• 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:
    The present invention relates to a breathing system (1) composed of a first unit comprising a desalination system (2) for pretreating, filtering and desalting water, a second unit consisting of an oxygen generator or electrolyzer (3) that allows to obtain oxygen from demineralized or deionized water once filtered and stored. Said oxygen is dehumidified and purified in a third unit (4) where the water vapor and the oxidizing compounds generated in the electrolyser (3) are eliminated. The system finally has an air recirculation or recycling unit (5) in which the air used for breathing or inhalation is recirculated continuously, reusing the contained nitrogen, injecting oxygen treated in the third unit (4) and eliminating continuously the CO2 (Machine-translation by Google Translate, not legally binding)
    公开号:ES2637033A1
    申请号:ES201700621
    申请日:2017-06-05
    公开日:2017-10-10
    发明作者:Alejandro HERRERO PIZARRO;Alberto PUIME OTÍN
    申请人:Alejandro HERRERO PIZARRO;Alberto PUIME OTÍN;
    IPC主号:
    专利说明:

    SYSTEM OF OBTAINING AND PURIFICATION OF OXYGEN FROM WATER FOR AUTONOMOUS BREATHING SECTOR OF THE TECHNIQUE
    The present invention is included in the technical sector of oxygen generation and purification systems and autonomous breathing systems. In particular, the present invention relates to a system for generating and purifying oxygen for underwater respiration or in environments with shortage or absence of oxygen as well as in atmospheres that due to their properties or composition are not breathable. The system allows generating oxygen from water and purifying said gas stream that is introduced into a closed circuit system where it is recirculated. In said circuit or air recycler, the proportion of oxygen is maintained at acceptable levels for human respiration. The closed system in which the air is recirculated is driven and allows the CO2 generated in it to be eliminated. BACKGROUND OF THE INVENTION
    The most commonly used underwater breathing systems consist of the use of bottles containing compressed air and an open or semi-open circuit system. Other systems also employ air bottles with a closed or semi-closed circuit system known as an air recycler (commonly known as rebreather) in which carbon dioxide (C02) is removed with a chemical reagent present in the circuit, which allows recycle exhaled gas into the system and recirculate it to be inhaled again. These systems employ bottles of air, oxygen or other mixtures to feed the required oxygen to the user who consumes it, which allows recirculating the inert gas that remains in the system. The reuse of the gas mixture allows the use of a smaller volume of inert gas (N2) which increases the autonomy of the system by supplying oxygen (02) to the extent that acceptable levels are achieved for human respiration. This longer time of use allows these systems to be used in diving, firefighting, mine operations, caving, rescue or high altitude activities as well as in medical applications such as the reuse of anesthetic gases.
    These systems allow to increase the autonomy of the system, supplying oxygen by means of high pressure gas bullets, which allows oxygen to be supplied when the partial pressure of oxygen in the system decreases after being recirculated in the breathing system. There are different types of air recycler depending on the arrangement and order of the main components. Thus, there are recyclers of semi-closed circuit, closed circuit oxygen, closed circuit with mixed gas (N2 and O2) or others. Some systems use absorbent compounds that allow CO2 to be removed while releasing oxygen to the circuit such as those that use potassium superoxide (K02) or use liquid oxygen known as cryogenic recyclers. Most air recycling systems use substances that absorb CO2 at different temperatures such as soda lime (mixture of CaO with NaOH), mixed with other compounds such as potash (KOH), soda (NaOH), calcium oxide (CaO), oxide of magnesium (MgO). Other substances used to remove CO2 at different temperatures are: Na2Zr03, BaSi03, Li2Zr03, CaZr03, BaZr03, BaTi03, Lithium hydroxide (LiOH), Lithium peroxide (Li20 2), Li4 Si04, cerium oxide (Ce02), hydrotalcites, serpentinite, olivine, amines such as alkanolamine (monoethanolamine [MEA], diethanolamine [DEA], methyldiethanolamine [MDEA], diisopropanolamine, methyldiethanolamine or 2 (2-aminoethoxy) ethanol and absorbent liquids being of interest to those cases that are capable of absorbing ambient temperatures (Tomé and Marrucho, Chem. Soco Rev. 45, 2785, 2016; Wu et al., Rev. Chem. Eng. 33, 271, 2016). Other substances manage to absorb (not absorb) CO2 in their porous structure as activated carbons and other carbonaceous materials such as carbon nanotubes, graphite, graphene, nanoporous carbons (NPCs), zeolites, aluminosilicates, metalorganic molecular sieves (MOFs), among others (Lu et al., J. Mat. Chem. a. 4, 12118,015).
    Porous adsorbent materials of high surface area containing CO2 absorbing substances inside as activated carbons with absorbent liquids or amines inside, hollow fiber polymer membranes with absorbent liquids or amines inside (Tomé and Marrucho, have also been combined) Chem. Soco Rev. 45, 2785, 2016), etc. Other systems use membranes to achieve the selective separation of CO2 from the rest of the gases present in the gas mixture.
    Other systems used in underwater vehicles try to increase the interaction surface between water and recirculated air in closed systems to improve the transfer of CO2 from air to water by using a tank filled with materials such as Dixon rings or others ( Kolaczkowski, S., et al., Chem. Eng. Res. & Design, 100 157, 2015). Direct contact systems between water and air can be used. Such systems allow contact between both phases by pressurizing the internal air to the external water pressure or by depressurizing the external water that is brought into contact with the indoor air. There are also systems that improve contact between both phases, known as indirect contact systems. In this case, semipermeable hollow fiber membranes can be used that may or may not have surface treatments to improve the contact between phases, be more selective to the passage of CO2 with respect to the rest of gases and can be modified superficially to avoid fouling in aquatic environments. These contact systems can be arranged in various forms in underwater systems. In a first arrangement of the indirect contact system, the air can be compressed to equalize the external pressure and put it in contact with the external water in the membranes and then depressurize it and return to the interior with a lower concentration of CO2. In another arrangement of the system the water can be depressurized to bring it into contact with the inner gas in the membranes and then pressurize the water again and pump it out of the system. Another option would be to use hollow fiber membranes without changing the pressure of the gas and water phases. In the latter case, the membranes must withstand the pressure difference between the two means. In the case of using this type of systems in atmospheres with depleted atmospheres in O2 there would not be so much difference in pressure, it being only necessary that the membranes be selective to the passage of CO2 and not that of other gases. It would only be applicable in aquatic environments.
    Air recycler means air recirculation systems in a closed system (in which all the air is recirculated by means of impulse, pumping systems
    or compression-decompression) or semi-closed (which lets out a volume of air outside every so often). In autonomous underwater breathing these air recirculation systems are helped by elements known as counterpulmones and have several advantages over open systems as their greater autonomy by requiring only oxygen as a gas to be supplied in the closed system and the absence of bubbles such as conventional equipment These systems allow the reuse of inert gas (such as Nitrogen) by increasing the operating time or autonomy by requiring only oxygen as a gas to be supplied to the system since it is consumed with breathing. In some types of recycler bottles of oxygen, nitrogen, helium or Nitrox are used to replace the lack of any of these gases, especially in semi-closed systems in which part of the gas is lost in the form of bubbles. Although recyclers allow the gas mixture to be reused, avoiding the use of bottles, they require the addition of oxygen stored in pressurized bullets, which limits the system's use time to the amount existing in them. In underwater environments this type of system has been used and there are numerous models that vary in its composition for diving. In particular, equipment has been patented that has a CO2 removal system (US patents 3575167, US 3794021, US 4939647, US 5964221, US 6302106, US 7520280, US 2007/0163591, US 2008/0276942, US 2010/0012124, US 2010/0313887, US 2012/0132206, US 6895961) but these devices do not include the generation of O2 or its purification. Air recycling systems can also be used in terrestrial environments where there is no oxygen or their presence is scarce or in atmospheres in which, even if there is oxygen, they are not suitable for breathing for other reasons such as low pressure or presence of harmful gases. In this case, the drive depends on drive or compression mechanisms that make the air recirculate.
    Regarding systems that use water to directly obtain oxygen in situ for breathing in closed systems, several systems for underwater navigation or underwater breathing have been developed but in many of them the oxygen stream obtained is not purified properly and does not occur A pre-treatment of water (patents US 3971372, US 5203325, US 6295984, DE 102010006354) nor explains how to remove CO2 or purify the gas stream. Obtaining oxygen can be carried out through the use of electrolysers in which water is converted into hydrogen (H2) and oxygen (02). Such systems require demineralized or deionized water when using proton exchange membranes, usually polymeric membrane (PEM). To obtain deionized or ultrapure water it is necessary to pretreat the water from which oxygen will be obtained. In submarine vehicles, distillation by means of water heaters has been used to obtain distilled water that is subsequently used in refrigeration systems, for crew and for oxygen generation through water electrolysis. Another way to obtain water is through the use of filtration systems such as microfiltration, ultrafiltration, nanofiltration or reverse osmosis, which are capable of retaining and separating different substances and compounds as different salts, obtaining a purer water with nanofiltration systems and Inverse osmosis. Reverse osmosis can eliminate 99% of all dissolved substances, as well as microorganisms and particles. The rejection or more concentrated water obtained can be returned to the outside of the system. Other systems used are based on electrodialysis, reversible electrodialysis, electrodeionization, cryodeslation, ion exchange systems, etc. Regardless of the system used to desalinate
    or deionizing requires a very low final conductivity or ultrapure water. It is important to maintain a low conductivity which will influence the durability of the cells.
    Obtaining hydrogen and oxygen through this type of electrolyzer (PEM) is based on the transport of protons in a solid electrolyte polymer (SPE) at temperatures between 20 and more than 100 oC. This type of electrolysers have electrodes with anode and cathode with metals such as Pt in the cathode and oxides of Ir or Ru in the anode. The reactions at the cathode and anode are shown below.
    Cathode: 2H ++ 2e '-7 H2
    Anode: H20 -7 1/2 O2 + 2H ++ 2e '
    In the cathode in contact with water, oxygen is formed. This type of electrolysers are usually used at low temperature between 20-100 oC, at low pressure and have a long durability. The electrolysis process requires direct current, so rectifiers are used to convert alternating current into continuous or electric accumulators or batteries. The process is carried out in a device called stack which is where the electrochemical processes indicated above occur. The stack consists of a stack of numerous cells compacted under pressure with collectors that collect the anode (water and oxygen) and cathode (water and hydrogen) gases and then be processed according to the utility of the gases.
    Depending on the voltage used, other compounds such as H20 2, 0 3, H02 ',' 0 ', HO · can be produced. The presence of chloride anions (Cr) can in turn produce undesirable compounds such as CI2 HCIO, HC102, C103 ', C104'.
    Gas purification is of key importance in breathing systems since the gas that must be free of contaminants must be recirculated. There are several pollutants whose limit values must be controlled (Lonkar et al., The Swedish Defense Research report No. FOA-R-97-00403-720-SE, 1997). Among them are 0 3, H20 2 and formaldehyde that can be eliminated by the system proposed in this invention. Ozone can decompose at room temperature in the gas phase or aqueous phase by means of different catalysts, converting it into O2 (Batakliev et al., Interdiscip. Toxicol. 7, 47, 2014). H20 2 can be broken down into oxygen and water with manganese oxides. Formaldehyde can also be decomposed into CO2 and water by means of catalysts based on manganese oxide under ambient conditions (Nie, at al., Catal. Sci. Technol. 6, 3649, 2016) whereby compounds normally produced in closed atmospheres would be eliminated.
    There is therefore a need to have a system or device that allows underwater breathing or in non-breathable environments for long periods of time, solving the problem of the use of oxygen by generating it from water and purifying it in the same device. The invention described herein allows to obtain oxygen from water from different sources. This oxygen is purified and injected into a recycling system for autonomous underwater breathing or in non-breathable environments or with oxygen shortage. The air recycling system has a system to purify the air inside, both eliminating CO2 and other substances generated. EXPLANATION OF THE INVENTION
    The present invention solves the problem of the state of the art by means of an in situ oxygen generation system and autonomous underwater breathing. Likewise, the invention allows breathing from water sources in environments where there is a non-breathable atmosphere.
    Thus, in a first aspect, this invention relates to an oxygen generation system from water that also allows said gas to be injected into a closed circuit where oxygen is purified and recirculated to be breathed by the user or users together with a inert gas such as nitrogen at levels suitable for human respiration.
    In the present invention water refers to waters of any type, both fresh and salt in any field, both at sea and in lakes and rivers or groundwater. The system can be used both in underwater environments and in atmospheres that are poor in oxygen or that, containing oxygen, are not breathable or have harmful compounds or where the atmospheric pressure is not adequate.
    The system proposed in the present invention consists of four main units sequentially linked, as detailed in Figure 1, which allow several functions to be achieved to achieve the ultimate goal of solving the problem of autonomous breathing from oxygen generated at from the water The system (1) whatever its form, arrangement or use contains four main units inside. It presents a system for obtaining deionized or demineralized water from water from outside (2), an oxygen obtaining system by means of an electrolyzer (3), an oxygen dehumidification-purification system obtained in the previous stage in which water, ozone and other harmful substances present (4) and a breathing gas recirculation system with CO2 removal system (5) known as an air recycler or recirculator into which the generated oxygen is introduced into the unit is removed which produces oxygen (electrolyzer) (3). Air recycler means any system or device that allows a mass of air to be recirculated by any mechanical means in order to be breathed by one or more people and that has a CO2 removal system, whatever its form or use.
    Figure 2 shows an example of a system that has been added to the 4 main units, an electric accumulator or battery (6) and a control system (7). Said control system allows to regulate the flow of treated water to produce oxygen in the electrolyzer. Said oxygen is generated in the volume required to maintain the proper concentration in the breathing unit 5.
    The first unit (2) refers to a deionization or water treatment system. The purpose of this unit is to remove the suspended matter, dissolved substances as well as salts from the water and generate demineralized or deionized water with a low electrical conductivity, whatever the process used. In a particular embodiment, said system can be based on a water filtration system consisting of a high pressure pump that supplies the impulse necessary to pass the water through: an initial filter system to remove larger particles. size, a microfiltration system and a reverse osmosis system. This osmosis system can be replaced by other systems based on electrodeionization, electrodialysis or exchange resins, depending on the source of water to be treated to remove the salts in solution. The amount of water required is regulated from a control system (7) based on the amount of oxygen required by the system to maintain the partial pressure of oxygen at optimal amounts for the user / s. The generated water is accumulated in a container that has a level regulator to control the amount of water required by the system.
    The second unit (3) consists of an electrolyzer that allows, from the demineralized or deionized water that is generated and accumulated in the first unit (2), to obtain the amount of oxygen required by the control system (7) to supply the breathing system or air recycler 5 the required partial oxygen pressure, as shown in figure 3. One of the advantages of the system is the use of potentials higher than those normally used. The use of potentials above 2.3 V also generates oxygen (02), ozone (03) and other species such as H20 2, among others, which constitutes a limitation in view of its possible use as an oxygen generator for systems of breathing because they are oxidizing substances that should not be introduced into the breathing system. On the other hand, the use of greater potentials allows a greater obtaining of O2 with the counterpart of generating ozone as indicated in patent EP 2657369 A 1. An electrolyzer with proton exchange membrane (PEM) can be used to generate a greater amount of oxygen In EP 2657369 A1, ozone is removed by subsequent catalytic reduction. Catalytic reduction with the hydrogen produced may entail certain risks when oxygen and hydrogen are present, so the system proposed in the system (1) eliminates ozone and hydrogen peroxide by decomposition in environmental conditions. In the system of the present invention ozone is decomposed by catalysts in the next purification unit (4). In this unit the water is removed by condensation or adsorbent materials and then the ozone in the gas stream is removed. In a preferred embodiment, the electrolyzer used should be proton exchange membrane (PEM). The oxygen generated in the anode is circulated through the third unit (4) that is responsible for dehumidifying the current and recovering the water by means of a condenser or by water absorbing substances or by desiccant materials or separating membranes of H20 and O2 . With this it is possible to separate the oxygen generated which is to purify it by means of a catalyst. In a preferred embodiment, the third unit consists of a condenser, desiccant material such as zeolites or molecular sieve, silica gel and separation membranes of H20 and O2. The control system (7) can regulate the temperature of this unit in order to increase the activity or reaction rate of the catalysts used by an oven.
    The catalyst used to remove ozone can be of various types and is capable of removing ozone at ambient temperatures, producing molecular oxygen at low temperatures and with high space velocities which increases the ability to remove this pollutant under environmental conditions (Batakliev et al ., Interdiscip. Toxicol. 7, 47, 2014). Catalysts with the following metals are used: Pt, Pd, Ru, Rh, W, Cu, CuO, Ag, Ag-Mn, Sn, Ni, Nb0 3, NiO, Co, C030 4, Fe, Zn, Ce02, Mn02 and Mn20 3 both in the form of oxide and supported on any other inert material such as classic supports of catalysts such as zeolites, activated carbons, alumina (Ab03), silica gel (Si02), clays, or other oxides such as Ti02 or Zr02. Said catalyst can also be presented in different forms such as extrudates, monoliths, spheres, rings, etc. Finally, in a preferred embodiment, one of the catalysts used to remove 0 3 previously listed that would be in contact with the anode water can be used, in which case it could also eliminate H20 2 and 0 3 generated in the electrolyzer. Another complementary element would be an ultraviolet lamp that could decompose traces of ozone and convert it into oxygen and water if necessary. The oxygen can be stored in a container whatever its shape through the use of a compressor or other mechanical device.
    The fourth unit (5) consists of an air / gas recirculation system, referred to herein as an air recycler, which has a CO2 removal system inside. The accumulated and / or compressed oxygen is introduced into said unit by regulating a valve. The necessary volume is introduced into this unit to maintain constant and acceptable levels for human respiration, being regulated by an automatic control system (7) or by its regulation by the user. The oxygen produced is introduced just after the CO2 removal system. The air is thus recirculated in this closed circuit in which the removal of CO2 is completed. Said removal can be carried out by different systems either by:
    - Absorbents such as soda lime (mixture of CaO with NaOH), potash (KOH), soda (NaOH), calcium oxide (CaO), magnesium oxide (MgO) and other substances that act at a higher temperature for which it will be required of an increase in the temperature of the unit that contains them as Na2Zr03, BaSi03, Li2Zr03, CaZr03, BaZr03, BaTi03, Lithium hydroxide (LiOH), Lithium peroxide (Li20 2), Li4Si04, cerium oxide (Ce02). Other materials that can be used to remove CO2 are hydrotalcites, serpentinite, olivine, amines such as alkanolamine, monoethanolamine [MEA). diethanolamine [DEA). methyldiethanolamine [MDEA1, diisopropanolamine, methyldiethanolamine or 2 (2-aminoethoxy) ethanol and CO2 absorbing liquids. These same absorbents can be immersed in other adsorbent materials or in polymeric or ceramic membranes.
    - Adsorbents such as activated carbons, zeolites, aluminosilicates, metalorganic molecular sieves (MOFs).
    - Systems of direct or indirect contact between water or external air and the internal air of the system by means of selective CO2 separation membranes. In these types of systems, 10
    they include elements that bring the internal air into contact with the water or external air by means of direct contact systems such as Dixon rings or bubbling systems. Indirect contact systems are also included, such as semipermeable hollow fiber membranes, whether or not they are selective to the passage of CO2. The CO2 can be transferred to the water or outside atmosphere selectively both by adjusting the pressures between the inside of the membrane and without adjusting the pressures while the membranes are able to withstand the different pressure between both media.
    In addition to these four main units, the system consists of a system that provides power supply of any kind, such as any electric generator, electric accumulators, batteries or other (6) that supplies the energy necessary for the water supply by pumps, for the operation of the electrolyser, for the control system, detectors, ovens, compressors, automatic valves and any other accessory required by the system.
    The electronic control system (7) allows to regulate the amount of water required to obtain the necessary volume of oxygen that must be introduced into the closed breathing system (5). The control allows the necessary amount of water to be pumped through the membranes in the first unit (2) when it decreases from a certain level in the demineralized or deionized water reservoir after the filtration / desalination system. It also allows the electrolyser to be operated to produce oxygen (3) and maintain acceptable levels inside the recycler (5). The oxygen detectors in the breathing system enable the operation of both the electrolyzer. Water level detectors can be arranged both in the demineralized or deionized water tank and in the electrolyzer as well as conductivity detectors in the demineralized or deionized water tank in order to check if it has been treated properly. Inside the air recycler there are pressure detectors, partial pressure of oxygen, nitrogen and CO2 in order to regulate the partial pressure of oxygen and CO2 in the system. These detectors are arranged in the inhalation zone where the breathable atmosphere is located. In another particular embodiment, the CO2 pressure or concentration controller is located just after the CO2 removal system (either by absorbents, adsorbents or selective membranes).
    In a particular embodiment, the invention contains a formaldehyde removal catalyst in the CO2 removal system.
    In a particular embodiment, the system contains desiccant material inside the air recycler prior to the passage of air into the CO2 removal system.
    In particular, the system proposed in the invention can be applied both in individual closed-loop or semi-closed breathing devices known as air recyclers, both in underwater environments and in environments that present non-breathable atmospheres such as those required in caving, in extinction of fires or other types of exploration or rescue in non-breathable atmospheres. It can be applied in underwater navigation vehicles of any type in which it is necessary to adjust the oxygen levels to those required for the crew. It can be used in environments where there is a low atmospheric pressure. In turn, said system can be arranged in a portable way for use in rescue of people trapped in caves or as a result of accidents in mines, in which case they can be used provided that a source of water and non-breathable or suffocating atmosphere is available. . These systems can be included in vehicles or drones used for rescue. Other uses include the use of this system in other environments such as underwater buildings or in non-breathable environments that have enough water to be used to obtain oxygen. Another use of the system would be the application in hospital or other systems where it is required to recirculate high cost gases and maintain a stable oxygen concentration. BRIEF DESCRIPTION OF THE DRAWINGS
    Fig. 1: Shows the configuration of the four consecutive main units of the system
    (1) proposed in the invention. Autonomous breathing system (1) divided into four main units; Water filtration or deionization system (2); oxygen generation system by electrolysis (3); oxygen purification system (4); air recycling system with CO2 removal (5).
    Fig. 2: Shows the general configuration of the autonomous breathing system (1) of the present invention together with the four main units (2, 3, 4, 5) to which an electric accumulator or battery (6) has been added and an automatic control system (7).
    Fig. 3: Shows a flow chart in the system (1) that indicates the generation of a rejection or brine in the desalination system and generation of demineralized or deionized water (2), the generation of hydrogen (H2) and oxygen ( 02) next to ozone (03) in the electrolyzer (3) and the steam output of H20 and O2 to the purification system (4). Finally, the reception of the O2 generated from the water in the recycler (5) and its reuse, as well as the separation of the CO2 formed in the breath is shown. The diagram shows the removal of brine, H2 and CO2.
    Fig. 4: Shows a specific configuration of the system described in the present invention whose recycling unit consists of a recycler with a counter-lung.
    Fig. 5: It shows a specific configuration of the system described in the present invention whose recycling unit consists of a recycler with two counter lungs.
    Fig. 6: Shows a system of transfer of the CO2-rich gas of indirect contact to a gas or external water stream without variation in the water or gas pressure.
    Fig. 7: It shows a system of transfer of the CO2-rich gas of indirect contact towards a gas stream or outside water at different pressure, using a compressor to equalize the pressure in the exchange system.
    Fig. 8: Shows an example of the system described in the present invention adapted to the practice of scuba diving.
    Fig. 9: Shows an example of the system described in the present invention adapted in an underwater vehicle. PREFERRED EMBODIMENT OF THE INVENTION
    Example 1. Specific system for diving through an oxygen production and purification system with a closed counterpulmon recycler.
    The system (1) shown in Figure 4 receives water from the outside through an inlet that has grilles to prevent the passage of thick particles inside (8) that through a pump (9) is directed to a prefiltration system to remove smaller particles (10). A high pressure pump (1 1) drives the water through a reverse osmosis system (14) from which two types of water are extracted when they seep into the membranes, a stream of deionized water and one of water concentrated in salts and other substances A safety valve (12) recirculates the water outside if necessary (13). The discarded salt water is driven outwards and can be used to cool in a water condenser (20). Demineralized or deionized water is accumulated in a tank (15) that collects an amount and measures the level to check the amount of water inside and the amount needed for the O2 production unit (3). In said unit the electrolyser is driven by a pump (16). The electrolyser (17) produces oxygen and water vapor in the anode and hydrogen cathode. In the oxygen purification unit (4) there is a catalyst (18) of manganese oxides (MnO / MnxOy) that treats the water in which the electrolyser is immersed in order to remove H20 2 and 0 3 in aqueous medium. The current is then passed through the condenser and a bed of zeolites
    (19) arranged before the catalytic reactor containing MnOx (20) where 0 3 of the gas stream is removed. A compressor stores the oxygen in a bullet (21) in order to inject it through a valve to the air recycling and CO2 purification system (5).
    The main gases are analyzed in the air recycler to ensure that they are present in proportions suitable for breathing. There is a stop valve for the inhalation and exhalation of gases (22) with non-return valves (33). The exhaled gas, with high concentration of CO2 (23) is conducted through a compound for the purification of CO2 (24) where a membrane system or an absorbent such as CaO mixed with NaOH removes the CO2 from the stream. A counter-lung (25) stores the air to be able to recirculate the air again without CO2 (27). An auxiliary air or oxygen bullet (28) allows to extend the life of the system in case of failure in the oxygen production system.
    Example 2. Specific system for diving at sea using a closed recycler with two against lungs.
    The system (1) shown in Figure 5 shows a device for underwater breathing with two counter lungs for diving activities at various depths. Seawater enters the equipment through the water collector (8) and passes the particle prefilter before being pumped (11) into the reverse osmosis unit (14). The rejection obtained is expelled outside the system. The quality of the purified water obtained is monitored with the help of a conductivity meter (35). In the electrolyser (17) the oxygen (02) that the diver will need during his immersion is obtained, accompanied by traces of ozone (03), The gaseous mixture is circulated through the system of elimination of said gas (18-20), where in addition to eliminating water vapor, the possible formation of species such as H20 2 U 0 3 that is converted into oxygen is eliminated. Hydrogen, another element obtained in the electrolyzer, is expelled from the system.
    The oxygen obtained passes through a compressor to be stored in the reserve bottle (21). From this bottle the diver regulates the oxygen during his dive, introducing the necessary amount of gas to the inhalation counterpulmon (25) keeping constant the partial volume of oxygen in the breathing gas that is being used: Air (02 / N2) or Triox (02 / He / N2). For this, the diver uses an oximeter and actuator (36) of the reserve stopcock (34).
    The necessary power supply for the units of reverse osmosis, hydrolyzer, ozone eliminator and compressor is achieved by means of an electric battery (6). It can also provide electricity to a stove to increase the temperature in the catalytic reactor unit. The rest of the equipment consists of an air recycling system, where the diver takes air from the inhalation counterpulmon (25) and expels it to the exhalation counterpulmon (37) thanks to the anti-return system of the mouthpiece (33). Air recirculation is completed when it enters the inhalation counterpulmon (25) again after crossing the CO2 removal unit (5). The operation of said unit is monitored with a CO2 detector at its entrance and exit (36).
    As it is gained in depth, it will be necessary to compensate the effects of the pressure on the breathing gas by injecting more diluent (N or He) to the breathing circuit from its reserve bottle (28). The diluent stopcock is controlled with an actuator that incorporates a pressure gauge (34). As an added security system, a small oxygen bottle (02) (28) is incorporated that covers the rise time of emergencies in case of malfunction of some of the elements or battery depletion. To switch to an open circuit in emergency ascension, an exhaust valve (26) is added to the equipment.
    Example 3. Example of a CO2 purification unit by means of an indirect contact system.
    One of the possible ways of eliminating the CO2 and that is represented in Figure 6 consists of an indirect contact system, between the CO2-enriched gas and an external current by means of contacting using semipermeable hollow fiber membranes. The exhaled gas stream circulates inside the cylindrical fibers of materials
    Polymers such as polysulfone or by resistant and selective ceramic materials to the passage of this gas. Water or outside air circulates outside the membranes. The CO2 crosses the membrane and is transferred to the external current since the membrane allows the selective separation of this gas.
    Example 4. Example of a CO2 purification unit by indirect contact with a gas compression system.
    The system shown in Figure 7 represents an indirect contact system for transferring CO2 from the system proposed in the invention to the alternative external medium to absorbent materials such as soda lime or other absorbents or adsorbents. In this case, the internal gas is compressed until the external pressure of the water is reached to pass through selective membranes to the passage of CO2 and to be able to eliminate it from the gas stream. Subsequently the gas is decompressed to reintroduce it to the recycler (5).
    Example 6. System applied to scuba diving
    Figure 8 represents an example of the compact system applied to scuba diving individually. The elements described in the invention are represented individually. The diver supports a battery (6) that feeds an ultrapure water system based on reverse osmosis (2) and an electrolyzer (17) that generates oxygen. The oxygen is purified by a small catalytic reactor with manganese oxide
    (18) being accumulated in a bullet by means of a compressor (21). The air recycling and CO2 purification unit (5) has an inhalation counterpulmon (25) and another counterpulmon (37), a pressure gauge (31) and a gas analyzer (36). The diver also has an auxiliary gas bullet (28) to be used if necessary.
    Example 7 System applied to underwater installation
    Figure 9 represents an example of a submarine in which the system proposed in the present invention has been included. The submarine has air ducts in which it enters from the conduits that are located in the upper part being extracted in the conduits that are located in the lower part, as indicated by the direction of the arrows. This method follows the recommendations of recirculation of air in closed environments of different establishments or rooms. The air recycling unit (5) includes an air compressor or pump or impeller that recirculates the air through said air recycling unit, which includes the passage through tanks that store material that absorbs CO2 removing it from the air stream.
    The submarine represented has a particle filtration system and external water storage (8) followed by a high pressure pump (11) and the filtration system (14). The electrical supply of the elements represented is achieved by a set of batteries (6) that includes an electrolyzer for oxygen generation from demineralized or deionized water obtained by filtration (17). A condenser and a bed of zeolites and silica gel remove excess water vapor from the oxygen generated. The oxygen stream, after removing the water vapor, is treated by a catalyst in the water in contact with the electrolyzer (18) and another in the gas stream (19) based on manganese oxides. A compressor (21) stores the oxygen in storage bullets. The submarine has auxiliary breathing gas bullets (28) if necessary. LEGEND
    1 System proposed in the invention. Set of units that compose it
    2 Water desalination unit / Water treatment unit
    3 Electrolysis / electrolyser unit
    4 Oxygen purification unit
    5 Air recycling and CO2 purification unit
    6 Battery / electric accumulator
    7 Control system
    Make up the desalination unit (2):
    8 Water receiver / tank with particle retention prefilter
    9 Water pump
    10 pre filter
    11 high pressure pump
    12 Safety valve
    13 water recirculation
    14 Filtration system
    15 Demineralized or deionized water tank
    They make up the oxygen production unit (3):
    16 Bomb
    17 Electrolyzer
    Make up the oxygen purification unit (4):
    18 Water purification catalyst
    19 Zeolite bed condenser
    20 Gas Purification Catalyst
    They make up the air recycling and purification unit of C06 (5)
    21 Gas compressor and storage bullet
    22 valve
    23 Exhaled gas
    24 CO2 removal system based on soda lime (mixture of CaO with NaOH)
    25 Inhalation counterpulmon or contrapumón
    26 Overpressure valve
    27 Inhaled gas
    28 Stored auxiliary breathing gas
    29 Auxiliary Gas Valve
    30 Regulator
    31 Pressure gauge 32 automatic compensation valve 33 Bypass valve or non-return valve 34 Valve 35 Pressure detector 36 Gas analyzer O2 • 0 3 • CO2 • N2 37 Counter-lung
    权利要求:
    Claims (25)
    [1]
    1. System for obtaining oxygen from water sources of any kind,
    gas purification and autonomous breathing (1), characterized in that it comprises:A water treatment and desalination unit (2) that allows water to be obtainedpure with very low conductivity,
    An oxygen generating unit or electrolyzer (3) in which oxygen is produced at
    from the treated water in the first unit (2),A purification unit (4) of the oxygen produced in the electrolysis unit (3) thatdehumidifies and eliminates the ozone (03) present in the gas and peroxide (H20 2) and ozonegenerated in the water in contact with the electrolyzer (4),
    An air recycler or gas recirculation system (5) that recirculates the air mixture for inhalation to which the oxygen generated in the purification unit (4) is injected and which has a CO2 removal system or device.
    [2]
    2. System according to claim 1 characterized in that the desalination system comprises a filtration and separation system by membranes and more preferably by reverse osmosis membranes.
    [3]
    3. System according to claim 1 characterized in that the desalination system comprises an electrodialysis or electrodeionization system.
    [4]
    Four. System according to claim 1 characterized in that the desalination system comprises an ion exchange resin system.
    [5]
    5. System according to claim 1 characterized in that the oxygen obtaining system (3) comprises a polymeric membrane electrolyzer (PEM).
    [6]
    6. System according to claim 1 characterized in that it contains a solid catalyst in the purification unit (4), selected from manganese, manganese oxide, Pt, Pd, Ru, Rh, W, Cu, CuO, Ag, Ag-Mn, Sn , Ni, Nb03, NiO, Co, C030 4, Fe, Zn or Ce02 supported on any solid material in contact with the water used by the electrolyzer
    (3) to eliminate by-products in contact with water.
    [7]
    7. System according to claim 1 characterized in that it contains a metal catalyst in the purification unit (4), selected from manganese, manganese oxide, Pt, Pd, Ru, Rh, W, Cu, CuO, Ag, Ag-Mn, Sn, Ni, Ni203, NiO, Co, C030 4, Fe, Zn or Ce02, for the elimination of ozone in the gas stream from the electrolyzer (3).
    [8]
    8. System according to claim 1 characterized in that it contains a dehumidification system by means of a condenser and an adsorbent material in the purification unit (4).
    [9]
    9. System according to the preceding claims characterized in that it contains a CO2 removal system based on selective membranes to the passage of CO2 in direct contact with water or with the air outside the system in the air recirculation unit (5).
    [10]
    10. System according to claims 1 to 8, wherein the CO2 removal system of the air recirculation unit (5) is based on absorbent substances such as soda lime (mixture of CaO with NaOH), potash (KOH), K02, soda ( NaOH), calcium oxide (CaO), magnesium oxide (MgO), Na2Zr03, BaSi03, Li2Zr03, CaZr03, BaZr03, BaTi03, lithium hydroxide (LiOH), Lithium peroxide (Liz0 2), Li4Si04, cerium oxide ( Ce02) and absorbent liquids or combinations of all of them.
    [11]
    eleven. System according to claims 1 to 8, wherein the CO2 removal system of the air recirculation unit (5) is based on adsorbent substances such as activated carbons, zeolites, aluminosilicates, metalorganic molecular sieves (MOFs).
    [12]
    12. Method of generation and purification of O2 for respiration comprising desalination systems (2), electrolysis (3), purification of 0 3 with catalysts or physical systems such as ultraviolet lamps (4) and CO2 removal by means of separation or absorption systems gas (5), included in an autonomous breathing system or closed circuit air recycler comprising the elements according to claim 1.
    [13]
    13. Method of generating O2 for respiration and purification of 0 3 and CO2 in a self-contained breathing system or closed circuit air recycler comprising the elements according to claim 1, in which auxiliary bottles containing oxygen, nitrogen, helium or Any of your combinations.
    [14]
    14. Formaldehyde removal method in closed breathing systems whatever their form containing CO2 removal systems (5) according to claim 1, by means of a manganese oxide catalyst included in the breathable gas recirculation system (5).
    [15]
    fifteen. 0 3 removal method after an electrolysis process using polymeric membrane electrolyzers (PEM) using manganese catalysts, manganese oxide, Pt, Pd, Ru, Rh, W, Cu, Cuo, Ag, Ag-Mn, Sn, Ni , Ni203, NiO, Co, C030 4, Fe, Zn or Ce02 supported on any solid material or by ultraviolet lamps.
    [16]
    16. Use of system (1) according to claims 1 to 11 in diving devices such as closed or semi-closed air recirculation systems.
    [17]
    17. Use of system (1) according to claims 1 to 11 for the generation of breathing oxygen in underwater or land installations or vehicles.
    [18]
    18. Use of system (1) according to claims 1 to 11 for the generation of breathing oxygen in marine rescue systems or devices.
    [19]
    19. Use of system (1) according to claims 1 to 11 for the generation of breathing oxygen in rescue equipment or devices for people in mines, disasters or accidents.
    [20]
    twenty. Use of system (1) according to claims 1 to 11 for the generation of oxygen in caving activities.
    [21 ]
    twenty-one . Use of system (1) according to claims 1 to 11 for implementation in rescue drones.
    [22]
    22 Use of system (1) according to claims 1 to 11 for use in medical applications where it is necessary to conserve breathable air in patients who need to conserve gas by recirculation in the CO2 removal unit (5).
    [23]
    2. 3. Air recirculation system with CO2 removal system (5) with desiccant elements. The materials for drying the air stream are chosen from activated carbons, zeolites, aluminosilicates, metallurgical molecular sieves (MOFs).
    [24]
    24. System according to claims 1 to 11 wherein the air is dried inside the air recycling unit (5). The materials for drying out the air stream are chosen from: activated carbons, zeolites, aluminosilicates, metalorganic molecular sieves (MOFs).
    [25]
    25. System of treatment of by-products generated in electrolysers or by electrolysis with catalysts selected from: manganese, manganese oxide, Pt, Pd, Ru, Rh, W, Cu, Cuo, Ag, Ag-Mn, Sn, Ni, Nb0 3, NiO, Co, C030 4, Fe, Zn or Ce02 or their combinations.
    类似技术:
    公开号 | 公开日 | 专利标题
    EP2142684B1|2012-04-25|Oxygen generation for battlefield applications
    US20090220388A1|2009-09-03|Breathing air maintenance and recycle
    JP3479950B1|2003-12-15|Environmental purification circulation type water electrolysis device
    US3910780A|1975-10-07|Separative barrier for preferential transport of CO{HD 2 {B and apparatus employing same
    KR20080047523A|2008-05-29|An emergency situation use safety oxygen mask
    US20190329076A1|2019-10-31|Oxygen concentrating self-rescuer device
    RU2491109C1|2013-08-27|Air cleaner for sealed manned objects
    KR102091547B1|2020-03-20|Portable Oxygen Concentrator by Respiratory
    WO2007142917B1|2008-05-02|Mine barrier survival system
    ES2637033B2|2019-03-25|System for obtaining and purifying oxygen from water for autonomous breathing
    KR101927061B1|2018-12-10|A system for preparing the purified air and structure for the same
    RU98938U1|2010-11-10|INSTALLATION FOR CONCENTRATION OF CARBON DIOXIDE REMOVED FROM THE ATMOSPHERE |
    CN105083500A|2015-11-25|Mermaid bionic gill type underwater breathing apparatus
    CN106940047A|2017-07-11|A kind of gas purification reforming unit
    KR101855104B1|2018-05-08|A process for preparing the purified air and the fresh water for the survival in the blocked space and its system
    CN204956889U|2016-01-13|Bionical gill formula rebreather of mermaid
    WO2018191216A1|2018-10-18|Closed or semi-closed loop onboard ceramic oxygen generation system
    Littau et al.2013|System and method for recovery of CO2 by aqueous carbonate flue gas capture and high efficiency bipolar membrane electrodialysis
    CN214370783U|2021-10-08|Electrochemistry air purification device
    CN107261289B|2020-06-30|Hydrogen breathing machine
    KR102252676B1|2021-05-18|Air inhaler with CO2 removing unit
    Warkander et al.2000|Review of Two Methods to Remove CO2 Using Seawater From Submarines During Emergency Conditions
    Erden2016|Two-stage PSA system for CO 2 removal and concentration during closed-loop human space exploration missions
    CN104152197A|2014-11-19|CO2 enrichment and methanation process in sealed space and reactor
    RU2190431C2|2002-10-10|Insulating respiratory system
    同族专利:
    公开号 | 公开日
    ES2637033B2|2019-03-25|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US3504669A|1967-09-07|1970-04-07|David Albert|Combined diving device and electrolysis operated oxygen generator|
    US3575167A|1968-06-06|1971-04-20|Charles E Michielsen|Multipurpose breathing apparatus|
    WO2009074160A1|2007-12-10|2009-06-18|Nokia Corporation|Portable oxygen delivery device and method for delivering oxygen to a mobile user|
    KR20100062983A|2010-04-27|2010-06-10|엘켐텍|Highly concentrated oxygen water purifier with electrolytic oxygen generator|
    法律状态:
    2019-03-25| FG2A| Definitive protection|Ref document number: 2637033 Country of ref document: ES Kind code of ref document: B2 Effective date: 20190325 |
    优先权:
    申请号 | 申请日 | 专利标题
    ES201700621A|ES2637033B2|2017-06-05|2017-06-05|System for obtaining and purifying oxygen from water for autonomous breathing|ES201700621A| ES2637033B2|2017-06-05|2017-06-05|System for obtaining and purifying oxygen from water for autonomous breathing|
    [返回顶部]