JP2003034508A - Oxygen concentrator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an oxygen concentrator made practically usable by using an oxygen-enriching film and preventing the reduction of the oxygen concentration capacity without using a fine-meshed filter. SOLUTION: In an oxygen concentration system for producing an oxygen- enriched air by generating a flow of air on the atmosphere side of the oxygen- enriching film and reducing the pressure of the other side of the oxygen- enriching film, the flow of air on the atmosphere side passing through the oxygen-enriching film produces a minus-ionized air through a minus ion generator.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oxygen concentrator using an oxygen-enriched membrane that can relax by absorbing air rich in oxygen and can be expected to have an aerobic exercise effect. The present invention relates to an oxygen concentrator that suppresses a decrease in the oxygen concentration capacity of an enrichment membrane and improves the life cycle of the oxygen enrichment membrane.

[0002]

2. Description of the Related Art In recent years, it has been reported that the concentration of carbon dioxide in the atmosphere is gradually increasing due to the popularization of automobiles and the popularization of air conditioning.

Therefore, in order to increase the oxygen intake due to the respiration of the human body, aerobic gymnastics, jogging, and the like have been popularized, and measures against them have been taken. However, oxygen-deficient situations, such as crowded vehicles and poorly ventilated rooms, exist throughout our living spaces.

For these reasons, oxygen respirators that are familiar and are used to easily replenish oxygen are used.
As a conventional oxygen respirator, one using a molecular sieve (called PAS method) has been known. However, in addition to the drawbacks of being large in size, producing noise, and being expensive, there is a problem that the oxygen concentrating ability of the molecular sieve decreases when it is used.

On the other hand, although an oxygen respirator using an oxygen-enriched membrane has been proposed, it has not yet been put to practical use. The reason is that the oxygen-enriched film is a non-porous film, but if an organic substance such as oil or cigarette tar adheres to the atmosphere side of the film, the oxygen concentration capacity decreases. For removing oil and tar,
A fine filter is required, but a fine blower increases air passage resistance, so a large blower had to be used to achieve the desired concentration, but a large blower was required. This is because the use of oxygen eliminates the advantage of using the oxygen-enriched film.

[0006]

[Problems to be Solved by the Invention]

The present invention has been made paying attention to such a point, and by utilizing an oxygen-enriched film, it is possible to prevent a decrease in oxygen concentration ability without using a fine filter.
An object of the present invention is to provide an oxygen concentrator that can be put to practical use.

[0008]

In order to achieve the above object, the present inventor has conducted earnest research and as a result, by negatively ionizing air in the atmosphere, oil and tar are less likely to adhere to the oxygen-enriched film. That is why the present invention has been reached. That is, by making the air negatively ionized, oil and tar will not be contained in the air,
This is because even if a small amount is contained, it can be removed even with a rough filter by negative ionization.

According to the first aspect of the present invention, oxygen is obtained by causing a flow of air on the atmosphere side of the oxygen-enriched film and depressurizing the other surface of the oxygen-enriched film to obtain oxygen-enriched air. In the concentrating device, the flow of air on the atmosphere side that has passed through the oxygen-enriched film is made into negative ionized air through a negative ion generator.

If the air flow is generated by a blower and the air in the room is circulated so that the flow of negatively ionized air is generated on the atmosphere side of the oxygen-enriched film, oil and tar will be oxygen. It can be effectively prevented from adhering to the enriched film (Claim 3).

When the air from the blower is passed through a filter for removing dust and the like to generate a flow of air on the atmospheric side of the oxygen-enriched film, oil and tar are more completely attached to the oxygen-enriched film. Can be prevented (Claim 4).

A first check valve is connected between the pump for reducing the pressure and the intake port of the oxygen-enriched air, and a second check valve is provided between the pump and the first check valve. By providing a bypass line connecting the sterilization filter and the sterilization filter, the second check valve does not pass oxygen-enriched air, but when the pump is stopped, the outside air passes through the sterilization filter. Good (Claim 5). According to this structure, since the bacteria do not pass through the oxygen-enriched membrane, the growth of bacteria in the device can be prevented and the device can be kept sterile at all times.

A mask or a cannula may be connected to the inlet of the oxygen-enriched air, and a water trap for removing water in the oxygen-enriched air may be connected to the mask or the cannula. By doing so, it is possible to prevent water from entering the nostrils even when the water concentration in the air is high.

Another object of the present invention is to provide an oxygen concentrator for producing oxygen-enriched air to which wave energy is added. Thus, conventionally, it has been known to apply wave energy to water, but it is not known to apply wave energy to a gas such as oxygen-enriched air.

The term "wave" as used herein refers to vibrational energy at the level of elementary particles such as electrons, protons and neutrons that compose atoms in the world of quantum mechanics, and is an extremely weak energy. Every substance that exists in nature consists of atoms, and a molecule consists of one or many atoms. And, all animals including human beings and plants such as trees have inherently normal and normal wave energy.

However, it is when the animal or plant is in a healthy state that it exhibits unique and normal wave energy, and external factors such as environment, respiration, intake of food, etc.,
Due to internal factors such as genetic information and negative emotions such as stress, organisms such as atoms, molecules, cells, organs and tissues,
Disturbance of waves occurs in an object or a living body, and normal wave energy is disturbed. As a result, an unhealthy state such as a disease occurs, and an abnormal wave is emitted.

The present invention is intended to provide oxygen-enriched air that can be actively involved in a healthy body and spirit or a healthy environment. The oxygen-enriched air is brought into contact with wave ceramics. The wave energy from the wave ceramics is applied to the oxygen-enriched air (claim 7). Dipping the wave ceramics in water,
It is more effective to apply the wave energy from the wave ceramics to the oxygen-enriched air via water (claim 8).

[0018]

BEST MODE FOR CARRYING OUT THE INVENTION Next, embodiments of the present invention will be described.

FIG. 1 shows the principle of oxygen concentration by an oxygen-rich film. When a pressure difference is provided on both sides of the oxygen-enriched film, oxygen and nitrogen on the atmosphere side "dissolve" on the film surface, "diffuse" in the film, and "disengage" from the film surface on the reduced pressure side. Since the speed of "dissolution" and "diffusion" of oxygen is about 2.5 times that of nitrogen, oxygen-enriched air is obtained on the reduced pressure side. The atmosphere side becomes nitrogen-enriched air, which is removed from the oxygen-enriched film by the flow of air.

FIG. 2 is a diagram showing the principle of the oxygen concentration system of the present invention, in which an air flow of a certain speed or more is created on the atmospheric side of the oxygen enriched film. If the flow is insufficient,
Oxygen concentration decreases on the membrane surface, and oxygen enriched air concentration decreases. When the pressure is reduced to -560 mmHg with a vacuum pump, oxygen-enriched air with an oxygen concentration of 32% is obtained as shown in FIG. The degree of decompression by the decompression pump depends on the type of oxygen-enriched film and the desired oxygen-enriched concentration, but in order to achieve a healthy oxygen concentration of around 32%, -500 to 60
It is preferable to set the pressure reduction degree to 0 mmHg.

FIG. 3 shows an embodiment of the oxygen concentrator of the present invention. The oxygen-enriched membrane 2 is a porous support membrane which is a continuous foam (not shown) which serves as a passage for oxygen-enriched air. The structure sandwiched via (not shown) is housed in a frame, and the connecting portion between the frame and the oxygen-enriched membrane 2 is formed in a structure sealed with a seal tape. The fan 1 is configured to generate an air flow on the outer atmosphere side of the oxygen-enriched film 2, and the pump 4 depressurizes the inner peripheral depressurized side including the porous support film and the continuous foam. It has become.

The oxygen-enriched air that has passed through the oxygen-enriched membrane 2 is
Through the porous support membrane and the continuous foam, the outlet 13 to the line passes through the pump 4, the check valve 5 and the outlet 6.

The flow of air on the outer peripheral side of the cylindrical body passes through the negative ion generator 3 to become negative ionized air (negative ionized air), and by the circulation of air in the room,
With the fan 1, the flow of negative ionized air
It occurs on the atmosphere side of the oxygen-enriched film 2.

The oxygen-enriched film is a non-porous film, but if organic matter such as oil or cigarette tar adheres to the atmosphere side of the film, the oxygen concentration capacity decreases. In order to use the membrane stably for a long period of time, it is necessary to keep the air supplied to the membrane clean. However, in order to purify oil particles and fine particles such as tars, a fine filter is required, but as the eyes become finer, the air passage resistance (ventilation resistance) increases, and a ventilation device such as a large blower is required. Becomes This is because in terms of the performance of the oxygen-enriched film, the flow rate of air on the atmosphere side needs to be about 50 times the flow rate of oxygen-enriched air.

By negatively ionizing the air as described above, oil, tar and dust are attached to the room, so that they can be prevented from attaching to the oxygen-enriched film.

However, the air from the blower 1 is changed by the air passing through the filter for removing dust and the like.
It is preferable to generate an air flow on the atmosphere side of the oxygen-enriched film 2. Even if it is negatively ionized, some foreign matter is mixed in, and by negatively ionizing it, it is possible to remove oil, tar and dust even with a coarse mesh filter, so it is not necessary to reduce the air flow rate. This is because it is possible to prevent a decrease in oxygen enrichment ability without using a large blower.

The oxygen-enriched film 2 and the negative ion generator 3 used in the present invention are known, and known ones may be used. Further, in the above embodiment, the oxygen-enriched film 2 is
The continuous foam is sandwiched by porous support membranes. This is because the oxygen-enriched film 2 is very thin,
Although this is done, other known means may of course be used.

When the decompression pump 4 is stopped, the oxygen enriched film 2
And the line of the decompression pump 4 becomes negative pressure, and the first check valve 5
There is a case where air flows backward from the oxygen-enriched air outlet 6 due to the malfunction of the above. When backflow occurs in this way,
Miscellaneous bacteria enter the inside of the pipe, and if it propagates, it becomes extremely unsanitary. Further, when the humidifying bottle is used, the water in the humidifying bottle enters the piping and the pressure reducing pump 4.

The second check valve 7 supplies air to the negative pressure side,
This backflow is prevented. A sterilization filter 8 that does not allow bacteria to pass therethrough is provided so that bacteria are not mixed in when air is supplied.

A mask 9 and a cannula 10 as shown in FIG. 4 are connected to the oxygen-enriched air outlet 6 by a tube 12. A water trap 11 is connected to the mask 9 and the cannula 10.

Since the oxygen-enriched membrane allows water molecules to pass therethrough,
Although there is an advantage that humidification using a humidifying bottle or the like is unnecessary, the humidity of the high-oxygen air obtained depends on the humidity of the air on the atmosphere side supplied to the oxygen-enriched film. Especially when the humidity of the air to be supplied is high, water vapor contained in the high oxygen air is condensed on the tube 12 of the mask 9 or the cannula 10, and the airflow in the tube may cause moisture to enter the nostrils.
As described above, by connecting the water trap 11, it is possible to effectively prevent water from entering the nostrils.

As shown in FIG. 6, the water trap 11 has a pipe 13 standing upright on the bottom surface to form a water storage space 14.

The distances A and A'between the mask 9 and cannula 10 and the water trap 11 are preferably within 30 cm.

A flavor box may be provided in the main body of the apparatus for connecting the mask 9 and the cannula 10 so that a desired flavor sheet can be put in the box.

In order to more fully bring out the effects of the present invention,
It is preferable that the oxygen-enriched air generated as described above is brought into contact with the wave ceramics to impart wave energy from the wave ceramics to the oxygen-enriched air. It is more effective to immerse the wave ceramics in water and apply the wave energy from the wave ceramics to the oxygen-enriched air via water. In this case, it is advisable to put wave ceramics in the humidifying bottle.

The wave ceramics used in the present invention preferably include ceramics emitting far infrared rays, for example, weathered granite, wood knot clay, quartz, tourmaline, cordierite ceramics and alumina ceramics.

Next, the result of measuring the effect of applying the wave energy using Omnisense manufactured by Omni Japan Co., Ltd. as a wave measuring device is shown. (A) The following 4 samples were tested. Air Oxygen-enriched air with an oxygen concentration of 32% produced by the oxygen concentrator of the present invention Oxygen-enriched air with an oxygen concentration of 32% produced by the oxygen concentrator of the present invention is wave ceramics (weathered granite is used).
Wave energy was applied by passing through a container containing 100 g. Oxygen concentration 32 produced by the oxygen concentrator of the present invention
% Oxygen-enriched air, 100 g of weathered granite and 250 c of water
c It was introduced into the contained water and wave energy was applied through the water.

The measurement results of wave values (all + values) showing the degree of wave disturbance are shown in Table 1 below.

[0039]

[Table 1] This wave-measuring device is filled with the gas to be inspected, placed on the input side of the measuring device, and uses the trained measurer's sensuality to contrast with a pre-coded normal (healthy) wave. It is a device that measures whether or not it resonates and digitally displays on the output side how much it is disturbed with respect to normal eigenwaves.

The wave value is evaluated in the range of +21 to -21, and +21 to +15 are in a very good state, +14 to +10.
Is a normal state, +9 to +5 is a caution state, and numerical values from +4 to a minus are dangerous states.

From the results shown in Table 1, normal air is in a state of caution, and the oxygen-enriched air concentrated by the oxygen concentrator of the present invention is improved to a normal state and further passed through the wave ceramics. , Normal to very good condition, and when wave water is further passed, all measurement items are improved to very good condition.

[0042]

As described above, according to the present invention, by negatively ionizing the air in the atmosphere, oil and tar are not contained in the air, and even if they are contained, they are negatively ionized. By doing so, it is possible to remove even coarse filters, so it is possible to prevent the oxygen concentration from decreasing even without using a large blower, and for the first time we have achieved the practical application of an oxygen concentrator using an oxygen-enriched membrane. It is a very innovative invention. As far as the applicant is aware, this type of oxygen concentrator is not commercially available in Japan or in foreign countries.

[0043]

[Brief description of drawings]

FIG. 1 is a principle diagram of oxygen concentration by an oxygen-rich film.

FIG. 2 is a principle diagram of an oxygen concentration system using an oxygen-enriched membrane.

FIG. 3 is a flowchart showing an embodiment of the present invention.

FIG. 4 is a perspective view showing an example of a mask used in the present invention.

FIG. 5 is a perspective view showing an example of a cannula used in the present invention.

FIG. 6 is a cross-sectional view showing an example of a water trap used in the present invention.

[Explanation of symbols]

1 ………… Fan 2 ... Oxygen-enriched film 3 ... Negative ion generator 4 ......... Decompression pump 5 ... 1st check valve 7 ... Second check valve 8 ………… Sterilization filter 9 ... Mask 10 ... Cannula 11 ……… Water trap

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) B01D 50/00 502 B01D 50/00 502Z 53/22 53/22 B01J 19/00 B01J 19/00 A 19 / 08 19/08 ZF term (reference) 4D006 GA41 HA28 KA71 KB14 KB30 MA02 MA06 MB04 PA02 PB17 PB62 PC71 4G042 BA29 BB02 4G075 AA03 BA08 BD13 CA22

Claims (7)

[Claims] 1. An oxygen concentrator for producing an oxygen-enriched air by reducing the pressure on the other side of the oxygen-enriched film by causing a flow of air on the atmosphere side of the oxygen-enriched film to pass through the oxygen-enriched film. An oxygen concentrator characterized in that the flow of air on the atmosphere side is changed to negative ionized air through a negative ion generator. 2. The air flow is generated by a blower, the air in the room is circulated, and the flow of the negative ionized air is generated on the atmosphere side of the oxygen-enriched film. The oxygen concentrator according to 1. 3. The oxygen concentrator according to claim 2, wherein the air from the blower is passed through a filter for removing dust and the like to generate a flow of air on the atmospheric side of the oxygen-enriched film. 4. A first check valve is connected between the pump for reducing pressure and an oxygen-enriched air outlet, and a second check valve is provided between the pump and the first check valve. A bypass line connecting the valve and the sterilization filter is provided, and the second check valve does not pass oxygen-enriched air, but when the pump is stopped, outside air passes through the sterilization filter. The oxygen concentrator according to any one of claims 1 to 3, wherein 5. The oxygen-enriched air outlet is connected to a mask or cannula, and the mask or cannula is connected to a water trap for removing water in the oxygen-enriched air. Oxygen concentrator. 6. The oxygen-enriched air is brought into contact with wave ceramics to generate wave energy from the wave ceramics.
The oxygen-enriched air is applied to the air according to any one of claims 1 to 5.
The oxygen concentrator according to the item. 7. The oxygen concentrator according to claim 6, wherein the wave ceramics is immersed in water, and wave energy from the wave ceramics is applied to the oxygen-enriched air via water.