US2005263444A1PendingUtilityA1

Sensing and notification systems and methods

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Assignee: BACA ANTHONY MPriority: Mar 14, 2002Filed: Jul 18, 2005Published: Dec 1, 2005
Est. expiryMar 14, 2022(expired)· nominal 20-yr term from priority
C02F 2209/36A61C 1/0076C02F 2201/3224C02F 2201/3228C02F 2201/3226C02F 2209/40C02F 1/006C02F 2201/326Y02W10/37C02F 1/325C02F 2209/008
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Claims

Abstract

A water-borne hazard detection and notification system deployed between water treatment facilities and water's points of use can include sensors (e.g., flow rate, microorganism detectors, and chemical detectors) and can be microprocessor controlled. Sensors detect microorganisms and/or chemicals within a water distribution system. Treatment areas can be deployed at various stages along a water distribution system, allowing for protection redundancy. Detector and/or treatment systems can be networked to remote monitoring systems (e.g., networked data/communications equipment located with agencies operating and command and control units) through wired and/or wireless network communication means and devices. Data networked monitoring and assessment can enable rapid deployment of counter measures (e.g., valve shut-off, UV treatment, field team deployment). Systems can be staged, providing for a system comprising more than one detection, shut-off and/or treatment. Staging can provide for concentrated redundancy prior to delivery of water to its point of use.

Claims

exact text as granted — not AI-modified
1 . A water-borne hazard detection and notification system, comprising: 
 water-borne hazard detection sensors deployed after a water treatment facility at nodes along a water distribution system leading to points of water use, said sensor for detection biological microorganims or chemicals; and    communications deployed with said sensors for notifying at least one remote monitoring system about detection by said at least one water-borne detection sensor of hazardous biological microorganisms or chemicals flowing through said water distribution system.    
     
     
         2 . The invention of  claim 1 , further comprising treatment areas deployed at said nodes for providing ultraviolet light into water containing said biological microorganisms or chemicals.  
     
     
         3 . The invention of  claim 2 , further comprising flow sensors deployed at said nodes and ultraviolet laser light sources located within said treatment areas, wherein said sensors turn on the ultraviolet laser light sources whenever fluid flow through said nodes is sensed.  
     
     
         4 . The invention of  claim 1 , further comprising filters deployed at at least one of input or output points relative to said nodes.  
     
     
         5 . The invention of  claim 1 , further comprising at least one shut-off valve deployed at said nodes, said at least one shut-off valve responsive to at least one of said detectors or said remote monitoring systems by blocking water flow through said nodes.  
     
     
         6 . The invention of  claim 1 , said treatment area further comprising a junction box having an entry point for receiving water from input tubing connected to the input portion of the junction box and an exit point to allow treated water to continue moving towards said points of use, and at least one ultraviolet laser light source coupled to the junction box to enable ultraviolet light to illuminate the water when it is located within the junction box.  
     
     
         7 . The invention of  claim 6  wherein said ultraviolet laser light source can be provided in the form of at least one of: a fiber optic line coupled to a laser and also coupled to the junction box, or as at least one laser directly coupled to the junction box, at at least one point about the junction box.  
     
     
         8 . The invention of  claim 6  wherein the junction box further comprises a stainless steel, watertight housing wherein internal surfaces of the housing are highly polished to allow for reflection of light.  
     
     
         9 . The invention of  claim 8  wherein said junction box further comprises at least one of reflectors, deflectors and diffusers within said housing to scatter light provided by said ultraviolet laser light source.  
     
     
         10 . The invention of  claim 6  further including at least one of baffles or walls that are formed within the housing to create flow channels throughout the housing, wherein said at least one of baffles or walls slow down water flow within said treatment area thereby providing more opportunities for ultraviolet light exposure of water and its treatment.  
     
     
         11 . The invention of  claim 6  wherein said treatment area includes a housing comprising baffles formed therein, said baffles creating chambers in a serpentine configuration that enable the flow of water through said chambers within the housing.  
     
     
         12 . The invention of  claim 11  further comprising at least one ultraviolet laser light source assigned to each chamber, wherein each of said ultraviolet laser light source can be tuned to a unique wavelength.  
     
     
         13 . A water-borne hazard detection and water treatment system for deployment at nodes along a water distribution system, comprising: 
 at least one detector, said detector for detecting the presence of biological microorganisms or chemicals in water;    a communication system, said communication system for reporting detection of the biological microorganisms or chemicals by said at least one detector to at least one remote monitoring system and for receiving treatment commands from said at least one remote monitoring system; and    a treatment area comprising a housing having an entry point for receiving water into said treatment area and an exit point for to allow treated water to continue moving towards its point of use and at least one ultraviolet laser light source coupled to the housing, said treatment area for providing ultraviolet light into water containing biological microorganisms or chemicals.    
     
     
         14 . The invention of  claim 13 , further comprising at least one shut-off valve responsive to said detector or said at least one remote monitoring system by preventing water flow.  
     
     
         15 . The invention of  claim 14  wherein said housing is watertight and comprised of stainless steel internal surfaces that are highly polished.  
     
     
         16 . The invention of  claim 14  wherein said housing further comprises at least one of reflectors, deflectors and diffusers to scatter light provided by said ultraviolet laser light source.  
     
     
         17 . The invention of  claim 13  said housing further including walls forming channels defining a serpentine configuration wherein water can flow through said channels.  
     
     
         18 . A water-borne hazard detection and notification system, comprising: 
 at least one detector located in nodes deployed along a water distribution system towards water's intended point of use, said detector for detecting the presence of biological microorganisms or chemicals in water flowing towards its intended point of use;    a communication system, said communication system for reporting detection of the biological microorganisms or chemicals by at least one detector deployed in at least one of the nodes to at least one remote monitoring system; and    at least one shut-off valve deployed at or near at least one of the nodes, said at least one shut-off valve responsive to at least one of said detectors or said remote monitoring systems by blocking water flow through said nodes.    
     
     
         19 . The invention of  claim 18  further comprising a treatment area, said treatment area including a housing having an entry point for receiving water into said treatment area and an exit point for to allow treated water to continue moving towards its point of use and at least one ultraviolet laser light source coupled to the housing, said treatment area for providing ultraviolet light into water containing biological microorganisms, wherein treatment is provided within said treatment area in response to treatment commands received from said at least one remote monitoring system through said communication system.  
     
     
         20 . The invention of  claim 19 , wherein said housing is watertight and comprised of stainless steel internal surfaces that are highly polished, includes at least one of reflectors, deflectors and/or diffusers for scattering light provided by said at least one ultraviolet laser light source, and includes walls that form channels which define a serpentine configuration wherein water can flow.  
     
     
         21 . The invention of  claim 19 , further comprising a variable wavelength controller, wherein said at least one ultraviolet laser light source can be adjusted by said variable wavelength controller in response to detection by said detector, thereby enabling for precise targeting of detected microorganisms.  
     
     
         22 . The invention of  claim 19 , further comprising: 
 a variable wavelength controller provided to adjust the wavelength of light produced by the ultraviolet laser light source in response to detection by said at least one detector.    
     
     
         23 . The invention of  claim 19 , further comprising a flow sensor wherein said flow sensor can cause said at least one ultraviolet laser light source to be turned on whenever water flow through said treatment area is sensed.  
     
     
         24 . The invention of  claim 19 , further comprising at least one filter deployed near at least one of said input or output points.  
     
     
         25 . The invention of  claim 19 , further comprising: 
 includes a housing comprising baffles formed therein, said baffles creating chambers in a serpentine configuration that enable the flow of water through said chambers within the housing;    at least one ultraviolet laser light source assigned to each of said chambers, wherein each of said ultraviolet laser light source can be tuned to a unique wavelength.

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