TH36378B - UV intensity detector in water treatment system - Google Patents

Abstract

DC60 The invention relates to the optical monitoring system implemented in the water treatment system. The monitoring system will including light guide and light intensity detector The light guide is impregnated with a changing glow color. Ultraviolet light is visible light. The light guide includes a number of internal angles in focus. The incident light on the light guide goes to the light intensity detector. The light intensity sensor will monitor The visible light is transmitted to the detector by an optical tube and the ultraviolet intensity is determined. The relative output of the luminaire assembly within the water treatment system depends on the visible light that is monitored. The invention relates to the light monitoring system implemented in the water treatment system. The monitoring system will including light guide and light intensity detector The light guide is impregnated with a changing glow color. Ultraviolet light is visible light. The light guide includes a number of internal angles in focus. The incident light on the light guide goes to the light intensity detector. The light intensity sensor will monitor The visible light is transmitted to the detector by an optical tube and the ultraviolet intensity is determined. The relative output of the luminaire assembly within the water treatment system depends on the visible light being monitored.

Claims (9)

Disclaimers (all) that will not appear on the advertisement page: 1. Water treatment system at the point of use that includes The base unit includes a photodetector. A lamp assembly that includes an outer casing At least partially placed lamp and light pipe assemblies are included in the enclosure. The lamp assembly includes the core and emits UV and visible light as the unit. Assembling the lamp gets power Light guides contain fluorescent colors that convert UV light into visible light. Light guides include a number of internal angles that are angled against each other and are focused. Visible light goes to photodetector and where it detects visible light emitted from the conduit. Light to determine the relative intensity of the UV light produced by the lamp assembly. 2. System according to claim 1, where the visible light intensity emitted by light pipes is generally proportional. Directly to the intensity of the UV light emitted by the lamp assembly. 3. System according to claim 2, where the light guide pipes glow and give green light. 4. System according to claim 3, where the lamp assembly will include a lamp with a first and second filament and a section between The extended medium between the first and second filament and the light guide tube has a filament surface that is generally opposite to the first filament of the series. Assemble the bulb and the lamp surface perpendicular to the middle part of the bulb. Where the visible light detected by the detector of such light intensity is produced by The luminescence of the light guide, which primarily responds to the UV light on the lamp surface. 5. System according to claim 4, where a lamp assembly will have a common U-shape with first and second filament. It is generally opposite of the filament surface of the light guide. 6. System according to claim 5, where the second lamp surface is generally bordered to focus on the center part of the bulb. 7. System according to claim 2, where fluorescent pigments are generally green. 8.A system according to claim 7, where the light-guide tubes have a light-emitting surface placed side-by-side with photodetectors, and the light guides are morphed to reflect and focus light on the surface. Front lamp Of the light guide pipe to the photodetector 9. System according to claim 1, where the lamp assembly also includes a reflector assembly that is placed within the casing to Reflect the light from the lamp assembly to the water passing through the lamp assembly 1. 0. System according to claim 1, where light guides are made of plastic 1 1. System according to claim 10, where the plastic will be acrylic 1. 2. System according to claim 1, where the light guide pipe will include the surface of the lamp and its assembly. The lamp will include a reflector assembly. The surface of the lamp is contoured and laid out. Where to receive light from reflector assembly 1 3. Light monitoring system in the water treatment system that includes Optical detectors Ultraviolet light source A light guide, placed between the a violet-rated light source and the photodetector, contains a fluorescent pigment that is modified to alter the ultraviolet light. Is released from such an ultraviolet light source and strikes the light guide tube. Visible being detected by the aforementioned photodetector The light guide pipe will include the exposure surface. Light-emitting skin And a number of internal angles that are compared and adjusted to focus light That hits on the face, receives such light to the face that emits light 1 4. Light monitoring system according to claim 13, where such light detectors will The relative intensity of the ultraviolet light emitted by such ultraviolet light sources by Depends on visible light 1 5. Optical monitoring system according to claim 13, where ultraviolet light is Lines with visible light 1 6. Optical monitoring system according to claim 13, where optical pipes are made of plastics and substances. The fluorescent paint will be mixed with plastic 1. 7.Light detector in the water treatment system at the point of use that includes Receptors tuned to detect visible light rays, source processors tuned primarily to emit ultraviolet light and emitters that include fluorescent pigments. The first surface is positioned adjacent to the source, and a number of internal angles are compared. By the emitter that will be adjusted to It receives ultraviolet light from a source through one such surface and focus the visible light rays. Got to the receptors with a number of such angles Where the processor will determine Relative intensity of light radiation, violet rate, depending on the light radiation, the rate of violet transmitted to 1 8. Photodetector according to claim 17, where such fluorescent pigments are mixed with each other. Through the aforementioned emitter 1 9. Optical detectors according to claim 17, where the transmitter and will be structured in hard plastic 2. 0. Light detectors according to claim 17, where the source will be an ultraviolet lamp. Including filament And where one such surface will be positioned adjacent to the filament.