Electronic Water Distribution Center With Electronic Drain Network

Abstract

The Apparatus is provided to electronically monitor, determine, and/or control the pressure and/or flow for a supply of water in a network, furthermore, the apparatus is provided to electronically monitor, determine, and/or control the pressure and/or flow of waste water flowing through a drain pipe in a network. The apparatus utilizes a plurality of controllers, Electronic Drain Stoppers devices, sensory inputs, and motorized valves and/or solenoid valves to fully control and/or monitor the flow of water, presence of water, water pressure, water temperature, water drainage, and/or TDS levels/contaminants in the water. The apparatus utilizes one or more central and/or local controllers to electronically control and/or monitor a user's entire home and/or business pipe lines in an online and/or offline network. The Apparatus is a universal device that can connect to any supply of water.

Description

BACKGROUND OF THE INVENTION

Today, we as humans are constantly innovating new ways to make our lives easier while also focusing on sustainable development. The key to excellent water and/or wastewater distribution is to distribute the water and/or waste water with ease, quickly, efficiently, and mostly, to distribute water precisely without wasting water. Those are the key functions of the “Electronic Water Distribution Center with Electronic Drain Network.” The apparatus (EWDC with EDN) is an electronic device that controls and/or monitor the contaminants, temperature, flow, and/or pressure of water which flows through a local water supply. The apparatus (EWDC with EDN) is constructed with and electronic drain stopper device which allows the user to control and monitor the temperature, flow, and/or pressure of waste water which flows through a local drain pipe assembly. The apparatus (EWDC with EDN) has many functionalities. The said apparatus can output water by utilizing the input system on one of the central controller and/or the said apparatus can output water by utilizing the input system upon one of the local controllers. The said apparatus also can save repetitiously used water depths for anytime access (ex: washing dishes or bathing). The user can auto-fill saved water depths with automatic cut-off. The EWDC with EDN also has a measurement system to output selected volume sizes a plurality of volume sizes by way of motion sensors, auditory signals, and/or the input system upon one of the wired or wireless controllers user interface. The apparatus also has a plurality of sensors and/or automatic timers upon the plurality of microcontrollers and/or Digital signal processors to control and/or monitor sinks, showers, tubs, sprinklers, swimming pools, waste water timed draining, toilets, water heaters, water main-lines, swamp coolers, air conditioners, and/or any local water supply. The EWDC with EDN is the answer for anybody who want to have the faucet of their choice and control there entire home and/or business water supply electronically. The said apparatus is universal, which means, it can control the flow and/or pressure of water and/or of waste water in a network buy connecting to any water supply and/or drain pipe the user has in mind, or the user can use the manual faucet or electronic faucet of there choice.

BRIEF SUMMARY OF VARIOUS EMBODIMENTS OF THE INVENTION

Various embodiment's of the invention include, but not to be limited to, one or more central controllers, a plurality of local controllers, one or more Electronic drain stoppers, sensors, one or more solenoids valves, and/or one or more motorized ball valves. The Electronic Drain stopper devices is constructed with a actuating device, linkage devices, a drain pipe assembly, a drain stopper assembly, and/or a disc shaped object. All Electronic Stopper devices will 100% block waste water from flowing through the drain pipe. The central controllers is either a self contained wired or wireless controller with inputs such as physical switches, motion sensors, voice command, touch screen, or any input type. The central controller can also be a mobile device, and/or a computation Device. The central controller is utilized to send control signals to the plurality of local controllers, which a plurality of local controller systems is connected to a plurality of Electronic Drain stoppers, solenoid valves, motorized valves, and/or water sensors, moreover, the local controllers control and monitor the flow and/or pressure of a local water supply, but also the local controllers have a user interface to control its devices that are connected to the local water supply. The central controller has hot, cold, and warm water inputs, menu inputs, drain stopper inputs, a microcontroller, electronic water overflow sensor inputs, water monitoring sensor inputs, on-board motion sensors, Bluetooth/WIFI/Lora, and/or any wireless communication device to send and receive control signals to and/or from the local controllers. The central controller functions consists of, depth saving functions to save repetitiously used water depths for any time use, water volume size select, swimming pool automatic water refill functions, swamp cooler automated fill up, automated water-main functions, automated waste water drain functions, and/or water sensors to start and/or stop the flow of water. The central controller is the global controller that can control a plurality of local controllers from anywhere in the world. The apparatus has a first Local controller which is constructed with hot, cold, and warm water inputs, menu inputs, electronic drain stopper inputs, electronic water overflow sensor inputs, water monitoring sensor inputs, a microcontroller, Bluetooth/WIFI/Lora and/or any wireless communication device to send and receive control signals to and/or from the local controllers. The apparatus has a plurality of wired/and or wireless Local controller user interface which is a microphone, one or more motion sensors, and/or any type of input control signals, a microcontroller, and a Bluetooth/WIFI/Lora and/or any communication device to send and receive control signals to and/or from the first local controller. A first plurality of local controllers is utilized for easy control of one or more of the apparatus's many functions, moreover, can be set to operate any function the EWDC with EDN has to offer from a single input. A second plurality of local controller is constructed with hot, cold, and warm water inputs, menu inputs, electronic drain stopper inputs, a microcontroller, a Bluetooth/WIFI/Lora, and/or any wireless communication device to send and receive control signals to and/or from the central controller, the plurality of local controllers, furthermore, a third plurality of local controllers is constructed with electronic water overflow sensor inputs, water monitoring sensor inputs, one or more solenoid valve inputs, and/or one or more motorized valve inputs. The third local controllers is the controllers which is connected to the Electronic drain stopper devices, solenoid valves, and/or motorized valves. The third local controller is utilized to control and/or monitor the pressure and/or flow of each local water supply in a network and is utilized to control and monitor the pressure and or/flow of waste water at a local drain pipe assembly in a network.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A Illustrates the EWDC with EDN and its connectivity between the solar powered central controller and a plurality of solar powered local controllers, furthermore, the plurality of local controllers are connected outside the users home to local water supply connections such as a shower, a tub, and/or a swimming pool.

FIG. 1B Illustrates the EWDC with EDN and its connectivity between the central controller and a water heater.

FIG. 2 Illustrates the EWDC with EDN and its connectivity between the central controller and a plurality of local controllers, furthermore, the plurality of local controllers are connected inside the users home and/or business bathroom to local water supply connections such as showers, tubs, sinks, and/or toilets.

FIG. 3 Illustrates the EWDC with EDN and its connectivity between the central controller and a plurality of local controllers, furthermore, the plurality of local controllers are connected inside the users home/business kitchen local water supply connections such as faucets, osmosis system and/or osmosis system faucets, drain control, and/or pot-fillers.

FIG. 4 Illustrates the EWDC with EDN and its connectivity between a plurality of solar powered and/or water turbine powered local controllers and a plurality of sensory inputs which connects to a water main connection of a plurality of homes and/or businesses, furthermore, depicts how the central controller's user interface at the water company and/or a mobile device can monitor and/or control the pressure and/or flow of water entering each users home and/or business.

FIG. 5 Illustrates the EWDC with EDN and its connectivity between the central controller and a plurality of local controllers, furthermore, the plurality of local controllers are connected to a water piping system and/or a drain water piping system.

FIG. 6 Illustrates the EWDC with EDN and its connectivity between the central controller and a plurality of local controllers, furthermore, the plurality of local controllers are connected to a water piping system and/or a drain water piping system, which are utilized to monitor and/or control the pressure and/or flow of water for the entire skyscraper.

FIG. 7 Illustrates the EWDC with EDN central and/or local controller and a plurality of motorized valves electronic schematics.

FIG. 8 Illustrates the EWDC with EDN central and/or local controller and a plurality of solenoid valves and/or motorized valves electronic schematics.

FIG. 9 Illustrates the EWDC with EDN and its connectivity between the central controller and local controllers, furthermore, depicts how the local controller is connected to water sensors and/or how it is connected to operate a plurality of motorized valves.

FIG. 10 Illustrates the EWDC with EDN and its connectivity between the central controller and local controllers, furthermore, depicts how the local controllers are connected to a plurality of water sensors, motorized valves, and/or solenoid valves.

FIG. 11 Illustrates the EWDC with EDN's all purpose electronic stopper device that is constructed with motors, furthermore, the illustration also depicts how the device is assembled.

FIG. 12 Illustrates the EWDC with EDN's all purpose electronic stopper device that is constructed with solenoids, furthermore, the illustration also depicts how the device is assembled.

FIG. 13 Illustrates the EWDC with EDN's electronic stopper device for a kitchen sink, furthermore, the illustration also depicts how the device is assembled.

FIG. 14 Illustrates the EWDC with EDN's electronic stopper device for a bathroom sink, furthermore, the illustration also depicts how the device is assembled.

FIG. 15 Illustrates the EWDC with EDN's electronic stopper device for a tub and/or shower, furthermore, the illustration also depicts how the device is assembled.

FIG. 16A Illustrates the electronic schematic diagram for the EWDC with EDN's electronic stopper device in conjunction with the motion sensors and/or switches on the user interface upon the central controllers and/or a local controllers.

FIG. 16B Illustrates the EWDC with EDN's electronic stopper device, furthermore the illustration depicts how the electronic stopper device is utilized in conjunction with the motion sensors and/or switches user interface upon the central controller and/or local controller.

FIG. 17A Illustrates the electronic schematic diagram for the EWDC with EDN's electronic stopper device in conjunction with its LCD/touch screen user interface on the central controllers and/or a local controllers.

FIG. 17B Illustrates the EWDC with EDN's electronic stopper device, furthermore the illustration depicts how the electronic stopper device is utilized in conjunction with the LCD/touch screen user interface upon the central controllers and/or local controllers.

FIG. 18A Illustrates the electronic schematic diagram for the EWDC with EDN's electronic stopper device in conjunction with its voice command user interface upon the central controllers and/or local controllers.

FIG. 18B Illustrates the EWDC with EDN's electronic stopper device, furthermore the illustration depicts how the electronic stopper device is utilized in conjunction with the voice command user interface upon the central controllers and/or a local controllers.

FIG. 19 Illustrates the EWDC with EDN's electronic block diagram, moreover, the illustrated block diagram depicts the operation for all devices used in conjunction with the EWDC with EDN.

DETAILED DESCRIPTION OF VARIOUS EMBODIMENTS

All components utilized in conjunction with the EWDC with EDN illustrations in this particular patent are subject to change, and should not be limited to what is depicted, but are utilized to fulfill the policy of this patent. All components whether mechanical or electrical will be re-analyzed and different components may or may not be utilized to assemble the EWDC with EDN. Any and all new components used will have similarities as the stated used components in conjunction with the EWDC with EDN.

FIG. 1A Illustrates the EWDC with EDN and its connectivity between the solar powered central controller (285) and (125) and a plurality of solar powered local controllers (290), furthermore, the plurality of local controllers (290) are connected outside the users home to a plurality local water supply connections such as a shower (345), a tub (350), and/or a swimming pool (180). Solar power is the conversion of energy from sunlight into electricity, either directly using photovoltaics (PV), indirectly using concentrated solar power, or a combination. The solar power panel (190) is either embedded with the user central controller (285) user interface or the solar panel (190) can be an external device. The central controllers is either a self contained wired and/or wireless controller with user interface inputs such as physical switches, motion sensors, voice command, touch screen, and/or any input type. The central controller can also be a mobile device, and/or a computation Device. The central controller (285) is utilized to send and/or receive control signals to and/or from a plurality of local controllers (290) which are connected to the shower (345), the tub (350), and/or the swimming pool (180). The local controllers (290) also have there on user interface to control there on individual peripheral devices. The plurality of local controller (290) systems all have inputs and/or outputs to connect to a plurality of Electronic Drain stoppers (355), furthermore, the Electronic Drain stoppers (355) are connected to the shower (345) and/or tub (350). The Electronic drain stopper (355) is an electronic actuating drain stopper that can proportionally actuate open and/or close by a user activating a input on the user interface upon the central controllers (285) and/or the local controllers (290). The Electronic drain stoppers (355) can also be actuated to a predetermined position and/or can be activated to actuate by a predetermined time schedule. This particular local controller (290) that's connected to The shower's (345) local water supply is constructed with Hot water (170) and/or cold water (175) motorized ball valves and water monitoring sensors (165). The central controller (285) and/or the local controller (290) can monitor and/or control the temperature, pressure, and/or flow of water which is outputting from the shower (345), furthermore, the shower (345) system can set and save a plurality of settings to operate the peripheral on a predetermined temperature, predetermined time schedule, and/or the user can play a predetermined song utilizing the apparatus's wired/and or wireless audio system (505). The particular local controller (290) that's connected to The Tub (350) local water supply is constructed with Hot water (170) and/or cold water (175) motorized ball valves, water level sensors (360), and water monitoring sensors (165). The central controllers (285) and/or the local controllers (290) can monitor and/or control the temperature, pressure, and/or flow of water which is flowing into the tub (350), furthermore, the tub (350) system has water overflow protection sensors (360) that will never let a user's tub (350) over flow and also a user can set and/or save a plurality of settings to operate the peripheral on a predetermined temperature, a predetermined volume of water, a predetermined water pressure, predetermined time schedule, and/or the user can play a predetermined song utilizing the apparatus's wired/and or wireless audio system (505). The particular local controller (290) that's connected to The swimming pool's (180) local water supply is constructed with solenoid valve's (100), water level sensors (360), and/or water monitoring sensors (165). The central controllers (285) and/or the local controllers (290) can monitor the temperature and/or control the flow of water which is flowing into the swimming pool (350), furthermore, the swimming pool (350) peripheral has water overflow protection sensors (360) which is constructed to never let a user's swimming pool (350) water level get low and/or will never let the water over flow by automating the water fill up of the pool. The swimming pool (350) peripheral can set and save a plurality of settings to operate the peripheral to output a predetermined volume of water into the pool, a predetermined time schedule to fill up the pool, and/or the user can play a predetermined song utilizing the apparatus's wired/and or wireless audio system (505) while in the pool. The Swimming pool Peripheral device is also constructed to control the pressure and/or flow of water for a swamp cooler unit and/or a air conditioner unit and the sensory inputs can also determine the water level for the swamp cooler and/or air conditioner systems.

FIG. 1B Illustrates the EWDC with EDN and its connectivity between the central controller (125) and a water heater (330). The central controller in this particular illustration is a mobile device and/or a computation Device. The central controller (125) is utilized to send and receive control signals to and/or from the local controller (290) that is connected to the local water supply lines upon the Water heater (330). The local controller (290) also has its on user interface to control the Water heater (330) peripheral device. The central controller (125) and/or the local controller (290) can monitor and/or control the temperature, pressure, and/or flow of water which is flowing through the Hot water (170) and/or cold water (175) motorized ball-valves. The Hot water (170) motorized ball-valves controls the hot water input which is flowing into the user's home and the cold water (175) motorized ball-valves controls the water going into the inlet of the Water heater (330) peripheral device, furthermore, the Water heater (330) peripheral also has water sensors (165) which are utilized to monitor temperature and water flow pressure. The Water heater (330) peripheral can set and/or save settings for automatic cut-off in case of emergencies. The user can also set and/or save settings to the peripheral to output a predetermined temperature, a predetermined volume of water, and/or to operate only between a predetermined time schedule.

FIG. 2 Illustrates the EWDC with EDN and its connectivity between a plurality of central controllers (285) and a plurality of local controllers (290), furthermore, the plurality of local controllers (290) are connected inside the users home/business bathroom to local water supply connections such as a shower (345) and tub (350) combination, sinks (340), and/or toilets (510). The central controllers (285) is either a self contained wired and/or wireless controller with user interface inputs such as physical switches, motion sensors, voice command, touch screen, and/or any input type. The central controllers (285) can also be a mobile device, and/or a computation Device. The central controller (285) is utilized to send and receive control signals to and/or from the plurality of local controllers (290) which are connected to the local water supplies in conjunction with the shower (345) and tub (350) combination, sinks (340), and/or toilets (510). The local controllers (290) also have there on user interface to control there on individual peripheral devices. The plurality of local controller (290) systems all have inputs and/or outputs to connect a plurality of Electronic Drain stopper (355) devices, moreover, the Electronic Drain stopper(355) devices are connected to the shower (345) and tub (350) combination, sinks (340), and/or toilets (510). The Electronic drain stopper (355) is an electronic actuating drain stopper that actuates open and/or close by a user activating a input on the user interface upon the central controllers (285) and/or the local controllers (290). The Electronic drain stoppers (355) can also be actuated to a predetermined position and/or can be activated to actuate by a predetermined time schedule. This particular local controller (290) that's connected to shower (345) and the tub (350) combination local water supply is constructed with Hot water (170) and/or cold water (175) motorized ball valves, water monitoring sensors (165), water overflow sensors (360), and solenoid valves (shower (300) and tub (295)). The central controllers (285) and/or the local controllers (290) can monitor the temperature and/or water purity by its user interface's Leds, touchscreen, and/or speaker system, but also the central controllers (285) and/or the local controllers (290) can control the temperature, pressure, and/or flow of water which is outputting from the shower (345) by the user activating the menu, hot, cold, and/or warm water inputs upon the central (285) and/or local controllers (290). The user can select one or more shower (345) spout outputs by utilizing an input on one of the controllers ((285) and (290)) to select the shower solenoid (300). The shower (345) system have settings which a user can set and save a plurality of settings to operate the peripheral on a predetermined temperature, predetermined time schedule, and/or the user can play a predetermined song utilizing the apparatus's wired/and or wireless audio system (505). The user can select one or more tub spout(350) outputs by utilizing an input on one of the controllers ((285) and (290)) to select the tub solenoid (295). The Tub (350) settings can monitor the temperature, flow pressure, and/or water purity by its user interface's Leds, touchscreen, and/or speaker system, but also the central controllers (285) and/or the local controllers (290) controls the temperature, pressure, and/or flow of water which is flowing into the tub (350) by the user activating the menu, hot, cold, and/or warm water inputs upon the central (285) and/or local controllers (290). The tub (350) system has water overflow protection sensors (360) that will never let a user's tub (350) over flow and also the system consist of settings which a user can set and save a plurality of settings to operate the peripheral on a predetermined temperature, a predetermined volume of water, predetermined time schedule, and/or the user can play a predetermined song utilizing the apparatus's wired/and or wireless audio system (505). The particular local controller (290) system that's connected to the sink and/or sink's faucet (340) local water supply is constructed with Hot water (170) and/or cold water (175) motorized ball valves, water monitoring sensors (165), water overflow sensors (360), electronic stopper device (355), and solenoid valves (335). The central controllers (285) and/or the local controllers (290) can monitor the temperature, water pressure, and/or water purity by its user interface's Leds, touchscreen, and/or speaker system, but also the central controllers (285) and/or the local controllers (290) can proportionally control the temperature, pressure, and/or flow of water which is outputting from the sink (345) by the user activating the menu, hot, cold, and/or warm water inputs upon the central (285) and/or local controllers (290). The sink (345) system has water overflow protection sensors (360) that will never let a user's sink (345) over flow and also the a user can set and/or save a plurality of settings to operate the peripheral on a predetermined temperature, a predetermined volume of water, a predetermined pressure, predetermined time schedule, and/or the user can play a predetermined song utilizing the apparatus's wired/and or wireless audio system (505). The particular local controller (290) system that's connected to the toilet's (340) local water supply is constructed with water overflow sensor (360), electronic drain stopper device (355), and/or solenoid valves (185). The central controllers (285) and/or the local controllers (290) can monitor the water level and/or water refill level by its user interface's Leds, touchscreen, and/or speaker system, but also the central controllers (285) and/or the local controllers (290) can control the flow of water which is flowing through the toilet by the user activating the menu, and/or the toilet on/off inputs upon the central (285) and/or local controllers (290). The toilet (340) system has water overflow protection sensors (360) that will send a signal to the solenoid valve(185) to cease all flow of water to the toilet if water overflow is detected. The toilet (340) system consist of settings which a user can set and save a plurality of settings to set the toilet (340) system peripheral to output a predetermined volume of water, to operate on a predetermined time schedule, and/or if a plurality of toilets is present, the user can select which toilets they want active and which toilets they want inactive. The electronic drain stopper (355) device, if in active status, will cease all flow of drain water by completely closing the drain and also will cease all flow of clean water which is flowing into the toilet. This particular function will allow a user to shut-off there toilet water supply and/or close there drain pipe immediately in case a user drop something inside the toilet accidentally. The local controller (290) connected to the toilet (340) device can also be set to send and/or receive data to and/or from the local controller at the sink (345) to auto detect a flush, moreover, once a flush is detected the local water supply at the sink (345) will automatically turn on the water to a predetermined water temperature, to a predetermined water pressure, a predetermined quantity of water, and/or for a predetermined time period, furthermore, automatically turn the sinks (345) water off after the predetermined time limit has expired. The Local controllers (290) can auto-detect toilet flushes by reading the water level sensors connected to the toilet and/or by reading the water metering sensors upon the electronic drain stopper (355) device connected to the toilet.

FIG. 3 Illustrates the EWDC with EDN and its connectivity between the central controller (285) and a plurality of local controllers (290), furthermore, the plurality of local controllers (290) are connected inside a users home and/or business kitchen local water supply connections such as faucets, osmosis system and/or osmosis system faucets, drain control, and/or pot-fillers. The illustration further depicts central controllers (285) (125) with internal (40) motion sensors, a first local controllers (130) with a user interface constructed with a microphone, switches, touchscreen, and/or motion sensors, and a second set of local controllers (290) user interface constructed with a microphone, switches, touchscreen, motion sensors, water level sensory inputs (45), water monitoring sensory inputs, and/or audio speaker (35) circuit. The illustration also depicts how all, said circuits above, connect with the wired and/or wireless local controller (290) to monitor and/or control the water temperature, contaminants in water, and/or water pressure which is outputting through the Hot water (95), cold water (100), osmosis device (150), and/or pot filler (160) electronic solenoid valves. The said apparatus utilizes four main circuits. The first main circuit that the apparatus utilizes is the wired and/or wireless central controller (285). The second main circuit is a first local controller (130). The third main circuit being a second local controller (290). The fourth main circuit being the water level sensors (45) and/or the water monitoring sensors upon the electronic valves. These four units, in this particular version, need to be connected in the following order, to have full control of the water supply lines in the users kitchen. The first connection that need to be made is: Connect the input for the hot water (95), cold water (100), and/or pot-filler (160) solenoid valves and/or motorized valves to the output coming from the kitchens plumbing hot and/or cold water riser lines, moreover, connect the output of the solenoid valves (95), (100), and/or (160) to the inputs of the user's faucet or spout hot and/or cold water inlet supply lines. Next, connect the input for the osmosis (150) solenoid valve to the filtered output of the osmosis system, hence, connect the output of the Electronic solenoid valves (150) to the input of the user's osmosis system faucet (140) hot and/or cold inlet water supply connection. Next, the central controller (285), once powered on, is connected by automatically sending and/or receiving a wireless Bluetooth, WiFi, zigbee, Lora, and/or radio controlled communication signal to and/or from the wired and/or wireless second local controller's (290) Bluetooth, WiFi, zigbee, Lora, and/or radio controller. The said ZIGBEE, Bluetooth, Lora, and/or WIFI Radio Controlled (85) communication system is utilized with this apparatus in order to communicate with the apparatus without having to use a infrared remote, which a infrared remote can be used, but a infrared remote can only operate if you are pointing the infrared remote directly at the sensor. The ZIGBEE, Bluetooth, Lora, and/or WIFI Radio Controller (85) utilized in conjunction with the apparatus is a commercially sold module that contains an on-board antenna, an on-board radio signal controller, and a on-board microcontroller. Using a radio controlled type of communication signal allows operation of the apparatus from anywhere around the users home and/or business, hence the said radio controller devices also allow a internet connection to operate the apparatus from anywhere in the world. All systems controllers (285), (290), (130), and (125) will work online while maintaining an internet connection and/or also all systems controllers (285), (290), (130), and (125) will fully work offline via its on private network. The second connection that need to be made is: The user need to connects the wired and/or wireless communication output signal from the first local controller (130), to input a wired and/or wireless connection to the wired and/or wireless second local controller (290). If the user has the first local controller (130), once powered on, the wired and/or wireless second local controller (130) will automatically broadcast a signal to connect to the wired and/or wireless second local controller's (290) Bluetooth, WiFi, Lora, and/or zigbee radio controller. The first local controller's (130) microphone, switches, touch screen, and/or motion sensor (40) user interfaces inputs send a wireless and/or touch-less signal to the second local controller radio controller, furthermore, the radio controller then send a wired/and/or wireless signal to the microcontroller to send a signal to operate the Hot (95), cold (100), osmosis (150), and/or pot filler (160) electronic solenoid valves. The central controller (285) also have microphones, touchscreens, any type of switches, and/or embedded motion sensors (40) as its user interfaces inputs. The microphones, switches, touchscreen, and/or embedded motion sensors (40) are utilized to send a wireless and/or touch-less signal to the second local controller (290) radio controller, furthermore, the radio controller then send a wired/and/or wireless signal to the microcontroller to send a signal to operate the Hot (95), cold (100), osmosis (150), and/or pot filler (160) electronic solenoid valves. All central controllers (285) and/or local controllers ((130) and (290)) microphone, touch screen, switches, and/or motion sensors user interface can each be individually set to operate a different task or functions of the EWDC with EDN. The Third connection that need to be made is the water sensors: The water sensors (45) has a wired and/or wireless output connection signal, which connects by sending and/or receiving a wired and/or wireless signal to and/or from the inputs of the second local controller (290). Once the central controllers (285), the first local controllers (130), and/or the water level detect circuit(45) is connected to the second local controller (290), all said controllers can send and/or receive control signals to and or from the second local controller (290) microcontroller. The second local controller (290) microcontroller then will send a output control signal to the driver circuit, which in turn, output a signal to control the Hot water (95), cold water (100), osmosis (150), and/or pot filler (160) electronic solenoid valves that is connected to the users hot and/or cold water kitchen supply lines. Once, the second local controller (290) send the control signal to the driver, which output a signal to actuate the electronic solenoid valves or motorized valves selected by the user, the second local controller (290) then send a feedback signal to the wired and/or wireless central controller (285) (125) and/or local controllers (130) to output signals through the user interface to a plurality of Leds, touch screens, Lcd, and/or speakers to let the user know that a specific task is starting and/or complete. A specific task meaning, if the user press the hot water button (5) up or down, the apparatus will actuate the hot (95) electronic water valve, hence the device will then send a visual, auditory, and/or tactile feed back signal to the user. If the user press the warm water button (10) up or down, the apparatus will actuate the hot water (95) and cold water (100) electronic water valves together, hence the device will then send a visual, auditory, and/or tactile feed back signal to the user. If the user press the cold water button (15) up or down,the apparatus will actuate the cold water (100) electronic water valve, hence the device will then send a visual, auditory, and/or tactile feed back signal to the user. The Local controllers ((130 and (290)) can also be fully controlled by the central controller and/or the mobile device (125) ((FIG. 1A) (FIG. 1B) (FIG. 3)) said Bluetooth, Lora, WiFi, and/or zigbee radio controller. The mobile device (125) application will consist of the exact functionalities as the central controller (285) ((FIG. 1A) (FIG. 1B) (FIG. 2) (FIG. 3)). The central controller (285) and the mobile cellular device (125) both have full control of the EWDC with EDN system, moreover, the central controller (285) and the mobile cellular device (125) also have full control of a plurality of EWDC with EDN systems which is utilized to control entire business's and/or home's water supply systems. The EWDC with EDN has a plurality of other functions which a user can use for there convenience. The cup size function operates without any sensors or hardware needed to measure the range of water outputted from the spout. The cup size function was configured by knowing that all homes water pressure range from 80-85 psi. With that being said, all homes have a standardized pressure range. Now, all that had to be done was to measure the time and the space of half cup or one cup of water coming out of the user's faucet. The microcontroller is utilized to: For example, if half cup of water took 1.5 seconds to be dispensed from the spout, we then multiply that 1.5 seconds×2, which equal one cup of water taking 3 seconds to be dispensed from the water spout, or if one quart equals four cups of water, we then multiply 3 seconds (time one cup take to dispense)×4 to achieve a precise quart (etc). The system can output any specific volume or quantity of water from any measurement system. The Hot water (95), cold water (100), osmosis (150), and/or pot filler (160) electronic water valves used in conjunction with the Electronic Water Distribution Center will first actuate fully on. Once the Hot water (95), cold water (100), osmosis (150), and/or pot filler (160) electronic solenoid valves actuate fully on, this now allows the same 80-85 psi water pressure to be delivered to the apparatus, hence allow the EWDC with EDN to time a precise water measurement for all homes and businesses. Now concerning the central controller (285) and/or local controllers (130) and (290)) user interface controls. First, the said apparatus hot (5), cold (15), and/or warm(10) inputs is utilized upon the system for the user to output selected water temperatures and/or water pressure from the local water supply for a prolonged period of time. Second, the central controller controls (285) and/or local controllers (290) is to select what temperature and/or pressure of water is outputted from the users sinks and/or faucets once a users preferred motion sensor circuit is activated. Meaning, the user can set there on individual motion sensor (40) on the central controller (285) and/or can set there on inputs and/or motion sensors upon the local controller (130) to activate the temperature and pressure the apparatus was on last, hence that said function will be started anytime they activate that individually set input and/or motion sensor circuit. The menu button (20) is there to select and/or change the temperature and counter settings in water depth modes, to set electronic drain options, to set power saving modes, manage time on the Lcd/touchscreen, voice command setup, and/or to turn the system vibrator and/or audio speaker system on and/or off. A second feature is Water depth mode. Once water depth modes is set, it enables the user to utilize the fill sink/tub mode button (25). Water depth modes allow the user to save a preferred depths of water that is used normally (to wash dishes and/or to get in the tub). Sink/tub fill up button (25) is to activate the saved water depths timer, temperature, and/or pressure that was selected during the saving procedure by way of the press of that particular button or input signal. The water depth saving function for sink/tub fill up was configured by utilizing a counter/timer program within the microcontroller. Once the user select to change a water depth mode in the menu, the user should select the temperature and/or pressure from the central controller (285). After the user has selected there preferred water temperature and/or pressure, the central controller (285) will then send a control signal to the second local controller (290) to send a control signal to the driver circuit to actuate the electronic stopper device (355) closed, furthermore, the central controller (285) will then send a second control signal to the local controller (290) which outputs a signal to actuate the hot (95) and/or cold (100) electronic water valves to turn the local water supply on. Next, the central controller's (285) microcontroller and/or the second local controller (290) microcontroller (75) will then start a timer/counter program to count the time it takes for the user to finish filling there sink and/or tub. Once the user has reached there preferred depth, the user should press the menu button to save the time from the counter program. Once setting is saved, the hot water (95) and/or cold water (100) electronic water valves will automatically actuate fully off. The electronic drain stopper can be set to actuate back open by a timer and/or the user can speak a word or select a motion sensor circuit upon one of the controllers ((285) and (130)) to control the electronic stopper device (355). If the user want to start that saved water depth, the user should activate the sink/tub fill up input (25) upon the central controller (285), local controller (130), and/or the mobile device (285). Once pressed or signaled, the central controller (285), local controller (130), or the mobile device (125) will then send a control signal to the second local controller (290) to send a control signal to the driver circuit to actuate the electronic stopper device (355) closed, furthermore, the central controller (285) will then send a second control signal to the local controller (290) which outputs a signal to actuate the hot water (95) and/or cold water (100) electronic solenoid valves to turn on the local water supply. The local water supply is actuated on for the same water temperature and/or water pressure that was, selected and saved, during the water depth fill up mode, hence the microcontroller will start the timer/counter program to start counting down from the saved time until it reaches zero. Once the counter reaches zero, the second local controller (290) then will send an second output control signal to the driver circuit, which outputs a signal to actuates the Hot water (95) and/or cold water (100) electronic water valves fully off. Once the water is actuated off, the central controller (285) and/or local controllers (130) (290) will alert the user by a touch screen, Leds, a vibrator starting to vibrate, and/or auditory speaker output for example: make a tone and/or say “water turning off”, to let you know that the sink and/or tub fill up mode is complete. This allow the user to not have to watch there water while waiting to wash there dishes and/or fill there tub up. The water over-flow sensors (45) is connected to the side of the user sink(s), as shown in both ((FIG. 1) (FIG. 2) and (FIG. 3)), by way of (for example a magnetic enclosure or an enclosure with a sticky double sided adhesive tape). This particular illustration depicts a plurality of water overflow sensors (45), which is also depicted in (FIG. 1A, FIG. 2, and FIG. 3). If a body of water reach the height and/or position of where the user placed any of the said water over-flow sensor (45), the water over-flow sensor (45) will then output a signal to the input of the microcontroller upon the third local controller (290), hence the third local controller (290) will then output a signal to the driver circuit, which automatically turn both hot water (95) and/or cold water (100) electronic water valves off until the water is positioned under the inputs to the water over-flow sensors (45). Once the body of water is under the water over-flow sensors (45), the apparatus can then be operated again. The vibrator and/or audio circuit (35) is utilized upon the system as an audio output signal and/or tactile indicator to the user. The vibrator and/or audio circuit (35) is connected directly to the outputs of the microcontroller or digital signal processor upon the central controller (285) and/or the microcontroller or digital signal processor upon the local controller's ((290) and (130)). The vibrator is a very small dc vibrator motor, which is utilized in the circuit as a physical indicator to the user, which vibrate the wired or wireless central controller (285) and/or local controllers (130) (290) if a button is pressed, if one or more motion sensor (s) are activated, if starting water depth fill-up mode, if starting or stopping sink/tub fill up mode, if the water level sensors is activated, if the electronic stopper is activated, and/or to let the user know how many cups, quarts, liters, milliliters, gallons, and/or pints of water the apparatus selected user inputs and/or motion sensors is operating on. The speaker (35) is utilized in the circuit to play audio and/or music files, as a audio indicator to the user, to sound out a song, tone, and/or speech, from central controller's (285) and/or local controllers (130) (290) if a button is pressed, if one or more motion sensors (40) upon the local controllers (130) (290) and/or the central controllers (285) are activated, if starting water depth fill-up mode, if stopping water depth fill-up mode, if the water level sensor (45) is activated, and/or to let the user know the volume size of water the apparatus is selected to output on. The voice command input microphones and/or the audio system speakers is commercially sold products that contains an analog to digital converters, digital to analog converters, codecs, a on-board microcontroller, and/or speakers and/or microphones connections for audio input and/or output functions.

FIG. 4 Illustrates the EWDC with EDN and its connectivity between a plurality of solar powered (190) and/or water turbine powered (195) local controllers (190) and a plurality of central controllers ((125) and (325)), which the local controllers are connected to the water main connection of each users home and/or business, furthermore, depicts how the water company (325) and/or a mobile device (125) can control the pressure and/or flow of the water entering each users home. The local controller's (190) solar panel is first embedded into the top of the water main enclosure. Next, the local controller (190) and the battery is embedded in the bottom of the water main enclosure. In a whole, the top of the water main enclosure is the local controller. The local controller (190) is constructed with a solar panel, user interface, microcontroller, radio controller, driver, battery, and/or battery charging circuitry. Now, concerning connecting the device for operation, first: Connect the water contaminant, water temperature, water pressure, and/or water flow sensors (165), furthermore connect the water turbine generator (195), and the motorized valve to the home and/or business local water supply. Second, the local controller (190) is wired and/or send wireless signal to communicate with the sensory inputs (165), the water turbine generators (195), and/or the motorized valves (175). Each Local controller in front of each user home and/or business can be controlled and/monitored from its on personal user interface and/or the central controller's (125) users interface. If the water utility company central controller (325) (computation device) turns off a users home and/or business because of unpaid bill's and/or servicing purposes, the user cannot use any of there personal controllers (190) or (125) to open and/or close the valve. The user can only regain access to the motorized valves if a user has paid there water bill and/or servicing is complete, furthermore, the water utility company's central controller (325) must output a communication signal to the individual local controller to unlock the device to allow a user to now use there on personal central controllers (125) and/or local controllers (190) to operate the apparatus. All controllers ((325) (190) (125)) user interfaces is constructed with one or more inputs to proportional actuate one or more motorized valve open and/or closed, furthermore, all controllers ((325) (190) (125)) also has visual outputs, auditory outputs, and a microcontroller which contain function's which can monitor and/or control the temperature, pressure, and/or flow of water which is flowing into the user's home and/or business, furthermore, the water main peripheral system has functions and settings to set the water main peripheral to output a predetermined volume of water, to output water on a predetermined time schedule, and/or to output a predetermined pressure of water. The sensory inputs (165) are used to monitor, sense, and/or determine water flow, water pressure, contaminants in water, and/or water temperatures which is flowing through the local water supply, moreover, the water sensors (165) send that saved recorded data to the local controllers (190) and/or central controllers ((325) (125)) microcontroller which will send signals to the user interface, to let the user know the motorized valves (175) position, to monitor sensory inputs, and/or display sensory data. The water turbine generators (195) is a electric generator with its electricity and current generated by how fast the water is flowing through the device via the local water supply. The water turbine generators (195) is connected to the battery charging circuitry upon the local controller (190) to charge the embedded battery upon the local controller (190) every time a user runs the water in there home and/or business, while still also receiving a charge from the solar panel upon the local controllers. This charging circuitry allow the local controller's in the front of each user's home and/or business to self charge.

FIG. 5 Illustrates the EWDC with EDN and its connectivity between the central controller (125) and a plurality of local controllers (290), furthermore, the local controllers (290) are connected to a water piping system and/or a drain water piping system. This Illustration depicts how the central controller (125) can monitor and control the flow of hot and/or cold water for each branch of connected pipelines in a network and also depicts how the hot and/or cold water main input pressure is controlled in a network via the central controller. All controllers ((290) (125)) user interfaces is constructed with one or more inputs to proportional actuate one or more hot (170) and/or cold (175) motorized valves, open and/or closed, to control the overall water pressure for all water pipeline branches, furthermore, all controllers ((290) (125)) also can actuate one or more hot (95) and/or cold (100) solenoid valves to control the flow of water for a particular pipeline branch. This specific set up will be utilized in multi-zone sprinklers systems to electronically adjust the water pressure and flow to keep the sprinklers from wasting water by watering the city streets, this specific set up will be utilized in water distribution environments to electronically distribute water to city streets, this specific set up will be utilized in oil refineries or secure environments to electronically distribute water to different parts of there specific environment. This specific electronic water distribution setup, can and will, change in conjunction with this apparatus. What this mean is that this electronic distributed water pipeline setup, can and will be, constructed with all electronic solenoids valves (hot (95) cold (100)) to control the flow water, will be constructed with all electronic motorized valves ((hot (170) cold (175)) to control the water pressure and/flow, and/or will be constructed with a mixture of electronic motorized valves ((hot (170) cold (175)) and/or solenoid valves ((95) (100)). This Illustration depicts how the central controller (125) can monitor and control the drain pressure and/or flow of waste water for each branch of connected waste water drain pipelines in a network. All controllers ((125) (290)) user interfaces is constructed with one or more inputs to proportional actuate one or more electronic drain stopper devices (355), open and/or closed, furthermore, each user interface is constructed with one or more inputs to control the electronic drain stopper device's (355A) that is connected to the main drain to control and monitor waste water flow and/or pressure for all waste water drain pipeline branches, furthermore, all controllers ((290) (125)) also can actuate one or more electronic drain stopper device (355B) to control the Pressure and/or flow of water for a particular drain pipeline branch. This specific set up will be utilized waste water distribution environments to electronically bypass drain water piping in city streets, this specific set up will also be utilized in secure environments to electronically operate electronic drain stoppers in different parts of there specific environment.

FIG. 6 Illustrates the EWDC with EDN and its connectivity between the central controller (125) and a plurality of local controllers (290), furthermore, the plurality of local controllers (290) are connected to a plurality of valves, which are connected to a plurality of local water supply piping systems located on each floor of the building, moreover, a plurality of electronic water valves, are utilized to control the pressure and/or flow of water in the entire skyscraper building. This Illustration also depicts how the central controller (125) can monitor and/or control the flow of hot and/or cold water for each floor of the building in a network, hence also depicts how the apparatus can monitor, control, and/or regulate the flow and/or pressure for the hot and/or cold water main pipeline input's in a network via the central controller. All controller's ((290) (125)) user interfaces is constructed with one or more inputs to proportional actuate one or more hot (170) and/or cold (175) motorized valves, open and/or closed, to control the overall water flow and/or water pressure for all water pipeline branches on each floor o the building, furthermore, all controllers ((290) (125)) also can actuate one or more hot (95) and/or cold (100) solenoid valves to control the flow of water for a particular floor's pipeline branch. This specific electronic water distribution setup will be utilized within skyscrapers, hotels, culinary art schools, boats, secure environments, and/or big homes or big businesses. This specific electronic water distribution setup, can and will, change in conjunction with this apparatus. What this mean is that this electronic distributed water pipeline setup, can and will be, constructed with all electronic solenoids valves (hot (95) cold (100)) to control the flow of water In a network, will be constructed with all electronic motorized valves ((hot (170) cold (175)) to control the water pressure and/flow of water in a network, and/or will be constructed with a mixture of electronic motorized valves ((hot (170) cold (175)) and/or solenoid valves ((95) (100)) to control the flow and/or pressure of water In a network.

FIG. 7 Illustrates the schematics to the EWDC with EDN control systems user interface and the connection to a plurality of motorized valves. This electronic schematics depicts the user interface upon the central controller (285) and/or the local controllers (290) (130). The user interface consist of a plurality of switches, which are inputs to the microcontroller (375), to send a control signal to the plurality of drivers circuits (415), furthermore, the driver circuits then send an amplified signal to proportionally actuate the plurality of hot (170) and/or cold (175) motorized valves. The plurality of input switches upon the user interface hot+ (385) hot− (395) cold+ (390) cold− (400) warm+ (405) warm− (425), and the menu (365) input. The hot+ (385) input proportionally open the hot motorized valves (170). The hot− (395) input proportionally close the hot motorized valves (170). The cold+ (390) input proportionally open the cold motorized valves (175). The cold− (400) input proportionally close the cold motorized valves (175). The warm+ (405) input proportionally open the hot motorized valves (170) and proportionally open the cold motorized valves (175). The warm− (425) input proportionally close the hot motorized valves (170) and proportionally close the cold motorized valves (175). The menu input (365) is used upon the central controller to select a different EWDC W EDN peripheral system to fully control, but also is utilized to select, save, and/or change data in various functions in conjunction with the EWDC W EDN plurality of peripheral systems. The menu input (365) is used upon the local controller (290) to select, save, and/or change data only in various functions in conjunction with the, locally connected, EWDC W EDN peripheral system. The driver circuit (415) was constructed with a full H-bridge and/or half H-bridge IC. The H-bridge driver circuit (415) is utilized to amplify the signal from the microcontroller (375), to drive the plurality of motorized valves (hot (170) cold (175)), hence, the H-bridge driver circuit (415) is utilized to switch polarity of the motorized valves, which the polarity is switched upon the driver to make the motorized valves proportional move open and/or closed. The motorized valves ((170) (175)) that are utilized in this particular schematic are stepper motor driven, which also means exact control of the motorized valves ((170) (175)) do to the apparatus being able to change the step size of the stepper motor to proportionally actuate the stepper motor constructed motorized valves ((170) (175)) in steps as low as millimeters. What makes the EWDC W EDN controller's really exceptional, is that it can change the turn ratio to the stepper motor driven motorized valves ((170) (175)) at any local water supply, furthermore, when the user change the turn ratio it determines the speed for how fast the valves ((170) (175)) proportionally, turn on and/or turn off, at the local water supply. The water sensory (165) inputs determines the water temperature, water flow, water pressure, water oxygen level, water hardness, total chlorine in water, mercury in water, lead in water, aluminum in water, fluoride in water, iron in water, and/or ph level in water. All of the water sensory inputs (165), utilized in conjunction with the apparatus, are commercially sold and communicate with the microcontroller (75) through an input/output pin. The water sensory inputs (165), that was stated above will, depending on the end user needs, be utilized in conjunction with one or more EWDC with EDN peripheral devices, furthermore, the water sensory (165) inputs send and/or receive data, to and/or from, the microcontroller (375) to monitor, determine, and/or to save sensory data that was recorded do to different types of water activity at a local water supply. The Uart communication (270) is the communication method that was used to communicate with the microcontroller (375) and the wired and/or wireless communication devices. The EWDC W EDN will use a plurality of wireless communication devices to communicate with each EWDC W EDN peripheral device, furthermore, the plurality of wireless communication devices that are used in conjunction with the EWDC W EDN are Lora, Zigbee, Bluetooth, WIFI, and/or any type of Radio Controller device. The Radio Controllers stated above are commercially sold modules that contains an on-board antenna, an on-board radio signal controller, and a on-board microcontroller. Using a radio controlled type of communication system allows operation of the apparatus from anywhere around the users home and/or business, hence the said radio controller devices also allow a internet connection to operate the EWDC W EDN from anywhere in the world. The communication to all EWDC W EDN peripheral devices will be able to operate in a online and/or offline network. The peripheral systems that this schematic apply to are shown in (FIG. 1A) shower local supply of water peripheral, tub local supply of water peripheral, swimming pool local supply of water peripherals, and also (FIG. 1B) water heater local supply of water peripheral. This schematic also apply to other peripheral systems of the EWDC W EDN, wherein, the system controls the flow and/or pressure of a local water supply by utilizing motorized valves.

FIG. 8 Illustrates the schematics to the EWDC with EDN control systems user interface and the connections to a plurality of solenoid valves and/or motorized valves. This electronic schematics depicts the user interface upon the central controller (285) and/or the local controllers (290) (130). The user interface consist of a plurality of switches, which are inputs to the microcontroller (375), to send a control signal to the plurality of drivers circuits (415), furthermore, the driver circuits then send an amplified signal to proportionally actuate the plurality of hot (170) and/or cold (175) motorized valves and/or the driver circuits sends an amplified signal to open and/or close the plurality of solenoid valves ((295) (175)). The plurality of input switches upon the user interface hot+ (385) hot− (395) cold+ (390) cold− (400) warm+ (405) warm− (425), and the menu (365) input. The hot+ (385) input proportionally open the hot motorized valves (170). The hot− (395) input proportionally close the hot motorized valves (170). The cold+ (390) input proportionally open the cold motorized valves (175). The cold− (400) input proportionally close the cold motorized valves (175). The warm+ (405) input proportionally open the hot motorized valves (170) and proportionally open the cold motorized valves (175). The warm− (425) input proportionally close the hot motorized valves (170) and proportionally close the cold motorized valves (175). The menu input (365) is used upon the central controller to select a different EWDC W EDN peripheral system to fully control, but also is utilized to select, save, and/or change data in various functions in conjunction with the EWDC W EDN plurality of peripheral systems. The menu input (365) is used upon the local controller (290) to select, save, and/or change data only in various functions in conjunction with the, locally connected, EWDC W EDN peripheral system. The solenoid select input (580) is used upon the central controllers (285) and/or the local controllers (290) for a user to select one or more solenoid valve to actuate, open and/or closed, at a users particular local supply of water. The solenoid select input (580) can be used on (FIG. 2) to, start and/or stop, the flow of water on the local water supply connected to the EWDC W EDN sink peripheral. The solenoid select input (580) can be used on (FIG. 2) shower and tub combination peripheral to, start and/or stop, the flow of water which flows through the shower local water supply and/or the flow of water which flows through the tub's local water supply. The solenoid select input (580) can be used on (FIG. 2) toilet peripheral to, start and/or stop, the flow of water which flows through the toilet's local water supply. The solenoid select input (580) can be used on (FIG. 3) kitchen peripheral to, start and/or stop, the flow of water, at each local water supply, which flows through the faucets local water supply, the osmosis system/faucet local water supply, and/or the pot-filler's faucet local water supply. The solenoid select input (580) can be used on (FIG. 5) pipelines peripheral to, start and/or stop, the flow of water which flows through each branch of pipelines. The solenoid select input (580) can be used on (FIG. 6) skyscraper building peripheral to, start and/or stop, the flow of water which flows to each floor of the building and/or is utilized to, start and/or stop, the flow of water which flows to each local water supply of the building. The driver circuit (415) was constructed with a full H-bridge and/or half H-bridge IC. The H-bridge driver circuit (415) is utilized to amplify the signal from the microcontroller (375), to drive the plurality of motorized valves (hot (170) cold (175)), hence, the H-bridge driver circuit (415) is utilized to switch polarity of the motorized valves, which the polarity is switched upon the driver to make the motorized valves proportional actuate open and/or closed. The motorized valves that are utilized in this particular schematic are dc motor driven, which also means exceptional control of the local water supply do to dc motorized valve being able to proportionally control the pressure and/or flow of the local water supply. The water sensory (165) inputs determines the water temperature, water flow pressure, water oxygen level, water hardness, total chlorine in water, mercury in water, lead in water, aluminum in water, fluoride in water, iron in water, and/or pH level in water. All of the water sensory inputs (165), utilized in conjunction with the apparatus, are commercially sold and communicate with the microcontroller (75) through an input/output pin. The water sensory inputs (165), that was stated above will, depending on the end user needs, be utilized in conjunction with one or more EWDC with EDN devices, furthermore, the water sensory (165) inputs send and/or receive data, to and/or from, the microcontroller (75) to monitor, determine, and/or to save sensory data that was recorded do to different types of water activity at a local water supply. The Uart communication (270) is the communication method that was used to communicate with the microcontroller (75) and the wired and/or wireless communication devices. The EWDC W EDN will use a plurality of wireless communication devices to communicate with each EWDC W EDN peripheral device, furthermore, the plurality of wireless communication devices that are used in conjunction with the EWDC W EDN are Lora, Zigbee, Bluetooth, WIFI, and/or any type of Radio Controller device. The Radio Controllers stated above are commercially sold modules that contains an on-board antenna, an on-board radio signal controller, and a on-board microcontroller. Using a radio controlled type of communication system allows operation of the apparatus from anywhere around the users home and/or business, hence the said radio controller devices also allow a internet connection to operate the EWDC W EDN from anywhere in the world. The communication to all EWDC W EDN peripheral devices will be able to operate in a online and/or offline network.

FIG. 9 Illustrates the EWDC with EDN and its connectivity between the central controller (285) and a local controller (290), furthermore, depicts how the local controller (290) is connected to transmit and/or receive data from the water sensors (165), but also depicts how the local controller (290) is connected to operate a plurality of motorized valves ((170) (175)). The central controllers (285) is either a self contained wired or wireless controller with user interface inputs such as IR motion sensors, PIR motion sensors, voice command module with (microphone input, amplifier, and speaker outputs), switches, touch screen devices, and/or any input type. The central controller (285) can also be a mobile device (125), and/or a computation Device (125). The central controller's ((285) (125)) user interface is utilized to send hot, cold, and/or warm water control signals to a first microcontroller, which will next output a control signal, via a wired means and/or via a first wireless communication device (Bluetooth, WIFI, Lora, and/or any wireless communication device), moreover the communication control signal is received upon a second wireless communication device upon the local controller's (290), furthermore the communication device send a signal to a second microcontroller upon the local controller (290) system to proportionally actuate, one or more, motorized valves. The water sensors (165) is a plurality of sensors which monitor and/or determine the water flow, water pressure, water temperature, and/or any contaminants in the water at a local water supply. The local controller (290) controls and/or monitor the flow and/or pressure of a local water supply, while also transmitting data to the receiving input on the central controller's (285) communication device to control and/or monitor the same controls of the local controller (290) and/or monitor the same data that is being recorded at the local controller (290). The local controllers also have its own personal user interface to control its devices that are connected only at that particular local water supply. Also, this specific EWDC W EDN peripheral setup will control the flow and/or pressure of one or more local water supplies by utilizing one or more motorized valves ((170) (175).

FIG. 10 Illustrates the EWDC with EDN and its connectivity between the central controller (285) and the local controller (290), furthermore, depicts how the local controller (290) is connected to water sensors (165) and also depicts how the local controller (290) is connected to operate a plurality of motorized valves ((170) (175)) and/or a plurality of solenoid valves ((295) (300)). The central controllers (285) is either a self contained wired and/or wireless controller with user interface inputs such as IR motion sensors, PIR motion sensors, voice command module with (microphone input, amplifier, and speaker outputs), switches, touch screen devices, and/or any input type. The central controller (285) can also be a mobile device (125), and/or a computation Device (125). The central controller's ((285) (125)) user interface is utilized to send hot, cold, warm water, and/or solenoid select control signals to a first microcontroller, which will next output a control signal, via a wired means and/or via a first wireless communication device (Bluetooth, WIFI, Lora, and/or any wireless communication device), moreover the communication control signal is received upon a second wireless communication device upon the local controller's (290). Next, the communication device send a signal to a second microcontroller upon the local controller (290) system to output a signal to proportionally actuate, one or more, motorized valves ((170) (175) and/or to actuate one or more solenoid valves ((295) (300)) at a local water supply. The water sensors (165) is a plurality of sensors which monitor the water flow, water pressure, water temperature, contaminants and/or any conductive materials in the water at a local water supply. The local controller (290) controls and monitor the flow and/or pressure of a local water supply, while also transmitting data to the receiving input on the central controller's (285) communication device to control and/or monitor the same controls of the local controller (290) and/or monitor the same data that is being recorded at the local controller (290). The local controllers also have its own personal user interface to control its devices that are connected only at that particular local water supply. This specific EWDC W EDN peripheral setup will control the flow and/or pressure of one or more local water supplies by utilizing one or more solenoid valves ((295) (300)) and/or will control the flow and/or pressure of one or more local water supplies by utilizing one or more motorized valves ((170) (175), furthermore, this specific EWDC W EDN peripheral setup will also control the flow and/or pressure of one or more local water supplies by utilizing one or more solenoid valves ((295) (300)) and/or one or more motorized valves ((170) (175).

FIG. 11 Illustrates the EWDC with EDN's all purpose electronic stopper device that is constructed with motors (200), furthermore, the illustration also depicts how the device is assembled. This particular Electronic Drain stopper device is constructed with a actuating device (200), a plurality of linkage devices ((215A) (215B)), a drain pipe assembly (220), and a disc shaped object (210). The first part of construction starts with a drain pipe assembly (220) with a housing molded into the drainpipe assembly (220) to house motors (200). The motors (200) is then housed inside the drainpipe assembly (220) and connected to a first set of linkage devices (215A) with a first gearing system, which the first linkage device (215A) can also be molded into the drainpipe assembly. Next, a groove (315) is constructed, directly in the middle of the drain pipe assembly (220), with and/or without rubber or silicon gaskets to house the CNC made disc shaped objects (210). Next, a second set of linkage devices (215B), with a second gearing system, is housed on top of the disc shape object (210), furthermore, the second gearing system is connected to the first gearing system which will now allow the disc shaped object (210) to be electronically actuated to slide, in and/or out, of the drain pipe assembly (220). The disc shape object (210) is made in a circular shape, just like the drain pipe assembly (220), because it needs to slide, in and/or out, in between the grooves (315) that is constructed in the drain pipe assembly. This apparatus can also be constructed, for example, with a plurality of grooves (315) in the inlets of a T shaped pipe assembly and also grooves (315) can be constructed in the outlets of a T shaped pipe assembly, moreover, these plurality of grooves will each house disc shaped objects (210), which is utilized to electronically divert the drain from draining from a specific inlets and/or outlets of the drain pipe assembly. If a specific drain pipe assembly that has multiple inlets and/or outlets is utilized with the electronic drain stopper, the drain pipe assembly will also connect to a local water supply to allow a user to use the user interface upon the EWDC W EDN central and/or local control to divert water at a local water supply. Also, sensory inputs will determine if the local water supply gets diverted to the local drain. This feature will be utilized to, for example: stop a child from getting burned. The cap (320) is the water proof cover, which with cover all the components and/or electronic devices. This apparatus can also house water sensors, which are already used in conjunction with the EWDC W EDN devices, to sense specific activities within the electronic drain stopper device. All components whether piping assembly, mechanical, or electrical will be re-analyzed and different components may or may not be utilized to assemble the electronic drain stopper assembly. Any and all new components used will have similarities as the stated used components in conjunction with the electronic drain stopper assembly. All Electronic Stopper devices can 100% block waste water from flowing through the drain pipe.

(FIG. 12 Illustrates the EWDC with EDN's all purpose electronic stopper device that is constructed with solenoids (205), furthermore, the illustration also depicts how the device is assembled. This particular Electronic Drain stopper device is constructed with a actuating device (205), linkage devices ((215A) (215B)), a drain pipe assembly (220), and disc shaped objects (210). The first part of construction starts with grooves (315) being constructed directly in the middle of the drain pipe assembly (220), with and/or without rubber or silicon gaskets, to house the CNC made disc shaped objects (210). The next part of construction is to connect the drain pipe assembly (220) with a first set of linkage devices (215A), which the first set of linkage devices (215A) is connected to the drain pipe assembly and/or molded into the drainpipe assembly (210). Next, a second set of linkage system (215B), which houses one ore more solenoids (205), is connected on top of the first set of linkage device (215A). This specific linkage system ((215A) (215B)) type is constructed like a slider rail. Next, the actuator of the solenoids (205) is connected to the disc shape object (210), which will now allow the disc shaped object (210) to be electronically actuated to slide, in and/or out, of the drain pipe assembly (220). The disc shape objects (210) are made in a circular shape, just like the drain pipe assembly (220), because it needs to slide, in and/or out, in between the grooves (315) that is constructed in the drain pipe assembly. This apparatus can also be constructed, for example, with a plurality of grooves (315) in the inlets on a X shaped pipe assembly, but also a plurality of grooves (315) can be constructed in the outlets of a X shaped pipe assembly, moreover, these grooves will each house disc shaped objects (210), which is utilized to electronically divert the drain from draining from specific inlets and/or outlets of the electronic drain stopper assembly. If a specific drain pipe assembly that has multiple inlets/outlets is utilized with the electronic drain stopper, the drain pipe assembly will also connect to a local water supply to allow a user to utilize the user interface upon the EWDC W EDN central and/or local control to divert water at a local water supply. Also, the sensory inputs can also send control signals to divert the local water supply to the drain. This feature will be utilized to, for example: stop an elderly person from getting burned. This apparatus can also obtain water sensors, which are already used in conjunction with the EWDC W EDN devices, to sense specific activities within the electronic drain stopper device. All components whether piping assembly, mechanical, or electrical will be re-analyzed and different components may or may not be utilized to assemble the electronic drain stopper assembly. Any and all new components used will have similarities as the stated used components in conjunction with the electronic drain stopper assembly. All Electronic Stopper devices can 100% block waste water from flowing through the drain pipe.

FIG. 13 Illustrates the EWDC with EDN's electronic stopper device for a kitchen sink completely assembled, furthermore, the illustration depicts all necessary electronic or mechanical components to make the apparatus fully functional. In this particular embodiment, the said electronic stopper drain assembly will consist of a kitchen drain stopper assembly (220), a strainer/stopper head (225) with and/or without a removable stem (250), a pivoting ball (230), a pivoting ball handle bar (235), a linkage rail system (240) constructed of machined metal or plastic parts, a actuating device (a servo motor, solenoid, stepper motor, or ac/dc motor)(5), a gearing system, and/or water sensors (165). The drain pipe assembly (220) is housed on the bottom of the kitchen sink while the strainer/stopper head (225) is assembled on the top of the kitchen sink. The strainer/stopper head (225) and the stopper head removable stem (250) is assembled hence dropped down through a hole directly in the middle of the strainer/stopper head (225). A pivoting ball (230) is then inserted on the side of the drain pipe assembly (220). The bottom of the stopper head's (225) removable stem (250) is then connected to the inner part of the pivoting ball handle (235). Next, the pivoting ball (230) is then fastened to the pipe by way of a wing nut to prevent the drainage from leaking on the outside of the drain pipe. The external end of the pivoting ball handle bar (235) is then connected to a first hex nut about a quarter away from the end of the pivoting ball handle bar (235). Next, the linkage rail (240) is slide on the outer part of the pivoting ball handle bar (235) next to the first hex nut, furthermore, a second hex nut was utilized to secure the linkage rail system (240) in its proper position, but also was utilized to secure the end of the pivoting ball handle bar (235). The plurality of hex nuts and/or clamps will be used to manually adjust the linkage system (240) position, which, as depicted in the illustration, the linkage system (240) has a plurality of holes upon the front and/or rear of the device. Next, the bottom of the linkage rail system (240) is secured to a first end of, a metal or plastic, gearing device, which the second end of the gearing device is attached to the actuating device (245) by way of fastening nuts and bolts. The actuating device (245) is secured to the pipe by way of nuts and bolts, a plastic casing, glue, and/or molded into the pipe assembly (220). Finally, the apparatus has a water sensor (165), which is also connected to the pipe by way of nuts and bolts, a plastic/metal casing, glue, and/or molded into the pipe. The all purpose electronic stopper device from ((FIG. 11) (FIG. 12)), can and will, be used in conjunction with the kitchen drain system. After all said connections were made the electronic stopper is ready to actuate in and/or out. The electronic stopper is a universal device that fits all standard kitchen drain sizes.

FIG. 14 Illustrates the EWDC with EDN's electronic stopper device for a bathroom/lavatory sink completely assembled, furthermore, the illustration depicts all necessary electronic or mechanical components to make the apparatus fully functional. In this particular embodiment, the said electronic stopper drain assembly will consist of a bathroom/Lavatory sink drain stopper assembly (220), a strainer/stopper head (225) with and/or without a removable stem (250), a pivoting ball (230), a pivoting ball handle bar (235), a linkage rail system (240) constructed of machined metal or plastic parts, a actuating device (a servo motor, solenoid, stepper motor, or ac/dc motor)(5), a gearing system, and/or water sensors (165). The drain pipe assembly (220) is housed on the bottom of the bathroom/Lavatory sink, while the strainer/stopper head (225) is assembled on the top of the bathroom/Lavatory sink. The strainer/stopper head (225) and the stopper head removable stem (250) is assembled hence dropped down through a hole directly in the middle of the strainer/stopper head (225). A pivoting ball (230) is then inserted on the side of the drain pipe assembly (220). The bottom of the stopper head's (225) removable stem (250) is then connected to the inner part of the pivoting ball handle (235). Next, the pivoting ball (230) is then fastened to the pipe by way of a wing nut to prevent the drainage from leaking on the outside of the drain pipe. The external end of the pivoting ball handle bar (235) is then connected to a first hex nut about a quarter away from the end of the pivoting ball handle bar (235). Next, the linkage rail (240) is slide on the outer part of the pivoting ball handle bar (235) next to the first hex nut, furthermore, a second hex nut was utilized to secure the linkage rail system (240) in its proper position, but also was utilized to secure the end of the pivoting ball handle bar (235). The plurality of hex nuts and/or clamps will be used to manually adjust the linkage system (240) position, which, as depicted in the illustration, the linkage system (240) has a plurality of holes upon the front and/or rear of the device. Next, the bottom of the linkage rail system (240) is secured to a first end of, a metal or plastic, gearing device, which the second end of the gearing device is attached to the actuating device (245) by way of fastening nuts and bolts. The actuating device (245) is secured to the pipe by way of nuts and bolts, a plastic casing, glue, and/or molded into the pipe assembly (220). Finally, the apparatus has a water sensor (165), which is also connected to the pipe by way of nuts and bolts, a plastic/metal casing, glue, and/or molded into the pipe. The all purpose electronic stopper device from ((FIG. 11) (FIG. 12)), can and will, be used in conjunction with the bathroom/Lavatory drain system. After all said connections were made the bathroom/Lavatory electronic stopper is ready to actuate in and/or out. The electronic stopper is a universal device that fits all standard bathroom/Lavatory drain sizes.

FIG. 15 Illustrates the EWDC with EDN's electronic stopper device for a tub and/or shower completely assembled, furthermore, the illustration depicts all necessary electronic or mechanical components to make the apparatus fully functional. In this particular embodiment, the said electronic stopper drain assembly will consist of a tub and/or shower drain stopper assembly (220), a strainer/stopper head (225) with and/or without a removable stem (250), a pivoting ball (230), a pivoting ball handle bar (235), a linkage rail system (240) constructed of machined metal or plastic parts, actuating device(s) (a servo motor, solenoid, stepper motor, or ac/dc motor)(5), a gearing system, and/or a water sensor (165). The drain pipe assembly (220) is housed on the bottom of the tub and/or shower drain assembly, while the strainer/stopper head (225) is assembled on the top of the tub and/or shower drain system. The strainer/stopper head (225) and the stopper head removable stem (250) is assembled hence dropped down through a hole directly in the middle of the strainer/stopper head (225). A pivoting ball (230) is then inserted on the side of the drain pipe assembly (220). The bottom of the stopper head's (225) removable stem (250) is then connected to the inner part of the pivoting ball handle (235). Next, the pivoting ball (230) is then fastened to the pipe by way of a wing nut to prevent the drainage from leaking on the outside of the drain pipe. The external end of the pivoting ball handle bar (235) is then connected to a first hex nut about a quarter away from the end of the pivoting ball handle bar (235). Next, the linkage rail (240) is slide on the outer part of the pivoting ball handle bar (235) next to the first hex nut, furthermore, a second hex nut was utilized to secure the linkage rail system (240) in its proper position, but also was utilized to secure the end of the pivoting ball handle bar (235). The plurality of hex nuts and/or clamps will be used to manually adjust the linkage system (240) position, which, as depicted in the illustration, the linkage system (240) has a plurality of holes upon the front and/or rear of the device. Next, the bottom of the linkage rail system (240) is secured to a first end of, a metal or plastic, gearing device, which the second end of the gearing device is attached to the actuating device (245) by way of fastening nuts and bolts. The actuating device (245) is secured to the pipe by way of nuts and bolts, a plastic casing, glue, and/or molded into the pipe assembly (220). Finally, the apparatus has a water sensor (165), which is also connected to the pipe by way of nuts and bolts, a plastic/metal casing, glue, and/or molded into the pipe. The all purpose electronic stopper device from ((FIG. 11) (FIG. 12)), can and will, be used in conjunction with the tub and/or shower drain system. After all said connections were made the tub and/or shower electronic stopper is ready to actuate in and/or out. The electronic stopper is a universal device that fits all standard tub and/or shower drain sizes.

FIG. 16A and FIG. 16B Illustrates one of the plurality of local controllers user interface ((130) (FIG. 3)) and the electronic drain stopper schematic and (FIG. 16B) illustrates the full assembly of the local controllers (130), local controller (290), and the electronic drain stopper. In this particular embodiment, the said apparatus components that are depicted to control the apparatus user interface are a plurality of motion sensors and/or switches ((255) (260)). The schematic is just to show a functioning electronic stopper at the bare minimum, but also to depict the inputs, outputs, and functionality of the invention. In this particular embodiment, the motion sensors and/or switches ((255) (260)) illustrates the inputs to the microcontroller (380). The microcontroller (380) unit is a means for receiving said signal from the plurality of motion sensors and/or switches ((255) (260)), save the data received, moreover, output a signal to the driver (90) to drive the actuating device (245) (a servo motor, solenoid, stepper motor, or ac/dc motor) used in conjunction with the electronic drain stopper assembly. The microcontroller (380) also is a means for saving accurate position of the electronic drain stopper, determining and/or recording input data from the water sensors (165) and outputting said data from the water sensors (165) to the local controllers (130) (290) or central controller, and/or to send visual auditory, and/or tactile feedback to the user interface. The first Local controller (130) communicates with the second local controller (290) by the first local controller (130) sending a wired and/or wireless communication signal from a first Bluetooth, Lora, WiFi, and/or zigbee radio controller (270) to a second local controller's (290) Bluetooth, Lora, WiFi, and/or zigbee radio controller (270). The second local controller (290) is the controller which is connected to the electronic drain stopper's actuating device and/or water sensors (165). Both local controller's ((130) (290)) can also send/and receive communication signals from a central controller device, and moreover, both local controller's ((130) (290)) can be fully controlled by the central controller and/or the mobile device (125). The central controllers ((285) (125) and/or the local controller's (130) (290), in conjunction with this specific EWDC W EDN peripheral device, has outputs such as visual indicators(265) and/or a vibrating motor (370) to alert a user, by a visual and tactile means, that a certain function is complete and/or that a specific input is being activated upon the user interface. The up (255) input is used to actuate the electronic stopper open. The down (260) input is to actuate the electronic drain stopper closed. The menu input (365) is utilized to select, set, and/or change electronic drain options such as actuating the electronic drain stopper to a predetermined position and/or actuating the electronic drain stopper on a predetermined time schedule. Once all said connections are made and/or all user settings are set, the electronic drain stopper is now ready to actuate fully in and/or fully out, furthermore, the electronic drain stopper can actuate proportionally depending on how one or more of the plurality of motion sensors and/or switches ((255) (260)) are activated. The USB (270) input upon the local controller (130) is an wired communication to also communicate with the second local controller (290), the harness (275) is a second output to communicate with the actuating device (245) upon the electronic drain stopper. The dc jack (280) inputs a 3.3 v-5 v signal to power up the apparatus or to power up and/or charge the battery operated, wired or wireless, controllers ((130) (290)). The electronic drain stopper assembly and its local controllers ((130) (290)) are very low powered universal devices that can be utilized with any drain system.

FIG. 17A and FIG. 17B Illustrates one of the plurality of central controllers ((285) (FIG. 3)) and electronic drain stopper schematic and (FIG. 17B) illustrates the full assembly of the central controller (285), the local controllers (290), and the electronic drain stopper. In this particular embodiment, the said apparatus components that are depicted to control the apparatus user interface is a Touch screen/LCD screen. The schematic is just to show a functioning electronic stopper at the bare minimum, but also to depict the inputs, outputs, and functionality of the invention. In this particular embodiment, the Touch screen/LCD screen inputs and outputs((255) (260) (365)) are connected to the microcontroller (380). The microcontroller (380) unit is a means for receiving said signal from the Touch screen/LCD screen inputs ((255) (260) (365)), display data upon the LCD screen, and/or save the data received, moreover, the microcontroller (380) output a signal to the driver (90) to drive the actuating device (245) (a servo motor, solenoid, stepper motor, or ac/dc motor) used in conjunction with the electronic drain stopper assembly. The microcontroller (380) also is a means for saving accurate position of the electronic drain stopper, determine and/or record input data from the sensory inputs (165) and outputting said data from the sensory inputs (165) to the local controllers (290) and/or central controller (285), and/or to visually output feedback data to the user, via its LCD screen. The central controller (280) communicates with the local controller (290) by the central controller (285) sending a wired and/or wireless communication signal from a first Bluetooth, Lora, WiFi, and/or zigbee radio controller (270) to the local controller's (290) Bluetooth, Lora, WiFi, and/or zigbee radio controller (270). The local controller (290) is the controller which is connected to the electronic drain stopper's actuating device and/or sensory inputs (165). The local controllers (290) can also send/and receive communication signals from a central controller device such as a computation device and/or mobile device, and moreover, the local controller (290) can be fully controlled by the central controller (285) and/or the mobile device (125). The central controllers ((285) (125) and/or the local controller's (290), in conjunction with this specific EWDC W EDN peripheral device, has other outputs such as visual indicator Leds (265) and/or vibrating motor (370) to alert a user, by a visual and/or tactile means, that a certain function is complete and/or that a specific input is being pressed upon a user interface. The up (255) input is used to actuate the electronic stopper open. The down (260) input is to actuate the electronic drain stopper closed. The menu input (365) is utilized to select, set, and/or change electronic drain options such as actuating the electronic drain stopper to a predetermined position and/or actuating the electronic drain stopper on a predetermined time schedule. Once all said connections are made and/or all user settings are set, the electronic drain stopper is now ready to actuate fully in and/or fully out, furthermore, the electronic drain stopper can actuate proportionally depending on how the inputs upon the Touch screen/LCD screen are activated. The USB (270) upon the central controller (285) is a wired, power and communication, input/output to also communicate with the local controller (290), the harness (275) is a second output to communicate with the actuating device (245) upon the electronic drain stopper. The dc jack (280) inputs a 3.3 v-5 v signal to power up the apparatus or to power up and/or charge the battery operated, wired or wireless, controllers ((285) (290)). The electronic drain stopper assembly and its controllers ((285) (290)) are very low powered universal devices that can be utilized with any drain system.

FIG. 18A and FIG. 18B Illustrates a central controllers ((285) (FIG. 3)) and electronic drain stopper schematic and (FIG. 17B) illustrates the full assembly of the central controllers (285), the local controllers (290), and the electronic drain stopper. In this particular embodiment, the said apparatus components that are depicted to control the apparatus user interface upon the central controller (285) is a voice command module with microphones (305) inputs and/or an audio speaker system (310). The schematic is just to show a functioning electronic stopper at the bare minimum, but also to depict the inputs, outputs, and functionality of the invention. In this particular embodiment, the microphone (305) are the input switches (305) which are connected to the microcontroller (380). The microphone (305) send a audible signal to the microcontroller (DSP) (380), which the microcontroller (380) utilizes its built in analog to digital converter to accept the users analog voice signal from the microphones, convert the analog data to digital data, and/or process and/or save that converted digital data, moreover, the microcontroller (DSP) (380) also send an output control signal of that digital data to the microcontroller of the local controller (290) to start and/or stop a certain function. Next, the local controller (290) can send a feedback signal back to the central controller's (285), built in digital to analog controller, which automatically encodes and/or decodes the digital data, convert it back to analog, which now output a analog signal to audibly speak and/or sound through the audio speaker system (310) what action is taking place in conjunction with the apparatus. For example: the apparatus uses its audio speaker system (310) to audibly send feedback to the user audio speaker system (310) speaking the words “cold water off” or “stopper is down”. The microcontroller (380) (DSP) can also send digital data to be encoded into audible data, this audible data can be saved and/or be spoken through the audio speaker system (310). The microcontroller (380) (DSP) utilizes its built in digital to analog converter, which automatically encodes and/or decodes digital data, to convert a text into speech, to listen to audio music files, and/or to convert digitally prerecorded audio/voice sample to output a analog signal to audibly speak through the audio speaker system (380). Once the microphone send a correct audio signal to the microcontroller, the microcontroller (380) will then output a signal to the driver (90) to drive the actuating device (245) (a servo motor, solenoid, stepper motor, or ac/dc motor) used in conjunction with the electronic drain stopper assembly. The microcontroller (380) also is a means for saving accurate position of the electronic drain stopper, determine and/or record input data from the sensory inputs (165) and outputting said data from the sensory inputs (165) to the local controllers (290) or central controller (285) user interface, and/or output data to the user that the electronic drain stopper assembly is in the position that is required. The central controller (280) communicates with the local controller (290) by the central controller (285) sending a wired and/or wireless communication signal from a first Bluetooth, Lora, WiFi, and/or zigbee radio controller (270) to a local controller's (290) second Bluetooth, Lora, WiFi, and/or zigbee radio controller (270). The local controller (290) is the controller which is connected to the electronic drain stopper's actuating device and/or the sensory inputs (165). The local controllers (290) can also send and/or receive communication signals to and/or from a central controller device such as a computation device and/or mobile device, and moreover, the local controllers (290) can be fully controlled by the central controller (285) and/or the mobile device (125). The central controllers ((285) (125)) and/or the local controller's (290), in conjunction with this specific EWDC W EDN peripheral device, has other outputs such as visual indicator Leds (265) and/or vibrating motor (370) to alert a user, by a visual and/or tactile means, that a certain function is complete and/or that a specific input is being activated upon a user interface. If the user speak “stopper up” the electronic stopper will actuate open. If the user speak “stopper down” the electronic drain stopper will actuate closed. If the user speak “ menu” the apparatus will enter its menu, which is utilized to select, set, and/or change electronic drain options such as, actuating the electronic drain stopper to a predetermined position and/or actuating the electronic drain stopper on a predetermined time schedule. Once all said connections are made and/or all user settings are set, the electronic drain stopper is now ready to actuate fully in and/or fully out, furthermore, the electronic drain stopper can actuate proportionally depending on the audible commands spoken into the user interfaces microphone. The USB (270) upon the central controller (285) is a wired, power and communication, input/output to also communicate with the local controller (290), the harness (275) is a second output to communicate with the actuating device (245) upon the electronic drain stopper. The dc jack (280) inputs a 3.3 v-5 v signal to power up the apparatus or to power up and/or charge the battery operated, wired or wireless, controllers ((285) (290)). The electronic drain stopper assembly and its controllers ((285) (290)) are very low powered universal devices that can be utilized with any drain system.

FIG. 19 Illustrates the EWDC with EDN's electronic block diagram, which depicts the operation for all devices used in conjunction with the EWDC with EDN. The top of the diagram shows how the power supply is inputted to power up the battery charger circuitry and the EWDC W EDN peripheral devices. On the left of the diagram it illustrates how all inputs systems, utilized in conjunction with the central and/or local controllers user interface, is inputted into the microcontroller to send control signals to the apparatus. Next, the illustration depicts how the microcontroller receives the said inputs from the user interface and output a control signal to the driver circuit to actuate one of the plurality of actuating devices. The next stage that the illustration depicts is how the microcontroller can receive a users input and output data from the sensory inputs to the user interface, for a user can monitor and/or calculate its current data, furthermore, the illustration also depicts how the microcontroller can write the sensory inputs data to the memory of the microcontroller. The next stage that the illustration depicts is how the microcontroller can receive a users input to output a signal to a user feedback device, which the user feedback output devices gives a user a visual, auditory, and/or tactile indication of the status of the central controllers and/or local controllers. The next stage that the illustration depicts is how the microcontrollers and the radio controller communication system can transmit and/or receive wired and/or wireless communication signals to and/or from a plurality of different EWDC W EDN peripheral systems and/or a plurality of local controllers and/or central controllers. The EWDC W EDN consist of a plurality of peripheral systems with a plurality of user functions. The plurality of different peripheral systems and/or the plurality of user functions are further discussed in the following paragraphs. A users water turbine generators and/or solar panels consist of a plurality of different uses and/or functions, wherein the water turbine generator's voltage and/or current is generated by how fast the water is flowing through the device via the local water supply and the solar panels generates its power from the energy of the sun, furthermore, the water turbine generators is connected to the battery charging circuitry upon the central controller and/or local controller to charge the embedded battery every time a user runs the water in there home and/or business, while, in unison, receiving a charge from the solar panel units. A user's water main peripheral system has functions and settings to set the water main peripheral to output a predetermined volume of water, to output water on a predetermined time schedule, and/or to output a predetermined pressure of water. The sensory inputs are used to monitor, sense, determine, and/or record water flow movement, water flow pressure, and/or water temperatures that is flowing through the local water supply, moreover, the sensory inputs send that recorded data to the local controllers and/or central controllers microcontroller which will send signals to be monitored upon the user interface, to let the user know the motorized valve position, water flow pressure, and/or water temperature. A users sinks and/or faucets consist of a plurality of water sensors and functions, wherein the sensory inputs functions is a means to determine, send, and/or save continues input data to the microcontroller for sensing the presence of water to stop the sink from over flowing, sensing water temperatures, sensing the water which is flowing volume amount, and/or sensing the water pressure. Other functions for a users sinks and/or faucets is that a user can set the apparatus to output a predetermined volume of water, output a predetermined temperature of water, to output a predetermined water pressure, and/or to output water on a predetermined time schedule. A user's shower peripheral have settings which a user can set and save a plurality of settings to operate the peripheral on a predetermined temperature, a predetermined time schedule, a predetermined water outlet, and/or a predetermined water pressure. A user tub peripheral consist of over flow sensors and other sensory inputs. Also, the tub features consist of a user being able to set and/or save a plurality of settings to operate the peripheral on a predetermined temperature, predetermined water pressure, a predetermined quantity of water, a predetermined water outlet, and/or predetermined time schedule. A users toilet's peripheral consist of sensory inputs to determine and/or monitor the water level, drain flow, water pressure, and/or water refill level by its user interface's Leds, touchscreen, and/or speaker system, but also the central controllers and/or the local controllers can control the flow of water which is flowing through the toilet by the user activating the toilet's on/off inputs upon the central and/or local controllers. The toilet system has sensory inputs that will send a signal to the solenoid valve to cease all flow of water to the toilet if water overflow is detected. The toilet system consist of settings which a user can set and/or save a plurality of settings to set the toilet system peripheral to output a predetermined quantity of water, to operate the toilet peripheral on a predetermined time schedule, and/or if a plurality of toilets is present, the user can select which toilets they want active and which toilets they want inactive. The electronic drain stopper device, if in active status, will cease all flow of drain water by completely closing the drain and also will cease all flow of clean water which is flowing into the toilet. This particular function will allow a user to shut-off there toilet water supply and/or close there drain pipe immediately in case a user drop something inside the toilet accidentally. The local controller connected to the toilet device can also be set to send and/or receive data to and/or from the local controller at the sink to auto detect a flush, moreover, once a flush is detected the local water supply at the sink can be set to automatically turn on the water to a predetermined water temperature and/or set a water pressure for a predetermined time, furthermore, automatically turn the sinks water off after the predetermined time limit has expired. The Local controllers can auto-detect toilet flushes by reading the sensory inputs connected to the toilet. A user's Water heater peripheral can set and/or save settings for automatic cut-off in case of emergencies. The user can also set and/or save settings to the peripheral to output a predetermined temperature, a predetermined volume of water, and/or to operate only between a predetermined time schedule. A user swimming pool peripheral has sensory inputs in which is constructed to never let a user's swimming pool water level get low and/or will never let the water over flow by automating the fill up of the pool. The swimming pool peripheral can set and/or save a plurality of settings to output a predetermined quantity of water into the pool, to output water on a predetermined time schedule to fill up the pool, to output water on a predetermined water temperature, and/or output water on a predetermined water pressure. A user's sprinkler peripheral has a plurality of sensory inputs and/or functions, which the sensory inputs functions is a means to determine, send, and/or save continues input data to the microcontroller for sensing the flow of water, sensing water temperatures, sensing the water which is flowing volume amount, and/or sensing the water pressure. Another function of the sprinkler peripheral is concerning a plurality of predetermined s time schedules settings, and/or concerning a factor wherein the user can set there on plurality of time settings while utilizing input signals which the user has set. The predetermined user input is utilized to proportionally actuate one or more motorized valves to a plurality of different positions, moreover the plurality of different positions are, but not to be limited to, slow flow mode, medium—slow flow mode, medium—fast flow mode, and fast flow mode. The sprinkler peripheral also has functions which can output water from the apparatus utilizing a predetermined water pressure, a predetermined quantity of water, and/or predetermined time schedule. A users electronic drain stopper peripheral functions consist of saving a plurality of time scheduling functions, which is a means for the apparatus to save a plurality of times during there day to automatically send a signal to actuate, in and/or out, the electronic drain stopper assembly. A second plurality of functions of the electronic drain stopper is concerning the sensory inputs, which the sensory inputs functions is a means to send, receive, and/or save continues input data to and/or from the microcontroller for sensing the flow of water, sensing water temperatures, sensing the water which is drained quantity amount, sensing the water drainage flow rate/pressure/speed, and for sensing if the apparatus and/or the drain pipe is clogged and need to get a snake job. A third plurality of functions of the electronic drain stopper is concerning a plurality of predetermined stopper position settings, and/or concerning a factor wherein the user can set there on plurality of stopper positions while utilizing any input signals, which the user has set. The set user input is utilized to proportionally actuate the electronic drain stopper to a plurality of predetermined positions, moreover the plurality of different positions are, but not to be limited to, slow drain mode, medium slow drain mode, medium—fast drain mode, and fast drain mode. A fourth function of the electronic drain stopper is concerning plurality of water depth level timer settings, which is utilized to, time a bath, to wash dishes, and/or to set a timer for waste water to not drain and/or to start draining in any drainage system connected to the apparatus. This specific function automatically actuate the Electronic drain Stopper closed before starting a timer period and/or before any water is turned on, furthermore, this specific function also actuate the Electronic drain Stopper open automatically, to drain used water, after a predetermined time period has expired. All EWDC W EDN peripherals have anti-burn devices and functions to calculate a user's water bill for the day, week, month, and/or year, furthermore, the user can also input into a controller how much money they want there water utility bill to be, wherein the central controllers and/or local controllers automatically calibrate the water flow/pressure rate by utilizing the sensory inputs to determine the water pressure and/or the water flow rate, furthermore, the controllers automatically calibrate the motorized valves to continuously set new parameters, which is utilized to output new predetermined water pressure's into a users home and/or business, which the new predetermined water pressures is utilized to compensate for a day of water over usage, wherein a user outputted a great deal of water on one or more day's and the system need to lower the water pressure in the users home to compensate water for a prolonged period of time. The system continuously calculates and calibrates the apparatus wherein a user's water utility bill will always remain the same price the user set it to be or lower.

CONCLUSION

The Electronic Water Distribution Center with Electronic Drain Network Has Been Modified Time After Time in The Last 5 year and a half, and will continue to be modified in due time. The EWDC W EDN can control a users home, business, city streets, and/or water distribution organizations entire clean water and/or waste water entire plumbing system in a network via a plurality of central controllers and/or local controllers. The apparatus utilizes a plurality of controllers, Electronic Drain Stoppers, sensory inputs, and motorized valves and/or solenoid valves to fully control, determine, and/or monitor the flow of water, the presence of water, the water pressure, the water temperature, and/or the composites/contaminants in the water. The Electronic Water Distribution Center With Electronic Drain network will not only control all homes and/or all business's local water supplies in a network, it will control the world's local water supplies in a network.

Claims

1-70. (canceled)

71. A system for monitoring and/or controlling the flow and/or pressure for a supply of water in a network, comprising: a plurality of local controllers wherein each local controller includes: a transceiver, a first user interface for inputting control signals to control a flow and/or pressure of water, and a first processor wherein the first processor receives user inputs from the first user interface and/or one or more sensor inputs and outputs first signals to control solenoid valves and/or motorized valves connected to a local water supply to control the pressure and/or flow of water wherein the user inputs is a command to output a predetermined quantity of water, a predetermined water pressure, a predetermined temperature of water, and/or output water on a predetermined time schedule; and the sensory inputs causes the first processor to start and/or stop the flow of water; and a central controller for communicating with each of the local controllers, wherein the central controller has a second user interface to send and/or receive control signals for monitoring and/or controlling the pressure and/or flow of water at each of the local controllers, a second transceiver for communicating with each of the local controllers, a second processor for receiving the control signals from the second user interface wherein the second processor uses the second transceiver to send the control signals to one of the local controllers to control the pressure and/or flow of water at the local controller and wherein the central controller receives input control signals from each of the local controllers.

72. The system for monitoring and/or controlling the flow and/or pressure for a supply of water in a network in claim 71, further including visual, auditory, and/or tactile outputs at each of the central controllers and/or at each of the local controllers to indicate the status of the central controllers and/or local controllers.

73. The system for monitoring and/or controlling the flow and/or pressure for a supply of water in a network in claim 71, wherein the first and/or the second user interface is constructed with one or more motion sensors, LCD, touchscreen devices, microphones, and/or any type of switches.

74. The system for monitoring and/or controlling the flow and/or pressure for a supply of water in a network in claim 71, wherein the first and/or the second user interface is constructed with one or more motion sensors to recognize a humans presence from long distances and/or short distances, to start and/or stop the flow of water, and/or to power up the device or wake up the device from sleep mode via a hands free means, and/or to send control signals to power down the device or put the device in sleep mode via a hands free means.

75. The system for monitoring and/or controlling the flow and/or pressure for a supply of water in a network in claim 71, wherein the first and/or the second transceivers communicates via a wire and/or wirelessly, the transceivers communicates on a online (world wide web) and/or offline network, and/or the transceivers communicates with the internal and/or external audio sound systems for playing, transmitting, and/or receiving music files or audio files.

76. The system for monitoring and/or controlling the flow and/or pressure for a supply of water in a network in claim 71, wherein the local controllers are connected to a body of water and the sensory inputs determines the level of water in the body of water; and/or the sensory inputs determines the level of water in the body of water and if the body of water decrease under the sensory inputs, the body of water will automatically start to refill the water until the body of water reaches the sensory inputs.

77. The system for monitoring and/or controlling the flow and/or pressure for a supply of water in a network in claim 71, wherein the local controllers are connected to a hot water supply and the sensory inputs determines the water temperature and/or pressure outputting from the hot water supply; and moreover, if the water is to hot for human use, will automatically shut off the hot water supply until the water temperature is under the predetermined temperature and/or the apparatus will automatically divert the local water supply to the drain until the water temperature is at a temperature deemed safe for human interactions.

78. The system for monitoring and/or controlling the flow and/or pressure for a supply of water in a network in claim 71, wherein the local controllers and valve systems is connected to monitor and/or control a user's sink, faucet, shower, tub, toilets, sprinklers, and/or air conditioner/swamp cooler system's plurality of local water supplies; and/or a user's sink, faucet, shower, tub, toilets, sprinklers, and/or air conditioner/swamp cooler system's local water supplies water pressure and/or flow of water is controlled by one or more motorized valves and/or one or more solenoid valves.

79. The system for monitoring and/or controlling the flow and/or pressure for a supply of water in a network in claim 71, wherein the local controllers are connected to monitor and/or control a local water supply and the sensory inputs determines the water temperature, contaminants in water, pH level in water, TDS level, water flow rate, and/or the water pressure outputting from the local water supply.

80. The system for monitoring and/or controlling the flow and/or pressure for a supply of water in a network in claim 71, wherein the first user interface and/or the second user interface receive data from the sensory inputs in which the data is utilized to monitor and/or save sensory data to calculate water usage, calculate a users water bill, and/or save a users water usage data; and/or the first user interface and/or the second user interface receive data from the sensory inputs to automatically calibrate the motorized valves and/or solenoid valves to output a predetermined quantity of water, a predetermined temperature of water, a predetermined pressure of water, and/or output water for a predetermined time period.

81. The system for monitoring and/or controlling the flow and/or pressure for a supply of water in a network in claim 71, wherein a central controller is housed in a water utility facility to send control signals to a plurality of local controllers to control the pressure and/or flow of water at one or more of the local controllers connected to a plurality of water main pipelines; and/or wherein a central controller is housed in a water utility facility to receive control signals from a plurality of local controllers to determine and/or monitor sensory data of the valves position, water pressure, and/or flow of water at one or more of the local controllers connected to a water main pipeline.

82. The system for monitoring and/or controlling the flow and/or pressure for a supply of water in a network in claim 71, wherein the central controller is implanted on a smart phone and/or the central controller is implanted on a computation device.

83. A method for constructing and operating an electronic drain stopper, comprising: a first electronic drain stopper device constructed with a drain pipe assembly, a actuating device housed onto the drain pipe assembly, a drain stopper, sensory inputs to monitor waste water conditions and/or activity flowing through the drain, a plurality of linkage devices to connect the actuating device to the drain pipe assembly and/or a plurality of linkage devices to connect the actuating device to a lever which is connected to a drain stopper upon the drain pipe assembly wherein the electronic drain stopper assembly can now electronically be actuated and/or proportionally be actuated in any direction; moreover, a plurality of local controllers wherein each local controller includes: a transceiver, a first user interface for inputting control signals to control the flow and/or pressure of waste water, and a first processor wherein the first processor receives user inputs from the first user interface and one or more sensory inputs and outputs first signals to control the actuating devices of the electronic drain stopper assembly connected to a local drain to control the pressure and/or flow of waste water wherein the user inputs is a command to set the electronic drain stopper to a predetermined stopper position, to actuate the Electronic Drain Stopper on a predetermined water temperature, and/or the user interface send commands to actuate the electronic drain stopper assembly automatically by utilizing a predetermined time schedule; and the sensory inputs causes the first processor to start and/or stop the flow of water.

84. A method for constructing and operating an electronic drain stopper in claim 83, wherein the electronic drain stopper device is further constructed with a drain pipe assembly that has a plurality of inlets and/or outlets, one or more disk shaped objects which slides in and/or out between a first set of linkage device sliding mechanisms and/or one or more grooves which is constructed upon the drain pipe assembly, one or more actuating devices housed onto the drain pipe assembly, sensory inputs to monitor waste water conditions and/or activity flowing through the drain, and a second plurality of linkage devices and/or gearing systems to connect the actuating device to the disk shaped objects wherein the disk shaped objects can now slide in and/or out between one or more sliding mechanisms and/or one or more grooves which is constructed upon the drain pipe assembly to start and/or stop the flow of waste water from draining at one or more inlets and/or outlets in conjunction to the electronic drain stopper assembly.

85. The system for monitoring and/or controlling the pressure and/or flow for a drain in a network, comprising: a plurality of local controllers wherein each local controller includes: a transceiver, a first user interface for inputting control signals to control the pressure and/or flow of waste water which flows through a drain pipe, and a first processor wherein the first processor receives user inputs from the first user interface and sensory inputs and outputs first signals to control the actuating device connected to a local electronic drain stopper assembly to control the drain pressure and/or flow of drain water wherein the user inputs is a command to output a predetermined stopper position, actuate on a predetermined time period, and/or to actuate the electronic drain stopper on a predetermined temperature of water; and the sensory inputs causes the first processor to start and/or stop the flow of waste water; and a central controller for communicating with each of the local controllers, wherein the central controller has a second user interface to send and/or receive control signals for controlling the pressure and/or flow of waste water at each of the drains local controllers, a second transceiver for communicating with each of the local controllers, a second processor for sending and/or receiving the control signals from the second user interface wherein the second processor uses the second transceiver to send the control signals to one of the local controllers to control the pressure and/or flow of waste water at the drains local controller and wherein the central controller receives input control signals from each of the local controllers.

86. The system for monitoring and/or controlling the pressure and/or flow for a drain in a network in claim 85, wherein the central controller is implanted on a smart phone and/or the central controller is implanted on a computation device.

87. The system for controlling the flow for a supply of water in a network in claim 41, further including auditory outputs at the central controllers and/or at each of the local controllers to indicate the status of the central controllers and/or local controllers.

88. The system for controlling the flow for a supply of water in a network in claim 41, wherein the first and/or the second user interface is constructed with one or more motion sensors, LCD, touchscreen devices, microphones, and/or any type of switches.

89. The system for controlling the flow for a supply of water in a network in claim 41, wherein a local controller is connected to monitor and/or control a shower system with one or more spouts; and/or a local controller is connected to a shower system to monitor and/or control the local water supply and the sensory inputs determines the water temperature, water pressure, and/or water flow rate outputting from the local water supply.

90. The system for controlling the flow for a supply of water in a network in claim 41, wherein the first and/or the second transceivers communicates via a wire and/or wirelessly, the transceivers communicates on a online (world wide web) and/or offline network, and/or the transceivers communicates with the internal and/or external audio sound systems for playing, transmitting, and/or receiving music files or audio files.