JP7343174B2 - oxygen breathing apparatus - Google Patents

Description

The present invention relates to oxygen breathing apparatus.

In recent years, technology has been proposed that uses hyperbaric pressure and high concentration oxygen to increase dissolved oxygen in the blood for the purposes of maintaining and improving health and physical strength, anti-aging, and disease prevention ( (See Non-Patent Documents 1 and 2). Dissolved oxygen is oxygen that is dissolved in blood in addition to bound oxygen that is bound to hemoglobin in red blood cells, and is also called dissolved oxygen. For this reason, dissolved oxygen can reach every detail of the body even when red blood cells are chained or aggregated, making it difficult to flow, or even through small blood vessels.

Oxygen capsules that accommodate users inside and oxygen rooms (also called oxygen boxes) that can accommodate multiple users are used as equipment to increase dissolved oxygen in blood. In an oxygen capsule, the user lies supine in the internal space of the capsule, which is a closed space. Then, an environment is created in which the internal space is pressurized and the oxygen concentration is increased, and the user stays in this environment for a predetermined time. The same applies to the oxygen room.

Akihiko Ishihara, “Mechanism and effects of mild hyperbaric oxygen”, Pharmacia, Japanese Pharmacological Society, 2017, Vol. 53, No. 3, p. 241-244 Akihiko Ishihara, “Mild hyperbaric oxygen: mechanisms and effects”, The Journal of Physiological Sciences, 2019, 69, p. 573-580

By the way, in general oxygen capsules and oxygen rooms, as described above, since the internal space is pressurized to a pressure higher than atmospheric pressure, there is a risk that barotrauma (for example, damage to the eardrum, etc.) may occur to the user. Furthermore, since the oxygen concentration is increased by pressurization, there is a limit to the increase in oxygen concentration. Furthermore, since the volume of the interior space is relatively large, it takes a relatively long time from when the user enters the interior space until the oxygen concentration rises to a predetermined concentration. Furthermore, when the capsule is opened after discontinuing its use in the event of an emergency such as an earthquake, it is not easy to evacuate quickly because the pressure in the internal space must be reduced to the same level as atmospheric pressure. Furthermore, oxygen capsules and oxygen rooms are large and expensive, and therefore cannot be said to be suitable for use in private homes.

On the other hand, portable oxygen sprays used for sports, nasal catheters (also called nasal cannula), medical oxygen masks, and the like are known as small devices for inhaling oxygen. However, when using a portable oxygen spray, the user breathes with the nose and mouth exposed, so the high concentration of oxygen supplied from the spray can diffuses into the atmosphere, causing the oxygen concentration to drop quickly. descend. Therefore, the user cannot inhale oxygen efficiently, and the amount of dissolved oxygen in the user's blood does not increase much. The same applies to nasal catheters. Medical oxygen masks cover the user's nose and mouth, but the masks have gaps and holes to allow the user's exhaled air to escape, so oxygen can escape through these gaps. Disperses into the atmosphere. Therefore, similarly to the above, the amount of dissolved oxygen in the user's blood does not increase much.

The present invention was made in view of the above-mentioned problems, and an object of the present invention is to increase the amount of dissolved oxygen in blood.

An oxygen breathing apparatus according to a preferred embodiment of the present invention includes an oxygen supply source, a storage tank that stores oxygen supplied from the oxygen supply source, and an exhaust section that discharges air in the storage tank to the outside. , a mounting part that covers a user's nose and mouth to form a breathing space isolated from an external space around the nose and mouth, and a connecting flow path that connects the mounting part and the storage tank. . Air containing a high concentration of oxygen moves from the reservoir via the connecting channel to the breathing space and is inhaled by the user. The user's exhaled air travels to the reservoir via the connecting channel. The exhaust section is provided with an exhaust control valve capable of adjusting the amount of air discharged from the storage tank, and is provided independently of the exhaust control valve, and the amount of air flowing into the storage tank is controlled by the exhaust control valve. The storage tank includes an exhaust valve that discharges air in the storage tank when the amount is greater than the amount of air discharged from the storage tank, and a detection unit that detects the flow of air discharged from the exhaust valve.

Preferably, the oxygen breathing apparatus further includes a concentration measuring section that measures the oxygen concentration within the mounting section or the oxygen concentration near the mounting section of the connecting flow path.

Preferably, the value of the oxygen concentration measured by the concentration measuring section decreases immediately after the user attaches the attachment section, increases once, and then decreases again.

Preferably, the connecting channel is a tube with a cross-sectional area of 125 mm ² or more and 750 mm ² or less, and a length of 70 cm or more and 110 cm or less.

Preferably, the wearing part is a cup-type mask whose edges closely fit around the user's nose and mouth, and the user's ears are located outside the breathing space.

Preferably, the oxygen source comprises one or more oxygen concentrators, each oxygen concentrator having a maximum flow rate of 10 liters/min or less.

According to the present invention, the amount of dissolved oxygen in blood can be increased.

FIG. 1 is a diagram showing the configuration of an oxygen breathing apparatus according to one embodiment. FIG. 3 is an enlarged view showing the vicinity of the mounting portion. It is a figure showing the flow of use of an oxygen breathing apparatus. FIG. 3 is a diagram showing an example of a change in oxygen concentration at a measurement position.

FIG. 1 is a diagram showing the configuration of an oxygen breathing apparatus 1 according to one embodiment of the present invention. FIG. 2 is an enlarged view showing the vicinity of the attachment part 26 (described later) of the oxygen breathing apparatus 1. The oxygen breathing apparatus 1 is an apparatus for a user to breathe air containing high concentration of oxygen. By breathing air containing high concentrations of oxygen, the user increases the amount of dissolved oxygen in the blood (i.e., oxygen dissolved in plasma), thereby maintaining and improving health and physical strength. Anti-aging, disease prevention, etc. can be achieved. The oxygen breathing apparatus 1 is installed, for example, at a user's home or the like. Note that the oxygen breathing apparatus 1 may be installed in various locations other than the user's home. In this application, the gas that a user breathes is referred to as "air" regardless of its oxygen concentration. Further, the atmosphere that normally exists around the user and has an oxygen concentration of about 21% (that is, the amount (density) of oxygen contained per unit volume is about 21%) is also called "atmosphere". That is, the air is a general concept that includes the atmosphere. Moreover, the above-mentioned air containing high concentration of oxygen is air that contains more oxygen than the atmosphere in a unit volume of space (that is, has a high oxygen density).

The oxygen breathing apparatus 1 includes an oxygen supply source 21, a supply channel 22, a storage tank 23, an exhaust section 24, a connection channel 25, a mounting section 26, a concentration measurement section 27, and a first thermohygrometer. 281, a second thermohygrometer 282, and a storage rack 29. The storage rack 29 is a shelf that stores the oxygen supply source 21, the storage tank 23, and the like. Wheels and the like are provided at the lower end of the storage rack 29, allowing the oxygen breathing apparatus 1 to be moved by a user or the like.

The storage tank 23 is a container such as a tank that has an internal space 231 that is a substantially sealed space inside. The outer shape of the storage tank 23 is, for example, approximately rectangular parallelepiped. The volume of the internal space 231 of the storage tank 23 is, for example, 40L (liter) to 100L, preferably 50L to 90L. The outer shape of the storage tank 23 and the volume of the internal space 231 may be changed in various ways.

Oxygen supply source 21 is connected to storage tank 23 via supply channel 22 . The oxygen supply source 21 supplies air containing high concentration of oxygen to the internal space 231 of the storage tank 23. Hereinafter, the gas supplied from the oxygen supply source 21 to the storage tank 23 will also be referred to as "high concentration oxygen." The oxygen supply source 21 includes, for example, one or more oxygen concentrators 211 that condense oxygen in the atmosphere to generate highly concentrated oxygen. In the example shown in FIG. 1, the oxygen supply source 21 includes two oxygen concentrators 211.

The oxygen concentration in the highly concentrated oxygen supplied from each oxygen concentrator 211 to the storage tank 23 is, for example, 80% by volume to 90% by volume. The maximum flow rate of high concentration oxygen supplied from each oxygen concentrator 211 is, for example, 10 L/min. Thereby, the oxygen concentrator 211 can be downsized. The flow rate of high-concentration oxygen from the oxygen concentrator 211 can be changed according to the user's respiratory rate, and is set to 8 L/min or more, for example. The oxygen concentrator 211 is preferably one in which the oxygen concentration in the high concentration oxygen does not change even if the flow rate is changed.

The supply channel 22 is, for example, a flexibly deformable bellows tube made of resin. Thereby, the degree of freedom in selecting the relative position of the oxygen supply source 21 with respect to the storage tank 23 can be improved. High-concentration oxygen (for example, high-concentration oxygen contained in air) supplied from the oxygen supply source 21 to the storage tank 23 via the supply channel 22 is stored in the internal space 231 of the storage tank 23 . Note that the structure of the supply flow path 22 can be changed in various ways, and for example, a substantially undeformable fixed pipe or the like may be used as the supply flow path 22.

The exhaust section 24 exhausts the air inside the storage tank 23 to the outside of the storage tank 23. The exhaust section 24 includes an exhaust valve 241, an exhaust control valve 242, and a detection section 243. In the example shown in FIG. 1, the number of exhaust control valves 242 is one, but a plurality of exhaust control valves 242 may be provided. The same applies to the exhaust valve 241 and the detection section 243.

The exhaust valve 241 is, for example, a check valve provided on the upper surface of the storage tank 23. When the pressure in the internal space 231 of the storage tank 23 is higher than a predetermined pressure (for example, the atmospheric pressure around the storage tank 23), the air in the storage tank 23 is continuously discharged to the outside via the exhaust valve 241. be discharged. On the other hand, when the pressure in the internal space 231 of the storage tank 23 is below the predetermined pressure, air does not flow in or out through the exhaust valve 241. In other words, when the pressure in the internal space 231 of the storage tank 23 is below the predetermined pressure, the air in the storage tank 23 is not discharged to the outside from the exhaust valve 241, and the air inside the storage tank 23 is not discharged to the outside. Air also does not flow into the storage tank 23 via the exhaust valve 241.

The detection unit 243 is connected to the exhaust port of the exhaust valve 241 and detects the flow of air exhausted from the exhaust valve 241. The detection unit 243 is, for example, a flow indicator (also called a flow monitor) that includes a relatively small windmill, a ball, or the like that is rotated by the air discharged from the exhaust valve 241. The structure and type of the detection unit 243 may be changed in various ways.

The exhaust control valve 242 is a valve whose opening degree can be adjusted, and is provided on the side surface of the storage tank 23, for example. The exhaust control valve 242 is provided independently of the exhaust valve 241 described above. By adjusting the opening degree of the exhaust adjustment valve 242 by a user or the like, the amount of air discharged from the storage tank 23 via the exhaust adjustment valve 242 is adjusted. When the exhaust adjustment valve 242 is closed, no air flows in or out through the exhaust adjustment valve 242.

In the exhaust section 24, the opening degree of the exhaust control valve 242 is adjusted so that the amount of air flowing into the storage tank 23 and the amount of air flowing out from the storage tank 23 via the exhaust adjustment valve 242 are approximately equal. Then, air is not discharged from the exhaust valve 241, and the detection unit 243 does not detect the discharge of air from the exhaust valve 241. For example, when the detection unit 243 is a flow indicator including a windmill, the windmill does not rotate. On the other hand, when the opening degree of the exhaust control valve 242 is made smaller than the above state, the amount of air flowing into the storage tank 23 becomes larger than the amount of air flowing out from the storage tank 23 via the exhaust control valve 242. , air is also exhausted from the exhaust valve 241. In this case, the detection unit 243 can easily visually confirm that the above-mentioned windmill is rotating and exhaust gas is being discharged from the exhaust valve 241.

The mounting part 26 is a member that covers the user's nose and mouth and forms a breathing space 261 around the nose and mouth that is airtightly isolated from the space outside the mounting part 26. In the example shown in FIG. 2, the mounting portion 26 is a cup-type mask that protrudes forward and away from the user's nose and mouth. The edge of the mounting portion 26 fits tightly around the user's nose and mouth all around the user's nose and mouth without any gaps. As a result, a breathing space 261 is formed that is surrounded by the mounting portion 26 and a portion of the user's face (ie, the area around the nose and mouth).

The attachment part 26 is detachably attached to the user's head using, for example, an elastic band or the like. When the wearing part 26 is worn, the parts of the user's face other than the area around the nose and mouth are exposed from the wearing part 26. Therefore, both ears of the user are located outside the above-mentioned breathing space 261.

The mounting portion 26 is connected to the storage tank 23 via the connection channel 25. The connection channel 25 is, for example, a flexibly deformable resin tube, preferably a bellows tube. Thereby, the degree of freedom in selecting the relative position of the user wearing the mounting part 26 with respect to the storage tank 23 can be improved. Air containing high concentration of oxygen (hereinafter also referred to as “high oxygen concentration air”) stored in the internal space 231 of the storage tank 23 is transferred to the breathing space 261 of the mounting portion 26 via the connection flow path 25. transferred and inhaled by the user. In addition, the user's exhaled breath moves from the breathing space 261 to the storage tank 23 via the connection channel 25.

The length of the connection channel 25 is preferably 70 cm or more and 110 cm or less, more preferably 80 cm or more and 100 cm or less. The area of the cross section perpendicular to the longitudinal direction of the connection flow path 25 (that is, the cross-sectional area of the flow path) is preferably 125 mm ² or more and 750 mm ² or less, more preferably 175 mm ² or more and 710 mm ^{2 or} less. The inner diameter of the connecting channel 25 is, for example, 15 mm to 30 mm. Note that the structure and size of the connection flow path 25 can be changed in various ways, and for example, a substantially undeformable fixed pipe or the like may be used as the connection flow path 25.

The attachment part 26 is not provided with any holes or openings through which air can pass, except for the connection part with the connection flow path 25. Therefore, the entire amount of the user's breath is discharged from the body into the breathing space 261. In addition, the entire amount of the user's exhaled air flowing out from the breathing space 261 flows into the connection channel 25. The air in the breathing space 261 that the user inhales directly flows into the breathing space 261 from the connecting flow path 25, and the air in the breathing space 261 directly flows into the breathing space 261 from the connecting flow path 25. It is not something that has flowed in from the environment).

The mounting portion 26 is preferably detachably connected to the connection channel 25. Thereby, when a plurality of users share one oxygen breathing apparatus 1, a mounting section 26 dedicated to each user is prepared, and the mounting section 26 can be replaced for each user. The opening at the tip of the connecting channel 25 (that is, the end connected to the mounting section 26) is an opening provided near the tip of the connecting channel 25, regardless of whether there is a connection with the mounting section 26. It can be closed airtight with a valve. The opening/closing valve may be provided near the end of the connecting flow path 25 on the side connected to the storage tank 23. Note that the tip of the connection channel 25 may be hermetically closed with a closure such as a removable cap.

The concentration measurement section 27 includes an oxygen meter 271 and measurement piping 272. The oxygen meter 271 is a device that measures the concentration of oxygen taken into the device and displays the measured value. As the oxygen meter 271, for example, a commercially available zirconia type, galvanic cell type, or magnetic type oxygen meter is used. The oxygen meter 271 is placed, for example, on the upper surface of the storage tank 23. The measurement piping 272 is a conduit connected to the oxygen meter 271 and extending from the oxygen meter 271 to a predetermined measurement position 273. The measurement pipe 272 is a flexibly deformable resin pipe. Since the diameter of the measurement piping 272 is smaller than the diameter of the connecting channel 25 (for example, an inner diameter of 1 to 2 mm), the measurement piping 272 is shown by a broken line in FIG.

In the example shown in FIG. 1, the measurement position 273 (that is, the position of the tip of the measurement piping 272) is a position within the connection flow path 25 near the connection between the connection flow path 25 and the mounting portion 26. The position near the connection part in the connection passage 25 is the position where the sum of the capacity of the connection passage 25 and the capacity of the breathing space 261 from the position to the attachment part 26 is less than or equal to the exhaled volume of the user. It is. The measurement position 273 is preferably close to the edge of the connection channel 25 on the mounting portion 26 side. The measurement position 273 may be a position inside the mounting section 26 (that is, inside the breathing space 261).

In the example shown in FIG. 1, the measurement piping 272 extends from the oxygen meter 271 to the internal space 231 of the storage tank 23, passes through the storage tank 23 and the connecting channel 25, and extends to the measurement position 273. Note that the measurement piping 272 does not necessarily need to pass through the internal space 231 of the storage tank 23, but extends from the oxygen meter 271 through the outside of the storage tank 23 to the connection channel 25, and extends from the side wall of the connection channel 25. It may also extend to the measurement position 273 through hermetically sealed passages. In the concentration measurement section 27, air near the measurement position 273 is sucked by the oxygen meter 271 through the measurement piping 272, and the oxygen concentration at the measurement position 273 is measured and displayed by the oxygen meter 271.

In addition, when the oxygen meter 271 in which the oxygen sensing part (i.e., the sensor part) can be installed at a position away from the oxygen concentration display part is used, the oxygen sensing part is located at the measurement position 273, and the display part is, for example, It may be arranged on the upper surface of the storage tank 23. In this case, the measurement pipe 272 is omitted.

The first thermohygrometer 281 is placed inside the storage tank 23 and measures the temperature and humidity of the internal space 231 of the storage tank 23 . The second thermohygrometer 282 is disposed outside the storage tank 23 (for example, on the top surface of the storage tank 23) and measures the temperature and humidity outside the storage tank 23. The measured values of temperature and humidity by the first thermohygrometer 281 are transmitted to the second thermohygrometer 282 and displayed together with the temperature and humidity outside the storage tank 23 in the second thermohygrometer 282 .

If the temperature and humidity of the internal space 231 of the storage tank 23 measured by the first thermohygrometer 281 are higher than the temperature and humidity of the outside of the storage tank 23 measured by the second thermohygrometer 282, the oxygen Increase in the amount of dissolved oxygen in the blood due to breathing may be suppressed. Further, if the humidity in the internal space 231 of the storage tank 23 is excessively low, if the user has a respiratory disease, there is a possibility that the user's respiratory system will be damaged. Therefore, when using the oxygen breathing apparatus 1, it is preferable to confirm that the temperature and humidity of the internal space 231 of the storage tank 23 are within appropriate ranges. In addition, in the oxygen breathing apparatus 1, as will be described later, the user's exhaled air containing a relatively large amount of water vapor moves into the internal space 231 of the storage tank 23 and increases the humidity to a certain extent. This prevents respiratory damage even when used.

Next, how to use the oxygen breathing apparatus 1 will be explained with reference to FIG. 3. When using the oxygen breathing apparatus 1, first, the oxygen supply source 21 (that is, the two oxygen concentrators 211) is driven, and high concentration oxygen is continuously supplied to the storage tank 23 (step S11). At this time, the exhaust control valve 242 is closed in advance, and the tip of the connecting flow path 25 is also closed in advance. The gas (for example, atmospheric air with an oxygen concentration of about 21%) that was present in the storage tank 23 is discharged from the exhaust valve 241 of the exhaust part 24, and thereby the internal space 231 of the storage tank 23 and the connecting flow are discharged. The oxygen concentration within channel 25 increases. Further, the pressure in the internal space 231 of the storage tank 23 is maintained at approximately the same pressure as atmospheric pressure.

When the oxygen concentration in the internal space 231 of the storage tank 23 reaches a predetermined concentration for starting use, the mounting part 26 is attached to the tip of the connecting flow path 25, and the user wears the mounting part 26 (step S12). The starting concentration is, for example, 80% to 90% by volume, preferably about 85% by volume. The user's nose and mouth are covered by the mounting portion 26 as shown in FIG. 2, and a breathing space 261 is formed around the nose and mouth. The user then starts breathing the high oxygen concentration air stored in the internal space 231 of the storage tank 23. The high oxygen concentration air in the storage tank 23 is inhaled by the user through the connecting flow path 25 and the breathing space 261, and the user's exhaled air flows into the storage tank 23 through the breathing space 261 and the connecting flow path 25. Inflow.

The fact that the oxygen concentration in the internal space 231 of the storage tank 23 has reached the starting concentration can be determined, for example, by the user visually observing the oxygen meter 271 of the concentration measurement unit 27 after a predetermined time has elapsed since the start of supply of high-concentration oxygen. Confirmed by. Alternatively, when the oxygen concentration in the internal space 231 reaches the starting concentration, the user may be notified by an alarm or the like. In either case, the user can move freely until he or she starts inhaling high-oxygen-concentrated air, so unlike an oxygen capsule or an oxygen room, the time required to be restrained before inhalation can be shortened.

The user wearing the mounting part 26 opens the exhaust control valve 242 and adjusts the opening degree of the exhaust control valve 242 to facilitate breathing (step S13). Specifically, the opening degree of the exhaust control valve 242 is set such that the amount of air flowing into the storage tank 23 and the amount of air flowing out from the exhaust adjustment valve 242 are approximately equal, and the pressure inside the storage tank 23 is reduced. It is set to be approximately equal to atmospheric pressure. The amount of air flowing into the storage tank 23 is determined by the amount of high-concentration oxygen flowing from the oxygen supply source 21 and the difference between the user's exhalation and inhalation (that is, the amount of inhalation subtracted from the expiration amount). It is the total. A user's expiratory volume is usually about 5% to 10% higher than the inhaled volume.

Note that when the amount of air flowing into the storage tank 23 is greater than the amount of air discharged from the exhaust control valve 242, the air in the storage tank 23 is exhausted from the exhaust valve 241. The exhaust of air from the exhaust valve 241 is detected by the detection unit 243. Therefore, the user gradually increases the opening degree of the exhaust control valve 242, and when the detection unit 243 hardly detects the exhaust of air from the exhaust valve 241 (for example, the windmill or ball of the flow indicator). It is preferable to finish adjusting the opening degree of the exhaust control valve 242 at the time when the rotation of the exhaust control valve 242 stops or immediately before the rotation of the exhaust control valve 242 stops. Thereby, the opening degree of the exhaust control valve 242 can be easily adjusted. Further, when the oxygen breathing apparatus 1 is used for the second time or later, the exhaust control valve 242 may be opened to the opening degree at the time of the first use, and the opening degree may be finely adjusted as necessary.

When the user of the oxygen breathing apparatus 1 is a man, the amount of breathing is generally higher than that of a woman, so the flow rate of high-concentration oxygen supplied from the oxygen supply source 21 to the storage tank 23 is lower than when the user is a woman. Many settings are made. The flow rate of high concentration oxygen from the oxygen supply source 21 is, for example, 16 L/min to 18 L/min if the user is a man, and 10 L/min to 12 L/min if the user is a woman. Therefore, the degree of opening of the exhaust control valve 242 when the user is male is usually larger than the degree of opening of the exhaust control valve 242 when the user is female.

The user breathes in high oxygen concentration air (so-called oxygen breathing) for a predetermined period of time while wearing the wearing part 26 (step S14). This increases the amount of dissolved oxygen in the user's blood. The predetermined time is, for example, 10 minutes to 15 minutes. When using the oxygen breathing apparatus 1 for 15 minutes, it is equivalent to staying in an oxygen room for 50 minutes in an environment of 1.3 atmospheres (i.e., 1317 hPa) and an oxygen concentration of 40% by volume (for example, approximately 103% of the time spent in an oxygen room) ) can take in dissolved oxygen. When the predetermined period of oxygen breathing is completed, the user removes the attachment part 26 from the face and stops the supply of oxygen from the oxygen supply source 21. Note that even if it is desired to interrupt the use of the oxygen breathing apparatus 1 during step S14 in an emergency such as an earthquake, it is sufficient to similarly remove the mounting portion 26 and stop the oxygen supply source 21. Therefore, the user can quickly take necessary actions such as evacuation.

FIG. 4 is a diagram showing an example of a change in the output from the concentration measuring section 27 (that is, the oxygen concentration at the measurement position 273) while the oxygen breathing apparatus 1 is in use. The horizontal axis shows the elapsed time from the start of use of the oxygen breathing apparatus 1, and the vertical axis shows the oxygen concentration at the measurement position 273 measured by the oximeter 271. As shown in FIG. 4, when the user starts using the oxygen breathing apparatus 1, the oxygen concentration at the measurement position 273 (that is, the measured value of the oxygen concentration by the concentration measurement section 27) is determined when the user attaches the attachment section 26. Immediately after that, it drops rapidly. Specifically, the oxygen concentration at the measurement position 273 decreases from the starting concentration C ₀ (for example, 80% to 90% by volume) to the first concentration C ₁ . This is because the measurement position 273 is located near the connection between the connection flow path 25 and the mounting part 26, and immediately after the oxygen breathing apparatus 1 starts to be used, the exhaled air of the user containing a large amount of carbon dioxide is placed at the measurement position 273. This is because the surrounding area is filled with water. The first concentration C ₁ is, for example, 50% to 60% by volume. The time it takes for the oxygen concentration at the measurement position 273 to decrease from the initial concentration C ₀ to the first concentration C ₁ is, for example, 30 seconds to 1 minute.

Subsequently, the oxygen concentration at the measurement position 273 increases (ie, recovers) from the first concentration C ₀ to the second concentration C ₂ . This is because the carbon dioxide contained in exhaled breath that is filled near the measurement position 273 moves (that is, diffuses) into the internal space 231 of the storage tank 23 via the connection flow path 25, and This is because the oxygen concentration air passed near the measurement position 273 and moved (that is, diffused) into the breathing space 261 of the mounting section 26 . The second concentration C ₂ is, for example, 65% to 75% by volume. The time it takes for the oxygen concentration at the measurement position 273 to increase from the first concentration C ₁ to the second concentration C ₂ is, for example, 1 minute to 2 minutes. Note that if the second concentration _C2 does not increase to, for example, 65% by volume, the amount of high concentration oxygen supplied from the oxygen supply source 21 may be increased. Further, when the second concentration _C2 increases, for example, more than 75% by volume, the amount of high concentration oxygen supplied from the oxygen supply source 21 may be reduced.

Thereafter, the oxygen concentration at the measurement position 273 gradually decreases again from the second concentration _C2 to the third concentration _C3 . This is because the cumulative amount of carbon dioxide emitted by the user increases as time passes from the start of use of the oxygen breathing apparatus 1. The third concentration C ₃ is, for example, 50% to 60% by volume. The time it takes for the oxygen concentration at the measurement position 273 to decrease from the second concentration C ₂ to the third concentration C ₃ is, for example, 12 minutes to 13.5 minutes. Note that the slope and shape of the graph shown in FIG. 4 may vary depending on the user's respiratory rate, the amount of high-concentration oxygen supplied from the oxygen supply source 21, and the like. However, as mentioned above, if the amount of air flowing into the storage tank 23 and the amount of air flowing out from the exhaust control valve 242 are approximately equal, the change in the oxygen concentration at the measurement position 273 will generally change. The shape is similar to the graph shown in FIG.

As described above, the oxygen breathing apparatus 1 includes the oxygen supply source 21 , the storage tank 23 , the exhaust section 24 , the mounting section 26 , and the connection channel 25 . The storage tank 23 stores oxygen supplied from the oxygen supply source 21. The exhaust section 24 exhausts the air in the storage tank 23 to the outside. The mounting portion 26 covers the user's nose and mouth and forms a breathing space 261 around the nose and mouth that is isolated from the external space. The connecting channel 25 connects the mounting portion 26 and the storage tank 23. In the oxygen breathing apparatus 1, air containing a high concentration of oxygen (ie, high oxygen concentration air) moves from the storage tank 23 to the breathing space 261 via the connecting flow path 25, and is inhaled by the user. In addition, the user's exhaled air moves to the storage tank 23 via the connection channel 25. Thereby, as described above, the amount of dissolved oxygen in the user's blood can be increased while simplifying and downsizing the device structure compared to an oxygen capsule or an oxygen room.

Note that in the oxygen breathing apparatus 1, it is preferable that air movement between the breathing space 261 and the external space is completely prevented, but if the breathing space 261 can be maintained at a desired oxygen concentration atmosphere, the breathing If the movement of air between the space 261 and the external space is not completely prevented (i.e., if some high-oxygen concentration air flows from the breathing space 261 into the external space and/or if the movement of air from the external space to the external space is 261), it can be said that the breathing space 261 is isolated from the outside space by the mounting portion 26.

As described above, in the oxygen breathing apparatus 1, it is preferable that the pressure within the storage tank 23 is maintained substantially equal to atmospheric pressure by the exhaust section 24. As a result, the structure of the storage tank 23 can be simplified compared to when the pressure is higher than atmospheric pressure (for example, when the pressure is 1.25 to 1.3 atm, such as in an oxygen capsule). .

As described above, the exhaust section 24 preferably includes an exhaust adjustment valve 242 that can adjust the amount of air discharged from the storage tank 23. This allows the user to breathe oxygen comfortably. Note that the exhaust control valve 242 is located not in the storage tank 23 but in the middle of the connection flow path 25 (for example, at a portion of the connection flow path 25 near the storage tank 23, or at the center of the connection flow path 25 in the longitudinal direction). may be provided. Even in this case, the user can comfortably breathe oxygen. However, if the exhaust control valve 242 is provided in the connection flow path 25, a part of the high oxygen concentration air traveling from the storage tank 23 to the mounting part 26 will be discharged to the outside from the exhaust control valve 242. Therefore, it is more preferable that the exhaust control valve 242 is provided in the storage tank 23. Thereby, the user can efficiently increase the amount of dissolved oxygen in the blood while breathing oxygen comfortably.

As described above, it is preferable that the exhaust section 24 further includes an exhaust valve 241 and a detection section 243. The exhaust valve 241 is provided independently of the exhaust control valve 242 and controls the air in the storage tank 23 when the amount of air flowing into the storage tank 23 is larger than the amount of air discharged from the exhaust control valve 242. Discharge. The detection unit 243 detects the flow of air exhausted from the exhaust valve 241. Thereby, it is possible to easily check whether the amount of air discharged from the exhaust control valve 242 is appropriate, that is, whether the opening degree of the exhaust control valve 242 is appropriate. Specifically, when the detection unit 243 detects the flow of air from the exhaust valve 241, it is confirmed that the amount of air discharged from the exhaust control valve 242 is insufficient. It is more preferable that the detection unit 243 has a structure that visually indicates the presence or absence of exhaust from the exhaust valve 241 (for example, the above-mentioned flow indicator).

As described above, the oxygen breathing apparatus 1 preferably further includes a concentration measuring section 27 that measures the oxygen concentration within the mounting section 26 or the oxygen concentration near the mounting section 26 of the connecting flow path 25. Thereby, the oxygen concentration of the high oxygen concentration air actually inhaled by the user can be measured with high accuracy. In addition, by monitoring the oxygen concentration, if high oxygen concentration air is leaking from the storage tank 23, the connecting flow path 25, the attachment part 26, the gap between the attachment part 26 and the user's face, etc. , leaks of high oxygen concentration air can be quickly discovered.

As described above, it is preferable that the oxygen concentration measured by the concentration measuring section 27 decreases immediately after the user attaches the attachment section 26, increases once, and then decreases again. By checking the change in the measured value of oxygen concentration, it can be confirmed that the user is properly performing the above-mentioned oxygen breathing.

As mentioned above, the connecting channel 25 is preferably a tube with a cross-sectional area of 125 mm ² or more and 750 mm ² or less, and a length of 70 cm or more and 110 cm or less. This allows the user to breathe oxygen comfortably. More preferably, the cross-sectional area of the connection channel 25 is 175 mm ² or more and 710 mm ² or less, and the length of the connection channel 25 is 80 cm or more and 100 cm or less. This allows the user to breathe oxygen more comfortably. Note that if the cross-sectional area of the connecting channel 25 is less than 125 ^mm2 or the length is longer than 110 cm, it may be difficult for the user's exhaled air to move to the storage tank 23, making it difficult for the user to breathe. There is. On the other hand, if the length is less than 70 cm, the amount of high oxygen concentration air supplied from the storage tank 23 to the breathing space 261 may decrease, making it difficult for the user to breathe.

As mentioned above, the fitting 26 is preferably a cup-type mask whose edges fit tightly around the user's nose and mouth, and the user's ears are located outside the breathing space 261. In this way, by using a small mask as the wearing part 26, the contact area between the wearing part 26 and the user's face can be reduced, so the gap between the wearing part 26 and the user's face can be reduced. It is possible to prevent (or suppress) leakage of high oxygen concentration air from etc. Additionally, since the user's ears are exposed through the mask, which is supplied with high oxygen concentration air, it is possible to eliminate the possibility of barotrauma to the eardrums, even for users with ear diseases. can. Note that, as described above, the mask does not need to be in perfect contact with the user as long as the breathing space 261 can be maintained at a desired oxygen concentration atmosphere.

As mentioned above, the oxygen supply source 21 preferably includes one or more oxygen concentrators 211, and the maximum flow rate of each oxygen concentrator 211 is preferably 10 L/min or less. Thereby, the oxygen supply source 21 can be downsized, and the oxygen breathing apparatus 1 can be downsized to the extent that it can be moved by one user. Furthermore, since the cost of the oxygen supply source 21 can be reduced, the manufacturing cost of the oxygen breathing apparatus 1 can be reduced.

Various modifications can be made to the oxygen breathing apparatus 1 described above.

For example, a flow rate adjustment valve may be provided in the connection flow path 25 so that the flow rate of the high oxygen concentration air supplied from the storage tank 23 to the breathing space 261 may be adjusted. The flow rate adjustment valve may be provided at the connection between the storage tank 23 and the connection channel 25.

In the oxygen source 21, the maximum flow rate of the oxygen concentrator 211 may be greater than 10 L/min. Further, the number of oxygen concentrators 211 may be changed as appropriate. The oxygen supply source 21 does not necessarily have to include the oxygen concentrator 211, and may be modified in various ways. For example, the oxygen supply source 21 may include an oxygen cylinder containing concentrated oxygen. Thereby, the oxygen breathing apparatus 1 can be further miniaturized, and the oxygen breathing apparatus 1 can be mounted on a cart or the like to be portable when going out.

The shape of the mounting portion 26 is not limited to the above-mentioned example, and may be modified in various ways. For example, the mounting portion 26 may be a large mask type that covers substantially the entire face of the user (ie, from the forehead to the chin) from the front side. Alternatively, the mounting portion 26 may be a full-face helmet type that accommodates the entire head of the user.

The oxygen breathing apparatus 1 may be provided with a control section that controls the oxygen supply source 21 based on the measurement result by the concentration measurement section 27 (that is, the oxygen concentration at the measurement position 273). In this case, the flow rate of the air containing high concentration oxygen supplied from the oxygen supply source 21 is automatically adjusted based on the above measurement result under control by the control unit.

The oxygen concentration measurement position 273 by the concentration measuring section 27 does not necessarily have to be within the mounting section 26 or near the mounting section 26 of the connecting channel 25. The measurement position 273 may be, for example, a position away from the attachment part 26 of the connection channel 25. Further, the concentration measuring section 27 may be omitted from the oxygen breathing apparatus 1.

In the exhaust section 24, the detection section 243 that detects the flow of air discharged from the exhaust valve 241 may be omitted. Further, the exhaust valve 241 and the exhaust adjustment valve 242 do not necessarily need to be provided independently from each other, and the exhaust valve 241 may be omitted. In this case, when high-concentration oxygen is supplied from the oxygen supply source 21 to the storage tank 23 and stored in step S11 described above, the exhaust control valve 242 is kept slightly open, and the The air having a normal oxygen concentration is discharged to the outside of the storage tank 23 from the exhaust control valve 242. Further, in the exhaust section 24, for example, a plurality of exhaust valves 241 may be provided, and the exhaust control valve 242 may be omitted.

The configurations of the above embodiment and each modification may be combined as appropriate unless mutually contradictory.

1 Oxygen breathing apparatus 21 Oxygen supply source 23 Storage tank 24 Exhaust section 25 Connection channel 26 Mounting section 27 Concentration measurement section 211 Oxygen concentrator 241 Exhaust valve 242 Exhaust control valve 243 Detection section 261 Breathing space S11 to S14 Step

Claims (6)

An oxygen breathing apparatus,
an oxygen source;
a storage tank that stores oxygen supplied from the oxygen supply source;
an exhaust section that exhausts air in the storage tank to the outside;
an attachment part that covers a user's nose and mouth to form a breathing space isolated from an external space around the nose and mouth;
a connection flow path connecting the mounting part and the storage tank;
Equipped with
Air containing a high concentration of oxygen moves from the reservoir through the connecting flow path to the breathing space and is inhaled by the user;
The exhaled breath of the user moves to the reservoir via the connecting flow path,
The exhaust section is
an exhaust control valve that can adjust the amount of air discharged from the storage tank;
an exhaust valve that is provided independently of the exhaust control valve and that discharges air from the storage tank when the amount of air flowing into the storage tank is greater than the amount of air discharged from the exhaust control valve; ,
a detection unit that detects the flow of air discharged from the exhaust valve;
An oxygen breathing apparatus characterized by comprising : The oxygen breathing apparatus according to claim 1 ,
The oxygen breathing apparatus further comprises a concentration measuring section that measures the oxygen concentration within the mounting section or the oxygen concentration near the mounting section of the connecting flow path. The oxygen breathing apparatus according to claim 2 ,
An oxygen breathing apparatus characterized in that the oxygen concentration measured by the concentration measuring section decreases immediately after the user attaches the attachment section, increases once, and then decreases again. The oxygen breathing apparatus according to any one of claims 1 to 3 ,
An oxygen breathing apparatus characterized in that the connecting channel is a tube with a cross-sectional area of 125 mm ² or more and 750 mm ² or less, and a length of 70 cm or more and 110 cm or less. The oxygen breathing apparatus according to any one of claims 1 to 4 ,
The wearing part is a cup-type mask whose edges closely fit around the nose and mouth of the user,
An oxygen breathing apparatus, wherein the user's ears are located outside the breathing space. The oxygen breathing apparatus according to any one of claims 1 to 5 ,
the oxygen source comprises one or more oxygen concentrators;
An oxygen breathing apparatus characterized in that the maximum flow rate of each oxygen concentrator is 10 liters/minute or less.

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