JPH0413284B2 - - Google Patents

Description

[Detailed Description of the Invention] [Technical Field] The present invention relates to an oxygen generation system that is used for emergency medical treatment for accidents such as flames, oxygen deficiency, generation of harmful gases, difficulty in breathing due to illness, or for respiratory support after sports. Regarding equipment.

[Background technology]

BACKGROUND OF THE INVENTION Conventionally, cylinders filled with oxygen have generally been used for emergency medical treatment for accidents such as flames, lack of oxygen, generation of harmful gases, difficulty in breathing due to illness, and for respiratory support after sports.
However, this is large, not easy to use, and expensive. For this reason, an oxygen generator that can be easily used is desired.

In order to meet this requirement, Japanese Unexamined Patent Publication No. 54-93896
There is one shown in the publication. This involves the generation of oxygen by a chlorate mixture,
It has the advantage of being easier to use than those using oxygen cylinders. However, in this oxygen generating device, it is necessary to remove impurities such as harmful chlorine gas, and in order to ensure the safety of the device, the device becomes complicated and expensive.

On the other hand, JP-A-54-26990 discloses that sodium peroxycarbonate 4Na ₂ CO _3.3 /
It has been shown that oxygen can be generated by contacting 2H ₂ O ₂ ) with a suspension or aqueous solution of a catalyst. This method has the characteristics of being much easier to use than the above-mentioned oxygen cylinders and chlorate mixtures, being safer and more reliable, and moreover, being inexpensive. For this reason, there is a demand for an oxygen generating device that is inexpensive and simple in structure and operation, using the peroxycarbonate, a safe chemical such as a catalyst, and water. However, since the above drugs are hygroscopic, they may become unusable if stored for a long time.
Furthermore, if the entire oxygen generator is thrown away after each use, a lot of parts will be wasted, no matter how cheap it is.

[Purpose of the invention]

This invention was made in view of the above problems, and is inexpensive, simple in operation and structure, and
The purpose is to provide an oxygen generator that can be used any number of times over a long period of time.

[Disclosure of the invention]

In order to achieve the above object, the present invention provides a cartridge that is replaceably connected to a container containing water and has a drug storage section containing a drug that reacts with water to generate oxygen. The drug storage portion of the cartridge is provided with a partition at a position facing the water in the container, and
An opening means for breaking the partition wall is also provided, an operating end of the opening means faces outside the cartridge, and the inside of the container and the inside of the cartridge are communicated when the partition wall is broken,
A discharge port for discharging oxygen generated in the container to the outside through the cartridge is provided at a portion of the cartridge where the opening means operation end faces, and the discharge port and the opening means operation end are covered. A mask is removably attached to the cartridge, and the mask is adapted to be attached to the cartridge even in an inverted state, and has an opening for opening the discharge port into the mask in this inverted state. The main focus is on the oxygen generators that are used.

The present invention will be explained in detail below based on the drawings showing one embodiment thereof. In the examples below, a two-component agent consisting of peroxycarbonate and a catalyst is used as the agent that reacts with water to generate oxygen, but it is also possible to use one component or three or more components. is also possible.

First, the embodiments shown in FIGS. 1a and 1b and FIG. 2 will be described.

The container 1 is made of a material such as polypropylene or polyethylene by blow molding or the like, and water 3 is accommodated in the container interior space 2 . The container 1 has a cylindrical shape with an opening at the upper end, and a cap 4 is connected and fixed by screws 5 so as to cover the opening. On the other hand, the cylindrical cartridge 6 is provided with an outwardly directed flange 7 at its upper end, and this flange 7 is sandwiched between the opening periphery 8 of the container and the cap 4. This cartridge 6 and container 1 are connected. A gasket 9, which is a sealing means, is provided at this connection part in order to prevent oxygen from leaking from this part.

Inside the cartridge 6 formed by injection molding or the like, there is an oxygen generating agent 1 made of peroxycarbonate that reacts with the water 3 to generate oxygen.
There is a first space 11 in which 0 is accommodated, and a cylindrical body 13 serving as a guide for an operating rod 12 serving as an opening means is provided at the center of the first space 11, into which the operating rod 12 is inserted. It is rare. On the other hand, a hole 14 is provided at one end of the cartridge 6, and a film 15 serving as a partition wall is pasted to cover the hole 14. Then, inside this film 15, a cap-shaped partition member 16 is provided at a central protrusion 16a.
is inserted into the cylindrical body 13 and is locked by a locking means 17 consisting of a convex strip and a groove, and a catalyst 18 is accommodated between the film 15 and this partition member 16. This is a second space 19 where Although the material of the film 15 is not particularly limited, preferred films for this invention include polyethylene terephthalate, polyethylene, aluminum foil, and laminates thereof.

There are no particular limitations on the method of filling the cartridge with the oxygen generating agent or catalyst as in the embodiment shown in the figure, but if the following steps are used, the cartridge can be easily filled with the chemicals. That is, first, the filter holder 21 to which the filter 20 is welded is welded to one end of the cartridge 6. Next, the cartridge 6 is turned upside down, and after filling the oxygen generating agent 10 through the hole 14, the restriction member 16 is pushed in until it is locked by the locking member 17. Thereafter, the catalyst 18 is filled here, and the film 15 is attached to the hole 14 by heat welding, thereby completing the filling of the drug.

As shown in the figure, the upper end (operating end) of the operating rod 12
An oxygen discharge port 23, which will be described later, is provided at a location facing the outside of the cartridge, and a mask 22 is removably attached. This mask 22 is designed to cover the discharge port 23 and the upper end of the operating rod 12, as shown in the figure.

When using the oxygen generator of this embodiment, first remove the mask 22 which also serves as a cap placed over the top of the apparatus, and push the upper end of the operating rod 12 toward the inside of the container. The mask 22 is provided with an opening 31 that opens the discharge port 23 into the mask 22 when the mask 22 is thus inverted. When the mask 22 is pushed in in this manner, the operating rod 12 is pushed out toward the hole in the aperture member 16. The extruded cutting member 16 first touches the film 1 attached to the hole 14 with its blade-shaped tip 16b.
5 is pushed out to make the second space 19 and the container inner space 2 communicate with each other. Therefore, the catalyst 18 falls into the water 3. If the squeeze member 16 is pushed out further, it will fall off from the cartridge 6, so
The first space 11 and the container space 2 are brought into communication, and the oxygen generating agent 10 falls into the water 3, and a reaction is started to generate oxygen.

The peroxycarbonate used in this example is a compound represented by the general formula M ₂ C ₂ O ₆ , and when brought into contact with water in the presence of a catalyst, it decomposes to produce carbonate and oxygen. It happens. Representative examples include sodium peroxycarbonate and potassium peroxycarbonate. Furthermore, examples of catalysts having the above-mentioned properties include manganese dioxide, the following metals, and compounds thereof, but the catalysts that can be used in the present invention are not limited to these.

Iron, copper, nickel, cobalt, manganese, chromium, lead, vanadium, tungsten and their compounds.

The above metals or their compounds are used as catalysts by enveloping them in a water-soluble polymer compound that gradually disintegrates in water. The reason why the catalyst is wrapped in a water-soluble polymer compound is to gradually bring the catalyst into contact with the peroxycarbonate and cause the reaction to occur.By doing this, oxygen can be generated for a certain period of time. This is because it can be done. Therefore, when a large amount of oxygen is suddenly required, it may be used without being wrapped in a water-soluble polymer compound.

After pushing in the operating rod 12 completely, place the mask 22 that was removed earlier on top of it, and then place the mask 22 on top of it.
As shown in Figure b, attach this mask 22 in the opposite direction.
Place the face on it as shown in the picture. Oxygen generated by the reaction flows through a large number of micropores of 3 to 5 μm held by the second space 19, the first space 11, and the filter holder 21, as indicated by the arrows in the figure. It is guided into the mask 22 through a filter 20 having a diameter and a discharge port 23, and is used for inhalation. Here, the filter 20 is used to remove the mist produced when oxygen is generated and to prevent the contents from coming out when the container is tipped over. In addition, in the figure, 24 is a vent hole to compensate for the lack of intake air with generated oxygen alone, 25 is a notch to prevent the user's nose from touching it, and 12a is a hole to prevent the operating rod from falling out or getting stuck. This is a locking ring for the operation rod to prevent it from happening.

As described above, in this embodiment, by simply removing the cap 4, the cartridge 6 containing at least the oxygen generating agent 10 and the catalyst 18 can be easily replaced. Therefore, if you prepare a large number of cartridges 6, when the drug becomes useless after not using it for a long time, or even after using it once, you can simply replace the cartridge 6 and throw away the used solution. Then, the other parts (for example, the container 1, the cap 4, the operating rod 12, the mask 22, etc.) can be used again. For this reason, for example, a picture or a pattern as shown in FIG. 2 can be drawn on the surface of the container 1.
In addition, in this embodiment, the operating rod 12 and the mask 2
2. Since the discharge port 23 and the like can be removed together with the cap 4, these parts can be used again.

Next, another embodiment is shown in FIGS. 3a and 3b.

In the illustrated embodiment, the connection between the container 1 and the cartridge 6 and the internal structure of the cartridge 6 are different from the previous embodiments. First, the connection between the container and the cartridge will be explained.

As shown in the figure, the container 1 is formed into a cylindrical shape with an opening provided at its upper end and a tapered portion. The cartridge 6 is provided with a knockout portion 26, which is a partition wall, on its bottom surface, and a cylindrical portion 27 extends so as to surround the knockout portion 26. Then, this cylindrical part 27 and the opening periphery 8 of the container fit together, and the magnet 2 provided in this part
The connection is fixed by the suction force of 8.
It is designed to be easily removed.
This connection portion is also provided with a seal 9, which is a sealing means, as in the previous embodiment.

The inside of the cartridge 6 is a first space 11 that accommodates the oxygen generating agent 10, and in the center thereof,
A cylindrical body 13 serving as a guide for an operating rod 12' serving as an opening means is provided so as to face a knock-out portion 26 serving as a partition, into which the operating rod 12' is inserted.

In this embodiment, when the operating rod 12' is pressed, the tip of the operating rod 12' is directly connected to the knock-out portion 2.
It differs from the previous embodiment in that it breaks through 6.
The operating rod 12' has a cylindrical shape with an opening at one end facing the knock-out portion 26, and the inside thereof forms a second space 19. Cylindrical body 1
An isolation film 29 is attached to one end of the handle 3 facing the knockout portion 26 so as to cover the opening thereof, thereby closing the second space 19 within the operating rod 12'.

When using the oxygen generator of this embodiment, first remove the stopper 12b that locks the operating rod 12' to prevent it from being pushed inadvertently, and then insert the operating rod 12' inside the container. Push it towards the end. The pushed-in operating rod 12' first passes through the isolation film 29 attached to one end of the cylindrical body 13.
, and then the knock-out portion 26. Isolation film 29 and knockout section 26
When this is broken through, the container inner space 2 and the first and second spaces 11 and 19 are communicated with each other, and the oxygen generating agent 10 and catalyst 18 fall into the water 3, and a reaction is started. Oxygen is generated. Thereafter, oxygen can be inhaled using the cap/mask (not shown) attached to the cartridge 6 in the same manner as in FIG. Note that the arrows in the figure indicate the flow of oxygen as in FIG. 1b.

In the above embodiment, the container 1 and the cartridge 6 were connected and fixed by the attraction force of the magnet 29, but as in the previous embodiment, they were connected and fixed by screwing. Good too. The partition wall may also be made of a hole and a film covering the hole, instead of the knock-out portion 26, as in the previous embodiment.

Yet another embodiment is shown in FIGS. 4a and 4b.

This embodiment also differs from the first embodiment in the connection between the container 1 and the cartridge 6 and the internal structure of the cartridge.

As shown in the figure, the container 1 has a cylindrical shape with an opening at its upper end. The cartridge 6 is provided with a cylindrical skirt 30 projecting around its body. Then, the container 1 is inserted into the gap 31 between the skirt 30 and the body.
The opening periphery 8 of the opening is inserted, and the suction force of the magnet 28 provided at this portion permanently fixes the opening, similar to the embodiment shown in FIG. 3, so that it can be easily removed. It's getting old. In this embodiment as well, the connection and fixation of the container 1 and the cartridge 6 may be performed by screwing together. This embodiment is also similar to the previous two embodiments in that the connecting portion is provided with a seal 9 serving as a sealing means.

The structure inside the cartridge is the same as the embodiment of FIG. 3a, except that the partition wall is a film 15 covering the hole 14, as shown. Therefore, when using the oxygen generator of this embodiment, the third
The same operation as in the embodiment shown in Figure a may be performed. first,
When the stopper 12b that locks the operating rod 12' from being pushed inadvertently is removed and the operating rod 12' is pushed toward the inside of the container, the tip of the pushed operating rod 12' will be The partition film 29 attached to one end of the cylindrical body 13 is pierced.
Subsequently, a film 15 pasted to cover the hole 14 of the cartridge 6 is attached to the operating rod 12'.
pierce through the inner space of the container and the first and second
The oxygen generating agent 10 and the catalyst 1 communicate with each other.
8 is put into water 3, a reaction is started and oxygen is generated. The generated oxygen is transferred to the filter 20 in the cartridge 6 as shown by the arrow in FIG. 4b.
and is discharged to the outside through the discharge port 23. This oxygen can be sucked in using a mask (not shown) that also serves as a cap attached to the cartridge 6 in the same manner as in FIG.

In this embodiment and the embodiment shown in FIG. 1a, a knock-out like the embodiment shown in FIG. 3a can also be used as a partition wall. This also applies to other parts; for example, when the internal structure of the embodiment shown in Fig. 1a is combined with a cartridge having a connection part as shown in Fig. 3a or Fig. 4a, You can also do the opposite combination.

Up to now, the oxygen generator of the present invention has been explained based on the above three embodiments, but the structural shape of the present invention is not limited to the embodiments shown in the figures. For example, the partition wall may have a structure in which an operating rod, a discharge port, a mask, etc. are provided in a container, and the shape of the container or cartridge does not have to be cylindrical as shown in the figures. The opening means for breaking the partition wall is not limited to the operating rod, and any shape or method depending on the structure of the partition wall can be used. In these Examples, the agent that generates oxygen upon contact with water is composed of two components, the peroxy carbonate and the catalyst, but in the oxygen generator of the present invention, the agent is As long as it generates oxygen when it comes into contact with water, it can be made of one component or three or more components, and the number of spaces for accommodating the drug can be as many as necessary. good. Even if the drug has two components as in the above example, one component can be wrapped in a water-soluble film and placed in the same space as the other component. , only one space is required. Further, in the above three embodiments, the cartridge was provided above the container, but the positional relationship between the container and the cartridge may be reversed, that is, the container containing water may be provided above the cartridge. . At least, if the cartridge containing the oxygen-generating agent is replaceable, other parts, such as the operating rod, mask, filter, etc., are likely to be replaced at the same time as the cartridge. may also continue to be used without being replaced. In short, if the cartridge containing the oxygen-generating agent was replaceable,
Other configurations are not particularly limited.

As described above, the oxygen generator of the present invention is easy to operate and has a simple internal structure because oxygen can be generated by simply pushing the operating rod that is the opening means for opening the partition wall. It has become a thing. Moreover, the cartridge containing the oxygen-generating agent can be easily replaced. Therefore, when the drug becomes unusable after being stored for a long time, or even after it has been used once, it can be used again by replacing the cartridge and discarding the used solution.
It becomes possible to obtain an oxygen generating device that is inexpensive and has less waste (used only once and then thrown away).

〔Effect of the invention〕

The oxygen generator of the present invention is configured as described above, and can generate oxygen simply by opening the partition wall, which simplifies the structure and operation. Since the cartridge containing the drug can be easily replaced, it can be used many times over a long period of time, resulting in a low cost and waste-free product.

Moreover, in the oxygen generator of the present invention, a discharge port is provided at a location of the cartridge where the operating end of the opening means faces, and the discharge port is provided for discharging the oxygen generated in the container to the outside through the inside of the cartridge. Since a mask is removably attached to cover the operating end of the opening means, this mask prevents contaminants such as dust from entering from the discharge port, and prevents the operating end of the opening means from being accidentally touched. It can prevent being pushed. In addition, this mask is adapted to be attached to the cartridge in an inverted state, and is provided with an opening that opens the discharge port into the mask in this inverted state. The operating end of the opening means can be pressed automatically, which is extremely convenient.

[Brief explanation of drawings]

FIG. 1a is a sectional view showing one embodiment of the present invention, FIG. 1b is a sectional view showing this embodiment in use, and FIG. 2 is an exploded perspective view of this embodiment.
FIG. 3a is a sectional view showing another embodiment of the invention, FIG. 3b is a sectional view showing this embodiment in use, and FIG. 4a is a sectional view showing still another embodiment of the invention. , FIG. 4b is a cross-sectional view showing the state of use of this embodiment. 1...container, 3...water, 6...cartridge, 10,
18...Drug, 12,12'...Release means, 15,1
6, 26, 29... bulkhead.

Claims (1)

[Scope of Claims] 1. A cartridge having a drug accommodating portion containing a drug that reacts with water to generate oxygen is replaceably connected to a container containing water, and the cartridge contains the drug. The part is provided with a partition wall at a position facing the water in the container, and is also provided with an opening means for breaking the partition wall,
The operating end of the opening means faces outside the cartridge, and the inside of the container and the inside of the cartridge communicate with each other when the partition wall is broken, and the opening end of the cartridge faces the outside of the cartridge. A discharge port is provided for discharging oxygen generated in the container to the outside through the cartridge, and a mask is removably attached to cover the discharge port and the operating end of the opening means. The oxygen generator is configured such that the mask can be attached to the cartridge even in an inverted state, and has an opening for opening the discharge port into the mask in this inverted state. 2. The container is formed into a cylindrical shape with an opening at one end and a cap covering the opening, and the cartridge is provided with a flange facing outward at one end, and this flange connects the periphery of the opening of the container with the cap that covers the opening. The oxygen generating device according to claim 1, wherein the container and the cartridge are connected by being sandwiched by a cap. 3. The container is formed into a cylindrical shape with an opening at one end, and the cartridge has a cylindrical part extending from around the partition wall, and this cylindrical part fits with the periphery of the opening of the container, so that The oxygen generator according to claim 1, wherein the container and the cartridge are connected. 4. The container is formed into a cylindrical shape with an opening at one end, and the cartridge is provided with a cylindrical skirt protruding around the body of the cartridge.
2. The oxygen generating device according to claim 1, wherein the container and the cartridge are connected by inserting the periphery of the opening of the container into the annular gap between the skirt and the body. 5. The oxygen generating device according to any one of claims 1 to 4, wherein the connection between the container and the cartridge is fixed by screwing. 6. The oxygen generating device according to any one of claims 1 to 4, wherein the connection between the container and the cartridge is fixed by the attraction force of a magnet. 7 The drug consists of two components: an oxygen generating agent mainly composed of peroxycarbonate that reacts with water to generate oxygen, and a catalyst that promotes the reaction, and the two components are separately contained inside the cartridge. first and second spaces are provided for accommodating the
The oxygen generating device according to any one of claims 1 to 6, wherein the two spaces and the inside of the container communicate with each other when the partition wall is torn. 8 At the center of the cartridge, there is a cylindrical body that serves as a guide for the operating rod that is the opening means, into which the operating rod is inserted. A partition member is provided, and the space between the partition wall and the partition member is a second space, and the part deeper than the partition member is a first space, and the center of the shade protrudes from the cylindrical part. when the operating rod is pressed, the partition member is pushed, the partition wall is broken by the partition member, and the first space and the inside of the container are communicated; 8. The oxygen generating device according to claim 7, wherein the barrier member is then removed so that the second space and the inside of the container communicate with each other. 9 At the center of the cartridge there is a cylindrical body that serves as a guide for an operating rod serving as an opening means, into which the operating rod is inserted. The interior thereof is a second space, and the outside of the cylindrical body is a first space, so as to cover the opening on the side of the cylindrical body facing the partition wall. An isolation film is pasted on the second space to close the second space, and when the operation rod is pushed, its tip breaks the isolation film and the partition wall of the cartridge, and the first and second spaces are closed. 8. The oxygen generating device according to claim 7, wherein the space portion and the inside of the container are communicated with each other. 10. The oxygen generating device according to any one of claims 1 to 9, wherein the partition wall is a film stuck to a hole made in a wall surface forming a cartridge. 11 Claim 1, wherein the partition wall is a knock-out portion provided on a wall surface forming a cartridge.
9. The oxygen generator according to any one of items 9 to 9.