Phosphorus release reactor for water treatment

Abstract

The invention relates to treatment of microorganisms from an activated sludge process operating with enhanced biological phosphorus removal in a reactor with baffles or other devices to induce similar plug-flow effort, designed to optimally release phosphorus and/or magnesium from the microorganisms with or without chemical addition. Further, the disclosure relates to a process designed to produce both a lower solids, phosphorus and magnesium enriched liquid stream and a higher solids, phosphorus and magnesium enriched stream. The reactor operates to give optimal performance by operating in a plug-flow mode.

Description

FIELD OF THE INVENTION

The invention relates to treatment of microorganisms from an activated sludge process operating with enhanced biological phosphorus removal in a reactor with baffles or other devices to induce similar plug-flow effort, designed to optimally release phosphorus and/or magnesium from the microorganisms with or without chemical addition. Further, the invention relates to a process designed to produce both a lower solids, phosphorus and magnesium enriched liquid stream and a higher solids, phosphorus and magnesium enriched stream. The reactor operates to give optimal performance by operating in a plug-flow mode.

BACKGROUND OF THE INVENTION

Increasingly stringent wastewater treatment plant (WWTP) effluent phosphorus permit limits have led many utilities to consider a variety of enhanced biological phosphorus removal (EBPR) activated sludge systems. When using EBPR systems to achieve high effluent quality, the presence of phosphorus accumulating organisms (PAOs) in the EBPR process leads to an accumulation of phosphorus and magnesium content of the waste activated sludge, which can lead to the unintended consequence of increased mineral struvite (MgNH₄PO₄.6H₂O) formation for facilities with anaerobic digestion. This in turn causes decreased performance and high maintenance costs of the anaerobic digesters and associated equipment.

To mitigate struvite, some utilities are installing phosphorus recovery systems. These recovery systems often include a phosphorus release system. The release system receives waste activated sludge and/or activated sludge mixed liquor and utilizes an anaerobic process that focuses on the release of the phosphorus from PAOs and may release phosphorus from other organisms so that the phosphorus can be diverted to the recovery system and away from solids treatment processes where struvite has a high potential to form. Release systems may also release magnesium, which is also beneficial for some types of recovery processes such as those that produce phosphorus in the form of struvite. Other recovery systems produce phosphorus in the form of calcium phosphate or other forms that would still benefit from the high phosphorus content stream from the release system.

Referring to FIG. 1, conventional release systems typically utilize complete or well-mixed anaerobic reactors 1 with hydraulic retention times of 18 to 36 or more hours to release sufficient phosphorus in an effluent stream 4 for the subsequent recovery process from waste activated sludge and/or activated sludge mixed liquid feed 2, which may or may not be pre-thickened. Where solids are present such reactors, the hydraulic retention time of the reactor is equal to the solids retention time. A complete or well-mixed reactor configuration also provides no elutriation benefit. In some cases, the hydraulic retention time may be reduced, however this requires additional equipment, processes and/or chemicals at additional expense. Further, prior art release systems, such as that shown in FIG. 1, use reactors with long hydraulic retention times (HRT), and may exceed 18 to 36 or more hours. HRT in prior art reactors may be reduced, however, require additional processes such as: addition of a chemical and/or supplemental biodegradable organic compounds stream 3, which may be expensive and requires additional equipment, facilities, operations, and maintenance effort; and/or pre-reactor solids thickening which is expensive and requires additional equipment, facilities, operations, and maintenance effort. Post-reactor dilution and/or re-thickening is also required of these systems. The accompanying lower reactor solids concentrations of prior art reactor systems result in lower phosphorus release kinetics, as well as lower solids concentrations in reactor effluent results, lower post-reactor (external) solids separator efficiency and increased demand for chemical input to support separation performance. Still further, the prior art reactors systems have longer HRT and therefore, larger volumes, costs and footprint requirements compared to equivalent performance of the reactor systems described in the present invention. Another disadvantage of the prior art reactor systems is potentially higher operating dissolved oxygen concentrations and/or oxidation reduction potential exists due to air entrainment from use of continuous mixing thus resulting in lower efficiency operation.

Accordingly, it is an objective of the invention to provide a reactor system to treat microorganisms from an activated sludge process operating with enhanced biological phosphorus removal in a reactor with baffles or other devices to induce similar plug-flow effort, designed to optimally release phosphorus and/or magnesium from the microorganisms with or without chemical addition.

A further object of the invention is to provide a reactor system which reduces headspace volume, thereby eliminating excessive malodor generation.

A further object of the invention is to provide thickening and/or solids separation benefits internal to the reactor system.

A further object of the invention is to provide a reactor system which provides expanded monitoring and control capabilities for conditions favorable to phosphorus and/or magnesium release.

Other objects, advantages and features of the present invention will become apparent from the following specification taken in conjunction with the accompanying figures.

SUMMARY OF THE INVENTION

In one embodiment, the present invention is a wastewater treatment system comprising an influent stream, a plug-flow reactor with at least two zones, and an effluent stream. The system further comprises a first zone, wherein concurrent thickening and denitrification occurs; a second zone, wherein further thickening, volatile fatty acid production, and/or phosphorus and/or magnesium release occurs; and a final zone, wherein solids separation occurs. The reactor further comprises baffles or walls which separate the zones. In a still further embodiment, the effluent is discharged to one or more of the following: a phosphorus recovery process, solids thickening and/or separation, solids treatment process, and/or other beneficial use for the enriched phosphorus and/or magnesium stream. In a still further embodiment, the system further comprises a means for mixing located within the reactor, wherein the mixing occurs intermittently and at a shear rate of from about 10 s−1 to about 50 s−1. The system further comprises a reactor float configured to remove solids from the top of one or any combination of the zones. The reactor float is configured to discharge solids to one or more of the following: solids thickening and/or separation, phosphorus recovery, returned to wastewater treatment plant, such as activated sludge process to seed the system with diverse population of phosphorus accumulating organisms, solids treatment process such as anaerobic digestion, recycled to another zone, and/or any other beneficial uses. In one embodiment, the system further comprises a solids recycle stream configured to remove solids separated from at least one zone of the reactor and/or configured to convey higher concentration solids to a first zone of the reactor. In a further embodiment, the system further comprises a solids recycle pump sized from about 0% to 200% of a desired reactor flow rate. In a still further embodiment, the system further comprises at least one measurement device, at least one safety device, at least one control system, and combinations thereof.

The present invention also is directed towards a method of phosphorus and/or magnesium removal comprising: providing an influent stream to a plug flow reactor; allowing the influent stream to pass through at least two zones of the plug flow reactor; and removing phosphorus and/or magnesium from the influent stream. The removal step is performed by holding the influent stream in the reactor for a defined period of time. The influent stream is a waste activated sludge and/or activated sludge mixed liquid. The influent stream is passed through a first zone, wherein concurrent thickening and denitrification occurs; a second zone, wherein further thickening, volatile fatty acid production, and/or phosphorus and/or magnesium release occurs; and a final zone, wherein solids separation occurs. In one embodiment, the hydraulic retention time of the reactor is between about 4 and about 20 hours. In another embodiment, the solids retention time of the reactor is between about 8 and about 72 hours. In a still further embodiment, the hydraulic retention time and the solids retention time of the reactor is based on total volume of the zones. In a still further embodiment, the hydraulic retention time and the solids retention time of the reactor are decoupled. The phosphorus and/or magnesium is removed in an amount from about 10% to about 60%. In one embodiment, the method further comprises a thickening of solids step, configured to produce a thickened solids concentration between approximately 1% and 6%. In a further embodiment, the method is free of the addition of supplemental chemicals and/or readily biodegradable compounds.

While multiple embodiments are disclosed, still other embodiments of the present invention will become apparent to those skilled in the art from the following detailed description, which shows and describes illustrative embodiments of the invention. Accordingly, the figures and detailed description are to be regarded as illustrative in nature and not restrictive.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of a prior art reactor system.

FIG. 2 is a block diagram of a first embodiment of the reactor system according to the present invention.

FIG. 3 is a block diagram of a second embodiment of the reactor system according to the present invention.

FIG. 4 is a block diagram of a third embodiment of the reactor system, including safety and control mechanisms, according to the present invention.

FIG. 5 is a flow diagram for a complete mix reactor.

FIG. 6 is a flow diagram for a two-zone reactor system according to the present invention.

FIG. 7 is flow diagram a three-zone reactor system according to the present invention.

FIG. 8 is a graph showing test results of phosphorus release at varied solids retention times.

FIG. 9 is a graph showing test results of phosphorus release at varied hydraulic retention time.

Various embodiments of the present invention will be described in detail with reference to the figures, wherein like reference numerals represent like parts throughout the views. Reference to various embodiments does not limit the scope of the invention. Figures represented herein are not limitations to the various embodiments according to the invention and are presented for exemplary illustration of the invention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to reactor systems and methods for removal of phosphorus and/or magnesium from waste activated sludge. These systems and methods have many advantages over conventional/existing/traditional reactor systems. For example, the systems and methods provide phosphorus and/or magnesium release rates exceeding rates observed by prior art. Further, the systems and methods provide enhanced phosphorus release (phosphorus release without concurrent magnesium release) due to microorganism decay products. Still further, the systems and methods incorporate internal thickening resulting in a thickened solids concentration between approximately 1% and 6%.

The embodiments of this invention are not limited to particular systems, and methods, which can vary and are understood by skilled artisans. It is further to be understood that all terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting in any manner or scope. For example, as used in this specification and the appended claims, the singular forms “a,” “an” and “the” can include plural referents unless the content clearly indicates otherwise. Further, all units, prefixes, and symbols may be denoted in its SI accepted form.

Numeric ranges recited within the specification are inclusive of the numbers defining the range and include each integer within the defined range. Throughout this invention, various aspects of this invention are presented in a range format. It should be understood that the description in range format is merely for convenience and brevity and should not be construed as an inflexible limitation on the scope of the invention. Accordingly, the description of a range should be considered to have specifically disclosed all the possible sub-ranges, fractions, and individual numerical values within that range. For example, description of a range such as from 1 to 6 should be considered to have specifically disclosed sub-ranges such as from 1 to 3, from 1 to 4, from 1 to 5, from 2 to 4, from 2 to 6, from 3 to 6 etc., as well as individual numbers within that range, for example, 1, 2, 3, 4, 5, and 6, and decimals and fractions, for example, 1.2, 3.8, 1½, and 4¾ This applies regardless of the breadth of the range.

Definitions

So that the present invention may be more readily understood, certain terms are first defined. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which embodiments of the invention pertain. Many methods and materials similar, modified, or equivalent to those described herein can be used in the practice of the embodiments of the present invention without undue experimentation, the preferred materials and methods are described herein. In describing and claiming the embodiments of the present invention, the following terminology will be used in accordance with the definitions set out below.

The term “about,” as used herein, refers to variation in the numerical quantity that can occur, for example, through typical measuring techniques and equipment, with respect to any quantifiable variable, including, but not limited to, mass, volume, time, and the like. Further, given solid and liquid handling procedures used in the real world, there is certain inadvertent error and variation that is likely through differences in the manufacture, source, or purity of the ingredients used to make the compositions or carry out the methods and the like. Whether or not modified by the term “about,” the claims include equivalents to the quantities.

The methods and systems of the present invention may comprise, consist essentially of, or consist of the components and ingredients of the present invention as well as other ingredients described herein. As used herein, “consisting essentially of” means that the methods, systems, apparatuses and compositions may include additional steps, components or ingredients, but only if the additional steps, components or ingredients do not materially alter the basic and novel characteristics of the claimed methods, systems, apparatuses, and compositions.

The term “weight percent,” “wt. %,” “wt-%,” “percent by weight,” “% by weight,” and variations thereof, as used herein, refer to the concentration of a substance as the weight of that substance divided by the total weight of the composition and multiplied by 100.

As used herein, the term “microorganism” refers to any noncellular or unicellular (including colonial) organism. Microorganisms include all prokaryotes. Microorganisms include bacteria (including cyanobacteria), spores, lichens, fungi, protozoa, virinos, viroids, viruses, phages, and some algae. As used herein, the term “microbe” is synonymous with microorganism.

As used herein, the phrases “objectionable odor,” “offensive odor,” or “malodor,” refer to a sharp, pungent, or acrid odor or atmospheric environment from which a typical person withdraws if they are able to. Hedonic tone provides a measure of the degree to which an odor is pleasant or unpleasant. An “objectionable odor,” “offensive odor,” or “malodor” has an hedonic tone rating it as unpleasant as or more unpleasant than a solution of 5 wt-% acetic acid, propionic acid, butyric acid, or mixtures thereof.

As used herein, the term “chemical-free” or “free of supplemental chemicals” refers to a system or method that does not contain a chemical treatment compound or to which a chemical treatment compound has not been added. Should a chemical treatment compound be present through contamination of system or method, the amount of chemical treatment compound shall be less than 0.5 wt %. More preferably, the amount is less than 0.1 wt-%, and most preferably, the amount is less than 0.01 wt %.

As used herein, the term “readily biodegradable organic compound-free” or “substantially readily biodegradable organic compound-free” or “free of readily biodegradable organic compound(s) refers to a system or method that does not contain readily biodegradable organic compound or to which a readily biodegradable organic compound has not been added. Should a readily biodegradable organic compound be present through contamination of a system or method, the amount of the readily biodegradable organic compound shall be less than 0.5 wt %. More preferably, the amount is less than 0.1 wt-%, and most preferably the amount is less than 0.01 wt %.

As used herein, the term “substantially free” refers to compositions completely lacking the component or having such a small amount of the component that the component does not affect the performance of the composition. The component may be present as an impurity or as a contaminant and shall be less than 0.5 wt-%. In another embodiment, the amount of the component is less than 0.1 wt-% and in yet another embodiment, the amount of component is less than 0.01 wt-%.

It should also be noted that, as used in this specification and the appended claims, the term “configured” describes a system, apparatus, or other structure that is constructed or configured to perform a particular task or adopt a particular configuration. The term “configured” can be used interchangeably with other similar phrases such as arranged, constructed, adapted, manufactured, and the like.

Reactor System and Methods

Referring to FIGS. 2 and 3, in preferred embodiments of reactor systems 10, 30 and methods for treatment of microorganisms from an activated sludge process, phosphorus and/or magnesium is released. One method for effecting this release is by adding feedstock(s) to the reactor via a feedstock influent 12, 32. The feedstock influent may include waste activated sludge and/or activated sludge mixed liquor. As one of skill in the art will appreciate, alternative embodiments may vary the number of zones to accommodate variation in feedstock characteristics or other operating conditions/restrictions. Zones may be present in the amount of at least two, three, four, five, or more zones.

In a preferred aspect of the invention, the influent to the reactor does not contain the addition of supplemental chemicals and/or readily biodegradable compounds. Once the influent enters the reactor 10, 30, zones are present in the reactor to facilitate phosphorus and/or magnesium removal. Without seeking to be limited to a particular theory or mechanism of the invention, it is believed that in a first zone, concurrent thickening and denitrification occurs. Solids separated from second, third, and/or subsequent zones may be recycled, as indicated by arrows 16,42 to the first zone. Further, it is believed that in a second zone, further thickening, volatile fatty acid production, and phosphorus and/or magnesium release predominantly occurs. Still further, it is believed that in a third and/or final zone, solids separation predominantly occurs. As the feedstock influent 12, 32 moves through the zones of the reactor systems and methods 10, 30, a phosphorus and/or magnesium enriched effluent with lower solids concentration 20, 36 is produced. The effluent 20, 36 may be discharged to one or more of the following: a phosphorus recovery process, solids thickening and/or separation, solids treatment process, or other beneficial use for enriched phosphorus and/or magnesium stream. Thickened solids are removed from the system via a thickened solids stream 18, 38, wherein the thickened solids are then discharged to one or more of the following: additional solids separation, additional thickening, phosphorus recovery, return to activated sludge process, solids treatment or other beneficial uses. According to an embodiment of the invention, the zones are separated by baffles 24 or a wall or other physical barrier.

Intermittent mixing may be used to incorporate floating solids to the reactor contents and/or to reduce short circuiting caused by channeling formed during high solids concentration conditions. Mixing, when employed, functions to break up solids, provide a homogenous mixture as the influent moves through the reactor system, and relieve any stratification which may occur. Such intermittent mixing may occur by any mechanical or flow-induced means and may be present in any one or a combination of the zones of the reactor system. Mixing is minimal so as to maintain a plug flow profile throughout the reactor. Mixing preferably occurs at a shear rate of from about 10 s⁻¹ to about 50 s⁻¹, preferably from 20 s⁻¹ to about 40 s⁻¹.

A reactor float or top solids removal stream 22, 40 may exit any one or combination of the zones. Such a solids removal stream 22, 40 may be discharged to one or more of the following: solids thickening and/or separation, phosphorus recovery, returned to wastewater treatment plant, such as activated sludge process to seed the system with diverse population of phosphorus accumulating organisms, solids treatment process such as anaerobic digestion, recycled to another zone, and/or any other beneficial uses.

The hydraulic retention time of the reactor of the present invention is separated or decoupled from the solids retention time. In a preferred embodiment, the hydraulic retention time is between about 4 and about 20 hours, preferably between about 8 and about 16 hours. In a preferred embodiment, the solids retention time is between about 8 and about 72 hours, preferably between about 16 and about 48 hours. In a still further preferred embodiment, the hydraulic and solids retention time is based on total volume of all reactor zones. The decoupling of the hydraulic and solids retentions times is achieved using the separation (final) zone to produce a lower solids concentration effluent and higher concentration solids. In this zone, and through the zones of the reactor, solids are allowed to settle and/or are removed. The removed solids are then present in higher concentration and are then conveyed to a solids recycle pump and stream 16,42 which conveys the higher concentration solids within the reactor to increase the residence time of the solids, thereby decoupling the hydraulic retention time and the solids retention time. The solid retention time is controlled by wasting solids from the system via the reactor float stream 22, 40 and/or the effluent stream 20, 36 and are balanced by the recycling of solids within the reactor via the recycle stream 16, 42 and pump.

The solids recycle pump is sized to pump from about 0% to 200% of the reactor feed flow rate. In a preferred embodiment, solids are recycled from the separation (final) zone to the first zone of the reactor; however, the system is configured so that solids can be conveyed to and from any zone. It is believed the recycle pump provides the benefit of elutriation of reactor solids to promote the release of phosphorus and/or magnesium into the bulk liquid effluent 20.

In an alternative embodiment of the invention, the recycle stream 18 returns a portion of the solids from the reactor to the activated sludge process located upstream of the influent in order to see the reactor with phosphorus accumulating organisms. The longer solids retention time in the reactor compared with the current state of the art (18 to 36 or more hours) results in a deeper anaerobic condition as confirmed by oxidation reduction potential measurements. The deeper anaerobic condition of the present invention promotes microorganism diversity including selection of a more diverse population of phosphorus accumulating organisms compared to prior art phosphorus release systems or compared to microorganisms selected in enhanced biological phosphorus removal activated sludge systems. Diverse populations of PAOs increase the reliability and performance of EBPR systems.

According to the methods and system of the present invention, phosphorus and/or magnesium is released in an amount from about 10% to about 60%, preferably from about 20% to about 40%, and more preferably from about 25% to about 35%.

Measurement Devices

In some aspects of the invention, the system may include at least one measurement device or a plurality of measurement devices. Such measurement devices are those suitable to measure one or more reaction kinetics or system operations for phosphorus and/or magnesium removal, including for example devices to measure oxidation reduction potential sensors, total suspended solids concentration sensors, nitrate/nitrite concentration sensors, ortho-phosphorus/phosphorus concentration sensors, magnesium concentration sensors, weight, flow (e.g. flow meters or switches), pH, pressure, temperature and combinations thereof. Such measurement devices may measure the system's inlets, piping, outlets, etc.

Examples of additional suitable measurement devices include, for example, concentration sensors, thermometers, alarms, monitors, and pressure switches. For example, temperature may be monitored at various points in the apparatus to ensure consistent temperature. In another embodiment of the invention, oxidation reduction potential (ORP) is monitored for an indication of reactor conditions and performance. Positive ORP indicates an oxidative condition and negative values indicates a reducing condition. ORP can be used to indicate the type of biochemical activity/conditions present, such as aerobic, anoxic or anaerobic. ORP values for specific conditions can vary based on wastewater characteristics and the type of ORP probe used, however aerobic environments will have higher ORP values than anoxic, which will be higher than anaerobic environments. The differences in biological activity within an anaerobic environment can be correlated to ORP, for example denitrification occurs at a higher ORP than phosphorus release. The reactor recycle rate, SRT or other functions can be controlled based on the ORP to optimize phosphorus release or other parameters.

In a further embodiment of the invention, flow rate is monitored with either a pressure sensor, magnetic meter, ultrasonic sensor, or an orifice plate/meter. In a further embodiment, solids retention time, hydraulic retention time, recycle rate, temperatures, pH and concentrations can all be optimized via monitoring systems and/or controllers. Additionally, an embodiment of the invention would allow for rinsing of the system for cleaning and maintenance.

Control System

In a preferred embodiment, the system for removal of phosphorus and/or magnesium removal further comprises an optional controller or software platform. The software platform provides a user or system to select a mode for a desired hydraulic retention and/or solids retention time. As a result, use of the system provides significant user flexibility to achieve phosphorus and/or magnesium removal for particular user-identified purposes. The control system preferably includes the above described measurement devices.

The controller may further include a mechanism for manually starting/stopping any of the same functions, including for example a manual switch panel for the same. In addition to manual controls, such as a manual switch panel, the controller preferably has buttons or other means for selecting particular embodiments according to option displayed by the control software platform. An embodiment of the controller may further include a display screen to assist a user in selecting a mode for a desired ortho-phosphorus release and any other options for user selection as one skilled in the art will ascertain based upon the description of the invention. Concomitant with the control software are user-friendly instructions for use displayed on the display screen (or the like).

The control software utilizes a control software algorithm to maximize desired conditions and provide safe operating conditions for the reactor vessel(s) of the system.

The system may include a data output means for sharing information related to the phosphorus and/or magnesium release according to the system. For example, an information backbone may be used to both collect and disseminate data from the process of release including, for example, concentration, recycle rate, and/or additional related data. Such data may be generated in real-time and/or provided in a historical log of operational data detectable or storable by a user or system. A user of the system is able to monitor usage and performance, including for example, hydraulic retention time, solids retention time, recycle rate, phosphorus and/or magnesium release and the like. According to an additional embodiment of the invention, a user or system is able to control systems, including program systems, remotely. Control systems also include safety shut off of pumps at no flow and shut offs when monitoring devices indicate equipment failures or other problems.

According to another aspect of the invention, any system operations suitable for use with the invention may be controlled and/or monitored from a remote location. Remote system operations control and/or monitoring may further include the system updates and/or upgrades. Such updates and/or upgrades to system operations may be downloaded remotely.

In another aspect of the invention, the data output for sharing information related to the removal according to the system may coordinate multiple systems on at a single site. According to this embodiment of the invention, information sharing between the multiple systems may take place using any communications network capable of coupling one or more systems according to the present invention, including for example, using a server computer and a database.

Safety Devices

In some aspects of the invention, the system may include a variety of safety mechanisms. Various safety mechanisms can measure water level, solids concentration, equipment operational status, difference in level, difference in solids concentration, or a combination thereof and provide a perceptible signal if one or more of these increases above a predetermined level. The level of measured difference, or a combination thereof at which safety system provides a perceptible signal can be selected to allow intervention to avoid undesirable or unsafe conditions.

A preferred embodiment of the control system is depicted in FIG. 4. Equipment represented in FIG. 4, is shown in Table A.

TABLE A
Equipment Listing for FIG. 4
Abbreviation
in Diagram	Description	Note
FM 1	Influent flow meter	Flowrate and solids measurement is important to
TSS 1	Influent total suspended	determine hydraulic and solids retention time.
	solids probe	However, could be accomplished with various
FM 2	Effluent flow meter	methods and instrumentation. The controls
TSS 2	Effluent total suspended	diagram shows a preferred embodiment.
	solids probe
FM 3	Recycle flow meter
TSS 3	Recycle total suspended
	solids probe
FM 4	Solids flow meter
TSS 4	Solids total suspended
	solids probe
FM 5	Float solids flow meter
TSS 5	Float solids total
	suspended solids probe
Mixer 1	Zone 1 mixer	Used intermittently/as needed to prevent
		channelizing of the solids. Not intended for
		complete mixing.
ORP 1	Zone 1 ORP probe	Indicates extent of anoxic/anaerobic condition,
		useful for process control.
Mixer 2	Zone 2	Used intermittently/as needed to prevent
		channelizing of the solids. Not intended for
		complete mixing.
ORP 2	Zone 2 ORP probe	Indicates extent of anoxic/anaerobic condition,
		useful for process control.
Solids Level	Solids blanket level	Indicates the depth of the sludge blanket in the
	sensor in settling zone	settling zone. Useful to control process and solids
		balance.
Influent	Influent Pump	Depending on configuration, alternative methods
Pump		such as a valve may be used to control flow.
Recycle	Recycle pump	Recycle pump is critical to process to maintain
Pump		solids balance in reactor. Depending on
		configuration, alternative methods such as a valve
		may be used to control flow.
Waste Pump	Waste pump	Waste pump is critical to process to maintain
		solids balance and target SRT in reactor.
		Depending on configuration, alternative methods
		such as a valve may be used to control flow.
Float Pump	Float Pump	Float pump removes floating solids from reactor.
		Depending on configuration, alternative methods
		such as a valve may be used to control flow.
Effluent	Effluent Pump	Effluent pump conveys effluent from the reactor.
Pump		Depending on configuration, alternative methods
		such as a valve may be used to control flow.
M1	Motor Valve 1 - Zone 1	When selected, valve opens when waste pump is
		on to allow solids removal from reactor. Valve
		closes when waste pump is off to prevent solids
		from leaking out of reactor.
M2	Motor Valve 2 - Zone 2	When selected, valve opens when waste pump is
		on to allow solids removal from reactor. Valve
		closes when waste pump is off to prevent solids
		from leaking out of reactor.
M3	Motor Valve 3 -	Valve opens when sludge blanket depth in settling
	Settling Zone	zone reaches high level (adjustable) and
		coordinated with recycle and/or waste solids
		removal.

In the preferred embodiment shown in FIG. 4, the influent flow meter (FM 1) sends a signal to influent control valve, pump or other device to control rate of flow into the reactor. A recycle pump maintains user adjustable sludge/solids blanket level in settling zone based on signal from solids level sensor (SOLIDS LEVEL). The recycle pump adjusts flow rate by variable frequency drive (VFD) (or other method) to maintain solids blanket level setpoint. An operator can enter minimum and maximum values for recycle pump speed/flow rate when in automatic operation. Further, an operator may enter values for low level, target level setpoint, high level and alarm level. In one aspect of operation, the recycle pump decreases to minimum speed and shuts off at low solids level setpoint. Alternatively, the recycle pump increases speed to max speed at high solids level setpoint. At high solids alarm level, the waste pump is started and user selectable waste motor valve is opened as described below. Any combination of one or multiple waste motor valves can be selected to be active, but normally zone 2 (motor valve M2) is opened, as described below. A time delay/deadband is included for the recycle pump control to avoid frequent on/off and/or high/low speed cycles.

A waste pump is interlocked with the user selected waste solids motor valve so that the valve opens when the pump is on, and the valve is closed when the pump is off. The pump will not start if the user selected waste solids motor valve is not open. The waste pump maintains user adjustable solids retention time (SRT) by adjusting pump operating speed using VFD (or other method) and/or by turning the pump on and off. The SRT is calculated in the programable logic controller (PLC), or similar device, as discussed below. It is preferred to maintain constant or near constant pump flow rate and operation. A time or other method of delay/deadband is included for the waste pump control to avoid frequent on/off and/or high/low speed cycles. If high solids level alarm in the final zone of the reactor is triggered, the motor valve 3 will open and the waste pump will either turn on or, if the waste pump is already on, the waste pump will increase speed. The motor valve 3 will close when solids level setpoint is reached and the waste pump will revert to SRT based control. In all scenarios, the waste pump will not operate unless the user selected motor valve is opened.

Solids retention time is calculated using a PLC, or similar device. Measurements and calculations could also be accomplished manually. The following formula is assumed; however, variations in the calculation could successfully be used. Table B provides a description of the variables included in the formula.

$\mathrm{SRT}=\hspace{1em}\frac{S_{\mathrm{reactor}}\times V_{\mathrm{reactor}}\times \left(8.34*{10}^{-6}\frac{\mathrm{lb}}{\mathrm{gal}}\right)}{〚\left(S_{\mathrm{eff}}\times Q_{\mathrm{eff}}\right)+\left(S_{\mathrm{waste}}\times Q_{\mathrm{waste}}\right)+\left(S_{\mathrm{float}}\times Q_{\mathrm{float}}\right)〛\times \left(\frac{1440\min }{1\mathrm{day}}\right)\times \left(8.34*{10}^{-6}\frac{\mathrm{lb}}{\mathrm{gal}}\right)}$

TABLE B
SRT Formula Variables
Parameter	Description	Unit	Source of Data
SRT	Solids Retention Time	Days	Calculated in PLC
Sreactor	Average total	mg/L	Averaged/composited
	suspended solids		suspended solids as
	concentration in		measured from sample
	reactor		ports and values
			entered into PLC.
			This value is stored until
			overwritten by operator.
			Alternatively, solids probes
			could be used to directly
			convey values to PLC.
Vreactor	Volume of reactor	Gallons	Constant based on
			constructed reactor
			dimensions
Seff	Effluent total	mg/L	Effluent solids probe (TSS
	suspended solids		2) based on user adjustable
	concentration		time average
Qeff	Effluent flow rate	Gal/Min	Directly from flow meter
			FM 2 or calculated by:
			FM 2 = FM 1 − FM 4
			based on user adjustable
			time average
Swaste	Waste total suspended	mg/L	Waste solids probe (TSS 4)
	solids concentration		based on user adjustable
			time average
Qwaste	Waste flow rate	Gal/Min	Flow meter FM 4
			based on user adjustable
			time average
SFloat	Float solids total	mg/L	Float solids probe (TSS 5)
	suspended solids		based on user adjustable
	concentration		time average
QFloat	Float solids flow rate	Gal/Min	Flow meter FM 5
			based on user adjustable
			time average

In a further aspect of the invention, mixer number 1 and 2 are controlled by user adjustable timers for each mixer (time on and time off) in minutes. The timers could be in the PLC, part of local mixer control panel or elsewhere. For example, the initial setpoint on for a first mixer (time running) could be 10 minutes, with an initial setpoint delay (off) of 11 hours 50 minutes. Further, the initial set point on for a second mixer (time running) could be 10 minutes, with an initial setpoint delay (off) of 11 hours 50 minutes. The mixers could also be controlled by differential level based on adjustable setpoints; by ORP to maintain a setpoint (adjustable) or manually by the operator.

EXAMPLES

Embodiments of the present invention are further defined in the following non-limiting Examples. It should be understood that these examples, while indicating certain embodiments of the invention, are given by way of illustration only. From the above discussion and these Examples, one skilled in the art can ascertain the essential characteristics of this invention, and without departing from the spirit and scope thereof, can make various changes and modifications of the embodiments of the invention to adapt it to various usages and conditions. Thus, various modifications of the embodiments of the invention, in addition to those shown and described herein, will be apparent to those skilled in the art from the foregoing description. Such modifications are also intended to fall within the scope of the appended claims.

Example 1

Three 10-liter bench-scale phosphorus release reactors were developed, constructed, tested and compared as shown in FIGS. 5-7 and described below: FIG. 5—traditional complete mix; FIG. 6—two-zone plug flow; FIG. 7—three-zone plug flow. Photos of the respective test set-ups are shown in FIGS. 8-10.

FIG. 5 shows the test configuration of the complete mix reactor. Waste activated sludge was conveyed to a day tank that was well mixed and continuously overflowed to drain. The day tank was completely turned over every 1-2 minutes to provide a fresh feed source to the reactor. A feed pump was used to convey waste sludge from the day tank to the reactor and control the flow rate to the reactor. The influent pump flow rate was verified daily by collecting all the effluent from the reactor and measuring the total volume.

A mechanical mixer was used to maintain complete mix conditions sufficient to suspend solids throughout the reactor while maintaining anaerobic conditions to support phosphorus release. In the complete mix reactor, the hydraulic retention time (HRT) was always equal to the solids retention time (SRT) and was controlled by the influent flow rate. The solids concentration in the reactor was directly controlled by the solids concentration and flow rate of the influent.

FIG. 6 illustrates the test configuration of the two-zone plug flow reactor. Without seeking to be limited to a particular mechanism or theory, it is believed that the following main processes predominantly occur in each zone. In the first zone, concurrent thickening, denitrification with off-gassing and potentially some VFA production depending on retention time. In the second zone, further thickening, VFA production, phosphorus release, and solids separation which permits uncoupling of the HRT/SRT. Thickened solids are typically removed from the bottom of the second zone to maintain a solids balance within the reactor.

Waste activated sludge was drawn from the same day tank as was used for the other reactors to maintain consistency. A feed pump was used to convey waste sludge from the day tank to the reactor and control the flow rate to the reactor. The influent pump flow rate was verified daily by collecting all the effluent from the reactor and measuring the total volume.

A waste pump was used to waste solids from the system to maintain a target SRT/solids balance. The SRT was determined by calculating a mass balance around the reactor using the reactor contents, influent, effluent and waste solids streams (flow rate and solids concentrations). The waste pump flow rate was verified daily by collecting all the discharge from the waste pump and measuring the total volume.

FIG. 7 shows the test configuration of the three-zone reactor, which was developed with goals to increase SRT control flexibility, reliability and reduce the effluent solids concentration in the effluent. Some P-recovery systems require low solids concentrations to produce struvite. Reducing the P-release reactor effluent solids concentration in the would eliminate or reduce the need for subsequent solids separation prior to conveyance to the P-recovery system. Without seeking to be limited to a particular mechanism or theory, it is believed the following processes predominately occur in each zone. In the first zone, concurrent thickening, denitrification with off-gassing and potentially some VFA production depending on retention time occurs. Intermittent mixing is included. In the second zone, further thickening, VFA production and phosphorus release occurs. In the final zone, solids separation and recycling occurs. The final zone solids separation and internal recycle improves the solids balance and decreases effluent solids concentration compared to the two-zone plug flow reactor, which improves the ability to uncouple HRT and SRT. The internal recycle is conveyed back to the first zone. Solids may be wasted from any portion of the reactor, however typically are removed from the bottom of the second zone and/or the bottom (thickened) portion of the final settling zone.

Waste activated sludge was drawn from the same day tank as was used for the other reactors to maintain consistency. A feed pump was used to convey waste sludge from the day tank to the reactor and control the flow rate to the reactor. The influent pump flow rate was verified daily by collecting all the effluent from the reactor and measuring the total volume.

The recycle pump flow rate was verified at least three times a week by directly measuring pump output.

A waste pump was used to waste solids from the system to maintain a target SRT/solids balance. The SRT was determined by calculating a mass balance around the reactor using the reactor contents, influent, effluent and waste solids streams (flow rate and solids concentrations). The waste pump flow rate was verified daily by collecting all the discharge from the waste pump and measuring the total volume.

The key control variables were the hydraulic and solids retention times. In the three-zone reactor, recycle pump rate was also a control variable. In the complete mix reactor, the HRT was equal to the SRT and was varied between 6 and 48 hours.

The two and three-zone plug flow reactors had the ability to decouple HRT and SRT. To demonstrate reduced volume requirements and cost reduction compared to a complete mix reactor, HRT was less than SRT for each run. HRT was varied between 6 and 24 hours and SRT between 18 and 54 hours. Table 1 presents the experimental plan for the reactor comparison evaluation and Table 2 shows samples and measurements regularly collected for each of the reactors. Additional constituents were sampled intermittently. A complete representation of the data can be found in the Appendix attached hereto.

TABLE 1
Bench Scale Test Conditions
				Internal
		Hydraulic	Solids	Recycle Flow
		Retention Time,	Retention	Rate, % of
	Run	HR	Time, HR	Influent Flow
Complete Mix Reactor
	1	24	24	N/A
	2	16	16	N/A
	3	12	12	N/A
	4	6	6	N/A
	5	10	10	N/A
	6	48	48	N/A
Two Zone Plug Flow Reactor
	7	12	42	N/A
	8	9	30	N/A
	9	9	48	N/A
	10	6	18	N/A
	11	18	36	N/A
	12	24	54	N/A
Three Zone Plug Flow Reactor
	13	12	24	200%
	14	12	36	100%
	15	18	36	100%
	16	12	24	50%
	17	12	18	200%
	18	18	36	100%
	19	12	30	200%
	20	12	54	50%
	21	18	48	50%
	22	12	54	100%
	23	18	54	200%

TABLE 2
Reactor Sampling Plan
	Constituent/Parameter
								Soluble
							TKN,	TKN,
							NO2-,	NO2-,		TP,
	Flow				TSS/		NO3-,	NO3-,		sTP,
Location	Rate	T	pH	ORP	VSS	VFA	NH3	NH3	Mg	Ortho-P
Influent	Daily	Daily	Daily	Daily	3/day	3-4/	2-3/	2-3/	2-3/	3-4/
						week	week	week	week	week
Reactor	N/A	Daily	Daily	Daily	Daily	3-4/	2-3/	2-3/	2-3/	3-4/
Contents						week	week	week	week	week
Effluent	Daily	N/A	Daily	Daily	Daily	3-4/	2-3/	2-3/	2-3/	3-4/
						week	week	week	week	week
Waste	Daily	N/A	N/A	N/A	Daily	N/A	2-3/	2-3/	2-3/	3-4/
Solids							week	week	week	week

Effluent ortho-P concentrations were dependent on the SRT and reactor ortho-P release was similar to batch testing when comparing equivalent SRT. The two-zone plug flow reactor concentrated the feed sludge in the reactor by natural thickening action, and a lower solids concentration supernatant stream was created. The separation and thickening facilitated uncoupling of HRT from SRT. While HRTs were reduced between 6 and 24 hours, SRTs were maintained in the range from 18 to 54 hours, resulting in a significant reduction in required reactor size compared to the conventional complete mix reactor, while maintaining a high level of performance.

The two-zone reactor required frequent operator adjustments to sludge wasting rate to maintain a stable SRT and solids balance when the solids inventory was high (high SRT conditions) and/or during periods with high reactor flow velocities (low HRT conditions), leading to solids washout. To improve operational control and reliability, the three-zone reactor was developed, and a bench scale reactor was tested for comparison to the complete mix and two-zone reactors. The three-zone reactor operated with a more stable SRT than the two-zone reactor, maintained high ortho-P release performance and a lower, more stable effluent/supernatant solids concentration.

Increasing the internal recycle rate of the three-zone reactor generally decreased reactor phosphorus release performance. Increasing the internal flow rate through the reactor conveyed nitrates from the influent further into the reactor, increasing the portion of the reactor in denitrification mode and decreasing the anaerobic portion of the reactor. Additionally, higher recycle rates shift the reactor from plug-flow to more mixed (hydraulic mixing effect). Recycle pump flow rates were fixed for each run during the bench tests to determine the impact of varied flow rates. However, it is anticipated that in practice variable flow rate recycle pumps will be used to maintain the target solids balance/SRT in the reactor using the lowest possible flow rate.

Based on batch testing periodically conducted during the reactor testing, the maximum percent phosphorus release (effluent ortho-P/influent total P) possible was approximately 34%-38%. The percent phosphorus release is a parameter that is commonly used to measure and compare performance of P-release systems. The maximum release was found to occur with long SRTs (typically >48 hours) and/or significant VFA addition. FIG. 11 illustrates the relationship. All three bench scale reactors showed similar response of increased phosphorus release with increased SRT. As previously noted, the practical maximum phosphorus release occurred at SRT of approximately 48+ hours. However, when comparing HRT and phosphorus release, the plug flow reactors showed increased phosphorus release at lower HRTs, due to higher corresponding SRT, compared to the complete mix reactor as shown in FIG. 12. Also, as HRT is equal to SRT for the complete mix reactor (by definition), FIG. 12 further supports the need for a longer HRT=SRT and therefore larger reactor volumes to facilitate phosphorus release for a complete-mix reactor configuration. Table 3 summarizes the phosphorus release for each of the test runs. By definition, a complete-mix reactor has a HRT equal to SRT.

TABLE 3
Reactor Phosphorus Release Comparison
				Average Percent
	Hydraulic	Solids	Internal	Phosphorus Release
	Retention	Retention	Recycle Flow	(Effluent Ortho-P/
Run	Time, HR	Time, HR	Rate, % Inf.	Influent Total-P)
Complete Mix Reactor*
1	24	24	N/A	26.2%
2	16	16	N/A	24.9%
3	12	12	N/A	21.0%
4	6	6	N/A	6.3%
5	10	10	N/A	28.4%
6	48	48	N/A	30.8%
Two Zone Plug Flow Reactor
7	12	42	N/A	31.4%
8	9	30	N/A	28.7%
9	9	48	N/A	31.6%
10	6	18	N/A	22.5%
11	18	36	N/A	34.5%
12	24	54	N/A	36.5%
Three Zone Plug Flow Reactor
13	12	24	200%	25.2%
14	12	36	100%	32.6%
15	18	36	100%	33.0%
16	12	24	50%	27.8%
17	12	18	200%	27.0%
18	18	36	100%	32.9%
19	12	30	200%	27.7%
20	12	54	50%	34.9%
21	18	48	50%	34.0%
22	12	54	100%	30.7%
23	18	54	200%	27.1%

The inventions being thus described, variations may be made, but are not to be regarded as a departure from the spirit and scope of the inventions and all such modifications are intended to be included within the scope of the following claims.

					Influent/Feed
							sol.
									VFA,		Soluble		sol.	NO2 +	NO2 +
		Actual	Actual	Reactor	TSS,	VSS,		ORP,	mg-	TKN,	TKN,	NH3,	NH3,	NO3,	NO3,	Mg,	TP,	sTP,	OrthoP,
Date	Scenario	HRT, Hr	SRT, Hr	T, F	mg/L	mg/L	pH	mV	HAc/L	mg/L	mg/L	mg/L	mg/L	mg/L	mg/L	mg/L	mg-P/L	mg-P/L	mg-P/L
Sep. 29, 2016	Baseline
Sep. 30, 2016	Two Zone
Oct. 1, 2016	Reactor				12,114
Oct. 2, 2016					11,778
Oct. 3, 2016					10,432
Oct. 4, 2016					11,665
Oct. 5, 2016					12,074
Oct. 6, 2016					11,264
Oct. 7, 2016					12,338
Oct. 8, 2016					10,623
Oct. 9, 2016					10,815
Oct. 10, 2016					11,857
Oct. 11, 2016		21.6	39.3		14,623
Oct. 12 ,2016		13.2	50.5		12,674
Oct. 13, 2016		14.0	21.3		10,479
Oct. 14 ,2016		14.2	52.1		11,692
Oct. 15, 2016		13.2	40.1		11,269
Oct. 16, 2016		11.4	44.8	69	7,874
Oct. 17, 2016		11.6	43.3	72	10,008
Oct. 18, 2016		12.9	41.5		11,414
Oct. 19, 2016		12.2	36.2	70	9,536
Oct. 20, 2016		12.9	40.0	71	7,300	6,200											227.0	7.4	7.3
Oct. 21, 2016		12.9	45.7	75	9,837
Oct. 22, 2016		13.1	45.5	78	9,212	7,185											265.0
Oct. 23, 2016		12.8	47.6		8,454
Oct. 24, 2016		11.1	34.7	72	5,900	4,600										21.0	167.0	37.4	8.0
Oct. 25, 2016		11.6	49.8	71	8,900	7,100	7.8					3.1				20.2	171.0	36.7	8.7
Oct. 26, 2016	Scenario 7	11.7	38.4	68	7,890	6,890	7.7			494	20.7	2.5	1.3			19.8
Oct. 27, 2016	HRT12; SRT42	11.8	39.2	69	8,100	6,200				581	22.7	2.4	1.2				199.0	25.9	9.3
Oct. 28, 2016		13.1	40.2	68	9,929											23.1	225.6
Oct. 29, 2016		13.1	38.8		9,890												236.0
Oct. 30, 2016		12.3	39.5	71	10,285		7.6
Oct. 31, 2016		11.0	50.2		11,066		7.4										245.0	69.0	11.0
Oct. 1, 2016		12.1	42.2		8,100	6,800				576	42.7	2.5	1.3	16.0	0.9	37.2	196.0
Nov. 2, 2016		10.2	33.9	74	9,974		7.3	215		476	26.2	2.0	1.1	19.0	0.0	26.2	194.0	21.2	10.1
Nov. 3, 2016	scenario 8	9.4	26.8	73	7,100	5,700	7.2	204								23.4	197.0	14.3	9.1
Nov. 4, 2016	HRT9,	9.2	31.9	74	9,260		7.2	210		708	21.4	3.0	1.6	19.9	0.0		248.0	59.9	11.3
	SRT30
Nov. 5, 2016		9.8	32.0	75	11,199		7.5	225									177.0
Nov. 6, 2016		8.9	31.6	72	10,330		7.3	198									182.0
Nov. 7, 2016		8.8	25.5	74	7,600	6,380	6.9	272	79.6	603	16.5	2.8	1.3			24.1	187.0	20.4
Nov. 8, 2016		8.4	34.7		9,500	7,700	7.7					2.1					204.0	32.8	8.3
Nov. 9, 2016		9.2	47.3		9,000	6,980	7.1									21.4	202.0	22.3	7.7
Nov. 10, 2016	scenario 9	8.4	55.8	72	10,285		7.4	211		632	23.4	2.8	1.3		0.0	21.9	249.0	27.1	9.0
Nov. 11, 2016	HRT9,	9.0	45.4	73	9,381		7.3	285									214.0		9.6
	SRT48
Nov. 12, 2016		10.8	47.5		8,094
Nov. 13, 2016		9.7	51.4		9,947				69.4
Nov. 14, 2016		9.7	42.5	75	8,300	6,900	7.2	230		643	8.0	2.9	1.3	17.3	0.0		217.0	15.3	11.1
Nov. 15, 2016		6.1	37.5	74	10,200	8,200	7.4	225	85.9								197.2		7.9
Nov. 16, 2016		6.0	19.8	75	9,000	7,300	7.0	255	69.1	633	13.7	2.5	1.6	16.8	<0.40	29.2	267.0		12.8
Nov. 17, 2016	scenario 10	6.1	18.9	76	10,689												273.0	31.2	12.9
Nov. 18, 2016	HRT6,	6.2	17.6		11,034		6.7	304	74.5								263.0		12.1
	SRT18
Nov. 19, 2016		6.7	17.7		10,576
Nov. 20, 2016		6.1	18.0	74	10,913	7,900	6.9	215									266.0		12.1
Nov. 21, 2016		6.2	18.7	76	11,363		7.4	241		652	12.8	3.8	1.4	15.2	0.0	26.6	257.0	24.9	11.1
Nov. 22, 2016		6.2	17.9	77	8,992		7.2	236
Nov. 23, 2016		17.7	36.4		6,844	4,859			95.3							31.8	174.0		9.2
Nov. 24, 2016		18.4	39.9	75	7,822
Nov. 25, 2016		17.9	37.5	75	7,089
Nov. 26, 2016		18.3	39.5	73	8,336
Nov. 27, 2016	scenario 11	18.3	35.7	75	9,044														9.2
Nov. 28, 2016	HRT18,	18.2	38.5	71	8,800	7,040	7.3	210	86.7	529	9.7	3.7	1.7	15.9	0.0	26.7	176.0	22.6	10.8
	SRT36
Nov. 29, 2016		18.4	37.6	76	9,500												275.5	21.8	10.7
Nov. 30, 2016		18.2	36.8	76	11,333		7.1	200									316.0		9.4
Dec. 1, 2016		18.9	35.8	74	11,689	7,460	7.5	198	78.3	588	16.8	4.7	1.7	14.9	0.1	23.4	309.0	29.4	10.2
Dec. 2, 2016	Scenario 12	23.1	54.1	73	8,800	7,500											184.8	15.2	9.7
Dec. 3, 2016	HRT24,	23.5	54.8	76	8,800	8,500	7.2										215.6	19.8	12.6
	SRT54
Dec. 4, 2016		23.9	56.0	76	10,267		7.1	202	96.0	594	14.7	4.2	1.3	13.4	0.0	30.5	232.3	22.8	7.3
Dec. 5, 2016		23.0	56.9	72	11,611	8,200	7.3
Dec. 6, 2017		23.9	57.6	75	10,882				81.2								296.0		8.8
Dec. 7, 2017	n/a	23.4	56.1	75	10,820		7.1	186
Dec. 8, 2017	n/a	23.8	55.5	73	10,820					624	17.3	3.7	1.2	14.8	0.0	24.1	288.0		7.9
Dec. 9, 2017		23.1	52.5	68	9,075		7.0	191	74.6
Dec. 10, 2017		24.1	57.1	70	11,169	7,900										22.4	293.0		6.9
Feb. 27, 2017		10.6	25.3	68	15,570				68.4							30.5	201.7
Feb. 28, 2017		12.2	27.0	72	15,390	11,390											166.4
Mar. 1, 2017		12.1	16.7	68	14,569	11,360			74.5
Mar. 2, 2017	SCENARIO	12.4	21.3	73	14,327	10,460	6.9	25								31.8	190.0	14.0	3.5
	13
Mar. 3, 2017	HRT12,	11.7	23.2	70	12,746	9,300		109	96.4	634	22.8
	SRT24
Mar. 4, 2017	Qr = 200	11.6	27.1	71	14,802	11,840		127									187.6	13.4	3.9
Mar. 5, 2017		12.4	23.8	69	14,194	10,500		107	95.1								197.1		4.4
Mar. 6, 2017		12.6	25.6	73	13,506	10,530		168		576	26.4						157.5
Mar. 7, 2017		12.9	23.3	69	13,569	10,040	6.9	−114	86.6			1.0	0.4			24.5	253.6	8.6	3.8
Mar. 8, 2017		12.7	24.7	74	13,939	11,150											276.0		17.2
Mar. 9, 2017		14.5	35.0	70	13,521	10,820	7.1	196	59.0							26.8	162.4		49.5
Mar. 10, 2017	Scenario 14	12.6	36.2	69	15,476	12,690											252.0	23.1
Mar. 11, 2017	HRT = 12,	11.7	35.3	68	14,475	11,000	7.0	212	74.0	561	21.9	2.7	1.2	18.9		34.6	243.0
	SRT = 42
Mar. 12, 2017	Qr = 100	11.8	37.6	67	12,766	10,340											305.0	27.6
Mar. 13, 2017		12.8	34.6	68	11,263	9,240		157	88.3	645						31.8	167.9	10.5	12.4
Mar. 14, 2017		12.7	35.6	69	10,850	8,350	7.2	206									128.1
Mar. 15, 2017		12.5	36.1		10,699	8,350		168	64.1								243.6
Mar. 16, 2017		17.7	36.8	68	8,612	6,800	7.1	89				3.5	1.7	14.2		22.7	211.4	27.5	5.9
Mar. 17, 2017		16.7	38.8	66	13,339	10,540		93	54.8	694									4.2
Mar. 18, 2017	Scenario 15	18.5	35.6	66	12,150	9,960	7.0	179								29.4
Mar. 19, 2017	H = 18,	17.6	38.7	70	12,833	9,750		141	55.1								287.0	27.2	7.1
	H = 48
Mar. 20, 2017	Qr = 200	17.8	35.5	65	14,080	10,980	6.9	140								24.2	318.9		6.8
		18.1	36.5	65	13,912	10,710		164											4.9
Mar. 22, 2017		17.8	36.9		13,650	11,060	7.4	185	91.0	602	24.3	3.1	1.6	16.8		24.6	301.5	34.6	9.1
Mar. 23, 2017		17.4	36.7	69	13,125	10,240		135											5.2
Mar. 24, 2017		17.4	37.2	70	13,000	10,010	7.2		92.0							33.7	311.2
May 1, 2017		12.7	25.7		9,500	7,000	6.8										214.2
May 2, 2017		12.8	23.4	66			7.4			512	9.2	2.2	1.0	16.4
May 3, 2017	Scenario 16	12.3	24.6	64			7.3									33.9			5.6
May 4, 2017	HRT = 12	12.0	24.6	68	12,400	9,000	6.6		68.0
May 5, 2017	SRT = 24	12.3	24.7	62	12,600	9,400	6.7	−217		419	14.5	1.4	0.6	14.5		43.6	276.0		14.0
May 6, 2017	Qr = 50	12.3	27.9	66	11,480		7.3	24									268.4	11.2
May 7, 2017		12.2	23.7	74	10,450		7.3	69								40.9	286.4	18.5
May 8, 2017		12.2	23.8	69	10,500	7,900	7.2	54		340	10.2	2.3	0.9	14.8			271.2	15.3
May 9, 2017		11.7	25.2	69	11,800		6.7	10											3.8
May 10, 2017		11.8	23.4	62	11,200	8,100	6.7	−27	128.0	498	33.6	2.7	1.2	19.4		44.4	480.0	55.9	67.3
May 11, 2017		11.7	26.8	74	8,900		7.0	24		294	12.7	1.6	0.6	17.3		31.3	252.0	24.0	24.2
May 12, 2017		11.8	22.8	64	9,930		6.9	3	85.0								294.0
May 13, 2017		12.1	24.0	63	10,300	8,000	7.2	32		403						31.5	298.0		4.9
May 14, 2017		12.7	18.6	62	9,820		6.8	−36
May 15, 2017	Scenario 17	12.3	18.5	64	9,100	6,700	7.3	32	69.3	404	16.5	1.8	0.7	16.0		31.3	224.0	14.6	4.0
May 16, 2017	HRT = 18	11.9	18.0	75	8,400		6.9	68									198.0
May 17, 2017	SRT = 24	12.0	18.5	74	9,100					476	18.2					36.3
May 18, 2017	Qr = 200	12.6	17.7	68	9,600	7,300	7.0	68				2.8	1.2	12.5			279.0	19.2	1.1
May 19, 2017		12.0	18.3	65	10,300	7,700	7.1	59									322.0
May 20, 2017		11.7	18.1	69	10,000	7,500	6.7	78	79.0							40.8	267.0	16.4	14.9
May 21, 2017		11.9	18.3	65	10,300		6.9	41		290	9.4	1.1	0.4	13.0			305.4
May 22, 2017		17.9	37.6		9,700	7,200	7.3	35									438.0		13.5
May 23, 2017		17.7	36.1	65	9,900		7.0			212	8.5	2.1	0.9	13.0		32.8	244.0
May 24, 2017	Scenario 18	17.7	36.1	63	10,200			22	47.0	358	27.5	2.8	1.2	11.8			590.0	56.9
May 25, 2017	H = 18	17.8	35.2		9,400		7.2			493	12.3	1.4	0.6	9.2			389.0		47.5
May 26, 2017	S = 36	19.7	36.2	67	9,800		7.1	95								35.1	327.1
May 27, 2017	Qr = 200	19.7	37.1	64	11,300		6.8	58									472.6		6.9
May 28, 2017		19.9	34.3	68	8,000		6.6	−36	82.0	374	15.7	1.3	0.5	8.6			328.1
May 29, 2017		18.1	35.2	65	10,000	7,300	6.8	−15								30.2			7.8
May 30, 2017		19.7	36.2	74			7.2	−19
May 31, 2017		12.4	32.5	70	8,900		6.7	8	59.0	299	14.7	2.8	1.1	11.4			297.0	66.2	4.8
Jun. 1, 2017		11.6	28.7	66			7.3	−16								39.4
Jun. 2, 2017	Scenario 19	12.4	32.9	66	11.300	10,900	6.9	39									384.0		6.9
Jun. 3, 2017	h = 12	12.1	28.2	66			6.7	13	86.0	338	12.5	1.4	0.6	15.9					7.9
Jun. 4, 2017	s = 30	12.4	29.6	75	10,900		7.3	−24									374.8
Jun. 5, 2017	Qr = 200	13.0	29.3	74	10,700	7,500	6.9	−8								33.3	358.0		5.3
Jun. 6, 2017		12.1	29.6	74	9,400		6.7	35		274	3.3	2.3	1.1	14.0			324.8
Jun. 7, 2017		12.8	30.0	70			7.2	8
Jun. 8, 2017		12.3	34.8	73	12,500	9,300	6.9	46								37.6	442.0		8.1
Jun. 9, 2017		12.2	31.5	63	9,200	6,300	6.8	36	110.0								384.0		7.2
Jun. 10, 2017		12.2	58.1	65	10,600	7,200	6.9	22		293	3.5	3.2	1.3	10.5
Jun. 11, 2017	RUN 20	13.2	51.7	66			7.2	−24								25.8
Jun. 12, 2017	h = 12	12.4	56.7	69	9,800	7,000	7.3	−10	52.0								413.8		4.7
Jun. 13, 2017	s = 54	14.2	45.6	65	10,500	7,700	7.3	−8									386.7
Jun. 14, 2017	Qr = 50	14.3	43.7	70			7.3	−12		418	12.1	2.2	0.9	12.4		24.6			6.1
Jun. 15, 2017		14.5	50.7	66	10,700	7,800	7.2	80	85.0								440.5		7.5
Jun. 16, 2017		13.9	50.0	65	9,900	7,400	7.2	−25									396.4
Jun. 17, 2017		13.5	50.3	68			6.7	54		302	6.9					29.1			4.5
Jun. 18, 2017		11.7	46.9	66			7.1	−12	67.0
Jun. 19, 2017		13.4	50.1	66	9,600	7,300	6.6	−40								38.4	386.5		4.7
Jun. 20, 2017		13.1	48.6	66	7,700	5,900	6.8	−10		342	15.4	3.0	1.2	14.0			349.6		4.4
Jun. 21, 2017		13.7	50.4	67	8,600		6.9	57								44.1	366.7	36.7
Jun. 22, 2017		18.0	45.3	69			6.9	−5	112.0
Jun. 23, 2017		17.9	48.0	67	9,500		6.8	47		374	15.0	2.3	1.0	13.0			304.2	63.9	7.4
Jun. 24, 2017	run 21	18.7	44.6	66	10,200		6.6	79								41.7	308.6	64.8	3.9
Jun. 25, 2017	H = 18	18.2	45.8	69			6.9	−18	132.0
Jun. 26, 2017	S = 48	18.1	45.9	66	11,900	8,000	7.1	59									479.2	47.9
Jun. 27, 2017	Qr = 50	18.4	47.4	70	8,600		7.0	3								35.8	334.9	46.9	6.4
Jun. 28, 2017		17.4	49.2	70			6.6	32	99.0	356	15.3	2.9	1.2	13.0
Jun. 29, 2017		18.0	47.7	68	5,500	4,000	7.0	75									406.0	73.1	8.4
Jun. 30, 2017		17.9	49.5	66	10,500	8,100	7.0	51									370.4	70.4
Jul. 1, 2017		18.1	44.4	66	7,100	5,200	7.4	−41	97.0								254.0	27.9
Jul. 2, 2017		17.9	41.2	69	7,400	5,600	7.4	5		297	3.3	2.9	1.3	17.2		28.0	267.9	64.3	5.1
Jul. 3, 2017		18.4	46.9	68	6,000	4,800	7.2	64									224.5	38.2
Jul. 4, 2017		18.1	49.4	68			6.9	−33	58.0
Jul. 5, 2017		18.4	49.5	69			7.3	49								29.8
Jul. 6, 2017		12.5	56.8	70	9,800	8,300	7.3	64									269.7
Jul. 7, 2017		12.2	46.2	70	9,600		6.9	15	98.0	326	13.0	2.4	0.9	13.4		35.3	261.0	46.4	5.4
Jul. 8, 2017	run 22	12.7	54.5	71			7.3	63
Jul. 9, 2017	h = 12	12.6	54.5	69	10,200		7.4	32	95.0								317.8		10.7
Jul. 10, 2017	s = 54	12.5	52.3	68	8,500	6,900	6.7	48									324.0
Jul. 11, 2017	Qr = 100	12.8	44.5	70	9,000		7.1	64	68.7	278	13.9	3.3	1.5	11.7		25.6	274.0	23.9	9.6
Jul. 12, 2017		12.5	54.7	68	9,400		7.3	97		304	22.0						302.1
Jul. 13, 2017		12.2	38.1	71	9,900		6.6	−34	57.0							37.1	348.2
Jul. 14, 2017		12.2	42.4	71			7.3	72										2.0
Jul. 15, 2017		12.3	39.6	71	10,400		7.1	−24	61.0	469	15.9	1.8	0.8	10.4			297.4	38.7	8.5
Jul. 16, 2017		12.7	51.3	71	8,400		7.0	78									263.8	36.9	7.1
Jul. 17, 2017		12.3	53.6	70	7,800	6,500	6.6	79	49.5							44.5	179.0
Jul. 18, 2017		12.3	53.5	69	6,100	4,900	7.1	48									223.0	20.1	6.8
Jul. 19, 2017		11.7	52.2	68			6.7	26
Jul. 20, 2017		18.3	60.7	71			7.0	20	41.0	342	9.6	1.8	0.7	12.9		31.3
Jul. 21, 2017		18.2	53.6	69	6,400		7.3	−32									195.0	39.0	8.9
Jul. 22, 2017		17.3	56.0	68			6.8	64								23.9
Jul. 23, 2017	run 23	18.2	52.7	71	6,900		7.4	−41	49.0								267.1	56.1	11.4
Jul. 24, 2017	h = 18	17.5	52.8	74	6,200	4,600	6.8	76								32.6	251.4	65.4	8.4
Jul. 25, 2017	s = 54	17.7	51.5	70			6.9	−32	67.0	422	11.0	1.3	0.5	15.3
Jul. 26, 2017	Qr = 200	17.6	52.7	71	7,900		6.9	84								39.0	350.0	70.0	7.2
Jul. 27, 2017		18.2	55.3	70			6.9	42
Jul. 28, 2017		17.8	53.4	70	8,900		7.3	37	72.0	371	5.2	3.2	1.3	13.8		35.4	452.1	63.3	4.6
Jul. 29, 2017		18.1	55.8	71	9,600		7.0	−23									425.1	97.8	5.6
Jul. 30, 2017		18.0	54.7	70			7.1	15	64.0							42.0
Jul. 31, 2017		18.0	48.9	68	11,500	9,200	6.8	−22		370	11.5	3.0	1.3	11.1			504.8	45.4	7.2
Aug. 1, 2017		17.7	55.2	68	10,600	8,300	6.8	71	107.0							36.3	478.3	81.3	4.3
Aug. 2, 2017		18.0	54.1	70	12,200	10,000	6.6	−33									508.2	71.1	6.5

		Plug Flow Reactor First Zone
						TKN,	NO2 + NO3,	VFA, mg-	Mg,	TP, mg-	sTP,	OrthoP,
Date	Scenario	TSS, mg/L	VSS, mg/L	pH	ORP	mg/L	mg/L	HAc/L	mg/L	P/L	mg-P/L	mg-P/L
Sep. 29, 2016	Baseline
Sep. 30, 2016	Two Zone
Oct. 1, 2016	Reactor
Oct. 2, 2016
Oct. 3, 2016
Oct. 4, 2016
Oct. 5, 2016
Oct. 6, 2016
Oct. 7, 2016
Oct. 8, 2016
Oct. 9, 2016				7.2
Oct. 10, 2016				7.0
Oct. 11, 2016		15,300	11,400	7.2
Oct. 12, 2016		17,000	12,900	6.8
Oct. 13, 2016		25,500	19,700	7.2
Oct. 14, 2016		21,580		7.1
Oct. 15, 2016				6.6
Oct. 16, 2016				7.2
Oct. 17, 2016		29,580	21,002	6.7						642.6
Oct. 18, 2016		34,870	25,804	7.0
Oct. 19, 2016		32,120	25,054	7.2
Oct. 20, 2016		32,480	24,685	7.2						623.5
Oct. 21, 2016		35,120	29,501	6.8						798.6
Oct. 22, 2016		27,080	21,935	7.0						610.4
Oct. 23, 2016		35,110	27,386	7.0	−168
Oct. 24, 2016		38,000	26,980	7.0						721.8
Oct. 25, 2016		23,580	18,864	6.6	−195			26.5	24.2
Oct. 26, 2016	Scenario 7	41,220	33,388	6.8						814.1	23.1	21.4
Oct. 27, 2016	HRT12;	40,580	12,000	7.2	−165
	SRT42
Oct. 28, 2016		35,120	25,638	6.9				25.7	21.6	876.3	32.1	27.7
Oct. 29, 2016		34,880	25,462	6.9	−175							30.8
Oct. 30, 2016		26,780	21,424	6.6	−127					745.6
Oct. 31, 2016		28,840	22,784	6.9							49.1	44.2
Nov. 1, 2016		35,820	27,940	6.9	−137	526.7	0.2	29.7	31.3	660.0
Nov. 2, 2016		37,360	29,514	7.2				32.8	27.8		36.8	32.3
Nov. 3, 2016	scenario 8	41,050	29,556	7.1	−185			30.1	23.8	943.4	42.0	35.9
Nov. 4, 2016	HRT9,	40,550	30,413			662.0	0.4
	SRT30
Nov. 5, 2016		43,500	30,450					39.9	28.5		27.2	28.0
Nov. 6, 2016		40,000	29,200							834.0	37.1	36.7
Nov. 7, 2016		42,840	30,416	7.6	−193		0.0	28.9	15.2		26.6	25.6
Nov. 8, 2016		25,130	19,350								24.3	21.9
Nov. 9, 2016		39,520	30,826	7.0	−201			34.6	24.0	841.4
Nov. 10, 2016	scenario 9	42,250	30,843	7.3							43.8	38.1
Nov. 11, 2016	HRT9,	41,250	31,350	7.2	−219						39.7	38.2
	SRT48
Nov. 12, 2016		37,420	27,691							687.5
Nov. 13, 2016		38,450	31,145							861.0
Nov. 14, 2016		41,380	32,276	7.1	−209	371.0	8.0	32.6		799.5	43.1	43.5
Nov. 15, 2016		25,000	20,000	7.3	−221					324.1
Nov. 16, 2016		26,010	13,240	6.9	−229	597.8	0.0	30.1	33.2		32.7	32.1
Nov. 17, 2016	scenario 10	22,510	16,207
Nov. 18, 2016	HRT6,	24,990	19,492	6.7	−278				34.2	412.5	17.2	17.7
	SRT18
Nov. 19, 2016		23,400	18,954				2.4			545.0
Nov. 20, 2016		21,560	16,170	6.8	−260						39.6	36.3
Nov. 21, 2016		20,070	12,860	7.3	−251			30.9	24.1		25.7	26.0
Nov. 22, 2016		21,120	15,629							689.4
Nov. 23, 2016		21,890	15,323	7.3	−248			30.1	35.3		30.6	25.9
Nov. 24, 2016		20,360	14,659	7.2						n/a
Nov. 25, 2016		21,820	15,274	7.2	−246					n/a
Nov. 26, 2016		21,010	15,547	6.7	−268					n/a
Nov. 27, 2016	scenario 11	20,800	14,768	7.1
Nov. 28, 2016	HRT18,	20,000	14,600	6.7	−193	533.8	0.2	31.5	38.4		26.1	24.4
	SRT36
Nov. 29, 2016		20,000	16,200	7.1						437.5	34.2	31.1
Nov. 30, 2016		20,580	15,641	7.1	−285
Dec. 1, 2016		19,020	15,026	7.2				37.9	27.1		60.1	61.3
Dec. 2, 2016	Scenario 12	36,440	25,144	6.6	−286					764.2	45.7	40.4
Dec. 3, 2016	HRT24,	34,560	24,883	7.4		611.1	0.0			645.7	31.9	31.6
	SRT54
Dec. 4, 2016		36,440	25,144	6.9	−239			35.2	39.0		46.8	45.0
Dec. 5, 2016		38,690	28,244	6.7
Dec. 6, 2017		36,440	25,508	7.0	−249	562.7	0.0			809.1	65.5	58.5
Dec. 7, 2017	n/a	40,020	30,815	6.9
Dec. 8, 2017	n/a	39,820	29,865	7.0	−248	638.8	0.0	25.2	24.5		39.0	39.4
Dec. 9, 2017		36,440	28,059	6.6
Dec. 10, 2017		36,440	28,788	7.0	−276		0.0	25.4	26.6	772.0	56.1	48.4
Feb. 27, 2017		15,890	12,080	6.7
Feb. 28, 2017		18,950	14,970	7.3	−275			30.7		442.9	36.3	33.3
Mar. 1, 2017		32,000	6,400	6.7	−253
Mar. 2, 2017	SCENARIO 13	32,580	26,060	7.4	−162			30.9	34.4	768.2	19.5	19.5
Mar. 3, 2017	HRT12,	34,870	27,900	6.7	−264
	SRT24
Mar. 4, 2017	Qr = 200	38,470	29,620	7.1	−197
Mar. 5, 2017				7.3	−181						29.4	27.5
Mar. 6, 2017		41,500	34,072		−191					967.2	27.1	27.9
Mar. 7, 2017		38,540	30,830	7.0	−286	617.6	0.4	29.2	27.6
Mar. 8, 2017		31,070	25,170		−187					578.3	24.4	22.4
Mar. 9, 2017		34,520	27,270	6.9	−162			27.5	27.2
Mar. 10, 2017	Scenario 14	44,870	35,900	6.8	−264					976.9	49.5	43.8
Mar. 11, 2017	HRT = 12,	39,860	29,900	6.7	−258	568.3	0.0		41.2	805.8	55.0	47.0
	SRT = 42
Mar. 12, 2017	Qr = 100	39,510	32,000	6.6	−172
Mar. 13, 2017		41,280	30,550	7.2	−267		0.0	36.6	35.6	788.9	32.8	29.0
Mar. 14, 2017		41,290	31,790	7.2	−234
Mar. 15, 2017		42,170	32,890	6.7	−230
Mar. 16, 2017		39,830	32,260	6.7	−205			26.4	30.0	728.9	28.4	27.8
Mar. 17, 2017		36,780	29,060	7.3	−188	639.8	0.1
Mar. 18, 2017	Scenario 15	36,220	26,800	7.4	−276			30.2	30.2
Mar. 19, 2017	H = 18, 48	39,510	30,420	6.6	−283					824.4	38.6	35.7
Mar. 20, 2017	Qr = 200	41,280	33,020	7.3	−248				29.3	885.4	53.7	53.2
Mar. 21, 2017		38,500	30,800	6.8	−236
Mar. 22, 2017		39,640	30,920	7.3	−227	575.5	0.0	36.4	20.1	793.2	42.3	42.7
Mar. 23, 2017		34,560	27,300	6.8	−283
Mar. 24, 2017		33,710	25,620	7.2	−181			38.1	36.0	725.2	38.2	37.8
May 1, 2017		10,580	8,040	7.1
May 2, 2017		12,270	9,330	6.8	−248	523.1	0.0			281.6
May 3, 2017	Scenario 16	18,120	14,310	6.9	−230
May 4, 2017	HRT = 12	19,850	16,080	7.1				24.9		452.5
May 5, 2017	SRT = 24	28,000	22,400	6.7	−298	385.6	0.2			592.7	56.5	49.1
May 6, 2017	Qr = 50	31,959	24,290	6.7								36.2
May 7, 2017		26,676	20,010	6.8	−237			31.2	34.5
May 8, 2017		26,154	19,090	7.1	−157	358.3	0.0			574.1	62.6	53.5
May 9, 2017		31,500	24,570	6.7	−171
May 10, 2017		26,914	21,530	6.6	−242	486.2	0.2	33.0	34.4	583.4	42.7	39.9
May 11, 2017		32,679	25,820	6.6	−172
May 12, 2017		27,081	21,660	6.7	−270			22.6		509.7	19.5	20.1
May 13, 2017		32,420	24,640	7.0	−173		0.0			678.4		26.3
May 14, 2017		28,579	18,520	6.6	−196
May 15, 2017	Scenario 17	26,550	19,910	6.7	−253	427.1	1.3	45.4	33.8	605.3	20.3	18.0
May 16, 2017	HRT = 18	28,125	21,090	6.9	−223					631.9	34.8	32.2
May 17, 2017	SRT = 24	27,987	21,550		−146		0.7	35.4	40.8
May 18, 2017	Qr = 200	28,137	20,540	6.7	−148					570.8	43.7	39.0
May 19, 2017		31,973	24,300		−203					614.5		34.8
May 20, 2017		31,863	25,170	6.7	−283
May 21, 2017		32,287	24,220	6.7		311.9	0.2	27.8		710.7	21.4	18.8
May 22, 2017		31,200	25,270	6.7	−217
May 23, 2017		32,562	25,720	6.8		220.5	0.0	43.2	37.7	603.9	40.8	36.8
May 24, 2017	Scenario 18	31,770	23,190	6.7	−245							19.1
May 25, 2017	H = 18	26,693	21,620	7.0	−204	486.8	0.3			614.1	72.1	63.8
May 26, 2017	S = 36	30,009	24,010	6.7	−270
May 27, 2017	Qr = 200	30,573	24,460	7.0	−245
May 29, 2017		31,111	24,290	6.9	−284
May 30, 2017		26,545	21,500	6.6	−281
May 31, 2017		27,192	21,750	6.4	−193	307.1	0.2	36.0		618.6
Jun. 1, 2017		31,575	25,260	7.0	−257
Jun. 2, 2017	Scenario 19	31,707	23,780	6.7	−175					726.2	37.4	34.6
Jun. 3, 2017	h = 12	26,394	21,380	7.1	−177
Jun. 4, 2017	s = 30	31,114	23,960	7.1	−261					592.5	56.1	57.8
Jun. 5, 2017	Qr = 200	32,739	25,540	6.8	−241
Jun. 6, 2017		32,596	25,750	6.8	−191	290.9	0.0	45.4		745.1	24.5	25.3
Jun. 7, 2017		27,465	20,600	6.9	−256
Jun. 8, 2017		29,551	21,570	6.8	−224					565.0	52.4	49.9
Jun. 9, 2017		30,444	22,220	7.0	−177							56.8
Jun. 10, 2017		32,286	25,830	6.9	−197	282.3	0.0	23.8
Jun. 11, 2017	RUN 20	34,660	25,650	6.7	−282
Jun. 12, 2017	h = 12	36,880	27,660	6.7	−247					820.1	77.9	70.8
Jun. 13, 2017	s = 54	35,840	34,580	6.7	−205					737.1	44.3	41.4
Jun. 14, 2017	Qr = 50	34,990	27,290	6.8	−270	434.7	0.0	50.3	30.3
Jun. 15, 2017		37,520	27,760	6.6	−299					801.4	43.2	36.9
Jun. 16, 2017		34,120	26,610	6.5	−311					704.1		49.0
Jun. 17, 2017		33,250	30,250	6.5	−278		0.0	28.2	32.7
Jun. 18, 2017		34,890	26,170	6.7	−287
Jun. 19, 2017		35,720	28,930	6.8	−304					673.6	58.5	51.8
Jun. 20, 2017		36,580	28,530	6.5	−178	320.4	0.0		54.2
Jun. 21, 2017		34,200	26,680	6.4	−209					720.3	75.2	70.3
Jun. 22, 2017		30,463	22,240	7.2	−286
Jun. 23, 2017		32,371	25,250	6.7	−189	359.9	0.0		19.5	740.3	33.0	30.0
Jun. 24, 2017	run 21	28,039	20,470	6.8	−221					569.0	41.0	38.7
Jun. 25, 2017	H = 18	33,596	26,540	6.7	−173
Jun. 26, 2017	S = 48	35,326	26,850	7.4	−189					651.5	99.7	96.8
Jun. 27, 2017	Qr = 50	29,325	20,480	6.5	−172					656.6	55.3	54.2
Jun. 28, 2017		32,801	26,570	6.9	−199	369.0	0.0	23.6	21.4
Jun. 29, 2017		34,958	27,970	6.5	−209					675.1	100.1	90.2
Jun. 30, 2017		33,670	26,600	6.4	−175							108.9
Jul. 1, 2017		34,520	27,270	6.4	−192
Jul. 2, 2017		36,980	29,580	6.8	−153	317.3	0.0	41.7	32.8
Jul. 3, 2017		34,700	25,330	7.1	−189					700.3	11.2	11.3
Jul. 4, 2017		33,710	25,620	6.8	−225
Jul. 5, 2017		33,580	26,860	7.3	−223
Jul. 6, 2017		39,861	29,100	6.7	−182					814.3	22.6	20.4
Jul. 7, 2017		40,870	29,840	6.8	−312	318.9	0.2	24.8	31.6		31.9	29.5
Jul. 8, 2017	run 22	39,680	32,140	6.7	−302
Jul. 9, 2017	h = 12	39,352	31,480	6.7	−295					720.7	40.4	36.4
Jul. 10, 2017	s = 54	38,155	28,620	6.9	−283
Jul. 11, 2017	Qr = 100	41,850	33,900	6.5	−184	260.7	0.0	40.6	34.1	888.0	43.6	41.1
Jul. 12, 2017		40,120	31,290	7.1	−216
Jul. 13, 2017		38,271	28,320	7.1	−303					759.3	34.2	33.2
Jul. 14, 2017		43,690	34,520	6.7	−272
Jul. 15, 2017		41,580	31,190	6.8	−309	441.0	0.0		39.2	926.7	33.4	33.7
Jul. 16, 2017		42,580	34,490	6.7	−223							33.2
Jul. 17, 2017		44,620	33,470	6.6	−318					820.8	15.9	15.4
Jul. 18, 2017		41,260	30,950	6.4	−247
Jul. 19, 2017		40,580	30,840	6.4	−261
Jul. 20, 2017		37,725	30,180	7.4	−319	319.3	0.1	33.0	33.5
Jul. 21, 2017		39,447	29,980	6.6	−189					755.9	18.6	19.2
Jul. 22, 2017		38,308	27,960	6.4	−232
Jul. 23, 2017	run 23	37,144	29,340	6.9	−287					746.2	56.4	54.8
Jul. 24, 2017	h = 18	39,066	31,640	7.0	−185						38.9	35.7
Jul. 25, 2017	s = 54	38,709	29,810	6.4	−262	384.8	0.1	44.2	34.8
Jul. 26, 2017	Qr = 200	39,424	29,170	6.4	−262					814.3	26.0	25.2
Jul. 27, 2017		38,814	28,720	7.0	−200
Jul. 28, 2017		37,420	28,070	6.6	−284	384.8	0.0	43.5	36.5	799.4	50.5	48.6
Jul. 29, 2017		39,702	30,570	6.9	−257					853.5	27.8	24.8
Jul. 30, 2017		37,430	27,320	7.4	−191
Jul. 31, 2017		37,081	27,440	6.4	−207	392.5	0.0	34.0	34.2	745.1	99.9	84.7
Aug. 1, 2017		38,501	31,190	7.1	−206
Aug. 2, 2017		36,897	29,890	6.6	−206					804.7	58.7	57.0

			Plug Flow Reactor Waste Sludge
		TSS,	VSS,	TKN,	NO2 +	Mg,	TP, mg-	sTP, mg-	OrthoP,
Date	Scenario	mg/L	mg/L	mg/L	NO3, mg/L	mg/L	P/L	P/L	mg-P/L
Sep. 29, 2016	Baseline
Sep. 30, 2016	Two Zone
Oct. 1, 2016	Reactor
Oct. 2, 2016
Oct. 3, 2016
Oct. 4, 2016
Oct. 5, 2016
Oct. 6, 2016
Oct. 7, 2016
Oct. 8, 2016
Oct. 9, 2016
Oct. 10, 2016
Oct. 11, 2016		8,250					204.0
Oct. 12, 2016		9,500
Oct. 13, 2016		25,100	19,600
Oct. 14, 2016		12,410					274.0
Oct. 15, 2016		12,000
Oct. 16, 2016		8,520
Oct. 17, 2016		12,220	9,530				264.0
Oct. 18, 2016		16,890
Oct. 19, 2016		12,000
Oct. 20, 2016		13,970					336.1
Oct. 21, 2016		12,300	10,300				314.5
Oct. 22, 2016		17,590					289.0
Oct. 23, 2016		10,000
Oct. 24, 2016		13,880	5,380				187.0
Oct. 25, 2016		520	420			25.4
Oct. 26, 2016	Scenario 7	9,900					167.0	20.0	59.5
Oct. 27, 2016	HRT12; SRT42	9,900	8,080
Oct. 28, 2016		8,990				22.7	229.0	56.0	58.5
Oct. 29, 2016		9,910							58.7
Oct. 30, 2016		11,880					234.0
Oct. 31, 2016		11,650						77.0	64.5
Nov. 1, 2016		6,900	3,300	552.1	0.6	31.3	210.0
Nov. 2, 2016		8,000						25.0	49.8
Nov. 3, 2016	scenario 8	9,100	7,500			30.1	184.0	38.0	56.2
Nov. 4, 2016	HRT9, SRT30	10,090		486.7	1.5
Nov. 5, 2016		1,400	966						52.6
Nov. 6, 2016		10,020					196.4	59.0	58.4
Nov. 7, 2016		7,010				18.2			43.0
Nov. 8, 2016		8,740	6,580					37.0	46.9
Nov. 9, 2016		8,040				34.6	217.5
Nov. 10, 2016	scenario 9	6,050	5,820					64.0	60.9
Nov. 11, 2016	HRT9, SRT48	6,020						72.0	71.8
Nov. 12, 2016		7,820	6,810				225.7
Nov. 13, 2016		9,770
Nov. 14, 2016		10,020	4,300	671.3	0.2		155.0	80.5	72.9
Nov. 15, 2016		12,540	1,200
Nov. 16, 2016		16,050						36.0	54.6
Nov. 17, 2016	scenario 10	7,010	11,540
Nov. 18, 2016	HRT6, SRT18	8,740				41.2	297.0	21.0	37.4
Nov. 19, 2016		8,040					286.0
Nov. 20, 2016		6,050						62.0	63.5
Nov. 21, 2016		6,020	12,080						57.6
Nov. 22, 2016		7,820					260.8
Nov. 23, 2016		9,770	16,930			34.0		58.0	54.5
Nov. 24, 2016
Nov. 25, 2016
Nov. 26, 2016
Nov. 27, 2016	scenario 11	14,250
Nov. 28, 2016	HRT18, SRT36	13,000	18,690	847.7	0.0	34.1		26.0	59.2
Nov. 29, 2016		13,000					284.8	38.0	82.7
Nov. 30, 2016		13,410	15,560
Dec. 1, 2016		13,840						93.0	82.0
Dec. 2, 2016	Scenario 12	18,950	15,100				387.0	27.0	54.6
Dec. 3, 2016	HRT24, SRT54	19,630		742.0	0.0		415.0		53.8
Dec. 4, 2016		18,950	15,070			43.3			76.5
Dec. 5, 2016		18,420
Dec. 6, 2017		17,520	14,020	738.7	0.1		402.0	79.0	95.2
Dec. 7, 2017	n/a	22,990
Dec. 8, 2017	n/a	20,130	16,130	763.6	0.0			106.0	94.5
Dec. 9, 2017		18,950
Dec. 10, 2017		17,540	14,030	951.4	0.1	30.9	414.0	77.0	72.5
Feb. 27, 2017		8,540
Feb. 28, 2017		11,590					349.2		49.0
Mar. 1, 2017		23,000	4,500
Mar. 2, 2017	SCENARIO 13	22,870	18,070			34.8	373.0	32.0	25.0
Mar. 3, 2017	HRT12, SRT24	24,690		926.6	0.3
Mar. 4, 2017	Qr = 200	22,190	16,200
Mar. 5, 2017		25,630							50.5
Mar. 6, 2017		22,350	17,000
Mar. 7, 2017		21,710			0.0		356.0
Mar. 8, 2017		21,000	17,000						37.5
Mar. 9, 2017		24,560				35.1	184.7	35.1
Mar. 10, 2017	Scenario 14	28,960	23,170						82.5
Mar. 11, 2017	HRT = 12, SRT = 42	24,710		702.2	0.0		446.4		91.5
Mar. 12, 2017	Qr = 100	22,940	18,350
Mar. 13, 2017		23,850		685.2	0.1	36.9	198.2	36.9	63.1
Mar. 14, 2017		24,880	19,160
Mar. 15, 2017		25,480	19,620
Mar. 16, 2017		23,570		573.6	0.0	31.1	247.4	31.1	48.9
Mar. 17, 2017		20,940		853.1	0.0
Mar. 18, 2017	Scenario 15	22,470	17,080				249.6
Mar. 19, 2017	H = 18, H = 48	20,450							86.1
Mar. 20, 2017	Qr = 200	22,850	18,280			41.2	385.5	41.2	81.4
Mar. 21, 2017		21,520
Mar. 22, 2017		20,180		1035.0	0.1		313.4		68.5
Mar. 23, 2017		21,100
Mar. 24, 2017		18,470	13,480			47.2	307.6	47.2	81.5
May 1, 2017		8,740					227.2
May 2, 2017		10,250	7,585
May 3, 2017	Scenario 16	12,024
May 4, 2017	HRT = 12	13,486
May 5, 2017	SRT = 24	22,680	19,278				314.2		85.0
May 6, 2017	Qr = 50	21,190					283.5
May 7, 2017		16,162	13,253			34.3	215.4
May 8, 2017		20,462					271.1
May 9, 2017		17,539	14,207	541.8	0.1				91.0
May 10, 2017		19,244		13.0		50.1	280.0	76.6	63.6
May 11, 2017		18,648		794.6	0.1
May 12, 2017		22,677	18,595				318.2	40.8	35.2
May 13, 2017		20,916							57.8
May 14, 2017		21,134	16,907	434.5	0.0
May 15, 2017	Scenario 17	18,479				51.5	180.0	31.9	30.7
May 16, 2017	HRT = 18	21,009		341.6	0.3				85.1
May 17, 2017	SRT = 24	18,136	13,965
May 18, 2017	Qr = 200	20,563		684.5	0.7		181.0	102.7	83.5
May 19, 2017		19,165	13,799						63.1
May 20, 2017		21,167
May 21, 2017		19,992					234.2	51.9	47.6
May 22, 2017		18,420	15,657	468.4	0.9
May 23, 2017		19,016	15,403			43.9	189.3	64.5	52.9
May 24, 2017	Scenario 18	22,087							49.1
May 25, 2017	H = 18	18,704					363.0	145.7	151.8
May 26, 2017	S = 36	22,435	17,499	561.8	1.3
May 27, 2017	Qr = 200	17,170
May 29, 2017		24,940		623.5	0.0
May 30, 2017		19,566	14,479
May 31, 2017		18,942					372.4
Jun. 1, 2017		25,573	21,226	746.8	0.1
Jun. 2, 2017	Scenario 19	22,011					530.1	71.1	63.5
Jun. 3, 2017	h = 12	21,617	16,213
Jun. 4, 2017	s = 30	24,092					415.6	115.6	93.2
Jun. 5, 2017	Qr = 200	25,929
Jun. 6, 2017		24,643					421.8	63.6	52.1
Jun. 7, 2017		20,022	14,216	286.3	0.2
Jun. 8, 2017		19,462					537.3	85.0	81.7
Jun. 9, 2017		21,968	17,794						85.2
Jun. 10, 2017		20,921
Jun. 11, 2017	RUN 20	22,635		457.6	0.0
Jun. 12, 2017	h = 12	21,914					738.9	137.9	115.9
Jun. 13, 2017	s = 54	17,231	13,440						94.7
Jun. 14, 2017	Qr = 50	20,796				19.5
Jun. 15, 2017		20,151	14,710	113.5	0.1		806.4	121.9	115.0
Jun. 16, 2017		21,969							72.7
Jun. 17, 2017		18,658	13,247			35.9
Jun. 18, 2017		19,205		418.4	0.0
Jun. 19, 2017		19,561	15,062				813.7	110.8	104.5
Jun. 20, 2017		23,140				40.2
Jun. 21, 2017		19,979	15,184				686.1	145.8	125.7
Jun. 22, 2017		18,902
Jun. 23, 2017		19,665				27.5	336.3	72.1	67.4
Jun. 24, 2017	run 21	19,515		372.2	0.1				93.5
Jun. 25, 2017	H = 18	21,498	18,058
Jun. 26, 2017	S = 48	24,209					577.3	172.1	162.4
Jun. 27, 2017	Qr = 50	18,369							100.9
Jun. 28, 2017		19,175	15,532			30.4
Jun. 29, 2017		23,418		738.0	0.0		496.4	159.8	159.8
Jun. 30, 2017		20,867							177.7
Jul. 1, 2017		24,862	18,647
Jul. 2, 2017		27,789				45.1	336.8
Jul. 3, 2017		23,176		242.8	0.0		261.2	34.2	30.8
Jul. 4, 2017		21,852	17,919
Jul. 5, 2017		19,528
Jul. 6, 2017		27,982	22,665				709.4	67.3	62.9
Jul. 7, 2017		26,200				29.3			55.8
Jul. 8, 2017	run 22	26,018		1048.2	0.0
Jul. 9, 2017	h = 12	26,090					1009.6	51.1	48.2
Jul. 10, 2017	s = 54	24,415	19,288
Jul. 11, 2017	Qr = 100	27,083				54.0	1022.6	90.9	75.1
Jul. 12, 2017		27,540		320.3	0.0
Jul. 13, 2017		25,412	18,297				1300.4	90.2	85.1
Jul. 14, 2017		24,818
Jul. 15, 2017		28,383				59.4	1167.7	67.8	60.5
Jul. 16, 2017		23,591		375.9	0.0				48.0
Jul. 17, 2017		23,255	17,209				428.2	35.9	30.7
Jul. 18, 2017		26,234					629.3
Jul. 19, 2017		24,841	20,370
Jul. 20, 2017		27,867				37.1
Jul. 21, 2017		23,964	17,014	550.6	0.1		228.1	43.8	38.1
Jul. 22, 2017		27,015
Jul. 23, 2017	run 23	25,258					444.7	74.4	70.9
Jul. 24, 2017	h = 18	25,616	19,468				407.6		62.3
Jul. 25, 2017	s = 54	25,207			0.0	46.4
Jul. 26, 2017	Qr = 200	26,808	22,251				493.7	82.6	67.7
Jul. 27, 2017		26,300
Jul. 28, 2017		26,901	21,521			49.8	651.5	80.5	67.1
Jul. 29, 2017		25,409		708.7	0.0		700.4		67.2
Jul. 30, 2017		26,051
Jul. 31, 2017		27,062	21,379			36.0	851.2	121.6	122.8
Aug. 1, 2017		26,196		446.7	0.0		742.1
Aug. 2, 2017		27,285	20,191				625.1	135.3	106.5

APPENDIX
		Plug Flow Reactor Second Zone
							NO2 +	VFA,		TP,	sTP,	OrthoP,
		TSS,	VSS,			TKN,	NO3,	mg-	Mg,	mg-	mg-	mg-
Date	Scenario	mg/L	mg/L	pH	ORP	mg. L	mg/L	HAc/L	mg/L	P/L	P/L	P/L
Sep. 29, 2016	Baseline
Sep. 30, 2016	Two Zone
Oct. 1, 2016	Reactor
Oct. 2, 2016
Oct. 3, 2016
Oct. 4, 2016
Oct. 5, 2016
Oct. 6, 2016
Oct. 7, 2016
Oct. 8, 2016
Oct. 9, 2016
Oct. 10, 2016
Oct. 11, 2016												1.1
Oct. 12, 2016
Oct. 13, 2016
Oct. 14, 2016					−182.0
Oct. 15, 2016					−265.0
Oct. 16, 2016				6.8	−238.0
Oct. 17, 2016		18,330	14,480	7.1						390.0
Oct. 18, 2016		17,820	13,190	6.8
Oct. 19, 2016				6.6
Oct. 20, 2016		28,240	15,930	7.2						647.0
Oct. 21, 2016		27,630	10,980	6.6						623.0
Oct. 22, 2016		25,250	13,790	7.0						421.0
Oct. 23, 2016		15,000	10,500	6.9	−200.0
Oct. 24, 2016		20,820	16,660	6.2						284.0
Oct. 25, 2016		5,930	4,680	6.7	−200.0			31.3	28.2
Oct. 26, 2016	Scenario 7	14,850	10,990	6.6						269.0	63.1	59.5
Oct. 27, 2016	HRT12;	16,590	13,270	6.6	−210.0
	SRT42
Oct. 28, 2016		13,620	11,300	6.6				26.9	25.5	337.0	64.7	61.6
Oct. 29, 2016		12,390	10,410	6.9	−180.0						54.6	58.1
Oct. 30, 2016		14,850	11,430	6.6	−150.0					312.0
Oct. 31, 2016		20,080	16,670	7.2							62.4	70.1
Nov. 1, 2016		20,510	14,970	6.8	−140.0	552.1	0.6	37.1	34.0	451.4
Nov. 2, 2016		12,000	10,080		−260.0			39.2	38.5		43.1	51.3
Nov. 3, 2016	scenario 8	16,650	12,990	7.1	−271.0			35.6	31.4	380.4	63.4	59.8
Nov. 4, 2016	HRT9,	21,580	15,970		−250.0	529.0	1.5
	SRT30
Nov. 5, 2016		19,000	12,920		−242.0			46.2	38.3		47.7	49.2
Nov. 6, 2016		20,000	13,800		−248.0					442.0	53.9	57.3
Nov. 7, 2016		24,250	19,400	7.5	−261.0			36.1	34.2			40.6
Nov. 8, 2016		20,000	15,800								42.0	43.8
Nov. 9, 2016		20,000	15,400	7.0	−254.0			35.3	34.3	442.0
Nov. 10, 2016	scenario 9	22,450	18,180	7.3							54.1	61.5
Nov. 11, 2016	HRT9,	29,630	23,110	7.3	−271.0						68.5	65.9
	SR148
Nov. 12, 2016		25,870	18,110							634.0
Nov. 13, 2016		27,690	22,150
Nov. 14, 2016		25,390	19,300	7.0	−264.0	706.6	0.2	37.0		417.0	76.8	77.6
Nov. 15, 2016		12,890	9,670	7.3	−283.0					242.0
Nov. 16, 2016		26,850	20,140	6.9	−274.0			36.7	44.5		45.6	50.1
Nov. 17, 2016	scenario 10	25,410	17,280
Nov. 18, 2016	HRT6,	19,870	15,500	6.6	−285.0				40.8	536.0	45.2	41.1
	SRT18
Nov. 19, 2016		18,700	14,590							523.0
Nov. 20, 2016		17,040	13,970	6.8	−231.0						68.4	60.5
Nov. 21, 2016		16,260	11,380	7.3	−246.0			35.0	30.7		63.3	63.3
Nov. 22, 2016		19,620	15,890	6.6						502.0
Nov. 23, 2016		18,590	13,200	7.1	−267.0			36.8	31.8		59.0	56.2
Nov. 24, 2016		20,360	15,070	7.1
Nov. 25, 2016		19,830	16,460	6.7	−267.0
Nov. 26, 2016		20,150	15,110	6.8	−296.0
Nov. 27, 2016	scenario 11	16,980	14,090	6.7
Nov. 28, 2016	HRT18,	18,000	13,860	7.1	−247.0	763.7	0.0	33.7	37.9		63.2	58.0
	SRT36
Nov. 29, 2016		16,980	14,260	7.2						381.0	87.6	81.9
Nov. 30, 2016		16,580	12,440	6.7	−297.0
Dec. 1, 2016		15,670	11,440	6.8				39.0	27.2		79.3	90.1
Dec. 2, 2016	Scenario 12	34,520	24,850	6.6	−314.0					708.0	52.3	59.4
Dec. 3, 2016	HRT24,	33,520	27,490	6.7		772.9	0.0			701.0		58.5
	SRT54
Dec. 4, 2016		34,520	28,650	6.5	−316.0			37.6	43.7		72.0	75.0
Dec. 5, 2016		35,200	24,640	6.7
Dec. 6, 2017		34,520	25,540	7.2	−290.0	677.7	0.1			732.0	79.2	94.3
Dec. 7, 2017	n/a	34,520	26,240	6.7
Dec. 8, 2017	n/a	32,470	25,330	7.0	−260.0	694.2	0.0	30.1	25.8		104.3	98.4
Dec. 9, 2017		34,520	25,540	6.4
Dec. 10, 2017		33,580	25,520	6.6	−297.0	914.8	0.1	28.8	32.5	746.0	65.5	78.0
Feb. 27, 2017
Feb. 28, 2017		8,560		6.6	−208.0			34.8		210.0	57.2	55.5
Mar. 1, 2017		12,230		6.2	−261.0
Mar. 2, 2017	SCENARIO	21,000	4,300	6.7	−240.0			34.0	30.8	460.0	36.8	43.3
	13
Mar. 3, 2017	HRT12,	22,870		6.7	−221.0	850.1	0.2
	SRT24
Mar. 4, 2017	Qr = 200	23,450	19,850	7.0	−259.0
Mar. 5, 2017		24,630		6.9						550.0	49.5	50.0
Mar. 6, 2017		29,420	12,000		−271.0					550.0	50.9	53.6
Mar. 7, 2017		14,600		6.9	−278.0		0.0	31.2	26.7
Mar. 8, 2017		16,520								350.0	46.9	53.3
Mar. 9, 2017		28,410		6.4	−276.0			31.2	35.8
Mar. 10, 2017	Scenario 14	33,580	26,864	6.9	−233.0					660.0	90.1	84.2
Mar. 11, 2017	HRT = 12,	42,590	34,072	6.5	−242.0	675.2	0.0		37.0	860.0	80.4	85.5
	SRT = 42
Mar. 12, 2017	Qr = 100	36,580	29,264	6.4	−238.0
Mar. 13, 2017		36,890	29,512	6.9	−223.0	721.3	0.1	37.3	39.3	750.0	52.1	57.9
Mar. 14, 2017		39,870	30,520	6.4	−297.0
Mar. 15, 2017		37,450		7.6	−282.0
Mar. 16, 2017		38,990	31,000	6.6	−225.0	585.3	0.0	29.9	31.4	750.0	48.4	55.6
Mar. 17, 2017		35,870	28,690	7.1	−174.0	907.6	0.0
Mar. 18, 2017	Scenario 15	34,120	25,410	7.2	−224.0			34.6	38.4
Mar. 19, 2017	H = 18,	33,440	26,890	7.0	−263.0					680.0	90.9	81.2
	H = 48
Mar. 20, 2017	Qr = 200	29,640		7.1	−246.0				30.1	650.0	74.0	83.1
Mar. 21, 2017		29,630		6.7	−243.0
Mar. 22, 2017		32,725	26,540	7.2	−224.0	924.1	0.1	38.2	36.0	710.0	59.0	67.8
Mar. 23, 2017		33,694	26,950	6.6	−282.0
Mar. 24, 2017		32,832		6.7	−263.0			45.5	47.2	610.0	85.5	80.7
May 1, 2017		8,960								230.0	37.7	37.3
May 2, 2017		9,870	7,700	6.9
May 3, 2017	Scenario 16	15,221	11,870	6.6
May 4, 2017	HRT = 12	15,682	15,240	6.7				30.4		320.0
May 5, 2017	SRT = 24	25,200	19,150	6.8	−277.0					540.0	75.4	87.7
May 6, 2017	Qr = 50	24,080	18,780	6.8							89.0	103.5
May 7, 2017		21,840	17,690	6.9	−223.0			33.3	30.4
May 8, 2017		23,520	18,350	6.4	−229.0	576.4	0.1			500.0	85.9	87.7
May 9, 2017		24,360	19,000	6.6	−234.0
May 10, 2017		22,120	16,810	6.6	−137.0	764.0	0.1	36.7	33.5	450.0	95.1	90.6
May 11, 2017		25,200	20,410	6.7	−248.0
May 12, 2017		25,480	19,360	7.2	−212.0			26.1		510.0	45.0	39.5
May 13, 2017		25,200	20,160	6.9	−248.0	462.2	0.0			490.0	59.8	65.7
May 14, 2017		24,292	19,190	7.0	−257.0
May 15, 2017	Scenario 17	21,240	16,350	6.7	−217.0	359.6	0.2	48.5	48.5	410.0	28.7	33.4
May 16, 2017	HRT = 18	25,313	20,250	6.4	−266.0					500.0	78.5	82.6
May 17, 2017	SRT = 24	25,188	20,650			611.2	0.7	43.2
May 18, 2017	Qr = 200	24,479	19,090	6.7	−237.0	57.1		285.0	50.1	450.0	84.3	79.5
May 19, 2017		25,898	20,200							500.0	67.3	59.0
May 20, 2017		28,995	22,040	6.8	−247.0
May 21, 2017		27,767	21,100	7.2	−219.0	454.8	1.0	30.9		560.0	53.9	52.3
May 22, 2017		25,584	19,700
May 23, 2017		26,050	21,100	6.8	−276.0	20.8		48.0	44.5	490.0	51.2	55.7
May 24, 2017	Scenario 18	25,098	19,330		−269.0							54.5
May 25, 2017	H = 18	24,291	19,920	6.8		585.2	1.2			>1225	196.7	172.5
May 26, 2017	S = 36	25,208	19,410	7.2	−233.0
May 27, 2017	Qr = 200	23,847	18,360	7.2	−282.0
May 29, 2017		28,341	22,960	6.1	−218.0
May 30, 2017		21,501	16,770	6.7	−124.0
May 31, 2017		23,385	15,420	6.7	−285.0	704.5	0.1	40.4		490.0	6.7	6.5
Jun. 1, 2017		28,733	22,700	6.6	−256.0
Jun. 2, 2017	Scenario 19	28,219	22,580	6.7	−224.0					590.0	65.0	70.6
Jun. 3, 2017	h = 12	23,755	20,480	7.1	−263.0
Jun. 4, 2017	s = 30	27,691	21,320	6.8	−232.0					590.0	77.7	86.3
Jun. 5, 2017	Qr = 200	29,465	23,280	6.9	−290.0
Jun. 6, 2017		27,381	21,080	6.8	−234.0	311.2	0.2	52.0		560.0	45.9	51.6
Jun. 7, 2017		22,247	17,130	6.8	−146.0
Jun. 8, 2017		26,300	20,510	7.4	−112.0						85.1	86.0
Jun. 9, 2017		26,791	20,900	6.7	−208.0					520.0	89.0	94.7
Jun. 10, 2017		29,057	22,080	6.4	−287.0	416.0	0.0	26.4		580.0
Jun. 11, 2017	RUN 20	25,433	20,600	6.7	−235.0
Jun. 12, 2017	h = 12	33,690	25,940	6.6	−228.0							107.3
Jun. 13, 2017	s = 54	22,378	18,350	6.8	−250.0					678.0	92.7	98.6
Jun. 14, 2017	Qr = 50	23,107	17,560	6.4	−286.0	118.2	0.1	51.3	41.9
Jun. 15, 2017		24,575	19,910	6.1	−252.0						120.4	108.5
Jun. 16, 2017		24,684	19,250	6.6	−240.0					480.0		79.0
Jun. 17, 2017		21,950	17,340	6.6	−215.0	414.3	0.0	34.0	39.7	490.0
Jun. 18, 2017		22,332	17,640	6.5	−272.0
Jun. 19, 2017		23,567	22,480	6.5	−249.0						114.9	103.5
Jun. 20, 2017		28,219	22,010	6.4	−289.0				51.3	869.0
Jun. 21, 2017		24,666	19,490	6.9	−212.0					540.0	121.1	115.3
Jun. 22, 2017		25,894	20,200	7.1	−287.0
Jun. 23, 2017		26,221	20,710	7.0	−242.0	396.0	0.1		26.7			62.4
Jun. 24, 2017	run 21	24,394	19,270	7.2	−258.0					510.0	106.4	107.5
Jun. 25, 2017	H = 18	26,541	20,170	6.8	−235.0					876.0
Jun. 26, 2017	S = 48	31,440	25,150	6.6	−232.0							164.0
Jun. 27, 2017	Qr = 50	25,513	20,670	7.0	−229.0					520.0	79.4	93.4
Jun. 28, 2017		25,913	20,990	7.5	−187.0	745.5	0.0	28.5	33.0	470.0
Jun. 29, 2017		30,413	24,330	7.0	−268.0						145.5	158.2
Jun. 30, 2017		26,970	21,850	7.1	−246.0							167.6
Jul. 1, 2017		30,140	24,110	7.3	−287.0					600.0
Jul. 2, 2017		30,537	23,820	7.2	−232.0	250.3	0.0	44.5	39.1
Jul. 3, 2017		29,820	24,450	6.7	−249.0					570.0	32.3	30.5
Jul. 4, 2017		29,680	24,340	7.1	−244.0
Jul. 5, 2017		30,190	23,250	6.8	−232.0
Jul. 6, 2017		35,875	20,570	7.0	−226.0					740.0	60.5	59.9
Jul. 7, 2017		37,560	29,670	7.0	−142.0	935.9	0.0	28.1	31.6			52.6
Jul. 8, 2017	run 22	36,520	28,850	6.4	−220.0
Jul. 9, 2017	h = 12	35,220	26,770	6.5	−290.0					910.0	47.2	53.6
Jul. 10, 2017	s = 54	30,906	23,490	7.0	−289.0
Jul. 11, 2017	Qr = 100	39,150	32,100	6.8	−292.0	24.2	0.0	49.1	44.3	318.0	82.9	79.1
Jul. 12, 2017		34,960	23,590	7.4	−282.0					630.0
Jul. 13, 2017		37,540	30,030	7.0	−312.0					700.0	80.6	89.6
Jul. 14, 2017		41,160	33,340	6.5	−321.0
Jul. 15, 2017		40,290	33,040	7.0	−310.0	404.2	0.0		60.4	710.0	77.7	68.8
Jul. 16, 2017		40,360	39,980	6.5	−281.0							51.1
Jul. 17, 2017		39,570	32,450	6.7	−219.0					740.0	31.9	30.7
Jul. 18, 2017		40,200	32,160	6.2	−268.0
Jul. 19, 2017		39,650	32,510	6.8	−287.0
Jul. 20, 2017		31,312	23,800	6.4	−282.0	514.6	0.1	74.5	38.2	600.0
Jul. 21, 2017		31,952	30,440	6.5	−237.0					620.0	36.7	36.3
Jul. 22, 2017		31,413	24,500	6.9	−274.0
Jul. 23, 2017	run 23	29,715	23,180	7.0	−242.0						75.0	80.6
Jul. 24, 2017	h = 18	30,862	25,310	7.6	−269.0		0.0			580.0	72.1	70.0
Jul. 25, 2017	s = 54	34,064	26,570	6.7	−213.0			45.1	43.2
Jul. 26, 2017	Qr = 200	31,539	30,650	6.7	−284.0					690.0	61.9	64.5
Jul. 27, 2017		34,156	26,980	6.9	−250.0
Jul. 28, 2017		34,052	27,580	6.7	−218.0	632.8	0.0	51.4	46.7	690.0	79.4	77.1
Jul. 29, 2017		31,762	24,770	6.1	−267.0							73.0
Jul. 30, 2017		29,944	23,060	7.0	−244.0
Jul. 31, 2017		30,406	24,330	7.3	−270.0	425.4	0.0	174.0	38.5	560.0	122.8	122.8
Aug. 1, 2017		32,341	26,200	6.9	−317.0
Aug. 2, 2017		32,100	24,720	6.4	−233.0					680.0	107.6	107.6

APPENDIX
Plug Flow Reactor Effluent
					VFA,						sol.
					mg-		sol.		sol.	NO2 +	NO2 +		TP,	sTP,
		TSS,	VSS,		HAc/	TKN,	TKN,	NH3,	NH3,	NO3,	NO3	Mg,	mg-	mg-	OrthoP,
Date	Scenario	mg/L	mg/L	pH	L	mg/L	mg/l	mg/L	mg/L	mg/L	mg/L	mg/L	P/L	P/L	mg-P/L
Sep. 29, 2016	Baseline
Sep. 30, 2016	Two
	Zone
Oct. 1, 2016	Reactor
Oct. 2, 2016
Oct. 3, 2016
Oct. 4, 2016
Oct. 5, 2016
Oct. 6, 2016
Oct. 7, 2016
Oct. 8, 2016
Oct. 9, 2016
Oct. 10, 2016
Oct. 11, 2016		51.0	34.0
Oct. 12, 2016		620.0	467.0
Oct. 13, 2016		116.0	72.0
Oct. 14, 2016		260.0
Oct. 15, 2016
Oct. 16, 2016
Oct. 17, 2016		480.0
Oct. 18, 2016		320.0
Oct. 19, 2016		190.0
Oct. 20, 2016		85.0	64.0										50.1	46.1	46.3
Oct. 21, 2016		340.0
Oct. 22, 2016		280.0
Oct. 23, 2016		400.0
Oct. 24, 2016		460.0	350.0										78.2	56.5	75.0
Oct. 25, 2016		6600.0	5300.0	6.8								31.0	188.0	67.5	56.6
Oct. 26, 2016	Scenario	1000.0											133.9	60.8	59.5
	7
Oct. 27, 2016	HRT12;	4000.0	3300.0	6.7	49.6								131.0	59.6	58.3
	SRT42
Oct. 28, 2016		4200.0										28.0	164.0	60.1	59.2
Oct. 29, 2016		3980.0	3300.0	6.9	43.2										80.7
Oct. 30, 2016		3340.0
Oct. 31, 2016		3450.0	2980.0	7.0									175.0	80.1	75.4
Nov. 1, 2016		8100.0	6900.0		25.8	536.0	59.8	44.5	40.1	0.4	ND	34.0	204.0		62.8
Nov. 2, 2016		6010.0	5138.6			279.0	36.1	34.6	33.4			36.3	135.0	56.7	63.3
Nov. 3, 2016	scenario	11000.0	9000.0	7.1								33.0	251.0	56.5	59.8
	8
Nov. 4, 2016	HRT9,	7150.0			112.0	575.0	33.2	25.4	23.4	1.5	<0.40		219.0	59.3	58.7
	SRT30
Nov. 5, 2016		9000.0	7470.0									43.2			51.8
Nov. 6, 2016		8000.0			89.0										52.1
Nov. 7, 2016		14750.0	12300.0	7.3		947.0	32.5	26.4	25.6			38.4	347.0	51.2	50.8
Nov. 8, 2016		5500.0			87.1								162.0	61.7	59.2
Nov. 9, 2016		6000.0	3900.0	6.9								33.3	141.0	49.9	69.4
Nov. 10, 2016	scenario	13450.0											348.0	86.5	84.2
	9
Nov. 11, 2016	HRT9,	7210.0	5700.0	132.1	519.5		18.5					41.5	221.0	73.1	72.4
	SRT48
Nov. 12, 2016		6850.0
Nov. 13, 2016		5480.0	4600.0
Nov. 14, 2016		9200.0	7800.0	7.0		768.0	40.1	10.7	9.4	0.1	0.0	39.4	244.0	68.7	78.4
Nov. 15, 2016		4600.0	3600.0	7.3	51.5								240.2		38.8
Nov. 16, 2016		6500.0	10000.0	6.9		1020.0	22.4	11.6	10.9	0.0	0.0	41.2	291.0	67.6	65.9
Nov. 17, 2016	scenario	6500.0	5590.0		63.8	473.4									46.1
	10
Nov. 18, 2016	HRT6,	5870.0		6.5								38.1	196.4	61.0	57.1
	SRT18
Nov. 19, 2016		5870.0	4637.3		59.1	402.8		24.2	25.1
Nov. 20, 2016		6870.0		6.8									218.9	75.0	70.4
Nov. 21, 2016		5980.0		6.9	46.5	658.0	44.7					33.7	180.4	62.1	58.6
Nov. 22, 2016		6680.0	5344.0
Nov. 23, 2016		9850.0			68.2	631.4						35.7			56.8
Nov. 24, 2016		9110.0	7290.0	n/a			n/a	n/a	n/a	n/a	n/a	n/a		n/a	n/a
Nov. 25, 2016		8760.0	7010.0	n/a			n/a	n/a	n/a	n/a	n/a	n/a		n/a	n/a
Nov. 26, 2016		7620.0	6700.0	n/a			n/a	n/a	n/a	n/a	n/a	n/a		n/a	n/a
Nov. 27, 2016	scenario	7430.0	6000.0
	11
Nov. 28, 2016	HRT18,	7000.0		6.6	77.2	741.5	53.0	27.3	26.4	0.0	0.0	37.9	186.7	69.4	67.4
	SRT36
Nov. 29, 2016		7030.0	5600.0										204.5	103.4	98.7
Nov. 30, 2016		6890.0	5510.0	6.6	114.2	713.5	29.7								103.1
Dec. 1, 2016		6710.0										39.4	197.4	102.3	101.2
Dec. 2, 2016	Scenario	13580.0	10860.0												71.6
	12
Dec. 3, 2016	HRT24,	12590.0	10070.0	6.7	116.4	765.2	42.5	31.2	30.0	0.1	0.0				81.2
	SRT54
Dec. 4, 2016		13480.0	10860.0									40.9	314.2	87.4	86.2
Dec. 5, 2016		13680.0	10700.0
Dec. 6, 2017		13200.0	10900.0	6.5	95.4	684.5	42.8	25.2	25.3	0.0	0.0	45.2	317.4	113.4	112.3
Dec. 7, 2017	n/a	12500.0
Dec. 8, 2017	n/a	12750.0	10890.0	6.9	110.5	746.5	51.0	35.1	30.2	0.0	0.0	28.4	328.5	95.4	94.4
Dec. 9, 2017		14270.0	11420.0
Dec. 10, 2017		13580.0		6.4	124.6	905.7	49.5	19.8	14.3	0.0	0.0	30.7	310.5	103.1	101.3
Feb. 27, 2017		43.0	31.9		85.6										56.8
Feb. 28, 2017		112.0										39.1			51.4
Mar. 1, 2017		93.0	30.0		98.7
Mar. 2, 2017	SCENAR-	72.0	51.0	6.7								31.8	29.2	28.0	39.7
	IO 13
Mar. 3, 2017	HRT12,	238.0			124.0	759.0	38.0	29.5	29.0	0.2
	SRT24
Mar. 4, 2017	Qr = 200	142.0	115.3									33.2			54.5
Mar. 5, 2017		181.0			119.2							35.4			51.0
Mar. 6, 2017		312.0			121.0	642.5	35.7								36.2
Mar. 7, 2017		217.0	158.4	6.9	87.6			26.0	28.1	0.0	0.0	30.3	32.0	25.4	54.0
Mar. 8, 2017		220.0	160.0										48.5		62.0
Mar. 9, 2017		369.0		6.9	141.0							32.5	36.9		45.2
Mar. 10, 2017	Scenario	412.0													85.9
	14
Mar. 11, 2017	HRT = 12,	178.0	143.0	6.7	152.0	726.0	42.7	31.2	28.4	0.0	0.0	39.4	50.0		81.4
	SRT = 42
Mar. 12, 2017	Qr = 100	454.0													105.0
Mar. 13, 2017		1690.0	1225.3		480.0	736.0	33.5	36.5	29.8	0.0	0.0	40.5	87.5	70.2	64.3
Mar. 14, 2017		690.0		6.9								29.3		28.6	35.6
Mar. 15, 2017		485.0			103.5										79.4
Mar. 16, 2017		218.0	162.6	6.6		597.2	31.4	17.5	23.4	0.0	0.0	29.3	45.2		64.7
Mar. 17, 2017		223.0			93.5	965.5	64.4	25.7	24.5	0.0	0.0
Mar. 18, 2017	Scenario	178.0	125.6	6.8								38.4	86.4
	15
Mar. 19, 2017	H = 18,	245.0			76.9										90.2
	H = 48
Mar. 20, 2017	Qr = 200	336.0	234.9	6.7								39.2	75.4	91.2	88.4
Mar. 21, 2017		209.0													84.6
Mar. 22, 2017		185.0	142.3	7.1	128.5	825.1	63.5	19.6	27.4	0.1	0.0	36.7	84.2	96.4	94.2
Mar. 23, 2017		142.0					0.0								97.1
Mar. 24, 2017		197.0	154.1	7.0	108.0							42.1	78.5	91.1	87.7
May 1, 2017		24.0	18.0					0.0	0.0			50.0	88.0	60.2	60.2
May 2, 2017		67.0	51.0	6.4		654.2	46.7	22.6	20.8	0.0	0.0		84.2
May 3, 2017	Scenario	62.0	49.0	7.0
	16
May 4, 2017	HRT = 12	265.0	201.0	6.9	86.5							33.0	94.2
May 5, 2017	SRT = 24	84.0	66.0	7.0		851.2	60.8	23.0	22.1	0.0	0.0			71.1	79.0
May 6, 2017	Qr = 50	96.0	75.0	6.4											88.5
May 7, 2017		237.0	190.0	6.4	85.5							32.0	75.5	84.1	80.9
May 8, 2017		177.0	133.0	6.6		554.2	36.9	19.8	18.4	0.0	0.0				76.3
May 9, 2017		87.0	70.0	7.1
May 10, 2017		132.0	99.0	6.9	135.7	694.5		23.2	23.9	0.0	0.0	36.0	53.4	138.5	133.2
May 11, 2017		98.0	79.0	6.5		495.2		17.7	17.2	0.0	0.0
May 12, 2017		92.0	72.0	6.6	186.0	884.0		24.6	21.9	0.0	0.0	29.0	480.0	73.5	68.1
May 13, 2017		203.0	158.0	6.8		502.4	29.6	15.2	13.5	0.0	0.0				73.0
May 14, 2017		201.0	147.0	6.5
May 15, 2017	Scenario	102.0	74.0	7.0		352.5	22.0	11.8	11.9	0.2	0.0	49.0	96.4	46.6	54.8
	17
May 16, 2017	HRT = 18	86.0	66.0	6.6	99.0							45.0			70.0
May 17, 2017	SRT = 24	57.0	44.0	7.1		657.2	38.7	18.8	18.4	0.1	0.0	48.0	79.5
May 18, 2017	Qr = 200	61.0	49.0	7.0										65.1	70.0
May 19, 2017		81.0	66.0	6.9											81.2
May 20, 2017		43.0	35.0	7.1	89.5									71.1	68.4
May 21, 2017		114.0	88.0	6.9		425.0	26.6	11.2	10.6	0.1	0.0	30.0	87.0		79.3
May 22, 2017		83.0	64.0	6.7											164.0
May 23, 2017		500.0	38.0	6.7		548.2	27.4	14.4	13.8	0.0	0.0	50.0	81.0	72.6	83.4
May 24, 2017	Scenario	85.0	68.0	6.9	68.5										199.7
	18
May 25, 2017	H = 18	117.0	87.0	7.0		585.2	27.9	16.3	15.5	0.0	0.0	49.0	92.0	106.6	128.4
May 26, 2017	S = 36	213.0	160.0	7.0											79.8
May 27, 2017	Qr = 200	232.0	174.0	7.0											155.2
May 29, 2017		117.0	90.0	7.0
May 30, 2017		101.0	75.0	6.8
May 31, 2017		95.0	72.0	7.1	97.5	652.3	36.2	21.7	21.9	0.0	0.0	40.0	81.0		89.7
Jun. 1, 2017		149.0	118.0	6.7			0.0
Jun. 2, 2017	Scenario	312.0	253.0	6.5										101.1	105.3
	19
Jun. 3, 2017	h = 12	147.0	115.0	6.9	105.5
Jun. 4, 2017	s = 30	253.0	190.0	6.7											107.9
Jun. 5, 2017	Qr = 200	53.0	43.0	6.7											96.4
Jun. 6, 2017		176.0	128.0	7.0		324.2	16.2	8.5	7.8	0.2	0.0	50.0	101.0	84.6	84.6
Jun. 7, 2017		288.0	219.0	7.0
Jun. 8, 2017		157.0	118.0	7.0											116.2
Jun. 9, 2017		232.0	176.0	7.2	137.5									106.7	108.9
Jun. 10, 2017		399.0	323.0	7.1		452.2	22.6	13.7	14.2	0.0	0.0	29.0	77.0
Jun. 11, 2017	RUN 20	678.0	515.0	6.8
Jun. 12, 2017	h =12	985.0	788.0	6.7	96.5									137.5
Jun. 13, 2017	s = 54	4780.0	3824.0	6.6										115.5	140.8
Jun. 14, 2017	Qr = 50	3540.0	2584.0	6.4		128.5	5.8	3.6	3.6	0.0	0.0	47.1	95.0
Jun. 15, 2017		2790.0	2232.0	6.7	87.5									140.3	144.6
Jun. 16, 2017		1190.0	893.0	6.4											112.8
Jun. 17, 2017		1970.0	1517.0	6.8		445.5	20.3	14.4	14.4	0.0	0.0	38.2	94.0
Jun. 18, 2017		2390.0	1769.0	6.7	88.6
Jun. 19, 2017		2360.0	1746.0	6.5											139.8
Jun. 20, 2017		2080.0	1581.0	6.4		521.2	32.6	17.4	16.0	0.0	0.0	46.2	100.0	126.2	137.2
Jun. 21, 2017		2090.0	1588.0	6.7											138.9
Jun. 22, 2017		326.0	245.0	6.7	135.5
Jun. 23, 2017		215.0	157.0	6.7		412.5	21.7	11.8	12.0	0.0	0.0	29.0	90.0	108.2	97.5
Jun. 24, 2017	run 21	890.0	703.0	7.0											101.4
Jun. 25, 2017	H =18	1270.0	965.0	6.4	152.5
Jun. 26, 2017	S = 48	987.0	740.0	6.8										159.2	159.2
Jun. 27, 2017	Qr = 50	578.0	422.0	6.8										119.8
Jun. 28, 2017		286.0	217.0	6.6	113.8	745.5	39.2	22.6	21.0	0.0	0.0	32.0	91.0
Jun. 29, 2017		241.0	190.0	6.8											134.1
Jun. 30, 2017		266.0	215.0	6.8										132.7	139.7
Jul. 1, 2017		259.0	194.0	6.6	124.2										74.6
Jul. 2, 2017		540.0	432.0	6.6		255.4	15.0	8.0	6.9	0.0	0.0	42.0	102.0	111.0	105.7
Jul. 3, 2017		625.0	481.0	6.7										47.9	56.4
Jul. 4, 2017		340.0	258.0	6.5	87.5
Jul. 5, 2017		410.0	299.0	6.4
Jul. 6, 2017		2630.0	1920.0	6.4											89.4
Jul. 7, 2017		6942.0	5484.0	7.1	125.7	985.2	61.6	26.6	26.6	0.0	0.0	29.0	98.0	67.9	64.1
Jul. 8, 2017	run 22	5037.0	3778.0	6.6
Jul. 9, 2017	h = 12	4727.0	3593.0	6.9	143.5										86.4
Jul. 10, 2017	s = 54	3569.0	2855.0	6.6										113.0	109.7
Jul. 11, 2017	Qr = 100	8148.0	6111.0	6.8	135.8	324.2	16.2	8.5	8.8	0.0	0.0	49.5	81.0	84.9	78.6
Jul. 12, 2017		3068.0	2454.0	6.8		258.2	12.9								83.9
Jul. 13, 2017		9278.0	7051.0	6.4	96.1									85.1	89.6
Jul. 14, 2017		9451.0	7372.0	6.8
Jul. 15, 2017		9330.0	7277.0	6.9	85.4	425.5	26.6	13.3	13.0	0.0	0.0	55.4	98.0	105.5	114.7
Jul. 16, 2017		7294.0	5471.0	6.6											68.1
Jul. 17, 2017		5311.0	3930.0	6.7	78.1										51.2
Jul. 18, 2017		4783.0	3874.0	6.5
Jul. 19, 2017		5772.0	4271.0	6.6
Jul. 20, 2017		852.0	690.0	6.9	114.2	485.5	27.0	15.7	14.3	0.0	0.0	39.4	101.0
Jul. 21, 2017		1177.0	883.0	6.6										46.0	48.4
Jul. 22, 2017		2611.0	1932.0	6.8
Jul. 23, 2017	run 23	4107.0	3162.0	6.7	119.5									64.5	76.8
Jul. 24, 2017	h = 18	4444.0	3511.0	6.8											68.6
Jul. 25, 2017	s = 54	1395.0	1018.0	6.8	135.2	596.7	39.8	16.6	16.1	0.0	0.0	48.5	77.0
Jul. 26, 2017	Qr = 200	1800.0	1422.0	6.8										93.9	94.8
Jul. 27, 2017		1844.0	1401.0	6.6
Jul. 28, 2017		1626.0	1236.0	6.7	79.3	652.4	34.3	22.5	20.3	0.0	0.0	47.2	97.0	113.2	124.4
Jul. 29, 2017		1821.0	1384.0	6.9											119.7
Jul. 30, 2017		638.0	472.0	6.9	148.9
Jul. 31, 2017		4589.0	3488.0	6.8		452.5	30.2	12.2	11.3	0.0	0.0	40.5	85.0	136.4	136.4
Aug. 1, 2017		1284.0	1002.0	6.7	152.1										132.2
Aug. 2, 2017		1797.0	1438.0	6.9										145.6	131.2

APPENDIX
Complete Mix Reactor Effluent
		Actual												sol.
		HRT						VFA,					NO2	NO2
		&						mg-		sol.		sol.	+	+		TP,	sTP,	OrthoP,
	Sce-	SRT,	T,	TSS,	VSS,			HAc/	TKN,	TKN,	NH3,	NH3,	NO3,	NO3,	Mg,	mg-	mg-	mg-
Date	nario	Hr	F	mg/L	mg/L	pH	ORP	L	mg/L	mg/l	mg/L	mg/L	mg/L	mg/L	mg/L	P/L	P/L	P/L
Oct. 20,		23.5	71															52.1
2016
Oct. 21,		24.5	75
2016
Oct. 22,		24.4	78															49.7
2016
Oct. 23,		24.4														182	55.7	46
2016
Oct. 24,	sce-	25.9	72															48.5
2016	nario
	1:24
Oct. 25,		20.6	71	8,880	6,100										33.4	187	59.7	55.5
2016
Oct. 26,		23.1	68					101.5	773	49.5	13.6	12.2	0	0				56
2016
Oct. 27,		22.5	69															58.1
2016
Oct. 28,		22.1	68					97.5	801	39.4	12.1	10.7	ND	0	30.9
2016
Oct. 29,		16.1														229	94.1	58.275
2016
Oct. 30,		16.0	71
2016
Oct. 31,		16.7		7,200	6,400			94.4	656	75.3	25.4	24.6	ND	0	36.9	231	96.3	60
2016
Nov. 1,		15.2				7	−207		615	34.5					37.1	186	60.5	51.28
2016
Nov. 2,	sce-	15.1	74	8,300	6,800	7	−220								33.5	200	49.8	45.12
2016	nario
	2: 16
Nov. 3,		20.3	73			7	−209	34.3	708	31.9	34.7	33.7	0	0			70	47.5
2016
Nov. 4,		16.0	74	9,320	7,260	7	−198								28.4			51.8
2016
Nov. 5,		15.3	75			7	−205		1910	18.5	15.2	12.7						42.3
2016
Nov. 6,		15.1	72	8,600	7,100	7	−178								31.8			57.1
2016
Nov. 7,		11.3	74	8,520		8			537.2	40.9	10.4	9.7	0	0		208	59.7	45.3
2016
Nov. 8,		12.7		9,500	7,000	7	−194	89								218	57.4	44.9
2016
Nov. 9,		12.6		8,940		7									35.4	211	53.5	52.8
2016
Nov. 10,	sce-	13.0	72	9,670		7	−182		530.8	37.2	9.7	22.36	0	0				40.8
2016	nario
	3: 12
Nov. 11,		13.2	73					86.4							32.4			41.7
2016
Nov. 12,		13.6		8,200
2016
Nov. 13,		12.2		7,700	6,500	7	−169		643	18.9	15.5	14.8	0	0		219	66	37.2
2016
Nov. 14,		12.6	75			7	−158	77.3										38.2
2016
Nov. 15,		11.7	74	6,400	4,800	7	−163	112.6	498	24.4	8.83	8.53	0	0	35.9	167	44.3	41.9
2016
Nov. 16,		6.2	75															19.4
2016
Nov. 17,		5.6	76						584.2	43.7	9.5	8.7	0	0				18.6
2016
Nov. 18,		5.9		9,850	7,280		−140	86.1							39.1	255.24	14.8	13.2
2016
Nov. 19,	Sce-	6.1				7	−155											11.8
2016	nario
	4: 6
Nov. 20,		6.1	74															16.3
2016
Nov. 21,		6.0	76	10,020	7,890	7	−178		610.5	45.8	7.9	7.6	0.2	0	34	258	15.4	15.5
2016
Nov. 22,		6.2	72			7	−168											13.8
2016
Nov. 23,		34.8				7		124.2	620.6	46.2	9.3	9.1	0	0	36.7			48.2
2016
Nov. 24,		38.8	75		n/a	n/a	n/a
2016
Nov. 25,		35.0	75		n/a	n/a	n/a
2016
Nov. 26,		35.5	73		n/a	n/a	n/a
2016
Nov. 27,		35.4	75
2016
Nov. 28,	Sce-	35.9	71	8,920	7,260	7	−185	114.6	549.5	41.2	7.4	7	0	0	46.1	191.7	60.7	58.7
2016	nario
	5: 36
Nov. 29,		37.3	76															75.6
2016
Nov. 30,		36.6	76	10,320	8,340	7	−195									254.1	64.1	76.4
2016
Dec. 1,		36.0	74			7		108.4	614.8	44.9	10.4	9.4	0	0	34.2			89
2016
Dec. 2,		47.4	73	10,030	7,890											267.1	64.6	59.4
2016
Dec. 3,		48.8	76			7	−212											70.2
2016
Dec. 4,		47.5	76	10,300	8,140	7	−224	139.7	600.1	44.1	6.5	6.1	0	0	49.5	234.1	78.1	74.5
2016
Dec. 5,		48.2	72			7	−214
2016
Dec. 6,	Sce-	47.6	75	10,950	8,540			142.1							48.1	261.4	90.1	86.7
2017	nario
	6: 48
Dec. 7,		47.7	75	11,040	8,800	7	−234
2017
Dec. 8,		48.0	73						579.4	43.7	12.4	11.2	0	0	33.4	290.1	84.3	82.4
2017
Dec. 9,		49.1	68	9,870	7,740	7	−228	140.8
2017
Dec. 10,		47.8	70	10,430	8,120													87.6
2017

Claims

1. A method of phosphorus and/or magnesium removal comprising: a. providing an influent stream to a plug flow reactor, wherein the influent stream is a waste activated sludge and/or activated sludge mixed liquor;b. allowing the influent stream to pass through at least two zones of the plug flow reactor;c. passing the influent stream through a first zone, wherein concurrent thickening and denitrification occurs; thend. passing the influent stream though a second zone, wherein further thickening, volatile fatty acid production, and/or phosphorus and/or magnesium release occurs; thene. passing the influent stream through a final zone, wherein solids separation occurs; andf. removing phosphorus and/or magnesium from the influent stream, wherein the removal is performed by holding the influent stream in the reactor for a defined period of time so that the hydraulic retention time of the reactor is decoupled from the solids retention time of the reactor, and wherein the phosphorus and/or magnesium is released from phosphorus accumulating organisms;g. removing a phosphorus and/or magnesium enriched effluent stream from the plug flow reactor.

2. The method of claim 1, wherein the first, second, and final zones are separated by baffles or a wall.

3. The method of claim 1, wherein the plug flow reactor comprises a reactor float configured to remove solids from the top of any combination of the zones.

4. The method of claim 1, further comprising removing solids from the first, second, and/or final zone and recycling the solids back into the first zone.

5. The method of claim 1, wherein the hydraulic retention time of the reactor is between about 4 and about 20 hours.

6. The method of claim 1, wherein the solids retention time of the reactor is between about 16 and about 48 hours.

7. The method of claim 1, wherein the phosphorus and/or magnesium is released in an amount from about 10% to about 60%.

8. The method of claim 1, wherein step e further comprises thickening the separated solids.

9. The method of claim 8, wherein the thickening solids step produces a thickened solids concentration between approximately 1% and 6% and is removed by a solids recycle and/or effluent stream.

10. The method of claim 1, wherein the method is free of the addition of supplemental chemicals and/or readily biodegradable compounds.

11. The method of claim 1 further comprising treating the effluent stream in an additional zone.

12. The method of claim 11 wherein the additional zone recovers phosphorus.

13. The method of claim 11 wherein the additional zone thickens solids.

14. The method of claim 11 wherein the additional zone separates solids.