TR2022008280A2 - A SYSTEM AND METHOD FOR WATER DISINFECTION THROUGH LIGHT - Google Patents

Abstract

It is a system (100) for water disinfection by means of light, and the system (100) contains a housing (300) made of plastic. The housing (300) contains the entry-exit point (110, 150) to provide a secure connection to the external water supply channel (130, 140). The channel (130, 140) is configured in the interior of the housing (300), where the channel (130, 140) is configured to carry the water that needs to be disinfected to the interior of the housing (300). Additionally, a light source (104) is provided, wherein the light source (104) is configured inside the housing (300) to emit the specific frequency for disinfection of water present in the plurality of channels (130, 140). A coating is provided on the inside of the housing (300), where the coating is adapted to reflect the light emitted from the light source (104), and a cooling means (310) is provided on the surface of the housing (300), where the cooling means (310) is adapted to reflect the light emitted from the light source (104). It is configured to ensure easy passage of hot air from 300) to the atmosphere.

Description

DESCRIPTION METHOD THEREOF TECHNICAL FIELD The present invention is in the field of water purification. In particular, the invention provides a method and system for purifying water with ultraviolet energy. PRIOR ART: The following prior art topic contains information that may be useful in understanding the present invention. It is not assumed that any of the information provided herein is prior art or that it relates to the present claimed invention, nor that any publication specifically or indirectly referenced is prior art. To make water suitable for drinking, disinfection of water is a very important step. Disinfection of water began early, and over the years a wide variety of methods, including chlorination, have been used to disinfect water. The guidelines first appeared in the modern era in 1854, when a cholera epidemic was discovered to be spread through water. The outbreak appeared to be less severe in areas where sand filters were installed. British scientist John Snow found that the direct cause of the epidemic was water pump pollution of sewage water. He used chlorine to purify water, which paved the way for water disinfection. However, recent research has provided strong evidence of health disadvantages associated with the use of chlorine as the primary means of disinfecting drinking water; For example, the US Environmental Protection Agency has reported that some chlorine byproducts formed during water treatment are carcinogenic. Additionally, chlorine is not effective in removing biofilm from a water source and harms the environment. Another disinfection process is the use of ozonated water treatment. In ozone water treatment, ozone is dissolved in water to kill microorganisms, destroy organics, and break down chloramines through oxidation. Although it is also effective as a disinfectant, the use of ozone is not recommended due to the corrosive nature of the gas, its odor, and its harmful nature to humans if its concentration is not properly regulated. Operating and equipment costs for ozonation are relatively high and require constant maintenance. Ozone is not as soluble as chlorine, which means special mixing techniques must be used to properly dissolve ozone gas. Another significant disadvantage of ozonation is that it leaves no residual disinfecting elements, which means that the regrowth of bacteria or viruses cannot be prevented. The most popular way to disinfect water is through the use of ultraviolet light. Ultraviolet light (UV) is a very effective disinfection agent. UV is found in nature by emitted from the sun. UV light does not add any chemicals to the water and therefore does not cause health, taste or odor problems. It is well known that germicidal lamps, which emit UV light in the 254 nm range, are effective in disinfecting most bacteria, viruses and cysts. To kill microorganisms, UV rays must hit the cell. UV energy penetrates the outer cell membrane, passes through the cell body and disrupts its DNA, preventing reproduction. UV treatment does not chemically change the water; Nothing is added except energy. Sterilized microorganisms are not removed from water. UV disinfection does not remove dissolved organic matter, inorganic matter or particles from water. The degree of inactivation by ultraviolet radiation is directly related to the UV dose applied to the water. Dosage, which is a product of UV light intensity and exposure time, is measured in microwatt seconds per square centimeter (uws/cmz). Going further, the water disinfection system uses UV rays emitted from a UV lamp. Most often, water that should be disinfectant is passed through the housing or module containing the UV Lamp. Generally, the housing or module in question is manufactured from metal or plastic polymers. These types of chambers have certain limitations. In the case of the chamber made of plastic, UV light is a very strong form of light that the human eye cannot see. UV light, a form of energy, is defined as light with wavelengths between 100 nanometers (nm, 1 billionth of a meter) and 400 nm. UV light is further divided into UV-A, UV-B and UV-C light. The wavelength of UV-C is 100 to 290 nm. All forms of UV are capable of producing a photochemical reaction within the polymer structure that can cause material degradation. UVC, which has higher energy, is most likely to damage polymers. Absorbed UV energy can excite photons in a plastic. Activated photons can cause the formation of free radicals. While many pure plastics cannot absorb UV radiation, the presence of trace amounts of catalyst residues and other impurities (e.g. oxygen and sodium) will often act as free radical scavengers. These free radicals have the potential to cause polymer bond breaks. Additionally, the manufacturing process of the metal chamber is somewhat complicated. Generally, metal bodies oxidize and form metal oxides, polluting water and posing a health hazard to consumers who consume the water. Also, in the traditional UV system the waiting time before dispensing water is usually 20-30 seconds and the lamp is always turned on before dispensing water. This delay is due to the limitation of the UV lamp, as it takes time for the germicidal UVC ray of the lamp to fully concentrate for effective results before the water flows through the UV module. The UV lamp can be kept ON constantly to reduce lag concerns. However, due to high intensity UV rays, due to light and limitation with the existing UV chamber outlet water, it gets hot if the user dispenses the water after a few hours. Therefore, there is a need for a UV system that not only uses less energy than a metal-body UV system, but is also less bulky and safe for use in any environment. There is also a need for a UV system that makes complex shape production easier with the use of plastic molded components. In addition, metallized coatings provide better focusing of UV rays in the water flow channel. Therefore, the present invention addresses the above-mentioned technical problem by providing a plastic housing with a reflective coating. The invention provides a UV system with plastic molded components with ventilation holes for cooling, and the inner surface is metallized for efficient use of UV energy. Metallized coatings allow better focusing of UV rays on the water flow channel and the highly polished reflective surface and also ensure that the plastic does not deteriorate. The UV system provides safe water for drinking with faster disinfectant time and energy efficient operation. PURPOSE OF THE INVENTION AND THE PRESENTED SYSTEM: The primary purpose of the present invention is to provide a UV system whose module is produced from plastic material. Another aim of the present invention is to provide a UV system whose inner surface is equipped with fins for non-heating and efficient temperature management. Another object of the present invention is to provide a UV system whose housing is designed in such a way that maximum UV rays after reflection from the surface can be focused or concentrated on the water flow path to achieve higher efficiency. Another aim of the present invention is to provide a UV system with improved heat distribution. Another aim of the present invention is to provide a UV system that has lower manufacturing costs and is more energy efficient. Another object of the present invention is to provide a UV system that is very safe and has better control over food grade fractions, thus making the water disinfected by the system safe from any contamination and health hazards. BRIEF DESCRIPTION OF THE INVENTION The general purpose of the present invention is to provide an energy-saving and non-hazardous water disinfection system that is easy to produce in different sizes and is cost-effective. To achieve the above objectives and meet the identified requirements, in one aspect, the present invention provides a water disinfection system comprising: a) a housing manufactured from plastic wherein the housing exterior includes the entry-exit point for providing secure connection to the water supply conduit; b) a plurality of channels configured in the interior of the housing, wherein the plurality of channels are configured to carry water that needs to be disinfected into the interior of the housing; c) a light source wherein the light source is configured inside the housing to emit specific frequency for disinfection of water present in a plurality of channels; d) a coating provided on the interior of the housing, wherein the coating is adapted to reflect light emitted from the light source; and e) a cooling means provided on the surface of the housing, wherein the cooling means is configured to allow easy passage of warm air from the housing to the atmosphere. In one embodiment, the invention provides a method for water disinfection by means of light, the method comprising the following steps: providing the entry-exit point on a plastic housing, wherein the housing includes the entry-exit point for providing safe connection to the external water supply channel; transporting water by a plurality of channels, wherein the plurality of channels are configured to transport water that needs to be disinfected into the interior of the housing; providing a light source, wherein the light source is configured inside the housing to emit specific frequency for disinfection of water present in the plurality of channels; d) applying a coating on the inside of the housing, wherein the coating is adapted to reflect light emitted from the light source; and e) providing a cooling means, wherein the cooling means is configured to allow easy passage of warm air from the housing to the atmosphere. This, together with other aspects of the present invention, together with various features of the innovation characterizing the present specification, are specifically set forth in the claims appended hereto and form a part of the present invention. For a better understanding of the present invention, its operational advantages, and the stated purpose achieved by its uses, reference should be made to the accompanying explanatory material in which exemplary embodiments of the present invention are illustrated. BRIEF DESCRIPTION OF THE DRAWINGS will be better understood by reference to the claims associated with the accompanying drawings, wherein: a) Figure 1 shows a detailed UV system diagram with internal components, according to certain exemplary embodiments of the present invention; b) Figure 2 shows a cross-sectional view of the UV housing with heat distribution detail according to various embodiments of the present invention. DESCRIPTION OF REFERENCES 100 System 104 Light source 110, 150 Entry-exit point 120 UV chamber 130, 140 Channel 300 Slot 310 Cooling device DETAILED DESCRIPTION OF THE INVENTION The above descriptions of specific embodiments of the present invention are presented for illustrative and illustrative purposes. They are not intended to be comprehensive or to limit the invention to the precise figures disclosed, and it is clear that many modifications and variations are possible in light of the above teaching. Exemplary embodiments are the invention of those skilled in the art and have been selected and described in order to best illustrate the principles and practical application of the invention to enable various applications to be used to their best advantage with various modifications suitable for the particular intended use. The term "one" herein does not indicate quantity limitation, but rather the presence of at least one of the item referred to. indicates the presence of the component. The invention provides a UV system (100) with a UV slot (300) made of plastic with a metallized coating on the inner surface to protect it from high dose UV rays. The water disinfection process may include the neutralization or removal of any organism, bacteria, microorganism, structure, formation, microbe, germ, virus, organic pollutant, or non-organic pollutant. Illustrative embodiments of the invention may refer to the use of ultraviolet (UV) light to disinfect fluid and/or oxidize particles within the fluid. However, it will be appreciated by those skilled in the art that light of any other suitable spectrum may be used in other embodiments of the invention. In one embodiment, the UV system 100 integrates multiple features/enablements whereby the device can be accessed remotely using a web interface. The UV system (100) can be controlled remotely by the user electronic device. In one embodiment, the UV system (100) is user-friendly as it is lightweight due to being made of plastic and can be easily mounted anywhere according to the user's needs. In one embodiment, the UV system 100 integrates features of Artificial Intelligence (AI), Blockchain Technology, and Machine Learning (ML) technology, which interpret, evaluate, and control UV exposure to water. This type of notification can be viewed on a mobile application installed for the device. In one embodiment, the device provides the availability of information to the user through a built-in mobile application (app) that supports IOS, Harmony OS systems (100) and Android systems (100). Once the mobile application is installed, the user can log in with their phone number. The present invention provides a device that not only uses less energy than the metal-body UV system (100%), but is also less bulky and safe for use in any environment. The UV system (100) can be controlled by the cloud using rf, internet (via Wifi or SIM) or bluetooth and wired/wireless controls. The device can be triggered to perform the disinfection function via the web or mobile platform using the analog switch, and can also be automated according to various conditions. In one embodiment, the invention provides a water disinfection system (100) in which the housing (300) is made of plastic and covered from the inside, thus preventing the internal coating of the housing (300) from deteriorating and extending the life of the system (100). The mechanical design we use is unique and ensures proper ventilation of the hot air coming from the body, lower energy consumption and higher efficiency. In one embodiment, the water disinfection system (100) includes the following components: a) a housing (300) made of plastic, where the housing (300) has inlet and outlet to provide a safe connection to the outer water supply channel (130, 140). contains the dot (110, 150); b) a plurality of channels (130, 140) configured in the interior of the housing (300), wherein the plurality of channels (130, 140) are configured to carry the water that needs to be disinfected to the interior of the housing (300); It is configured in the interior of the housing (300) to emit the specific frequency for disinfection of the available water; d) a coating provided on the interior of the housing (300), wherein the coating is adapted to reflect light emitted from the light source (104); and e) a cooling device (310) provided on the surface of the housing (300), where the cooling device (310) is configured to provide easy passage of hot air from the housing (300) to the atmosphere. Referring to Figure 1, there is a detail diagram of the UV system (100) with internal components, said system (100) consisting of a tube or channel (130, 140) to carry the water to be disinfected and one or more light sources ( 104). According to embodiments of the invention, light sources can be UV light sources capable of emitting light at 254 nm. The channel (130, 140) may have an inlet to receive the water to be disinfected from an external water pipe and an outlet to discharge the liquid through an external discharge pipe. The UV system (100) may also include adapters to connect the channel (130, 140) to external liquid pipes. In one embodiment, the light source 104 can emit UV light with wavelengths in the range of 100 nm to 400 nm. The UV light in question is further divided into UV-A, UV-B, UV-Vacuum and UV-C light. The wavelength of UV-A is 315-400nm, the wavelength of UV-B is 280- and all types of UV light wavelengths can disinfect water. In one embodiment, the channel (130, 140) can be produced from UV-transparent glass such as quartz. Light sources can illuminate the liquid to be disinfected while flowing in the channel (130, 140). In this configuration, the water in the channel (130, 140) is exposed to UV light from all sides. The UV light directly hits the quartz front channel (130, 140) and the back side of the channel (130, 140) receives most of the reflected UV light from the surface of the slot (300). In one embodiment, the light source 104 is capable of producing UV light of a suitable UV-germicidal spectrum. For example, the light source 104 may include one or more UV lamps, e.g., low pressure UV lamp, low pressure high output UV lamp, medium pressure UV lamp, high pressure UV lamp, and/or microwave excitation UV lamp. In one embodiment, the pipes have diameters that vary along their length. The shape of the channel (130, 140) can be determined in advance to increase the efficiency of the disinfection process. The inner diameter of the pipe may vary along its length. The specific shape of the channel (130, 140) can affect the water flow pattern and the shape can be predetermined to increase the overall efficiency of the disinfection system (100). Experimental data to evaluate disinfection at different water flow rates are explained with the following example: Laboratory UV CHAMBER and Influent water milking Wastewater milking Reduction Log 10 reduction AWRTCL/l ' - - › 3.3010g10 o loglO 0 1-2.0LPM 99.9995 3.3010g10 o loglO 0 2-1.0LPM 99.9996 3.48log10 o loglO 8 AWRTCL/l 2-1.5LPM AWRTCL/l 3-1.5LPM 99.9995 3-2.0LPM 99.9995 3.3010g10 o loglO 8 -- . 5. Recommended by the Laboratory Test water Specification V Concentration provided concentration Ph 6.5 to 8.5 7.30 TDS mg/L 50 - 500 390 TOC mg/L 0.1 to 5.0 lmg Turbidity NTU <1NTU <1 Temperature 0C 20±5 0C 24 0C TEST WATER COMPOSITION: GTW#1 (General Test water- 1) UV chamber-Z -- .5. Recommended by the Laboratory Test water Characteristic V Concentration provided concentration Ph 6.5 to 8.5 7.30 TDS mg/L 50 - 500 390 TOC mg/L 0.1 to 5.0 lmg Turbidity NTU <1NTU <1 Temperature 0C 20±5 0C 24 0C COMPOSITION OF TEST WATER: GTW#1 (General Test water- 1) UV chamber-3 .. w. Recommended by the Laboratory Test water Characteristic V Concentration provided concentration Ph 6.5 to 8.5 7.30 TDS mg/L 50 - 500 390 TOC mg/L 0.1 to 5.0 lmg Turbidity NTU <1NTU <1 Temperature 0C 20±5 0C 24 0C In an embodiment, the invention Three UV chambers (120) with the same configuration are provided to control the disinfecting rate of the said UV chamber (120) at different water flow rates. Additionally, UV chamber (, turbidity and temperature were measured (value described in the table above). Additionally, UV chamber water flow rates between 1 and 2 LPM were maintained and after exposure of UV light to the water sample, Sarcina with a minimum inlet concentration of 2.X103 cfu/ml 99.99% percent reduction and 3.3 log reduction were achieved with lutea. In one embodiment, to check the disinfection rate of the UV chamber (120) (2) of the present invention, water samples were collected and total pH, total dissolved solids (TDS), turbidity and temperature was measured (the value is described in the table above). Additionally, UV chamber water flow rates between 2 and 2.0 LPM were maintained and after exposure of the water sample to UV light, a 99.99% reduction and 3.48 percent with Sarcina lutea with a minimum input concentration of 3.X103 cfu/ml. log reduction was achieved. In one embodiment, to check the disinfecting rate of the UV chamber (120) (3), water samples were collected and total pH, total dissolved solids (TDS), turbidity and temperature were measured (the value is explained in the table above). Additionally, UV chamber water flow rates between 3 and 3.20 LPM were maintained, and after exposure of the water sample to UV light, a 99.99% percent reduction and a 3.48 log reduction was achieved with Sarcina lutea with a minimum input concentration of 2.X103 cfu/ml. The above-mentioned water sampling in three compartments (1-3) at different water flow rates has been checked and it has been observed that a flow rate of 1-3 LPM is an ideal water flow rate to achieve maximum disinfection result in the UV chamber (120) of the present invention. Reference is made to Figure Zaye, which depicts an exemplary representation. A disinfection system (100) may include a channel (130, 140) to carry the water to be disinfected. The channel (130, 140) may contain more than one branch, for example two branches, to increase the liquid flow and increase the exposure time to UV light. Having more than one branch can allow better control of the internal pressure in the pipe and be more efficient in disinfecting the water. The channel (130, 140) may have an inlet to receive the water to be disinfected from an external water pipe and an outlet to discharge the water through an external discharge pipe. In one embodiment, there is a housing (300) with a body made of plastic or polymer, the inner surface of which is polished by vacuum metallization process. Before the process begins, the plastic component is washed and coated with a base coat so that the metal layer is smooth and uniform. The aluminum metal is then evaporated in a vacuum chamber. The steam then condenses on the surface of the substrate, leaving a thin layer of metal (aluminium) coating. The entire process takes place in a vacuum chamber to prevent oxidation. In one embodiment, the vacuum deposition process is a physical vapor deposition process. Depending on the application of the component, a topcoat may be applied after deposition to increase properties such as wear resistance and prevent degradation of the inner plastic layer of the housing 300. Referring to Figure 3, a cross-section of the UV housing 300 is shown. The housing (3 00) contains air holes for heat distribution in the phase. While using the UV lamp to disinfect the water flowing through the channel (130, 140), the surrounding air inside the UV housing (300) is heated. During use, when the UV lamp is kept on for a long time to disinfect the water, the ambient air inside the housing (3 00) becomes warm. Hot air may trigger the deterioration of the components used in the housing (300). The ventilation holes provided on the side of the housing (300) ensure the effective passage of hot air within the housing (300) to escape to the surrounding environment. The ventilation holes prevent the undesirable effects of hot air in the chamber and ensure the proper functioning of the UV system (100) components. The above descriptions of specific embodiments of the present invention are provided for illustrative and illustrative purposes. They are not intended to be comprehensive or to limit the present invention to the precise figures disclosed, and it is clear that many modifications and variations are possible in light of the foregoing teaching. Embodiments have been selected and described for the purpose of best illustrating the principles and practical application of the present invention to enable those skilled in the art to make best use of the present invention and various embodiments with various modifications appropriate to the particular intended use. It is understood that various omissions and substitutions of equivalents are contemplated as circumstances may suggest or warrant, but such omissions and substitutions are intended to cover practice or application without departing from the scope of the present invention.TR TR TR TR

Claims (1)

1. THE SYSTEMS include the following: a) a housing (300) made of plastic, wherein the housing (300) contains an outer water supply channel; b) a plurality of channels (130, 140) configured in the interior of the housing (300), wherein the plurality of channels (130, 140) are configured to carry the water that needs to be disinfected to the interior of the housing (300); It is configured in the interior of the housing (300) to emit the specific frequency for disinfection of the water present therein; d) a coating provided on the interior of the housing (300), wherein the coating is adapted to reflect light emitted from the light source (104); and e) a cooling device (310) provided on the surface of the housing (300), where the cooling device (310) is configured to provide easy passage of hot air from the housing (300) to the atmosphere. It is a system (100) according to claim 1, where the said entry-exit point (110, 150) of the housing (300) provides an airtight connection to the external water supply channel (130, 140) with o-rings or sealing materials. . It is configured so that the water flow inside is ideal for disinfection. It is a UV lamp configured to emit the UV frequency. It is a system (100) according to claim 1, where the coating provided on the interior of the housing (300) is applied in such a way that UV light passes through the channel (130, 140) and is reflected in the channel, for the effective use of light energy. It consists of multiple fins provided on it and is adapted to pass the hot air coming from the slot (300) to the atmosphere. It includes the steps: b) providing an entry-exit point (110, 150) on a plastic housing (300), where the housing (300) is the entry-exit point to provide a safe connection to the external water supply channel (130, 140). It contains (110, 150); c) transporting water by a plurality of channels (130, 140), wherein the plurality of channels (130, 140) are configured to carry water that needs to be disinfected to the interior of the housing (300); d) providing a light source (104), wherein the light source (104) is configured inside the housing (300) to emit the specific frequency for disinfection of water present in the plurality of channels (130, 140); I) applying a coating on the interior of the housing (300), where the coating is adapted to reflect the light emitted from the light source (104); and g) providing a cooling means (310), wherein the cooling means (310) is configured to provide easy passage of hot air from the housing (300) to the atmosphere. The method according to claim 73, wherein said plurality of channels (130, 140) are configured in such a way that the water flow in the transparent is ideal for disinfection. The method according to claim 73, where the light source (104) is a UV lamp configured to emit different UV frequencies within the housing (300). It is a method according to claim 73, where the coating provided on the interior of the slot (300) is applied in such a way that UV light passes through the channel (130, 140) and is reflected in the channel, for the effective use of light energy. The method according to claim 73, where the cooling means (310) is a plurality of fins provided on the body of the housing (300) and is adapted to pass the hot air coming from the housing (300) to the atmosphere. TR TR TR TR