JPH02221102A - oxygen enrichment device - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to an oxygen enrichment device that enriches oxygen in the air by using an oxygen enrichment membrane module that allows oxygen to permeate more easily than nitrogen.

Conventional technology In recent years, various oxygen enrichment devices have been studied to absorb oxygen after sports or to refresh while driving.In general, oxygen is packed in a small cylinder and the oxygen is released through a chemical reaction. Oxygen enrichment devices that generate oxygen are commercially available. However, both the cylinder type and the chemical reaction type have problems in that oxygen is generated for a short time, that is, they can be used for a short time, are highly concentrated, and have uneven scents.

An example of a conventional oxygen enrichment device will be described below.

Portable canned oxygen, which is a small cylinder filled with oxygen, has a purity of 95.
Concentrated oxygen is packed in a spray can (5 liters) and can be used for about 2 minutes. There are also tasteless and odorless types and scented types. In addition, oxygen enrichment devices that generate oxygen through a chemical reaction generate oxygen through a chemical reaction when water is placed in a container and a special agent containing a manganese compound, sodium carbonate wham, and hydrogen peroxide adduct that acts as a catalyst is added. .

A total of around 5 lifts/I/oxygen is produced in 4 to 5 minutes from the start of the reaction, which is inhaled using an attached inhalation mask. The nine oxygen species obtained by this device are available in both tasteless and odorless versions, as well as scented ones, just like spray cans.

Problems to be Solved by the Invention However, conventional scented portable oxygen bottles have uneven scent. This is due to the specific gravity of the fragrance packed in the can, which causes the fragrance to accumulate at the bottom of the can, resulting in uneven scent. There was a problem in that the perfumes that could be used were limited. In addition, in the case of scented oxygen enrichment devices that generate oxygen through chemical reactions, the scent may change depending on the type of fragrance, which limits the types of fragrances that can be used. Further, the above-mentioned cylinder type and chemical reaction type have a problem that they can be used for only a short time and have a high concentration, so they must be diluted to the required concentration before use.

The present invention solves these problems by increasing the oxygen generation time so that it can be used for the necessary time, and also allows the use of any type of fragrance without the need to dilute the oxygen concentration. The purpose is to

Means for Solving the Problem In order to solve this problem, the present invention provides an oxygen-enriching membrane module that allows total oxygen permeation more easily than nitrogen, a pressure-reducing means for reducing the pressure of the oxygen-enriching membrane module, and a pressure-reducing means for reducing the pressure of the oxygen-enriching membrane module. It consists of an exhaust line connected to the exhaust side, and a fragrance provided in a flow path on the semi-solid or downstream side of the oxygen enrichment membrane module.

Function: With this configuration, scented, oxygen-enriched air can be obtained continuously for the required time, and there is no need to dilute the oxygen concentration, and the scent does not change as it is not caused by a chemical reaction unlike conventional methods. , the type of fragrance is not limited.

EXAMPLE Hereinafter, the 91st patent example of the present invention will be explained based on the drawings.

Figure @1 shows a configuration diagram of an oxygen enrichment device in a first embodiment of the present invention.

In the figure, the oxygen enrichment membrane module /L/1 is connected to an exhaust line 4 via a vacuum tube 2 and a vacuum pump (pressure reducing means) 3.
In this configuration, the oxygen-enriching membrane module Ivl allows oxygen to permeate at a higher rate than nitrogen, and is connected to the vacuum tube 2' with a differential pressure from the atmosphere by the vacuum bonder 3. k fr and oxygen-enriched membrane module A/1 (By fully transmitting the differential pressure, oxygen-rich air (hereinafter referred to as oxygen-enriched air) is obtained.The oxygen concentration of oxygen-enriched air is approximately Set it to around 404 to avoid any negative effects.In order to keep the oxygen concentration around 40,
The material of the oxygen enrichment membrane of oxygen enrichment membrane module #1 is poly4methymubenzone-1 (11f product name TPX).

DX 810 Mitsui Petrochemical Industries, Ltd. m! Blend 100 wt% of Rini 7 Maμ acid esthetics/L/ (trade name: Kobo Vtsux 1, manufactured by Nippon Oil & Fats Co., Ltd.) and reduce the degree of vacuum to -6.
Set it to 00tgHy. In this way, by keeping the material of the oxygen-enriching membrane and the degree of vacuum constant, the oxygen concentration of the oxygen-enriched air will be constant, and the oxygen concentration can be adjusted to a level that does not adversely affect the human body, and there is no need to dilute it. The exhaust line 4 is connected to the exhaust side of the vacuum bonder 3 and takes out oxygen-enriched air. The fragrance 5 is introduced into the exhaust line 4, and oxygen-enriched air with various fragrances is taken out from the outlet. In addition,
The fragrance 5 may be placed anywhere in the exhaust line 4,
It may be provided near the vacuum bonder 3. For fragrance 5, you can choose your favorite, such as menthol and borneol, which make you sleepy, lavender, which makes you sleepy, and jasmine, which makes you feel energized. As mentioned above, the oxygen enrichment device using the oxygen enrichment membrane module lvl does not cause any chemical reaction, and the type of fragrance is not limited. Moreover, the scent is agitated by the oxygen-enriched air, so the scent is even.

FIG. 2 shows a configuration diagram of an oxygen enrichment device in a second embodiment of the present invention.

In this embodiment, two types of fragrances 5a and 5b are placed in the exhaust line 4.
The other configurations are the same as in the first practical example.

According to a certain configuration, it is possible to add a desired fragrance to the oxygen-enriched air by selecting one of the two types of fragrances 5ae5b. Note that three or more types of fragrances may be provided.

Figure 3 shows @3 of the present invention! It shows a block diagram of an oxygen enrichment device in Example J.

In this embodiment, a removable cartridge-type fragrance agent is provided as a fragrance, so that the desired fragrance 5C can be freely attached to the exhaust twin 4, and the other configurations are as follows.
*Same as the example.

Figure @4 is a sectional view of the oxygen enrichment device in the @4 embodiment of the present invention.

In the figure, there is an oxygen enrichment membrane module /L/8 inside the casing 7, and a vacuum tube 9 is connected to this oxygen enrichment membrane module A/8! Twelve vacuum bonders 10 connected to each other and nine exhaust lines 11 connected to the vacuum pump 10 are provided. The oxygen enriched membrane Joule A/8 is provided in the upper space of the casing 7, and the vacuum tube 9 is connected to the casing 7.
An intake filter 12 is provided at one end of the casing 70 located above the oxygen enrichment membrane module/I/8 in a partial space of the casing 70, and an exhaust filter 12 is provided at the other end. A fan 13 is provided, and a fragrance 14 is provided between the intake filter 12 and the oxygen enrichment membrane module/L/8.

With such a configuration, the air sucked into the case 7 from the intake filter 12 passes through the fragrance 14, becomes scented, enters the oxygen enrichment membrane module 8, and then passes through the vacuum tube 9, the vacuum pump 10, and the exhaust twin. Scented, oxygen-enriched air is withdrawn from 11. At the same time, scented air is discharged from the exhaust fan 13, so that it can also be used as an indoor air freshener.

By the way, as the material for the oxygen enrichment membrane of the oxygen enrichment membrane modules lv1 and 8, in addition to using a blend of poly 4-methy-pentene-1 and 7-maric acid ester as described above, silicone-based polymers and the like may also be used. May be used. Also,
In the above @4 lol implementation, fragrance 1 was added in addition to the intake filter 12.
4 was installed, but the intake fin! -n may be impregnated with a fragrance. Furthermore, the oxygen concentration is not limited to 401, and can be set to a desired oxygen concentration by adjusting the permeation ratio of oxygen and nitrogen in the oxygen enrichment membrane modules /L/1 and 8 and the degree of vacuum of the vacuum pump 3.10.

Effects of the Invention As described above, according to the present invention, there is provided an oxygen-enriching membrane module that allows oxygen to pass through more easily than nitrogen, a pressure-reducing means for reducing the pressure of the oxygen-enriching membrane module, and an exhaust side of the pressure-reducing means. By consisting of a connected exhaust twin and a fragrance provided in the flow path on the upper side or the lower side of the oxygen enrichment membrane module, scented oxygen enriched air can be obtained continuously for the necessary time, However, there is no need to dilute the oxygen concentration, and since it is not caused by a chemical reaction unlike conventional methods, the fragrance does not change, and the types of fragrances are not limited.

[Brief explanation of the drawing]

The drawings show embodiments of the present invention. Figure 1 is a schematic sectional view showing the first embodiment, Figure 2 is a schematic sectional view showing the second embodiment, and Figure 3 is the third embodiment. A schematic sectional view, FIG. 4 is a side sectional view showing the ffI4 embodiment. l...Oxygen enrichment membrane module, 2...Vacuum tube, 3...Vacuum pump, 4...Exhaust line, 5*
5ae5be5c...Fragrance, 7...Casing, 8
...Oxygen enrichment membrane module, 9...Vacuum tube,
10... Vacuum pump, 11... Exhaust line, 14.
...Fragrance. Agent Yoshihiro Morimoto FF Min Line

Claims (1)

[Claims] 1. An oxygen enrichment membrane module that allows oxygen to permeate more easily than nitrogen, a pressure reduction means for reducing the pressure of this oxygen enrichment membrane module, an exhaust line connected to the exhaust side of this pressure reduction means, and the oxygen enrichment membrane module. An oxygen enrichment device consisting of a fragrance provided in the flow path on the upper or lower side of the oxygen enrichment device.