of which improves sediment settling  140 . The turbulence deflectors  150 ,  160  have a wall on the side closest to the center of the chamber  60  and have no wall nearer the sides of the box  190 . There is a space between the sides of the box  190  and the open end of the turbulence deflectors  150 ,  160  to channel flow away from the center of the box  190  thereby assisting in the widening of the overall flow as well as reducing turbulence under the inflow pipe  20  for improved sediment settling. 
     Referring to  FIGS. 7-8 , backpressure can also be created by the circulating loop currents dead-heading into the baffle turbulence deflectors  170  in first and second chambers  60 ,  70  spread the flow across the width of the chambers  50 ,  60 , reduce turbulence, and reduce the velocity of the flow, all of which improves sediment settling  240 . Both ends of the baffle deflectors  170  are open and spaced off of the box walls to facilitate the flow moving toward the sides of the box  190  thereby widening the overall flow. 
       FIG. 17  is a perspective view of baffle box  270  with deflectors and an optional elongated flow spreader  280 . Spreader  280  is similar to but longer than previously described spreader  180 . The facing wall of the baffle box is cut away. The top of the elongated flow spreader  280  is co-linear with the top of the inside of the inflow pipe  20   FIG. 18  is a cross-sectional view of the baffle box  270  of  FIG. 17  showing the extra height of the elongated spreader  280 . The spreader allows for the linear velocity of incoming water to be reduced at the point of the first baffle  50  in the first sediment chamber  60  and increase sediment pickup in the first chamber  60 . Spreading the sediment to a wider flow at a reduced velocity increases detention time in the chamber that allows for more time to allow sediment to drop and increase sediment removal efficiency. 
       FIG. 19  is a perspective view of the baffle box  290  with deflectors and the standard flow spreader  180 , and single baffle turbulence deflectors  170  in all the chambers  50 ,  60 ,  70  This embodiment has had the right and left inflow turbulence deflectors  150 ,  160  in first chamber  60  replaced with a single baffle turbulence deflector  170  that is the same as the deflector(s) installed on the baffles  50  of the second and third chambers  60 ,  70 . Here, the extra deflector  170  is attached to the inside of the wall of chamber  60  beneath the inlet pipe  20 . 
     The previous embodiments of using two deflectors spaced apart under the inlet pipe allows for larger and heavier sediment particles and debris to drop down the wall and chamber floor space adjacent the wall. Using a single elongated deflector in the first chamber can be preferable when sediment particles are much finer (for example, sand like). The single elongated deflector can eliminate the splash up effects water that can occur with the space that exists between two separate deflectors. The single deflector can enhance the circulation of water. A combination of a high velocity incoming water flow through the inlet pipe along with sediments that are more fine (for example, sand like) would allow for reduced turbulence in the water circulation and increased sediment retention in the sediment chamber when using single elongated deflector. 
     Referring to  FIGS. 5-19 , the invention includes apparatus, devices, systems and methods for significantly calming the water and reducing currents within a baffle box  10  to significantly increase the pollutant removal efficiency of this treatment structure. Adding the features of turbulence deflectors  150 ,  160 ,  170  in all three sediment chambers  60 ,  70 ,  80  and a flow spreader  180  on the wall of the baffle  50  in the first sediment chamber  60  can make a dramatic difference and take the baffle box beyond what is commonly referred to as conventional. Because the first chamber  60  of baffle boxes experience far greater turbulence than the second and third chambers, the greatest increase in the removal efficiency can be achieved by reducing and modifying the turbulence in the first chamber  60 . 
     Adding turbulence deflectors  150 ,  160  to the wall under the inflow pipe  20  and to the top of each of the downstream sides of the baffles  50  the rectangular current that can form in the sediment chambers can be dramatically reduced. In addition, the turbulence deflectors  150 ,  160 ,  170  will physically block sediment from re-suspending and entering back into the water flow passing by above the baffles. Turbulence deflectors  150 ,  160 ,  170  create a kind of back pressure within the sediment chambers  60 ,  70 ,  80  that reduces the volume of water that can enter the chambers. By reducing the volume of water that can enter the sediment chambers, more efficient settling of particles will be achieved and the potential for re-suspension will be dramatically reduced. 
     Dealing with the turbulence in the first chamber  60  is different than dealing with the turbulence in the second and third chambers  70 ,  80 . As fast flowing water enters the baffle box  10  from the inflow pipe  20  above the first chamber  60 , it is a concentrated current that begins to spread wide and down as it flows across the first sediment chamber  60 . When the inflowing current hits against the inflow side of the first baffle  50  it is still relatively concentrated and central within the first sediment chamber  60 . By the time the water flow passing through the baffle box reaches the second baffle  50  it has spread wider and is flowing close to the full with of the baffle box  10 . Preventing the rectangular current in the second and third chambers  70 ,  80  is about dealing with water that has spread the full width of the baffle box, while the water current in the first sediment chamber  60  is concentrated and typically within the central approximate ⅓ of the chamber  60 . 
     By placing a flow spreader  180  on the center of the baffle wall in the first chamber  60  the water current is spread and deflected wide toward the corners where the inflow wall and the sides of the baffle box meet. Deflecting and spreading the current wide within the first chamber guides the current away from the area directly below the inflow pipe, greatly reducing the potential to re-suspend sediments from directly below the inflow pipe  20  into the inflowing water. Because the water directly under the inflow pipe  20  is not upwelling, sediments can more easily settle adjacent and directly below the inflow pipe  20 , and there is no need for a turbulence deflector directly below the inflow pipe. By not having a turbulence deflector directly under the inflow pipe, a clear path is provided for sediment to settle straight down the wall under the inflow as it enters the baffle box. 
     By having a left and right turbulence deflectors  150 ,  160  on the inflow wall in the first chamber  60  a space under the inflow is left open for sediment to settle straight down the inflow wall. The current that has been deflected by the flow spreader will be cut off by the left and right turbulence deflectors. However, to prevent ultra fine sediments from flowing horizontal under the turbulence deflectors  150 ,  160  toward the inflowing water which is in the center of the baffle box, the turbulence deflectors  170  will be shaped to have a vertical wall on the underside of the deflector adjacent to the inflow, and a gap will be provided between the deflector and the side wall of the baffle box. By shaping the deflector in this way and providing a gap between the deflector and the side wall, any current carrying ultra fine sediments that impact the bottom of the deflector will be conveyed wide toward the sides of the baffle box. This will help to remove ultra fine sediments from turbulence by keeping them away from the inflowing water while maximizing retention time within the baffle box which will increase the removal efficiency of the treatment structure. The turbulence deflector(s)  150 ,  160 ,  170  is shaped so that the top of the deflector is angled enough to provide a sufficient slope for particles that settle on top of deflector  150 ,  160 ,  170  to slide off and settle into the sediment chamber  50 ,  60 ,  70 . 
     By minimizing turbulence within the first sediment chamber  60  the amount of fine and ultra fine sediments captured in the first chamber will increase. Because medium and coarse sediments will not likely pass the first chamber  60 , the blend of sediment sizes in the first chamber  60  will have a higher ratio of fine and ultra fine sediments. During higher flow events the medium and coarse sediments will shield the fine and ultra fine sediments from turbulence and further prevent re-suspension of previously captured sediments. In addition, these small particles will have a higher concentration of chemical pollutants than the larger particles. By improving the capture of particles and preventing previously captured particles from re-suspending within the first sediment chamber  60  will significantly increase the overall removal efficiency of the baffle box. 
     Reducing the turbulence within the second and third sediment chambers  60   70  requires a different approach because the shape of the water flow that influences these chambers is different. As the water flow passes above the second chamber it spreads wider and slightly down into the second chamber, the linear velocity is reduced. The further the water flow moves down the length of the baffle box the more the linear velocity is reduced, however, the flow volume remains the same. As the velocity is reduced so does the turbulence which increased the potential for particles to settle into the sediment chambers. 
     By the time the flow reaches the second baffle  50  it is close to flowing the full width of the vault (box). The rectangular currents commonly found in the second chamber  70  of a conventional baffle box are going to be dramatically reduced because of the turbulence deflector  170  in the second chamber on the downstream side of the first baffle  50 . The portion of water flow that impacts on the upstream side of the second baffle  50  will have a tendency to flow down the face of the baffle  50  and into the second chamber  70  which could possibly initiate the formation of a rectangular current within the chamber  70 . However, the turbulence deflector  170  will create static pressure within the chamber  70 , and when compared to a conventional baffle box, will significantly reduce the volume of water entering the second chamber. With less turbulence within the chamber there will greater potential for the settling of particles and less potential for scouring. The rectangular current commonly found in conventional baffle boxes will either not be able to form or be dramatically reduced. 
     The turbulence deflectors  150 ,  160 ,  170  will also act as a physical barrier to prevent particles from being introduced back into the water flowing by above the baffles  50 . The turbulence deflectors  150 ,  160 ,  170  are shaped so that the top of the deflector is angled enough to provide a sufficient slope for particles that settle on top of deflector to slide off and settle into the sediment chamber(s)  50 ,  60 ,  70 . 
     As the water flow passes over top of the second baffle  50  and enters the area above the third sediment chamber  80  the linear velocity of the flow is at its slowest. The settling process and hydrodynamics in the third chamber is almost the same as that in the second chamber with one significant difference. In the area above the third sediment chamber  80  adjacent to the outflow, the water flow accelerates and then exits the baffle box. 
     The invention can work with only a deflector(s) and no spreader in a single baffle box chamber. Alternatively, the invention can work with a single spreader in a first chamber and no deflector. The spreader can be located in the first chamber against the rear baffle (downstream side of the rear wall) of the chamber. The spreader can be located in more than one chamber, such as in a series of the chambers. Likewise the deflector can be in the front chamber and/or the second chamber and/or the third chamber. 
     The invention can be retrofitted into existing baffle boxes. For example, the invention can be sold in a kit form with the deflectors and/or the spreaders sold separately or in packages for existing baffle boxes. The invention deflectors and/or spreaders can be attached by fasteners such as but not limited to bolts, screws, and the like. 
     The invention has been tested and passed standards such as those from the State of New Jersey. Testing has also shown that up to approximately 300% increased sediment retention occurs when using the novel deflectors and spreaders of the invention. 
     While the deflectors are generally shown as having top surfaces that that are angled and incline downward, the top surfaces of the deflectors can also be substantially horizontal. 
     The deflectors and spreaders can be formed from materials such as but not limited to molded plastic, fiberglass, resin, composites, metals, combinations, thereof, and the like. The deflectors and flow spreaders can be made from aluminum, stainless steel, galvanized metal. 
     While the invention has been described, disclosed, illustrated and shown in various terms of certain embodiments or modifications which it has presumed in practice, the scope of the invention is not intended to be, nor should it be deemed to be, limited thereby and such other modifications or embodiments as may be suggested by the teachings herein are particularly reserved especially as they fall within the breadth and scope of the claims here appended.