METHOD AND APPARATUS FOR TREATMENT OF WASTEWATER

Information

  • Patent Application
  • 20150041393
  • Publication Number
    20150041393
  • Date Filed
    August 20, 2014
    10 years ago
  • Date Published
    February 12, 2015
    9 years ago
Abstract
Introducing a high surface area media into a sewage treatment process to improve and increase capacity of a given process. The high surface area media can be dispersed at strategic locations in a new or existing attached growth wastewater treatment plant so as to provide additional sites for biological growth and improved wastewater renovation.
Description
BACKGROUND OF THE INVENTION

The present invention pertains to a method and apparatus for the treatment of wastewaters, more specifically, sanitary wastewaters, with a combination of materials, apparatus and equipment for both improvement of the treatment processes as well as the creation of additional treatment capacity. More particularly, the present invention pertains to a method and apparatus for modifying an attached growth process employing biofilms with high surface area materials as well as suspended attached growth processes as either intermittently or continuously feeding of zeolitic material.


Over the past 20-30 years there has been an increase in the use of the Attached Systems in the wastewater treatment processes because of the inherently more efficient settling and stable and higher treatment efficiency. Attached growth process are Trickling Filters, Rotating Biological Contactors, IFAS (Integrated Fixed Film Activated Sludge), MBBR (Moving Bed Biofilm Reactors), RBC (rotating Biofilm Reactors). Denitrification filters including but not limited to conventional flow through rock or plastic media trickling filter modifications as well as submerged growth reactors.


Trickling filter reactors are large tanks filled with rock or plastic media upon which the wastewater is applied over the surface either continuously or intermittently and allowed to trickle down over the media. The filters have either passive or forced draft air ventilation system.


Wide variations in both the hydraulic and biological loading as well as temperature in attached growth sewage treatment process give rise to numerous operating problems as well as process inefficiency. Attached biofilm reactors become problematic when the wastewater volume or wastewater characteristics exceed the ranges designed for the systems. Any agent or combination of agents that can improve or expand the range of the operation band for attached growth type plants, will improve the operating efficiency as well as compliance excursions with effluent standards as well as being cost effective.


Zeolites have been successfully employed for improved wastewater treatment plant performance in accordance with the published literature and can provide a stabilizing effect during both long term and short term so fluctuations in sludge settleablilty and bacterial mass growth in sewage treatment plants are improved. It provides not only a weighting agent for increasing the sludge settling characteristics but also a platform for bacterial growth which performs a function similar to that of an attached growth media systems.


The use of zeolitic materials on various support media for sewage treatment has been documented. A prior art search specifically for zeolite attached to these materials is republished in the following patents:


















Patentee
Patent No.
Filing Date
Issue Date









Stuth
7,252,766
February 2005
Aug. 7, 2007



Horing
6,855,255
January 2003
Feb. 15, 2005



DeFilippie
6,395,522
January 1994
May 22, 2002



Heitkamp
5,980,738
October 1996
Nov. 9, 1999



Sanyal
5,217,616
December 1991
Jun. 8, 1993



Lupton
4,983,299
April 1989
Jan. 8, 1991










The above referenced patents employ a method of attachment of the zeolite or other materials to the support material. These all employ a packed bed reactor through which the wastewater is forced. Another example of prior art are the following patents:


















Patentee
Patent No.
Filing Date
Issue Date









Smith
7,452,468
September 2006
November 2008



Smith
7,507,342
February 2007
March 2009










These patents are based on the dosing of either the zeolite and bacteria or both zeolite and bacteria into wastewater treatment plant which employs a form of activated sludge processing retrofitted with media, as well as attached growth processes. In these patents materials are separate and unsupported dosed materials applied to trickling filter or rotating biological contractor, integrated fixed film activated sludge wastewater treatment processes.


SUMMARY OF THE INVENTION

The present invention is a method for improving the treatment of wastewater, e.g. sanitary wastewater in an attached growth biofilm wastewater process such as trickling filters, rotating biological contactors, integrated fixed film activated sludge or Moving Bed Biofilm Reactors or fixed bed reactor, employing rock or plastic media either stationary or rotating through the wastewater or suspended in the reactor by the addition or feeding of zeolitic or high surface area materials as a dosed material which is added to the wastewater as it is applied to the reactor. Feeding of the zeolitic material is defined as the addition of the zeolite material directly into the aerated or mixed reactors or by the feeding of the zeolitic material into a wastewater stream feeding directly into the reactors or a recirculation stream that discharges into the reactors. The term “hybrid media processing” has been employed to describe a conventional trickling filter or rotating biological contactor, integrated fixed film activated sludge or Moving Bed Biofilm Reactors that employ both conventional media and the dosed high surface area media. The term “hybrid rotating biological contactor” has been employed to describe a conventional rotating biological contactor that employs both conventional media and the dosed high surface area media.


Incorporation of zeolitic materials in trickling filter, rotating biological contactor, integrated fixed film activated sludge or Moving Bed Biofilm Reactors or other attached growth reactors will improve the overall efficiency of the process.


The zeolitic material can be dispersed into an attached growth reactor or the bioreactors of a conventional flow through process by the dosage of the zeolitic material into the applied wastewater stream to the reactors. The zeolitic material can be applied dry or as a liquid mixture or slurry.


Therefore, in one aspect the present invention is a method for improving a wastewater treating process employing one of trickling filter process, a rotating biological contactor process integrated fixed film activated sludge or Moving Bed Biofilm Reactors comprising the step of introducing into said trickling filter, rotating biological contactor, integrated fixed film activated sludge or Moving Bed Biofilm Reactor treatment process a quantity of separate and unsupported natural zeolitic material being one of clinoptilolite, mordenite, chabazite or phillipsite, for better liquid solid separation; removal of ammonia, denitrification, removal of carbonaceous material, reduction of surfactant interference with liquid solid separation, and provide a balanced nutrient formulation in the wastewater.





BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will hereinafter be described in conjunction with the appended drawing figures wherein like numerals denote like elements.



FIG. 1 is a plot of the zeolite dose against effluent COD. As the dosage is increased so is the amount of surface area and therefore the decrease in the amount of COD.



FIG. 2 is a plot of the zeolite dose against equivalent media surface area present in the reactor as a result of the amount of zeolite added.



FIG. 3 is a plot of the zeolite dose against effluent TKN. Total Kjeldahl Nitrogen or TKN is the sum of organic nitrogen, ammonia (NH3), and ammonium (NH4+) in the chemical analysis of soil, water, or wastewater (e.g. sewage treatment plant effluent). To calculate Total Nitrogen (TN), the concentrations of nitrate-N and nitrite-N are determined and added to TKN.



FIG. 4A is a schematic representation of point of application of zeolite at the point where the primary effluent from the primary clarifier is mixed with a portion of the effluent from the Trickling Filter for recycle to the Trickling Filter.



FIG. 4B is schematic representation of the application of the zeolite into the effluent from the primary classifier prior to injection into the Trickling Filter.



FIG. 4C is schematic representation of the application of the zeolite to the primary effluent from the primary classifier mixed with a portion of the effluent from a secondary Trickling Filter prior to injection into a first Trickling Filter and application of the zeolite to the effluent of the first Trickling Filter prior to injection into the second Tickling Filter.



FIG. 4D is a schematic representation of the application of the zeolite in a process featuring multiple clarifiers and multiple Tickling Filters where the first zeolite application point is into the effluent from the primary classifier mixed with a portion of the recycle from the first Trickling Filter and the second zeolite application point is in the effluent from an intermediate clarifier mixed with a portion of the recycle from a secondary Trickling Filter prior to injection into the second Trickling Filter.





DETAILED DESCRIPTION OF THE INVENTION

The following detailed description provides preferred exemplary embodiments only, and is not intended to limit the scope, applicability, or configuration of the invention. Rather, the ensuing detailed description of the preferred exemplary embodiments will provide those skilled in the art with an enabling description for implementing the preferred exemplary embodiments of the invention. It being understood that various changes may be made in the function and arrangement of elements without departing from the spirit and scope of the invention, as set forth in the appended claims.


The following equation is normally employed for estimating the removal of nitrogen by a trickling filter. The nitrification rate units are lb-N/ft̂2/day. This equation therefore is dependent upon the surface area of the tricking filter for the media employed in the trickling filter. The smaller the carbon to nitrogen ratio the higher is the nitrification rate. This is due to the preferential oxidation of the carbon before the nitrogen. This equation does not specifically employ any recirculation rate considerations but can take into it into consideration if it is included in the Carbon & Nitrogen loading onto the trickling filter. This equation is empirically based on the ratio of the applied Carbon loading to Total Kjeldahl Nitrogen loading onto the trickling filter using empirically developed correction coefficients









NitriRate
=

0.82
·


[

Si
RawTKN

]


(

-
0.44

)







Equation





1







Using the data below and solving Equation 1, one arrives at a nitrification rate of 0.00012 lb-N/ft̂2/day.


All of the data reported in Tables 1-7 was generated by mathematical model.














TABLE 1





Status
Input
Name
Output
Unit
Comment






















NitriRate
0.00012
Lb-N/ft{circumflex over ( )}2/day
Nitrification Rate Oakley







Albertson Nitrification Rate




Si
207
mg/l
COD Loading onto Filter



86
RawNH3

mg/l
Influent NH3 concentration



0.85
TKNfactor


Ratio factor of NH2 to TKN










Equation 2 can be employed to compute the value of the applied TKN if the ratio of the TKN to Ammonia (NH3) is known. The value of 0.85 shown in Table 1 is a commonly employed value for domestic wastewater.









RawTKN
=


RawNH





3

TKNfactor





Equation





2







Equation #3 is the standard equation employing the total fixed media surface area, a factor and the Nitrification to determine the mass of ammonia (NH3) removed by a trickling filter with a given amount of surface area based on the media employed in the filter.





NH3removed_Std=(ÓFixedArea.0.0283.NitriRate)  Equation 3


Two parallel trickling filters with the total surface area of 27,695 square feet of rock media having a specific surface area of 15 square feet of surface area per cubic foot of media were loaded at 12,000 gallons per day with the loadings shown in Table 1. Table 2 shows the trickling filter specifics for this installation. The filters were preceded by an equalization basin and a single primary clarifier. The value of Si used in the loading equation was after assigning a 35% COD removal efficiency for the primary clarifier and a filter recycle rate of 400%.














TABLE 2





Status
Input
Name
Output
Unit
Comment




















FilterArea
307.72
ft{circumflex over ( )}2
Estimated Hickory Run






Filter Area



ΣFilterVol
1,846
ft{circumflex over ( )}3
Total Filters Volume



ΣFixed Area
27,695
ft{circumflex over ( )}2
Total Filters Surface Area






Fixed Media



FixMediaSurfaceArea
15
ft{circumflex over ( )}s/ft{circumflex over ( )}3
Media Type Surface Area










Employing Equation 3 the mass of NH3 predicted to be removed is 10.3 lb per day as is shown in Table 3.














TABLE 3





Status
Input
Name
Output
Unit
Comment




















NH3removed_Std
10.3
lb/day
TKN removal based on






conventional Media






Surface Area










Table 4 below shows a model for the same trickling filter plant to which has been added 5 pounds per day of a zeolitic material according to the present invention. The zeolite has a specific surface area of 29,500 square feet per pound. It has been reported in the literature that 98% of zeolite is removed from a trickling filter plant. This includes removal in both the primary and final clarifiers as well as any material enmeshed in the biofilm on the trickling filter. In the trickling filter plant being discussed the zeolite was dosed to an aerated recirculation sump after the two primary trickling filters which then recirculate back to the influent to the two rock trickling filters. Field data indicated that 3.3% of the dosed zeolite surface area was effective in increasing the total surface area in the trickling filters.


Table 4 indicates that an additional 4,868 square feet of surface area is being added daily to the trickling filter media by the addition of the zeolite.














TABLE 4





Status
Input
Name
Output
Unit
Comment




















L
5
ZeroMassDose

lb/day
Dosage of zeolite




ZeoliteConc
50
mg/l
Zeolite Concentration







Dosage based on flow



29,500


ft{circumflex over ( )}2/lb
Surface Area of Zeolite



0.033
ZeoliteEffective

Decimal
Zeolite Effective Area







factor




ΣZeoliteAreaAdded
147,500
ft{circumflex over ( )}2/day
Total Zeolite Surface Area







Added




DailyZeoliteArea
4,868
ft{circumflex over ( )}2
Effective Surface Area







added daily




ΣZeoliteBiofilm
97,350
ft{circumflex over ( )}2
Total Zeolite Area







@Biofilm Age









In trickling filter plants just as in Activated Sludge wastewater plants there is an age to the bacteria. In Activated Sludge it is determined by sludge wasting whereas in a trickling filter plant it is controlled by the biofilm growth and resulting sloughing of the biofilm off the media. Using the numbers shown in the model and a sloughing rate of 5% one has a 20 day biofilm age and a 97,350 square feet of additional surface area due to the zeolite. This results in a total effective surface area of the 27,695 square feet due to the rock media plus the 97,350 square feet due to the zeolite (3.3% effective area for the zeolite as explained previously) for a 352% increase in total surface area. The net effect of this is that it has the same effect as removing the rock media and replacing it with plastic media having a specific surface area of 67.73 square feet per cubic foot without additional capital costs.


Table 5 indicates that the volumetric loading rates, a measure of carbonaceous material materials, are dramatically improved as well.














TABLE 5





Status
Input
Name
Output
Unit
Comment

























====> Conventional







Trickling Filter Design







Calculations <====




Si
207
mg/l
COD Loading onto Filter



12,000
Q

gpd
Raw Sewage Flow



675
So

mg/l
Primary Effluent COD







(can use BOD)



4
a


Ratio of Return Flow to







Raw Flow



90
Se

mg/l
Trickling Filter Effluent







COD



0.39
K1

min{circumflex over ( )}-1
Organic removal velocity







constant @ T1



1.04
Theta


Temperature coefficient







(1.1 to 1.35)



18
T2


Water Temperature Actual







Deg. C.



20
T1


Water Temperature Ideal







20 Deg. C.




Av
15
sqft/cuft
Specific Surface of Media



6
D

ft
Media Depth




q
0.54
gpm/sqft
Hydraulic loading onto







filter - media only




n
2.71

Visilind ‘n’ after Vicarri







2007



14
d

ft
Diameter of Filter




Qr
48,000
gpd
Recirculation Flow




Er
86.67
%
COD Removal Efficiency



2
Filter#


Number of Filters




FilterArea
307.72
ft{circumflex over ( )}2
Estimated Hickory Run







Filter Area




ΣFilterVol
1,846
ft{circumflex over ( )}3
Total Filters Volume




ΣFixedArea
27,695
ft{circumflex over ( )}2
Total Filters Surface Area







Fixed Media




FixedMediaSurfaceArea
15
ft{circumflex over ( )}2/ft{circumflex over ( )}3
Media Type Surface Area




FixedMediaLoadingRate
36.59
lb COD/
Conventional Loading






1000 Ft{circumflex over ( )}3
Rates for Roc (5 to 20







lb/1000 ft{circumflex over ( )}3)




Vlr
73.14
lb/1000 ft{circumflex over ( )}3
Organic Volume Loading







(w/recirc.) lb/1000 cuft




Vl
112.15
lb/1000 ft{circumflex over ( )}3
Organic Volume Loading







(w/recirc.) lb/1000 cuft




HydLoading
39
gpd/ft{circumflex over ( )}2
Fixed Media Hydraulic







Loading Rate




CODload
67.55
lb COD/
Estimated Plant COD






day
Loading




HydClass
″Low

Hydraulic Filter Loading





Rate

Class based on physical







filter volume




OrgLoadClass
″High

Organic Filter Loading





Rate

Class based on physical







filter volume







====> Zeolite







Calculations <====


L
5
ZeoMassDose

lb/day
Dosage of zeolite




ZeoliteConc
50
mg/l
Zeolite Concentration







Dosage based on flow



29,500
ZeoliteArea

ft{circumflex over ( )}2/lb
Surface Area of Zeolite



0.033
ZeoliteEffective

Decimal
Zeolite Effective Area







factor




ΣZeoliteAreaAdded
147,500
ft{circumflex over ( )}2/day
Total Zeolite Surface Area







Added




DailyZeoliteArea
4,868
ft{circumflex over ( )}2
Effective Surface Area







added daily







====> Zeolite







Calculations <====




BiofilmVolume
577
ft{circumflex over ( )}3
Biofilm Volume on Fixed







Media



0.25
BiofilmThickness

inch
Biofilm Thickness




BiofilmMass
5.2983
lb
Biofilm Mass




BiofilmAge
20
days
Equivalent Fixed Media







Age based on sloughing



0.05
BiofilmSoughingRate

%
Media Sloughing Rate %




ΣZeoliteBiofilm
97,350
ft{circumflex over ( )}2
Total Zeolite Area @







Biofilm Age




SurfaceAreaIncrease
352
%
Surface Area Increase %







using Biofilm Age Σ area







====> Zeolite







Calculations <====




Vlhybrid
12.43
lb/1000 ft{circumflex over ( )}3
Volume Loading







(w/recirc.) lb/1000 cuft




Vlryhbrid
2.49
lb/1000 ft{circumflex over ( )}3
Volume Loading







(w/recirc.) lb/1000 cuft




ΣCombinedArea
125,045
ft{circumflex over ( )}2
Total Effective Surface







Area in Filters




EqTotalVol
8,336
ft{circumflex over ( )}3
Equivalent Filter Volume







for both Media




HybridLoadingRate
0.54
lb COD/
Organic Loading Rate for






1000 ft{circumflex over ( )}3
Hybrid




Sehybrid
0
mg/l
Effluent COD hybrid


L

Avhybrid
67.73
ft{circumflex over ( )}2/ft{circumflex over ( )}3
Equivalent Surface Area







based on filter volume




Qhybrid
0.005
gpm/sqft
Hybrid loading onto Σ







filter surface area












NH3removed=(ÓCombinedArea.0.0283.NitriRate)  Equation 4


Table 6 shows the mathematical model calculated nitrification rate base on the data shown in Table 5 and as calculated by Equation 1 and shown in Table 1.














TABLE 6





Status
Input
Name
Output
Unit
Comment




















NitriRate
0.00012
lb-N/ft{circumflex over ( )}2/day
Nitrification Rate






Oakley Albertson






Nitrification Rate










Equation 4 is similar to Equation 3 with the only difference being total effective surface area. The Nitrification Rate as determined by Equation #1 can be employed in both Equation #3 and Equation #4. Now if one had a mathematical model for the trickling filter plant and empirical field data for both the influent and effluent Ammonia then though invertible iterative solving of the mathematical model one could arrive at the Nitrification Rate that was actually taking place in the plant under actual operation condition. Employing actual field data from the full scale hybrid trickling filter plant employing the zeolite and a Nitrification Rate increase of 0.00012 lb-N/ft̂2/day as shown in Table #6 the effective surface area of the added zeolite was determined to be 3.3%. Therefore the use of the zeolite has added additional surface area which in turn via both plant performance and mathematical modeling validates the increase in surface area created by the dosing of zeolite to a fixed media wastewater treatment process and the resulting improved trickling filter performance. The increase in ammonia removal was 40% based field data which confirms the increase in surface area. The effect of the zeolite is not solely a surface area phenomenon. The model has assumed that the nitrification rate stayed at a fixed value. In reality the improvement is due to both an increase in surface area and an increase in biological processes for both carbonaceous and nitrogenous materials.


Table 7 is shows in input and output data from the mathematical model based on the field data. It should be noted that the “NitriRate” variable shown in Table 7 is the same as that shown in Table 6 and Table 1.














TABLE 7





Status
Input
Name
Output
Unit
Comment

























====> Primary Filter







Nitrification Calcula-







tions <====




NitriRate
0.00012
lb-N/ft{circumflex over ( )}2/day
Nitrification Rate Oakley







Albertson Nitrification







Rate




RawTKN
101.18
mg/l
Raw TKN applied to







trickling filter



86
RawNH3

mg/l
Influent NH3







concentration



0.85
TKNfactor


Ratio factor of NH3 to







TKN




RawTKNmass
10.13
lb/day
Raw TKN Loading on







Filter




NH3removed
4.66
lb/day
TKN removal based on







combined Media Surface







Area




NH3removed_Std
10.03
lb/day
TKN removal based on







conventional Media







Surface Area




TKNeffmasshydridel
5.45
lb/day
TKN left with hybrid







surface media




TKNeffmassstd
9.09
lb/day
TKN left with standard







surface media




EffTKNstd
90.84
mg/l
Effluent TKN with







standard media




EffTKNhybrid
54.51
mg/l
Effluent TKN with hybrid







media




NH3RemovalEff %
40%
%
Hybrid Filter NH3







removal increase










The data shown below in Table 8 is actual field data that has been measured in the field and employed in the mathematical models to evaluate the performance of the hybrid media processing.














TABLE 8





Plant Flow
Influent EQ
Influent
EQ Basin
Eff Batch
Eff Batch


gpd
NH3—N
TKN
COD
NH3—N
NO3—N




















51,328
38.4

419
0.153
1.640


30,000
31.2

376
0.144
0.930


32,400
30.6

620
0.0159
0.898


31,700
32.6

526
0.064
0.921


35,500
38.4

709
0.026
1.020


30,598
29.8

536
0.012
1.350


36,782
35.8

461
0.053
1.330


52,300
33.4

442
0.174
1.550


37,515
33.4

338
0.002
1.170


38,289
32.4

350
0.041
0.954


41,012
26.0

463
0.040
1.420


35,700
35.8

775
0.013
1.830


22,097
31.0

438
0.020
2.300


45,597
35.4

244
0.442
1.910


59,081
26.6


1.340
1.930









The plotted data shown in FIG. 1, FIG. 2, and FIG. 3 illustrate a significant and dramatic impact of the addition of the zeolite to a fixed film media reactor, either Trickling Filter or Rotating Biological Contactor with more effective surface area.


An evaluation of the field data since the use of the zeolite addition has produced the following evaluation of the actual rock trickling filter performance vs. the model predictions employing standard design equations for nitrification performance. This evaluation again shows that there has been a dramatic increase in the surface area in the trickling filter.









TABLE 9







Mathematical Model vs. Field Data Comparison


Trickling Filter Performance - Mathematical Model vs. Field Data


(Standard Filter vs. Hybrid Media Processing)










Name
Value
Unit
Comment













EffTKNstd
90.84
mg/l
Model Prediction Effluent TKN with standard





media


EffTKNhybrid
50.21
mg/l
Model Prediction Effluent TKN with hybrid





media


Field Raw NH3
71.98
mg/l
Measure Average Applied NH3


Model Raw NH3
81.40
mg/l
Model Applied NH3


Field TF Eff NH3
29.58
mg/l
Measure Average Hybrid Media Eff NH3


EffNH3std
72.80
mg/l
Model Prediction Effluent NH3 with standard





media


EffNH3hybrid
51.40
mg/l
Model Prediction Effluent NH3 with hybrid





media


% NH3 Std Model
10.6%
%
Projected % Removal by Model Standard





Trickling Filter


% NH3 Field
28.59%
%
Actual % Removal by Hybrid Media





Processing


& NH3 Std Model
−1.14%
%
Predicted % Removal by Model for Std





Trickling Filter


Model vs Field
−73.7%
%
Correlation between Model vs. Field for





Hybrid Media Processing








Effective Surface Area
2.30 Zeolite Effective Area factor


Nitrification Rate Model
0.00012 lb-N/ft{circumflex over ( )}2/day


Equivalent Surface Area
51.75 ft{circumflex over ( )}2/ft{circumflex over ( )}3 Equivalent Surface Area based on filter volume


Nitrification Rate Field
0.00027 lb-N/ft{circumflex over ( )}2/day


Data


Equivalent Surface Area
93,577 ft{circumflex over ( )}2/ft{circumflex over ( )}3 Equivalent Surface Area based on filter volume


Field Data
















TABLE 10







Field Performance Evaluation















Primary








Filter
Primary
Actual lb

%



Primary
Nitrification
filter
NH3

Increase



filter %
Rate lb
Nitrification
Removed
Equivalent
in



NH3
N/day-Sq-
Rate Field
lb N/day-
Surface
Surface



Removed
Ft
Data
Sq-Ft
Area ft{circumflex over ( )}2
Area

















Average
44.18%
0.00007
0.00027
7.83
98,452
355%


Maximum
85.33%
0.00013
0.00074
15.74
160,791
581%


Minimum
3.85%
0.00004
−0.00005
1.79
34,549
125%


Std. Dev
21.08%
0.00002
0.00020
3.63
43,297
156%









Both Table 9 and Table 10 indicate that for the trickling filter to be performing as measured by actual field data indicates that a large increase in viable surface area in the trickling filter has been achieved by the addition of the zeolitic material. According to Table #10 it would appear that the nitrification rate has decreased. These values were in fact back calculated from the field data. The “Primary Filter Nitrification Rate” value was determined using Equation 1 whereas the “Primary Filter Nitrification Rate Field Data” employed the amount of nitrogen removed based on the surface area of the rock media. Therefore in order for the Trickling Filter to be removing the amount of nitrogen that was measured in the field there had to be an increase in the surface area and thus the values indicated in the “Equivalent Surface Area” as shown in Table 10.


A particular Trickling Filter plant was experiencing wide variations in applied hydraulic and organic loadings due to seasonal activities e.g. weekend vs. weekday flows. Superimposed on top of these varying loads was the fact that it was for a rest stop facility on a major Turnpike with its related variations in flows due to varying use of the rest stop as well as wastewater characteristics. In addition, the rest stop generated wastewater that was high in ammonia and Chemical Oxygen Demand due to the use of low water use toilets with winter temperatures of the wastewater in the 4 to 5° C. (39.2 to 41.0° F.) range. The regulatory agency was taking actions due to the facility not meeting its NPDES permit requirements even after being retrofitted with an addition plastic media trickling filter complete with covers for the trickling filter and hot air ventilating/heating system.


The raw waste exhibited ammonia nitrogen levels in the range of 50 to 135+ mg/l with Chemical Oxygen Demand (COD) levels as high as 900+ mg/l as well as temperatures of 4 Degrees C. Adjustment of the recirculation rates, sludge wasting and normal process adjustments for a trickling filter plant to address the reduction of these values was met with limited success. In addition, due to the wide swings in wastewater characteristics, swings in biofilm sloughing were incurred with the resulting decrease in the settleablilty of the sludge and subsequent loss process control. The plant also had problems meeting its ammonia requirements for a large portion of the year round.


A Trickling Filter treatment plant comprised of an equalization tank, primary clarifier, two parallel rock trickling filters, a secondary plastic media trickling filter followed by a final clarifier and a disinfection system with the plant having a design capacity of 40,000 gallons per day. The Trickling Filter was out of compliance due to excessively high concentrations of COD and BOD, ammonia-nitrogen, low conversion of ammonia nitrogen, poor settling, low BOD5 removal and low temperatures.


In a first part of the process of the present invention, Zeolite, obtained from Daleco Resources Corporation of West Chester, Pa., were employed at a dosage of 50 parts per million based on the average daily flow to the plant. It should be noted that the Trickling Filter process is preceded by both an Equalization Basin and Primary Clarifiers and has an internal recycle from the effluent from the Trickling Filter. The dosage is based on the raw sewage flow to the plant. Therefore each train of the Trickling Filter process was having 25 parts per million of zeolite being applied to it.


The zeolitic material addition operated as a weighting agent, substrate and structural unit with large surface area per unit volume for bacterial growth to occur as well as an ion exchange site for ammonia. In wastewater treatment it is the culturing of assimilated bacteria to the wastewater composition that affects the treatment process performance. Employing a zeolitic material allowed more bacteria to grow and stay in the process longer to affect the treatment process performance, stability and operability. The design of Trickling Filters and attached growth treatment processes are based on the organic (BOD) loading rate per unit of surface area. The surface area is defined by the square feet of surface created by the specific media employed e.g. rock has 15 square feet per cubic foot of media volume while synthetic plastic media can be as much as 32 square feet per cubic foot of media volume. The amount of zeolite employed is based on the desired increase in surface area required in order to achieve the desired loading rates for either or both carbon and nitrogen based pollutants.


In order for the zeolites to reach an effective level in the waste treatment process an optimum dose must be reached; in this case 30 to 60 parts per million, based on the daily flow to the plant. Additionally, since the bacteria must grow and create a culture on the zeolites material the zeolites effectiveness is directly related to the Retention Time in the treatment system. For a Trickling Filter or attached growth system the equivalent Retention Time would be based on the amount of sloughing that occurs of the biofilm that is attached to the media. In this instance a value of 5% was employed for the amount of biofilm sloughing that was taking place. The other consideration is the amount of zeolite that would be entrapped in the biofilm. It has been reported in the literature that 95% of a zeolite applied to a Trickling Filter plant is removed. This value was the basis for employing 5% as the amount of zeolite entrapped in the biofilm. In this application the daily flow of 6,000 gallons per day would be ((6,000*8.34*60)/1,000,000) or 3.0 pounds per day. The biofilm age (based on the sloughing rate) was 20 days and each reactor was receiving 3,000 gallons per day, each reactor would be receiving 1.5 pounds of material. On the first day 0.075 pounds of the zeolite would be retained in the biofilm. On day two there would be another 0.075 pounds of zeolite retained in the biofilm with a sloughing loss of 5%. After the first day 5% of the first day's 0.075 pounds of zeolite would be wasted. On the second day 5% of the 0.07125 pounds would be wasted along with 5% of the second day's 0.075 pounds. After two days there would be 0.139 pounds of zeolite enmeshed in the biofilm. At the end of 20 days there would be 1.425 pounds of zeolite in the biofilm on each trickling filter.


If the average surface area for zeolites is 700 square meters per gram, (29,500 square feet per pound) then in the 20 day biofilm age example there would be 1.425 pounds of zeolites in the biofilm at a 5% biofilm enmeshment rate The effective growth area for bacterial growth that one would have is 2,213 square feet of surface area per day per trickling filter or at a biofilm age of 20 days over 44,250 square feet of surface area. The combined primary filters have a total surface area of 27,695 square feet using 15 square feet per cubic foot for the rock media. This amounts to a 159% increase in surface area if all the added zeolitic material was effective or a total surface area of 71,945 square feet. Actual field data at the plant indicated that the effective surface area of the added zeolite is 3.3% effective when the actual effective surface area is computed based on the performance of the rock filters. The higher the biofilm age the greater square feet of added effective surface area retained in the filter. This effectively increases the rock media from 15 to 47 square feet per cubic foot of surface area for each Trickling Filter. This has effectively increased the rock trickling filter to a plastic media trickling filter without the cost of retrofit. The effectiveness of increasing surface area for bacterial growth in wastewater treatment via numerous methods is well documented in the literature. Taking the amount of zeolitic material up to the steady state concentration has been employed; however, it still takes a number of biofilm ages for the zeolitic material in the reactor to develop the bacterial colonization. The 3.3% effective surface area takes into consideration sloughing loss and effective surface area for colonization.


Using removal rates for BOD5 for the zeolitic material is equivalent to changing the media in the filter based on the additional media with a 3.0% effective surface area for the total amount of zeolitic material that is in the system at a steady state the BOD5 removal could be improved from approximately 30% to 80%+ as shown in the data.


The cost effectiveness of the implementation of the use of this method of improving an attached growth e.g. trickling filter or rotating biological contactor plant employing different types of media including rock and plastic media would be the cost of the zeolite additive. Assuming an installed cost to replace the rock media in a 20,000 gallon per day trickling filter plant with high surface plastic media of $300 per cubic foot installed then the capital savings for the demonstration plant are $553,800 minus the ongoing going cost of the zeolite For this plant they are using 5 pounds per day. The cost for the zeolite is approximately $2.50 per day or $912 per year to get this performance enhancement vs. a cost of $553,800.


As show in FIG. 4A through FIG. 4D, the processes of the present invention can be applied at numerous locations in a trickling filter plant. As used in FIG. 4A through FIG. 4D the following abbreviations are used to describe the different pieces of equipment used in a typical trickling filter plant:

    • Legend: (RS)—raw wastewater, (PC) primary clarifier, (PE) primary effluent, (TFINF) trickling filter influent, (TF) trickling filter, (TFEFF) trickling filter effluent, (TFRCY) trickling filter recycle, (SC) secondary clarifier, (WS) waster sludge, (SE) secondary effluent, (IC) intermediate clarifier, (ICE)


In place of a trickling filter, a sewage treatment process may employ rotating biological contactors growth or suspended attached growth, e.g. integrated fixed film activated sludge, or Moving Bed Biofilm Reactor systems. In that case the additions are also made to the wastewater stream.


The foregoing detailed description provides illustrative embodiments only, and is not intended to limit the scope, applicability, or configuration of the invention. Referring to the detailed description of the preferred exemplary embodiments will provide those skilled in the art with an enabling description for implementing the invention.

Claims
  • 1. A method for improving a wastewater treating process employing one of a trickling filter, rotating biological contactor, moving bed bioreactor or integrated fixed film activated sludge reactor comprising the step of introducing into said trickling filter, rotating biological contractor, moving bed bioreactor or integrated fixed film activated sludge reactor contactor of the wastewater treatment process one or more of a quantity of separate and unsupported natural zeolitic material being one of clinoptilolite, mordenite, chabazite or phillipsite for better liquid solid separation, or removal of ammonia, denitrification, COD and BOD removal, reduction of surfactant interference with liquid solid separation, provide a balanced nutrient formulation in the wastewater.
  • 2. A method according to claim 1 including the step of introducing one or more of the zeolitic material onto the trickling filter media of the wastewater treating process.
  • 3. A method according to claim 1 including the step introducing the zeolitic material into one of a conduit or wastewater conveyance leading directly to the trickling filter reactor.
  • 4. A method according to claim 1 including the step of introducing the zeolite material into a recirculation system of the trickling filter reactor.
  • 5. A method according to claim 1 including the step of introducing the zeolitic material into the trickling filter reactor as method of increasing the surface area of the trickling filter for the biofilm.
  • 6. A method according to claim 1 including the step of introducing zeolite material onto a rotating biological contactor of the wastewater treating process.
  • 7. A method according to claim 1 including the zeolitic material into one of a conduit or wastewater conveyance leading directly to the rotating biological contactor.
  • 8. A method according to claim 1 including the step of introducing zeolite material into a recirculation system for a rotating biological contractor.
  • 9. A method according to claim 1 including the step introducing zeolite material into the recirculation system for the rotating biological contractor as a method of increasing the effective surface area of the rotating biological contactor for the biofilm.
  • 10. A method according to claim 1 including the step of introducing one or more of the zeolitic material into an integrated fixed film activated sludge reactor of the wastewater treating process.
  • 11. A method according to claim 1 including the step introducing the zeolitic material into one of a conduit or waste water conveyance leading directly to the integrated fixed film activated sludge reactor.
  • 12. A method according to claim 1 including the step of introducing the zeolitic material into recirculation systems of said integrated fixed film reactor.
  • 13. A method according to claim 1 including the step of introducing zeolitic material into the integrated fixed film activated sludge as a method of increasing the effective surface area of the integrated fixed film activated sludge reactor for the biofilm.
  • 14. A method according to claim 1 including the step of introducing zeolitic material directly into said moving bed biofilm reactor.
  • 15. A method according to claim 1 including the step introducing the zeolitic material into a channel or pipe leading directly into the moving bed biofilm reactor.
  • 16. A method according to claim 1 including the step of introducing one of the zeolitic materials into a recirculation system for the moving bed biofilm reactor.
  • 17. A method according to claim 1 including the step of introducing zeolitic material into the moving bed biofilm reactors as a method of increasing the effective surface area of the moving bed biofilm reactors for the biofilm.
  • 18. A method according to claim 1 including the step of mixing the zeolitic material with alumina, silica, hydroxide, hydroxide precursors, and calcium oxide with a silica to alumina ratio equal to or greater than 2.5.
Continuation in Parts (1)
Number Date Country
Parent 13230227 Sep 2011 US
Child 14464320 US