JPH0449137Y2 - - Google Patents

Description

[Detailed Description of the Invention] (Field of Industrial Application) The present invention relates to an oxygen supplementation device that supplies oxygen for breathing support and recovery from fatigue after engaging in strenuous sports.

(Prior Art) There is a device disclosed in Japanese Patent Application Laid-Open No. 61-222906 that supplies oxygen with simple operations. In this system, sodium percarbonate for generating oxygen, manganese dioxide as a decomposition catalyst, and water are stored separately in containers and stored, and when generating oxygen, the separating walls of each storage section are closed to the container. It is designed to open in conjunction with the opening operation of the.

Furthermore, in JP-A-61-77604, a hydrogen peroxide derivative sealed in dissolving paper and water mixed with a decomposition catalyst sealed in moisture-proof vinyl are separated into an outer bag equipped with a gas purification membrane and a mask. A technique is disclosed in which a bag-like moisture-proof vinyl bag is broken and opened by pressure when it is stored, and when oxygen is generated, a chemical reaction is started, and the generated oxygen is inhaled through a mask.

(Problem to be solved by the invention) In the technique disclosed in Japanese Patent Application Laid-Open No. 61-222906, the separation wall of the storage section that separates and stores the drug is destroyed when oxygen is generated. ,
It is difficult to reuse the container after use, and even if the container is reused, setting up the drug is complicated. For this reason, there is a problem that the same container is not suitable for repeated use.

Furthermore, the technology disclosed in Japanese Patent Application Laid-open No. 61-77604 is small and lightweight, disposable, and extremely convenient to carry. However, there is a problem in that the outer bag becomes hot (approximately 40 degrees Celsius) due to the heat generated by the chemical reaction that occurs when oxygen is generated. and,
There is a risk that the moisture-proof vinyl bag may be damaged and opened due to external pressure inadvertently applied during carrying, and a chemical reaction may begin.

The present invention was developed in view of the above-mentioned circumstances of conventional devices, and is an oxygen device that is convenient to carry, has no risk of inadvertently generating oxygen, and can generate oxygen with simple operation. The purpose is to provide replenishment equipment.

(Means for Solving the Problems) In order to achieve the above object, the oxygen supplementation device of the present invention includes a first storage body in which a hydrogen peroxide derivative is enclosed in a first bag-like member that dissolves in water; A second bag-like member that is impermeable to water and can be opened by pressure is sealed with water mixed with a decomposition catalyst, and a third bag-like member that is permeable to oxygen and impermeable to water is enclosed. The oxygen generator is housed in a chamber of a container, and a movable press movable part is provided so as to protrude into the chamber of the container, and the protruding movement of the press movable part causes the The second bag-like member of the oxygen generator is configured to be pressed and opened.

Further, the container may be provided with a pressing movement amount regulating means for restricting the amount of movement of the pressing movable portion into the chamber.

Furthermore, the press movable part may be configured to retreat from the chamber due to an increase in the internal pressure of the third bag-like member due to the generation of oxygen.

A protrusion is provided on the inner wall of the chamber, and the protrusion provides a gap between the inner wall and the oxygen generator.
A ventilation path may be formed that communicates with an oxygen discharge hole formed in the container.

(Function) Since the oxygen generator is housed within the chamber of the container, the container prevents external pressure from being applied to the oxygen generator. Further, the heat of chemical reaction when generating oxygen is blocked by the container. Furthermore, if the pressing movable part is pressed, the oxygen generator inside the chamber is pressed and the second bag-like member is broken and opened, and a chemical reaction is started to generate oxygen, so oxygen can be generated with a simple operation. can occur.

Moreover, if the pressing movement amount regulating means is provided, only the second bag-shaped member is damaged and opened by the pressure of the pressing movable part, and the first and third bag-shaped members are also prevented from being opened.

Furthermore, due to the increase in the internal pressure of the third bag-like member,
If the pressing movable part retreats, the generation of oxygen can be confirmed by this retreat.

If the protrusion forms a ventilation path communicating with the oxygen discharge hole between the inner wall of the chamber and the oxygen generator, the generated oxygen will be released from the oxygen discharge hole without being retained.

(Example) Hereinafter, an example of the present invention will be described with reference to FIGS. 1 to 7. FIG. 1 is a longitudinal cross-sectional view of one embodiment of the oxygen supplementation device of the present invention, FIG. 2 is a cross-sectional view taken along the line A-A in FIG. 1, and FIG.
4 is a plan view of the figure, FIG. 4 is a view taken along arrow B in FIG. 1, FIG. 5 is a sectional view taken along line C-C in FIG. 1, and FIG. 7 is a side view of the oxygen generator, and FIG. 7 is a plan view of the oxygen generator.

First, the container 1 will be explained. The container 1 is made of metal, hard plastic, or the like. Then, the lid member 3 is attached to the chamber container 2, which has one side open, so as to be able to be connected and separated so as to close the opening. An O-ring 4 is interposed at the contact portion between the lid member 3 and the chamber container 2 to provide an airtight structure, and a chamber 5 is formed by the chamber container 2 and the lid member 3.
Rib-shaped protrusions 6, 6, . . . are provided on the inner wall of the chamber container 2 toward the opening. Further, the chamber container 2 and the lid member 3 are configured to be able to be connected and separated by claw-like locking portions 7, 7.

Furthermore, a hole 9 is bored in the center of the wall 8 of the lid member 3 that closes the opening of the chamber container 2, and the cylindrical portion 10 is inserted into this hole 9 so that the sliding member 11 is moved against the lid member 3. It is assembled so that it can slide freely in 5 directions of the chamber. Also,
This sliding member 11 is provided with a guide wall 12 that is substantially parallel to the wall 8 and is connected to the end of the cylindrical portion 10 on the opposite side to the side where it is inserted into the hole 9. It is configured to be able to freely slide on the inner peripheral surface of the cylindrical wall 13 of No. 3 with a slight clearance. Then, the cylindrical portion 10 of the sliding member 11, the guide wall 12 and the lid member 3
A chamber 14 is formed by the wall 8 and the cylindrical wall 13 . Note that the wall 8 and the guide wall 12 constitute a pressing movement amount regulating means. The cylindrical portion 10 is provided with locking portions 15, 15, . Exhaust hole 1 communicating with chamber 14
7, 17... are drilled. Furthermore, the guide wall 12
A filter 18 is placed so as to close the cylindrical portion 10 . Here, the inside of the cylindrical part 10 is the container 1
This is the oxygen discharge hole in.

Furthermore, a mask member 19 is coupled to the guide wall 12 of the sliding member 11 through engaging portions 20 , 20 .
This mask member 19 is provided with an opening 21,
A mask lid 22 is swingably disposed so that the opening 21 can be opened and closed. Note that the sliding member 11 and the mask member 19 constitute a pressing movable part.

Next, the oxygen generator 30 will be explained. In the oxygen generator 30, first and second storage bodies 32 and 33 are enclosed in a third bag-like member 31 having a size that can be stored in the chamber 5 of the container 1. In the first storage body 32, a hydrogen peroxide derivative 35 such as granular sodium percarbonate is sealed in a first bag-like member 34 made of dissolving paper that dissolves in water. Further, in the second storage body 33, water 37 mixed with manganese dioxide as a decomposition catalyst is sealed in a second bag-like member 36 made of moisture-proof vinyl or the like which does not allow water to pass through and is easily damaged. . Furthermore, the third bag-like member 31 is formed of a gas purification membrane or the like that allows oxygen to pass through but does not allow water to pass through. Then, when the second bag-like member 36 is damaged and opened,
Water 37 mixed with enclosed manganese dioxide
However, a chemical reaction occurs with the hydrogen peroxide derivative 35 sealed in the first bag-like member 34, and oxygen is generated. Furthermore, when the internal pressure of the third bag-shaped member 31 increases due to the generation of oxygen and exceeds a predetermined value, only oxygen permeates the membrane and flows out.

In such a configuration of the container 1 and the oxygen generator 30, the locking parts 7, 7... are expanded from the chamber container 2, the lid member 3 is separated, and the oxygen generator 30 is housed in the chamber 5 through the opening. do. Furthermore, the lid member 3 is placed on the chamber container 2 and coupled with the locking portions 7, 7, . . . . In addition,
The second bag-like member 36 of the oxygen generator 30 will not be damaged unless pressed with strong force, so as shown in FIGS. 1 and 2, the sliding member 11
0 and located in the opposite direction to the chamber 5.

If carried in such a state, the external pressure will be absorbed by the container 1, and the oxygen generator 30 will not inadvertently start a chemical reaction. It should be noted that when the mask member 19 is carried, the opening 21 of the mask member 19 is closed with the mask lid 22.

When generating oxygen, the mask member 19 forming the pressing movable part is pressed with strong force in the direction of the chamber 5 to cause the cylindrical portion 10 of the sliding member 11 to protrude into the chamber 5 . Then, the oxygen generator 30 is strongly pressed and the second bag-like member 36 is broken open, and the water 37 mixed with manganese dioxide dissolves the first bag-like member 34 and undergoes a chemical reaction with the hydrogen peroxide derivative 35. to generate oxygen. Then, due to the generation of oxygen, the internal pressure of the third bag-shaped member 31 increases and the volume increases. For this reason, the sliding member 11 is pushed back and the generation of oxygen can be confirmed. Note that when the sliding member 11 moves, the volume of the chamber 14 changes, but the air inside is sucked in or exhausted through the exhaust holes 17, 17, . . . . Furthermore, the third bag-like member 3
1 rises to a predetermined value or higher, oxygen permeates through the third bag-like member 11 and is discharged from the chamber 5 into the mask member 19 via the orifice 16 of the cylindrical portion 10 and the filter 18.

Therefore, the mask lid 22 is opened and the mask member 1 is opened.
If you put your nose into the opening 21 of 9 and take a deep breath,
Oxygen can be easily supplied by inhalation. Then, the filter 18 may impart an appropriate fragrance or the like to the intake air. Note that oxygen leaking into the chamber 14 from the clearance between the hole 9 of the wall 8 and the cylindrical part 10 is sucked out through the exhaust holes 17, 17, etc. by the negative pressure generated around the orifice 16 when the oxygen passes through the orifice 16. It can be done. Further, the volume of the third bag-like member 31 of the oxygen generator 30 increases and it tries to come into close contact with the inner wall of the medicinal container 2, but since the protrusions 6, 6... are provided, the third bag-like member 31
As shown in the figure, the ventilation passage 40,
40... is ensured, and the oxygen that has passed through the third bag-like member 31 is discharged into the mask member 19 through the cylindrical portion 10 serving as an oxygen discharge hole without being retained.

After the oxygen generation is completed, only the oxygen generator 30 needs to be replaced.

In the above embodiment, the sliding member 11 and the mask member 19, which are separate members, are connected by the connecting parts 20, 20 to form the pressing movable part, but it goes without saying that they may be formed integrally. Furthermore, in the oxygen generator 30, the hydrogen peroxide derivative 35 is not limited to sodium percarbonate, but may also be calcium peroxide, barium peroxide, urea peroxide, etc., as shown in Japanese Patent Application Laid-Open No. 61-85959. good. Further, as the decomposition catalyst, various metal salts disclosed in JP-A-61-222906 may be used.

Furthermore, if the container 1 is made of metal, the chamber 5
A heat insulating member may be appropriately placed on the inner circumferential surface of the container 1 to prevent the chemical reaction heat of the oxygen generator 30 from being transmitted to the outside of the container 1.

Furthermore, in order to prevent the second bag-like member 36 from being damaged and unsealed by the pressure of the oxygen generator 30 by the pressing movable part and the first and third bag-like members 34 and 31 to be unsealed, the second bag-like member The pressure resistance of the bag 36 may be made small, or the first and third bag-like members 34 and 31 may have sufficient internal volume.
Here, when the second bag-like member 36 is damaged and opened, the third bag-like member 31 must not be opened, but the first bag-like member 34 may be damaged and opened at the same time.

The pressing movable part is not limited to one that reciprocates in a straight line as in the above embodiment, but may have a slidable structure. And furthermore, oxygen generator 3
It is also possible to configure the pressing movable part to be pushed back by the pressure of the oxygen released from the gun chamber 5 and filled in the chamber 5, so that the generation of oxygen can be confirmed.

(Effects of the invention) Since the present invention is configured as described above, it produces the effects described below.

There is no risk of inadvertently generating oxygen when carrying.
It is extremely convenient to carry. In addition, oxygen can be generated simply by strongly pressing the pressing movable part, and the operation is simple. In addition, the heat of chemical reaction is not transmitted to the outside of the container when oxygen is generated, so there is no discomfort caused by heat.

Furthermore, if the pressing movement amount regulating means is provided, the oxygen generator can be reliably pressed enough to generate oxygen, and the operation can be performed reliably. In addition, the oxygen generator will not be damaged due to excessive pushing.

Furthermore, the generation of colorless and odorless oxygen can be easily confirmed due to the retreat of the pressing movable part.

In addition, by ensuring an oxygen ventilation path with the protrusion, oxygen is not retained and oxygen is stably released.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view of an embodiment of the oxygen supplementation device of the present invention, FIG. 2 is a sectional view taken along the line A-A in FIG. 1, and FIG. FIG. 4 is a plan view taken along arrow B in FIG. 1, FIG. 5 is a sectional view taken along line C-C in FIG. 1, and FIG. 6 is a side view of the oxygen generator. FIG. 7 is a plan view of the oxygen generator. 1... Container, 2... Medicine chamber container, 3... Lid member,
5...Message chamber, 6...Protrusion, 8...Wall, 9...
Hole, 10...Cylindrical part, 11...Sliding member, 12...
... Guide wall, 19 ... Mask member, 30 ... Oxygen generator, 31 ... Third bag-shaped member, 32 ... First
storage body, 33... second storage body, 34... first storage body
bag-like member, 35... hydrogen peroxide derivative, 36...
...Second bag member, 37...Water mixed with decomposition catalyst.

Claims (1)

[Claims for Utility Model Registration] (1) A first storage body in which a hydrogen peroxide derivative is sealed in a first bag-like member that dissolves in water, and a second bag that is impermeable to water and can be opened by pressing. An oxygen generator is constructed by enclosing a second container containing water mixed with a decomposition catalyst in a third bag-like member that allows oxygen to pass through but does not allow water to pass through. Store in the chamber of the container,
A movable pushing movable part is provided so as to protrude into the chamber of the container, and the second bag-like member of the oxygen generator is pressed and opened by the protruding movement of the pushing movable part. Features: Oxygen supplementation device. (2) The oxygen supply device according to claim 1, characterized in that the container is provided with a pressing movement amount regulating means for regulating the amount of movement of the pressing movable portion into the chamber. (3) The oxygen supply device according to claim 1 or 2, characterized in that the pressing movable part is configured to retreat from the chamber due to an increase in the internal pressure of the third bag-like member due to the generation of oxygen. . (4) A protrusion is provided on the inner wall of the chamber, and the protrusion forms a ventilation path between the inner wall and the oxygen generator that communicates with an oxygen discharge hole bored in the container. The oxygen supply device according to claim 1, characterized in that: