Method and Apparatus To Implement A Managed Distributed Wastewater Process

Abstract

The method of the managed sewer is a Netcentric distributed process that is managed in real-time and implemented through several apparatuses that enable the low capital cost and low installation cost of a smaller diameter pipe (smaller than typically used in gravity flow systems). The apparatuses enable the method of managing the grinding, pumping and staging processes to optimize the effectiveness of the collection process through the small pipe and increase system efficacy by using the pumping and transport action of the material in the pipe as part of the process activity.

Claims

1) A method to optimize the efficacy of waste transfer through small diameter pipe in a random grid source field through the real-time management of the system resources including pumps, valves and buffer tanks. a) Where the method sequentially schedules pumping full or fractionally full tanks, maximizing the transfer efficacy. b) Where the method effectively improves system performance by transferring products which are partially refined, purified, cleaned or treated by embedded processes that benefit from the agitation and dwell times of the pumping and buffering activities. c) Where sufficiently fast control and data processing provides real-time monitoring and management to start and stop sequential flows such that the flow at the terminus appears constant without disruptions. d) Where the movement of a tainted product is kept isolated by the movement of a buffer fluid ahead and behind the product transfer. e) Where a tainted product is refined or processed to a benign product for reuse throughout the system within the field of tainted product collection. f) Where the reprocessed product is used within the system as a buffer fluid to isolate and move the tainted product forward through the pumped piping system. g) Where the reprocessed product is used as a carrier of an additive, either chemical or physical or both, which may aid in the reprocessing of the tainted product and benefit by the agitation of the pumping and flowing activities during the time spent in the piping system.

2) The method benefits from the apparatus of a locally managed, remotely scheduled buffer tank pumping station that is capable of locally injecting a product-modifying additive, grinding and pumping the tainted product and/or mixing the flow with either the locally produced additive or the delivered additive-enhanced reprocessed product or both. a) Where the locally managed, remotely scheduled tank pumping buffer station includes embedded processor, netcentric control and communication implemented in a robust, redundant architecture. b) Where the locally managed, remotely scheduled tank pumping buffer station is powered by alternating current distributed from the terminus sewage processing facility. c) Where the apparatus is capable of generating and dispensing oxygen and/or ozone or other ionic products created from atmospheric air or from reprocessed product. d) Where the apparatus can create a sterile product either by mixing the tainted product with oxygen and/or ozone or other ionic products as part of the grinding and pumping activity or by mixing the tainted product with chemically and/or physically treated reprocessed product or both. e) Where the locally managed apparatus under remote control can be commanded to grind/pump/treat specific volumes sequenced at specific times to be discharged at specific pressures. f) Where the locally managed pumping/grinding apparatus is designed and built with a fully redundant hardware, communication and processing capability that can be remotely switched through redundant channels.

3) The apparatus of a remotely controlled switching device to enable the effective use of redundant hardware, communications and control capability that simultaneously monitors current flow on both the load and the neutral circuit of the AC power supply for over-current, Ground-Fault or Arc-Fault conditions. a) Where the apparatus has a built-in AC current magnitude measurement capability to detect, manage and report excessive current flow. b) Where the apparatus has a built-in AC current magnitude measurement capability to detect, manage and report conditions of Ground-Faults. c) Where the apparatus has a built-in magnitude and frequency measurement capability to monitor the AC supply for indications of Arc-Fault conditions and to report and manage such faults.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

[0028] FIG. 1 reveals a typical residence or pick-up point with local buffer tank and pumping system along with network and piping connections.

[0029] FIG. 2 shows a layout of a typical residential community of pick-up points, processed water storage tanks, wastewater, processed water, power and network piping and conduits.

[0030] FIG. 3 presents a process distribution and functional flow diagram.

[0031] FIG. 4 shows background processing functions and data storage references in support of the distributed processes implementing the control and process functionality of the Managed Sewer shown in FIG. 3.

TABLE-US-00001 Reference Markings Description 1 Purple water pipe for agricultural and fire suppression application 2 Low-voltage communications, including dedicated fibers for Internet, broadcast television and local network connectivity 3 AC Power distribution 4 Wastewater out, ground through macerator pump, mixed with high floc affinity polymer and Ozone treated 5 Property Line isolation/distribution equipment (PLI) 6 Macerator/grinder pump (typical) low pressure, 45 psi nominal 7 Single station buffer tank and equipment housing (SSBT) 8 Residence wastewater output carried in 4-inch (typical) pipes 9 Purple water output faucet 10 Internet router and television antenna cable 11 Residence (typical) 12 Treated (processed) water with high affinity floc polymer added 13 Access to outside air though check valve 14 Ozone injectors 15 Ozone generator 21 Internet Cloud Interface 22 Wastewater Processing facility and Power Generation/ Distribution 23 Sewer System Network Operations Center (NOC) 24 Purple Water buffer storage tank (e.g., fire water storage) 25 Fire Hydrant 30 Smart System branch circuit valve (SSBV)

DETAILED DESCRIPTION OF THE INVENTION

[0032] The method of the managed sewer is a distributed process which transforms sewer wastewater to a sterile benign product without using biological reduction, therefore eliminating the creation of any methane and/or hydrogen sulfide.

[0033] The managed sewer method is enabled by a series of unique apparatus that deploy novel technologies along the distributed piping path. As shown in FIGS. 1 and 2, the Single Station Buffer Tank and equipment housing (SSBT) 7 receives the waste material from the residence 11, or commercial / industrial facility. The SSBT 7 serves several functions. The SSBT enables the immediate sterilization of the wastewater, eliminating any hydrogen sulfide and/or methane production during the wastewater transportation or treatment process. The SSBT provides a storage buffer allowing the optimized pumping of material to maximize the utility of the small diameter connection pipe. The waste material 8 is first ground to a fine particle by the macerator pump 6. Simultaneous with the pumping and grinding action is the injection of ozone 14 to kill all pathogens in the waste material. The ozone generator 15 uses atmospheric air collected through a directional valve-equipped duct 13. During the pumping action the waste material 8 is diluted with high floc affinity polymer-laced reprocessed water 12 incorporating a disinfectant and sent to the buffer tank from the central processing facility 22.

[0034] The backbone of the managed sewer system is the enabling network. The sewer system network is a truly integrated utility that enables the new technology sewer process and also delivers Internet and local television through a master channel cable TV antenna system as a component of the sewer processing facility. These additional services are distributed to the sewer subscribers as a sewer feature. The delivered features significantly support the value received by the subscribers.

[0035] The managed sewer process is implemented through a series of embedded processors and smart switches (disclosed in Provisional Patent application No. 62/354,630), located within the Single Station Buffer Tank and equipment housing SSBT 7, the Property Line Isolation/distribution equipment (PLI) 5 and the Smart System Branch circuit valves (SSBV) 30. An important aspect of the managed sewer method is the apparatus of the smart switches which detect and alert the Network Operations Center (NOC) 23 as to any Ground Fault, Arc Fault or Over-Current condition occurring in any individually switched embedded electrical hardware.

[0036] Each of the embedded pumps or valves is either redundant in function by co-located replicated hardware or is functionally replicated in the extended system architecture. This feature enables continued operation and the dispatch of field repair as a normal operational activity. Additionally, the SSBT 7, the PLI 5 and the remote valves SSBV 30 contain a plurality of sensors including valve position status, current monitoring of all motors and switches, flow rates and pressures. The local processing of these sensors provides full system and specific device status and characterization to the NOC 23. The incorporation of redundant distributed processors enables a level of autonomous control to continue operations when communication is slow or problematic.

[0037] The method of the managed sewer incorporates the optimization of the installed facility by using a consistently smaller pipe (versus traditional gravity flow systems) which reduces initial capital costs as well as installation costs, by enabling the use of horizontal drilling or narrow trenching to install separate dedicated ducts for power, wet products and low-voltage communications. The installed ducts provide routing for the pipes containing the remotely treated wastewater 4 collection, AC power distribution 3, processed water 1 (i.e., purple pipe water) for agriculture and fire suppression, processed and prepared water 12 for use as a distributed floc collection aid, and fiber optic cables 2 distributing system network, Internet and broadcast television to the sewer system clients.

[0038] Key to the reliability and robust operation of the managed sewer is the controlled distribution of AC power 4. The system uses grid-supplied power as primary resource and self-generated power as back up or as a supplement when required. Power is routed for distribution from the sewer processing / power routing / generating facility 22 to the NOC 23 and out to the system wide switching 5 nodes, pumping nodes 7 and the system branch nodes 30.

[0039] The system does not rely on power delivered from the subscribing residences. All power 3 required to operate the system is under system control and management. As such, the system of distributed power 3, with its own back up power, is more resilient than a system relying on client-sourced power at the connecting nodes.

[0040] The managed sewer system is networked on an isolated fiber optic network 2 which enables managed control from a redundant set of servers located in the NOC 23.

[0041] Although the Internet Cloud connection 21 is connected to the NOC 23, isolation and buffering through a network router and system firewall 10 are provided as an interface for Internet distribution to the subscribing clients' residences 11.

[0042] The managed wastewater treatment system makes optimum use of smaller piping by exploiting the capabilities of the SSBT 7 and the functionality of the PLI 5. The SSBT 7 is equipped with capacitive sensors which accurately measure the level of the wastewater collection in the tank. By controlling the valves of the PLI 5, the process controllers as commanded by the NOC 23 are used to isolate a direct pumping line from an individual SSBT 7 macerator pump 6 to the process facility 22. The control computers in the NOC 23 analyze in real-time the system-wide wastewater levels in the aggregate 7 tanks and develop adaptive schedules to distribute the pumping activity over the full day. This is a process which anticipates any surge requirements, by dissipating the volume over the smaller pipes and a longer flow time.

[0043] Unlike conventional gravity flow collection or low pressure collection sometimes used in traditional biological processing systems, the managed sewer wastewater collection system delivers the wastewater 4 to the processing center 22 with the solids ground to a fine particle size by the macerator pump 6, treated with high floc affinity polymers 12 and disinfected with pathogen-killing ozone 14.

[0044] The method is built on a set of predefined pumping maps and schedules for each branch pipe circuit 30 such that the most distant buffer tank 7 will be pumped first and flushed with clean processed recycled water 12. The clean processed recycled water is buffered in large storage tanks 24. These tanks provide a field reserve for those communities where this system provides reservoir fire suppression water 24 for the locally distributed fire hydrants 25. These large buffer tanks can also be fitted with output faucets 9 to support legitimate agricultural use. The SSBV 30 also meters the returned processed waster 1 (e.g. purple pipe water).

[0045] The wastewater 4 will be pumped from the farthest buffer tank 7 and back-filled with processed water 12 to the smart system branch circuit valve SSBV 30 or the property line instrument and valve PLI 5. All valves, 5, 7 and/or 30 which have been pumped clean will then be closed and the next buffer tank 7 in line will be pumped and the process repeated until the entire branch pipe system 30 is filled with clean processed water 12.

[0046] When the most distant branch piping circuit 30 is pumped and filled with clean processed water 12, the next most distant branch circuit 30 will be pumped using the specific pumping map created for that branch circuit. This process is repeated until all of the branch circuits 30 have been pumped.

[0047] The method builds on a live data map supported by the high-speed managed sewer system local network 2. The data map includes SSBT 7 fill factors, which are the processed histories of each individual collection point be it a residence or an industrial/commercial facility. The method uses this data to compute pipe loading and sequential scheduling as a basis for controlling and sequencing the property line isolation valves PLI 5 and the smart system branch circuit valves SSBV 30. Included in the scheduling analysis is the computation of the quantities of prepared reprocessed water 12 allocated to each SSBT 7. The prepared reprocessed water 12 is used to flush each SSBT 7 and chase or flush each connected pipe route used to move the wastewater 4 from the SSBT 7.

[0048] The method is characterized in the process flow diagrams FIGS. 3 and 4. The method is implemented as a series of data-driven processes in three classes. The physical class is run uniquely at the completion of construction to set up the table of physical resources 670, 635. This includes processes 634 that translate pipe lengths and diameters into storage volumes and pumping pressures and flow rates into volume rates. From these data tables, process 641 from the physical class computes fractional and total flows to pump out the wastewater and flush out a SSBT 7 and fill the connecting pipe with treated reprocessed water 12. Processes 650 and 651 of the physical class calculate the SSBT 7 sequence maps within a branch circuit as a function fill volumes for each SSBT 7 in the branch. Additionally, process 640 calculates the optimal branch circuit pumping order to minimize pumped volumes of treated reprocessed water and pumping energies.

[0049] The timing tables of process 660 build on the data of the other processes of the physical class. Process 660 builds the specific timing tables that provide supplemental structure to the real-time control models of the data-driven class of processes. The timing tables of process 660 define the backstop limits to the functional processes that execute to move wastewater from the SSBT 7 to the processing facility 22 in response to demand requirements. The SSBT 7 uses a capacitive sensor strip (not shown) embedded in the polyethylene housings and shielded from ground water on the soil side of the tank. The strip extends down the side of the tank which allows the local processor to make precise measurements as to the fill level of the SSBT 7. The method uses the timing schedules of process 660 to drive the appropriate pumping cycle, considering the fill rate of each SSBT 7, and preconditions the ozone generator 15 of each SSBT 7 to charge the ozone injectors 14 to deliver ozone to the grinding/pumping cycle of each macerator pump in conjunction with emptying the SSBT 7. As the tank level falls, the data-driven class process 661 will then release a measured flow of treated reconditioned water 12 to the SSBT Ito flush the grinder/pump machinery and to back-fill the branch piping from this particular SSBT Ito the PLI valve 5 and possibly to the SSBV 30, depending on the pumping sequence.

[0050] Processes 610 and 620 represent the concurrent class of processes that run at startup 600 and then periodically in the background to provide continuous status data on the operability of the communications and embedded processor resources. Such processes also provide evaluation data on the wastewater processing facilities by monitoring residual pressure decay in the pressurized pipe segments left full of treated reprocessed water between operational cycles.

[0051] The principal program loop 605 supporting the managed sewer method is characterized as the data-driven class of processes beginning with process 606 which evaluates and responds to alarm conditions from the class of processes 625 which deals with electrical circuit safety alarms. These processes automatically break down equipment failures to a set of general testable conditions related to electrical power distribution and are important because of life safety considerations. These processes also facilitate switching to backup hardware to maintain operational consistency.

[0052] Data-driven process 617 accepts the backup hardware into the normal equipment operational schedules or drives the search for the cause of the alarm condition to evaluate the communications channels. This search is facilitated by processes 671, 672, 673 and 674 to attempt a communications workaround using local channels between remote processors as a means of communicating to peripheral devices to which direct communications has failed.

[0053] Processes 618, 661 are the main functional data-driven processes of the data-driven process class. These processes perform the work of servicing the remote wastewater tanking 7 in the various embodiments of single tank, branch circuit with multiple tanks or multiple branches with multiple tanks. These processes make use of the equipment schedules created by the physical class of processes and the timing and application tables of the concurrent class of processes to optimize the managed sewer system.