• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    System for the automatic disinfection of water and production of disinfectants. It comprises a water pipe (10) and a control loop (10, 11, 12, 13) comprising: sensors (11) measuring, in the pipeline, a water pollution value and communicating it to a control module (12), in which a sample of the water that is retained in containers with filters (33) is poured, and the presence of possible bacteria and/or infectious microorganisms present in the water is computed, with the addition of different reagents to it and markers and related proteins (40), to determine a degree of infection and the infecting bacterium or microorganism by means of a computer and communication device (5), which communicates an infected water signal to a water disinfection module (13).) (action phase) that is activated from a disinfection module (1) to produce disinfectant (3) and drive means (4) to infected water, at a re-injection point in the pipeline. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2663130A1
    申请号:ES201631315
    申请日:2016-10-11
    公开日:2018-04-11
    发明作者:Antonio CUEVAS CUADRADO
    申请人:Antonio CUEVAS CUADRADO;
    IPC主号:
    专利说明:

    SYSTEM FOR AUTOMATIC WATER DISINFECTION AND DISINFECTANT PRODUCTION
    DESCRIPTION
    5
    TECHNICAL SECTOR OF THE INVENTION
    The present invention relates to a system for automatic water disinfection and disinfectant production.
    10
    The present invention finds special application in the disinfection mainly of the water of hospital centers and operating rooms, in urban buses, but also in public buildings where outbreaks of infections can occur, such as for example of E.Coli or Legionella.
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    The present invention relates to the disinfection of water, although it should be understood that it is equally applicable to the disinfection of other fluids, such as blood or air.
    Therefore, the present invention is circumscribed within the scope of
    Elements for measuring concentrations of chemical compounds and microorganisms, as well as actuators that generate in-situ disinfectant to sanitize water in a given installation according to the data it receives from the sensors. This intelligent disinfection can be done via
    25 fixed devices in an installation or using portable devices for use in any other type of location
    BACKGROUND OF THE INVENTION
    30
    Currently, one of the most important problems in the
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    society is access to water in acceptable hygienic conditions. The human being is prone to contracting diseases of microbiological type. Microorganisms such as viruses, bacteria, fungi and fungal spores reproduce in organic media and in water. The industry in general needs to disinfect everything that has to do with human contact, and the responsibility that the products marketed are free of microorganisms that may represent a source of infection or disease generates disinfection protocols in all food manufacturers, drinks, hospital supplies, water, etc.
    At present, the use of conventional disinfectants means shock treatments for the industry that involve:
    - technical stops of the facilities,
    - production and therefore economic losses,
    - deterioration of facilities
    -use of dangerous, caustic, aggressive, corrosive products, etc.,
    - make a post treatment so that there are no remains of the
    products used without even having the guarantee to solve the
    trouble.
    WO2013135923A1 and PCT / ES2016 / 070335 provide a partial solution to the above problems.
    The most common of conventional disinfectants is sodium hypochlorite, which at low concentrations eliminates much of the microbiological spectrum, but, nevertheless, is dangerous in commercial concentrations (bleach), is caustic (generates oxidation in metals), its residue leaves an unpleasant smell and alters the surface of food causing oxidation of them prematurely.
    With the chemical electroactivation technology (ECAS) a product of a high percentage of concentration of hypochlorous acid, ozone, hydrogen peroxide, in balanced concentrations and at neutral pH is produced, which is lethal to microorganisms and harmless to higher organisms. This product has the property of degrading the cell membrane of microorganisms without altering metals, does not generate annoying odors, and its toxicity starts from high concentrations. Its manufacture must be "in situ" since from a certain time of its production it begins to lose its 10 properties because recombination occurs in other non-activated compounds.
    However, the technical problem remains that in order to disinfect the water, it is necessary to take a sample of the infected water, 15 to take it to an approved laboratory that processes the sample and reports on its possible infection. This process could take several days, and cause long-term detention of the installation prior to the production of the disinfectant and disinfected water, (not necessarily according to the method produced by the principles of patents WO2013135923A1 or 20 PCT / ES2016 / 070335. For example, a consequence could be the closure of a
    operating room for several days, or stopping a vehicle from an urban bus line.
    The object of the present invention is to provide a solution to this technical problem.
    EXPLANATION OF THE PRESENT INVENTION
    For this purpose, the object of the present invention consists of a system 30 for automatic disinfection of water and production of disinfectants, which
    in its essence it is characterized by the characterizing part of claim 1.
    Specific embodiments of the system of the present invention are disclosed in claims 2 and later.
    5
    Thus, the system of the present invention allows the possibility of having fully controlled the possible proliferation of microorganisms by means of exhaustive water monitoring before and after the disinfection process. The disinfectant product generated by the equipment, eliminates in its entirety the biofilm that is generated in the facilities, which improves the performance in the heating / cooling circuits, prevents corrosion of the materials, wear of the facilities, etc.
    BRIEF DESCRIPTION OF THE DRAWINGS
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    To complement the description that will then be made and in order to help a better understanding of its characteristics, a set of drawings is attached to the present specification, whose drawings, given merely by way of illustration and not limitation, illustrate the embodiments 20 preferred of the system of the present invention. In these drawings:
    Fig. 1 is a generic scheme of the "P" type automatic control loop of the automatic water disinfection system according to the present invention;
    25 Fig. 2 is a schematic representation of the disinfection system
    of water of the present invention; Y
    Fig. 3 is another schematic view, illustrating an embodiment of the system applicable to air disinfection.
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    PREFERRED EMBODIMENT OF THE INVENTION
    In said drawings the constitution and the operating mode of the system for automatic water disinfection and disinfectant production according to the present invention can be seen. The system finds special application in the disinfection mainly of water and air in hospital centers and operating rooms, in urban buses, but also in public buildings where outbreaks of infections can occur, such as for example of E.Coli or Legionella.
    The present invention relates to the disinfection of water, although it should be understood that it is equally applicable for the disinfection of other fluids, such as, for example, blood.
    The system of the invention essentially consists in applying water to a water pipe (10) to a control loop (10, 11, 12, 13) to automatically determine and correct possible water infections. For a better understanding, the automatic water disinfection system is illustrated in Fig. 1, following the classic scheme of representation of the “P” type automatic control loop schemes. Next, its own characteristics are explained.
    The system includes:
    - sensors (11) that measure, in the pipeline (10), a water contamination value and that, if said value is greater than a predetermined minimum value, they communicate said value to;
    - a control module (12), in which a sample of water 30 that is retained in containers with filters (33) is poured, and the presence is computed
    of possible bacteria and / or infectious microorganisms present in the water, with the addition to it of different reagents and related markers and proteins (40), to determine a degree of infection and the bacterium or microorganism, by means of:
    5 - a computing and communication device (5), which, if it is
    the degree of infection exceeding a minimum, communicates an infected water signal to;
    - a water disinfection module (13) (actuation phase) that is activated from a disinfection module (1) to produce disinfectant (3) and discharge means (4) to the infected water, at a point of re-injection in the pipeline (10).
    This control module (12) can be, as a whole or partially, of those of the type described in the PCTES patent2016070680 (priority ES201531409), of the Spanish Center for Scientific Research, which is cited here by way of reference.
    Thus, the elements (10, 11, 12, 13), close the automatic control loop, 20 in which the process is the water conduction itself (10), regardless of the use made of it, downstream of said conduction (10).
    When the sensors (11) detect one or more values of water contamination greater than a predetermined minimum value, they issue an order for the control module (12) to activate, the water entering it through the conduit (10 ") .
    Reagents (40) are applied following the criterion that the presence of a certain microorganism (Legionella, e-Coli, etc.) responds to the presence of a certain combination of reagents. Therefore, when the sample retained
    in the container with the filters (33) it responds positively to a combination assigned to, for example, a specific bacterium, this is a sign that the water in the conduit (10) is contaminated by this microorganism, and the system must respond with the disinfectant production for water in the 5 disinfection module (13).
    The computing and communication device (5) that is in the control module, comprises a communications module (51) for transmitting via Wi-Fi, an HTML, 4G or other protocol, the convenient and interpretable signals 10 by devices laptops (21) or servers in the cloud (or a WILAN network, for example, internet), (22) that issue the activation orders to the disinfection module (13) and to the convenient actuation valves or valves. The transmission of the orders can be carried out after human supervision or automatically, which allows the system of the present invention.
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    The disinfection module (13) can be of any known type, but preferably it will be of the type comprising at least one electrochemical cell (2) by electro-chemical activation of the infected water (10 '), for treating an aqueous solution that It contains a metal salt, solution 20 that enters through an inlet conduit (32) and is subjected to the action of an electromagnetic field, and that generates a disinfectant current (3) based mainly on the electro-activated acid of the incoming metal salt , also known as anolyte. The water to be treated in the electrochemical cell (2) is collected from the pipe (10) through a conduit (10 ’) that is opened by indication of the control software, when the" infected water "signal is received.
    The salt is introduced into the electrochemical cell (2) from a salt tank (14).
    30
    In particular, the metal salt is a metal chloride, and the anolyte is
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    based on that based mainly on electro-activated hypochlorous acid, and may also contain other chemical species. An example of this technique is that described in patents WO2013135923A1 and PCT / ES2016 / 070335.
    The sensors are arranged in a channel (20) in parallel and countercurrent with the main pipe (10), and serve to detect the presence of possible contamination in the water. They can be of the following types, preferably, but not exclusively:
    - chemical sensors, in particular pH, conductivity, redox potential, disinfectant and necessary ions);
    - Biological sensors (biofilms, E. coli, Legionella and those other bacteria of interest) that characterize the quality of the water passing through its location.
    In a particular embodiment, shown in Fig. 3, the invention allows to automatically disinfect the ambient air (16) if necessary.
    In this case, upstream of the pipeline (10), a fan (30) is provided that feeds the air to a water condenser (15), the condensed water flowing into the pipeline (19) and the dry air produced (16 ') as a product that may be used. Preferably, but not exclusively, this water condenser (5) is a "Peltier" cell condenser.
    Being dry produced air (16 ’) is a cooling element in summer. A heater or heating system (31) heats dry air in winter to produce heating.
    In this case, the air disinfection system operates in a similar way, and when the system performance of the air conditioning module is required
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    disinfection (13), the system sends the "infected water" signal, generated by the computing and communication device (5), and the disinfection module (13) generates an "anolyte" disinfectant, which, alone or mixed with water disinfected, it is sprayed by sprinklers (50) to ambient air
    The most common protocol for the use of the control module (12) as a microbial capture and detection element is based on:
    1. Locking the filter or filters (33) with solutions based on detergents mixed with various reagents (40).
    2. Sample filtration and retention of micro-organisms.
    3. Second filter block (33), where the microorganisms are found, with solutions based on detergents mixed with various reagents that vary depending on the bacteria to be detected.
    4. Marking of bacteria with proteins related and selective to the bacteria to be detected.
    5. Addition of reactive solutions that generate a simple sensing reaction product.
    6. Sensory measurement of the generated byproduct.
    On the other hand, with the system described, usable information is obtained for making real-time decisions about the state of the water without the need for aggressive procedures, or having to go to external laboratories, with the consequent saving of time.
    The invention is of interest in all types of applications in the public health and food safety environment, and also for its easy integration into other measurement and control procedures currently in use, for example water purification in remote areas. Finally, these intelligent disinfection devices work "on site" at the foot of the installation and their use is indicated for any sector in which microbiological contamination poses a health risk.
    10 It does not alter the essentiality of this invention variations in materials,
    shape, size and arrangement of the component elements, described in a non-limiting manner, this being sufficient for reproduction by an expert.
    权利要求:
    Claims (5)
    [1]
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    R E I V I N D I C A C I O N E S
    1. - System for automatic disinfection of water and disinfectant production, characterized in that it comprises a water pipe (10) and a control loop (10, 11, 12, 13) comprising:
    - sensors (11) that measure, in the pipeline (10), a water contamination value and that, if said value is greater than a predetermined minimum value, they communicate said value to;
    - a control module (12), in which a sample of the water that is retained in containers with filters (33) is poured, and the presence of possible bacteria and / or infectious microorganisms present in the water is computed, with the addition to this one of different reagents and related markers and proteins (4), to determine a degree of infection and the infecting bacterium or microorganism, by means of:
    - a computing and communication device (5), which, if the degree of infection is higher than a minimum, communicates an infected water signal to;
    - a water disinfection module (13) (actuation phase) that is activated from a disinfection module (1) to produce disinfectant (3) and discharge means (4) to infected water, at a point of re -injection in the pipeline, thus closing the control loop.
    [2]
    2. - Disinfectant system according to claim 1, characterized in that the disinfection module (13) comprises at least one electrochemical cell (2) by electro-chemical activation of the infected water (10 '), for treating an aqueous solution containing a salt based on a metallic chloride, in which the solution enters through an inlet conduit (32) and is subjected to the action of an electromagnetic field, and which generates a disinfectant current (3) based mainly on electro-activated hypochlorous acid or in the electroactivated acid of the incoming metal salt.
    12
    [3]
    3. - Disinfectant system, according to claim 1, characterized in that said sensors (11) for measuring a water contamination value are one or more of those of the following group: chemical sensors, in particular pH, conductivity, redox potential, disinfectant and necessary ions as biological
    5 (biofilms, E. coli, Legionella and those other bacteria of interest) that characterize the quality of the water as it passes through its location.
    [4]
    4. - Disinfectant system according to claim 1, characterized in that, upstream of said pipe (10), it comprises a water condenser
    10 (15) from an air stream (16), whose infection is to be analyzed,
    leaving the condensed water to the pipeline (19) and the dry air produced as an optionally usable product.
    [5]
    5. - Disinfectant system according to claim 4, characterized in that said water condenser (15) is a "Peltier" cell condenser.
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    同族专利:
    公开号 | 公开日
    ES2663130B1|2019-01-25|
    WO2018069561A1|2018-04-19|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20060076248A1|2004-10-08|2006-04-13|Electric Aquagenics Unlimited|Apparatus and method for producing electrolyzed water|
    WO2011066834A1|2009-12-02|2011-06-09|Danish Clean Water A/S|Regulation of an electrochemically produced fluid in response to changed demands|
    WO2015179919A1|2014-05-27|2015-12-03|Efficiency Filters Pty Ltd|Improved chemical management for swimming pools|
    ES2426016B1|2012-03-16|2014-09-29|Blue Water Treatment, S.L.|Device for the production of disinfectant and disinfected water by electrochemical activation of aqueous solutions|
    法律状态:
    2019-01-25| FG2A| Definitive protection|Ref document number: 2663130 Country of ref document: ES Kind code of ref document: B1 Effective date: 20190125 |
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    优先权:
    申请号 | 申请日 | 专利标题
    ES201631315A|ES2663130B1|2016-10-11|2016-10-11|System for automatic disinfection of water and production of disinfectants|ES201631315A| ES2663130B1|2016-10-11|2016-10-11|System for automatic disinfection of water and production of disinfectants|
    PCT/ES2017/070676| WO2018069561A1|2016-10-11|2017-10-11|System for automatically disinfecting water and producing disinfectants|
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