JP2004358034A - Oxygen enrichment machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an oxygen enrichment machine of high usability which can be used at any place, can control the state of oxygen-enriched air, and in which the state can be recognized by a user. <P>SOLUTION: The oxygen enrichment machine is provided with: an oxygen enrichment means 15 for generating the oxygen-enriched air; a suction part 2 for taking air into the oxygen enrichment means 15; a discharging part 3 for discharging the oxygen-enriched air; an air channel 16 for communicating between the suction part 2 and the discharging part 3; and a carrying means 10 for carrying the oxygen-enriched air. The carrying means 10 has a motor part 12 operated with a DC power, thereby the oxygen enrichment machine can conveniently be used at a place where commercial power is not supplied at home, outdoor, etc. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an oxygen-enriching machine for providing air containing high-concentration oxygen obtained by using an oxygen-enriching means, that is, so-called oxygen-enriched air to a user.
[0002]
[Prior art]
As a conventional oxygen enrichment machine, the basic configuration of a device main body that generates oxygen-enriched air by concentrating oxygen in the air and an oxygen discharge unit connected to the device main body, for example, including negative ion generating means (See, for example, Patent Document 1).
[0003]
[Patent Document 1]
JP-A-10-234836
[Problems to be solved by the invention]
However, in the conventional invention, first, the oxygen enricher was intended to be connected to a commercial power supply and used at home. Further, with respect to the function of discharging high-concentration oxygen, which is the basic performance of the oxygen enrichment device, to the outside at a desired air volume, there is no means for controlling the oxygen concentration and air volume of the oxygen-enriched air to be discharged. . Furthermore, there is no means for informing the user about the oxygen concentration and the air volume of the oxygen-enriched air which are invisible to the user, and the user feels the state of the oxygen-enriched air discharged and provided as a real feeling. However, it was not always in a state of good usability.
[0005]
SUMMARY OF THE INVENTION The present invention solves the above-mentioned conventional problems, enables the use of an oxygen-enriching machine anywhere, controls the state of oxygen-enriched air, and further allows the user to recognize the state. An object of the present invention is to provide a highly usable oxygen enricher by making it possible.
[0006]
[Means for Solving the Problems]
In order to solve the conventional problems, the present invention provides an oxygen-enriched unit that generates oxygen-enriched air, a suction unit that takes in air into the oxygen-enriched unit, and a discharge unit that discharges the oxygen-enriched air. , An air flow path communicating the suction unit and the discharge unit, and a transport unit for transporting the oxygen-enriched air, wherein the transport unit has a motor unit operated by a DC power supply, and is commercially available at home. The present invention can be used in a place without a power source or outdoors, and can provide a highly convenient oxygen enricher.
[0007]
BEST MODE FOR CARRYING OUT THE INVENTION
The invention according to claim 1 is an oxygen-enrichment unit that generates oxygen-enriched air, a suction unit that takes in air into the oxygen-enrichment unit, a discharge unit that discharges the oxygen-enriched air, and the suction unit. , An air flow path communicating with the discharge unit, and conveying means for conveying the oxygen-enriched air, the conveying means having a motor unit operated by a DC power supply, a place where there is no commercial power in the home Or, it can be used outdoors or the like, and can provide a highly convenient oxygen enricher.
[0008]
The invention according to claim 2 is an oxygen-enrichment unit that generates oxygen-enriched air, a suction unit that takes in air into the oxygen-enrichment unit, a discharge unit that discharges the oxygen-enriched air, and the suction unit. , An air flow path communicating with the discharge unit, and conveying means for conveying the oxygen-enriched air, wherein the conveying means has an inverter motor unit operated by at least one of a DC power supply and an AC power supply. Since the transfer means is constituted by an inverter motor having a high efficiency during operation, power consumption is reduced and energy is saved, and when using a DC power supply, a long use time can be secured.
[0009]
According to a third aspect of the present invention, there is provided an oxygen-enriching unit for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched unit, a discharge unit for discharging the oxygen-enriched air, and the suction unit. An air flow path communicating with the discharge unit, a conveying unit for conveying the oxygen-enriched air, a flow amount adjusting unit that allows a user to set an air flow discharged from the discharge unit, and an electric motor included in the transfer unit. Control means for changing the number of rotations of the unit, wherein the control means changes the power consumption of the electric motor unit based on information from the air volume adjustment means, and the user can arbitrarily select The air volume of the oxygen-enriched air and the oxygen concentration can be adjusted.
[0010]
The invention according to claim 4 is an oxygen-enriching unit that generates oxygen-enriched air, a suction unit that takes in air into the oxygen-enriched unit, a discharge unit that discharges the oxygen-enriched air, the suction unit, An air flow passage communicating with a discharge unit, a conveyance unit for conveying the oxygen-enriched air, an oxygen concentration detection unit for detecting an oxygen concentration of the oxygen-enriched air discharged from the discharge unit, and the conveyance unit. Control means for changing the number of revolutions of the motor section, wherein the control means changes the power consumption of the motor section based on information from the oxygen concentration detecting means, and air discharged from the discharge section. It is possible to detect the oxygen concentration for detecting the oxygen concentration in the medium and to control the transporting means so as to keep the oxygen concentration of the oxygen-enriched air to be discharged constant.
[0011]
The invention according to claim 5, wherein the oxygen-enriched means for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched means, a discharge unit for discharging the oxygen-enriched air, the suction unit, An air flow path communicating with the discharge unit, conveying means for conveying the oxygen-enriched air, oxygen concentration detecting means for detecting the oxygen concentration of the air flowing from the suction unit, and rotation of a motor unit included in the conveying means Control means for changing the power consumption of the electric motor unit based on the information from the oxygen concentration detection means, wherein the oxygen concentration in the air sucked from the suction unit is changed. Is detected, the conveying means is controlled in accordance with the oxygen concentration in the intake air, and the oxygen concentration of the oxygen-enriched air to be discharged can be kept constant.
[0012]
The invention according to claim 6, wherein the oxygen-enriched means for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched means, a discharge unit for discharging the oxygen-enriched air, the suction unit, An air passage communicating with a discharge unit, a conveying unit for conveying the oxygen-enriched air, an air flow detecting unit for detecting an air flow of the oxygen-enriched air discharged from the discharge unit, and an electric motor unit included in the conveying unit Control means for changing the number of rotations of the motor, wherein the control means changes the power consumption of the electric motor unit based on information from the air flow detection means, and the air flow in the air discharged from the discharge unit. Is detected, and the transport means can be controlled so as to keep the flow rate of the oxygen-enriched air constant.
[0013]
The invention according to claim 7, wherein the oxygen-enriched means for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched means, a discharge unit for discharging the oxygen-enriched air, the suction unit, An air flow path communicating with a discharge unit, a conveying unit that conveys the oxygen-enriched air, an oxygen concentration detection unit that detects an oxygen concentration of the oxygen-enriched air discharged from the discharge unit, and the oxygen concentration detection unit And a notifying means for notifying the user of the information from the user, so that the user can easily recognize the oxygen concentration of the oxygen-enriched air to be discharged.
[0014]
The invention according to claim 8, wherein the oxygen-enriched means for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched means, a discharge unit for discharging the oxygen-enriched air, the suction unit, An air flow passage communicating with a discharge unit, conveying means for conveying the oxygen-enriched air, air flow detecting means for detecting an air flow of the oxygen-enriched air discharged from the discharge unit, and information from the air flow detecting means And an informing means for informing the user of the fact that the air amount of the oxygen-enriched air to be discharged can be easily recognized by the user.
[0015]
【Example】
(Example 1)
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
[0016]
FIG. 1 is an external view of the main body of the oxygen enricher, and FIG. 2 is an internal configuration diagram of the main body.
[0017]
In FIG. 1, a main body 1 is provided with a suction section 2 for taking in ambient air, and a discharge section 3 for discharging oxygen-enriched air having an increased oxygen concentration inside the main body 1. The discharge section 3 is connected to a tube 5 for guiding oxygen-enriched air to the vicinity of the user. The other end of the tube 5 is connected to a headset 6 to be worn near the head when a user uses this apparatus to suck oxygen-enriched air. A discharge unit 7 for discharging air to a user is provided.
[0018]
In FIG. 2, an air flow path 16 that forms an air flow path from the suction section 2 to the discharge section 3 is formed inside the main body 1, and the space between the air flow paths 16 is taken in on the suction section 2 side. A filter 14 for removing air dust, an oxygen-enriching means 15 (oxygen-enriched membrane unit in the present embodiment) downstream of which increases the oxygen concentration after passing, and a flow of air further downstream. Is provided. The conveying means 10 drives a diaphragm-type pump unit 11 capable of obtaining a high pressure in order to increase the air volume of the oxygen-enriched air against the pressure drop through the oxygen-enriched membrane of the oxygen-enriching unit 15 and a pump unit 11 And a motor unit 12 for performing the operation. The motor section 12 has a DC motor section 19 operated by a DC power supply, and is connected to the DC power section 17. The DC motor unit 19 is operated or stopped by operating an operation switch 18 provided on the main body 1.
[0019]
Here, the oxygen enrichment means 15 will be described.
[0020]
The oxygen-enriched membrane unit of the oxygen enrichment means 15 is composed of a flat membrane made of an organic polymer and utilizes the difference in the speed of molecules passing through the membrane. An oxygen-enriched air having a high oxygen concentration is obtained. In ordinary air, the oxygen concentration is about 21% (about 79% nitrogen). The oxygen concentration and air volume of the generated oxygen-enriched air vary depending on the form, size, quantity, etc. of the oxygen-enriched membrane unit, but in this embodiment, the oxygen-enriched air passes through the oxygen-enriched membrane unit (oxygen enrichment means 15). The oxygen concentration of the subsequent oxygen-enriched air is about 30% (about 70% nitrogen). Further, the oxygen concentration of the oxygen-enriched air has characteristics that are influenced by external factors, that is, the speed, air volume, temperature, humidity, and the like of the air passing through the oxygen-enriched film.
[0021]
The operation of the oxygen enrichment device configured as described above will be described.
[0022]
By operating the operation switch 18, the DC motor unit 19 operates with the electric power obtained from the DC power supply unit 17, and by operating the motor unit 12, the pump unit 11 is operated. As a result, the operation of the transfer unit 10 is stopped. Therefore, air flows from the suction unit 2 to the discharge unit 3 via the filter 14, the oxygen enrichment unit 15, and the pump unit 11 in the air flow path 16 in the main body 1. In this flow of air, on the leeward side of the oxygen enrichment means 15, the air becomes oxygen-enriched air in which the oxygen concentration in the air is increased, and is discharged through the discharge section 3, the tube 5, and the discharge section 7 of the headset 6. Supplied to the user.
[0023]
As described above, since the main body 1 has the transporting means 10 and the DC power supply unit 17 for operating the transporting means 10 and can operate the oxygen enrichment apparatus, the commercial power supply for home use is supplied. Even where it is not, the oxygen enricher can be used anywhere.
[0024]
In this embodiment, the configuration in which the DC power supply unit 17 is provided in the main body 1 is shown. However, the same applies to the case where a DC power supply is provided outside the main body 1 and the power is drawn into the main body and operated. It is natural that the effect of is obtained.
[0025]
(Example 2)
Next, a second embodiment of the present invention will be described with reference to FIG. FIG. 3 is an internal configuration diagram of the main body. Note that the same components as those in the above embodiment are denoted by the same reference numerals, and description thereof will be omitted.
[0026]
In FIG. 3, an air flow path 16 that forms an air flow path from the suction section 2 to the discharge section 3 is formed inside the main body 1, and the space between the air flow paths 16 is taken in on the suction section 2 side. A filter 14 for removing air dust, an oxygen-enriching means 15 (oxygen-enriched membrane unit in the present embodiment) downstream of which increases the oxygen concentration after passing, and a flow of air further downstream. Is provided. The transport unit 10 includes a pump unit 11 and an electric motor unit 13 for driving the pump unit 11. The motor unit 13 is equipped with an inverter motor 20 driven by a DC power supply and driven by an inverter, and is connected to the DC power supply unit 17. The inverter motor 20 is driven through a control unit 30 that changes the rotation speed based on information on the operation switch 18 provided on the main body 1 and information on the air volume operation unit 31 also provided on the main body 1.
[0027]
The inverter drive type inverter motor 20 has a higher operation efficiency than other motor types, that is, an induction motor unit or a brushed DC motor unit, and thus requires less power consumption to obtain the same output. There is. In addition, the inverter drive system also has a feature that the number of revolutions can be changed relatively easily.
[0028]
The operation of the oxygen enrichment device configured as described above will be described.
[0029]
By operating the operation switch 18, the control unit 30 of the inverter motor 20 operates the inverter motor 20 to operate the transport unit 10. At this time, air flows from the suction part 2 to the discharge part 3 through the filter 14, the oxygen enrichment means 15, and the pump part 11 in the air flow path 16 in the main body 1. In this flow of air, on the leeward side of the oxygen enrichment means 15, the air becomes oxygen-enriched air in which the oxygen concentration in the air is increased, and is discharged through the discharge unit 3, the tube 5, and the discharge unit 7 of the headset 6. Supplied to the user.
[0030]
During operation, the motor is driven by the inverter motor 20, so that the motor is driven with lower power consumption as compared with the motor unit of another system.
[0031]
When the user operates the air volume operation unit 31 provided on the main body 1 to obtain a desired air volume, the control unit 30 receives a signal from the air volume operation unit 31 and changes the rotation speed to change the user's intention. The inverter motor 20 is controlled so as to reflect the above. Needless to say, if the rotation speed of the inverter motor 20 is increased, the air volume of the discharged oxygen-enriched air is increased. Conversely, if the rotation speed is reduced, the air volume of the discharged oxygen-enriched air is also reduced. Is done.
[0032]
By mounting the inverter motor 20 as described above, power consumption during operation can be reduced, leading to energy saving, and operation for a longer time than before can be performed. In addition, if the use time is set to be the same as the conventional one, the capacity of the DC power supply unit 17 can be reduced, so that the DC power supply unit 17 can be reduced in size and weight, and the oxygen enricher can be reduced in size and weight.
[0033]
Further, by the operation of the user, it is possible to arbitrarily adjust the flow rate of the oxygen-enriched air to be discharged and the oxygen concentration according to the user's desire.
[0034]
The inverter motor 20 includes both a motor driven by a DC power supply and a motor driven by an AC power supply (commercial power supply). In this embodiment, an inverter motor driven by a DC power supply and operated by the power of the DC power supply unit 17 has been described. However, unlike this embodiment, an inverter motor that can be driven by an AC power supply It is needless to say that the same effect as described above can be obtained even in a configuration in which an
[0035]
(Example 3)
Next, a third embodiment of the present invention will be described with reference to FIGS. FIG. 4 is an internal configuration diagram of the main body, and FIG. 5 is a circuit configuration block diagram. Note that the same components as those in the above embodiment are denoted by the same reference numerals, and description thereof will be omitted.
[0036]
In FIG. 4, an air flow path 16 that forms an air flow path from the suction section 2 to the discharge section 3 is formed inside the main body 1, and a filter 14 and an oxygen enrichment means are provided between the air flow paths 16. 15 (in the case of this embodiment, an oxygen-enriched film unit) and a transporting means 10 are provided. The transport unit 10 includes a pump unit 11 and an electric motor unit 13 on which an inverter motor 20 is mounted. The operating state and the number of revolutions of the inverter motor 20 are changed by the control means 30.
[0037]
Further, an oxygen concentration detecting means 32 for detecting the oxygen concentration in the oxygen-enriched air to be discharged and an air volume detecting means 34 for detecting the air volume of the oxygen-enriched air are provided in a part of the air flow path 16. I have. The control unit 30 also changes the rotation speed of the inverter motor 20 based on information output from the oxygen concentration detection unit 32 and information output from the air volume detection unit 34.
[0038]
The operation of the oxygen enrichment device configured as described above will be described.
[0039]
By operating the operation switch 18, the control unit 30 of the inverter motor 20 operates the inverter motor 20 to operate the transport unit 10. At this time, air flows from the suction part 2 to the discharge part 3 through the filter 14, the oxygen enrichment means 15, and the pump part 11 in the air flow path 16 in the main body 1. In this flow of air, on the leeward side of the oxygen enrichment means 15, the air becomes oxygen-enriched air in which the oxygen concentration in the air is increased, and is discharged through the discharge unit 3, the tube 5, and the discharge unit 7 of the headset 6. Supplied to the user.
[0040]
The oxygen concentration detecting means 32 detects the oxygen concentration in the oxygen-enriched air supplied to the user, and when the oxygen concentration has changed from a desired value due to some influence, detects this and sends it to the control means 30 of the inverter motor 20. Transmit information as a signal. Upon receiving this information, the control means 30 changes the rotation speed of the inverter motor 20. For example, when the oxygen concentration of the oxygen-enriched air supplied to the user is decreased, the rotation speed of the inverter motor 20 is decreased, and the oxygen concentration in the oxygen-enriched air generated by the oxygen enrichment means 15 is increased. Let it. Conversely, when the oxygen concentration of the oxygen-enriched air supplied to the user increases, the rotation speed of the inverter motor 20 is increased, and the oxygen concentration in the oxygen-enriched air generated by the oxygen enrichment means 15 decreases. Let it. By these actions, the oxygen concentration in the oxygen-enriched air supplied to the user is always automatically controlled to a desired value. Further, the information of the oxygen concentration detected by the oxygen concentration detecting means 32 is displayed on the oxygen concentration display section 33 provided in the main body 1 so that the user can determine the oxygen concentration in the oxygen-enriched air discharged from the discharge section 3. Easy to recognize.
[0041]
Further, the air volume detection means 34 detects the air volume of the oxygen-enriched air supplied to the user, and when the air volume changes from a desired value due to some influence, detects this and sends information to the control means 30 of the inverter motor 20. Transmit as a signal. Upon receiving this information, the control means 30 changes the rotation speed of the inverter motor 20. For example, when the air volume of the oxygen-enriched air supplied to the user decreases, the rotation speed of the inverter motor 20 is increased, and the air volume of the oxygen-enriched air discharged from the discharge unit 3 is increased. Conversely, when the air volume of the oxygen-enriched air supplied to the user increases, the rotation speed of the inverter motor 20 is reduced, and the air volume of the oxygen-enriched air discharged from the discharge unit 3 is reduced. By these actions, the air volume of the oxygen-enriched air supplied to the user is always automatically controlled to a desired value. Further, by displaying information on the discharge air volume of the oxygen-enriched air detected by the air volume detection unit 34 on the air volume display unit 35 provided in the main body 1, the user can use the air volume of the oxygen-enriched air discharged from the discharge unit 3. Can be easily recognized.
[0042]
FIG. 5 shows a circuit block diagram of the above configuration. It should be noted that the oxygen concentration detecting means 32 and the air flow detecting means 34 are separate systems, and needless to say, even if they are not simultaneously provided as described above, the respective effects are exhibited.
[0043]
(Example 4)
Next, a fourth embodiment of the present invention will be described with reference to FIG. FIG. 6 is an internal configuration diagram of the main body. Note that the same components as those in the above embodiment are denoted by the same reference numerals, and description thereof will be omitted.
[0044]
In FIG. 6, an air flow path 16 that forms an air flow path from the suction section 2 to the discharge section 3 is formed inside the main body 1, and a filter 14 and an oxygen enrichment means are provided between the air flow paths 16. 15 (in the case of this embodiment, an oxygen-enriched film unit) and a transporting means 10 are provided. The transport unit 10 includes a pump unit 11 and an electric motor unit 13 on which an inverter motor 20 is mounted. The operation and rotation speed of the inverter motor 20 are controlled by the control means 30.
[0045]
In the vicinity of the suction section 2 of the air flow path 16, a second oxygen concentration detecting means 36 for detecting the oxygen concentration in the air to be sucked is provided. The control unit 30 controls the rotation speed of the inverter motor 20 as desired based on the information output from the second oxygen concentration detection unit 36.
[0046]
The operation of the oxygen enrichment device configured as described above will be described.
[0047]
By operating the operation switch 18, the control unit 30 of the inverter motor 20 operates the inverter motor 20 to operate the transport unit 10. At this time, air flows from the suction part 2 to the discharge part 3 through the filter 14, the oxygen enrichment means 15, and the pump part 11 in the air flow path 16 in the main body 1. In this flow of air, on the leeward side of the oxygen enrichment means 15, the air becomes oxygen-enriched air in which the oxygen concentration in the air is increased, and is discharged through the discharge unit 3, the tube 5, and the discharge unit 7 of the headset 6. Supplied to the user.
[0048]
The second oxygen concentration detecting means 36 detects the oxygen concentration in the air sucked into the main body 1, and when the oxygen concentration in the sucked air changes from a desired value, detects this and controls the inverter motor 20. The information is transmitted to 30 as a signal. Upon receiving this information, the control means 30 changes the rotation speed of the inverter motor 20. For example, when the oxygen concentration in the intake air is lower than the steady state (about 21%), the oxygen concentration of the oxygen-enriched air obtained by passing this air through the oxygen enrichment means 15 becomes lower than the steady state. In such a case, the rotation speed of the inverter motor 20 is reduced, the oxygen concentration in the oxygen-enriched air generated by the oxygen enrichment means 15 is increased, and the same concentration as the oxygen concentration obtained in a steady state is secured. . Conversely, when the oxygen concentration in the intake air is higher than the steady state (about 21%), the oxygen concentration of the oxygen-enriched air obtained by passing this air through the oxygen enrichment means 15 is higher than the steady state. In such a case, the rotation speed of the inverter motor 20 is increased, the oxygen concentration in the oxygen-enriched air generated by the oxygen enrichment means 15 is reduced, and the same concentration as that obtained in a steady state is secured. .
[0049]
Since the second oxygen concentration detecting means 36 is for detecting the oxygen concentration in the air to be inhaled, the second oxygen concentration detecting means 36 is not required to be located in the vicinity of the suction portion 2 of the air flow path 16, but may be located in the main body 1. The same effect can be obtained even if the device is installed in a portion away from the main body 1 or in a place away from the main body 1.
[0050]
【The invention's effect】
ADVANTAGE OF THE INVENTION As mentioned above, according to this invention, while making it possible to use an oxygen-enrichment machine anywhere, controlling the state of oxygen-enriched air, and also enabling a user to recognize the state This makes it possible to provide a highly usable oxygen enricher.
[Brief description of the drawings]
FIG. 1 is an external view of an oxygen enrichment device according to a first embodiment of the present invention. FIG. 2 is an internal configuration diagram of a main body of the oxygen enrichment device. FIG. 3 is an oxygen enrichment according to a second embodiment of the present invention. FIG. 4 is a diagram showing the internal configuration of the oxygen-enriching machine according to a third embodiment of the present invention. FIG. 5 is a block diagram showing the circuit configuration of the oxygen-enriching machine. 4 is a diagram showing the internal configuration of the main body of the oxygen enrichment device according to the fourth embodiment.
DESCRIPTION OF SYMBOLS 1 Main body 2 Suction part 3 Discharge part 10 Conveying means 13 Motor part 15 Oxygen enrichment means (oxygen enrichment membrane unit)
16 Air flow path 17 DC power supply unit 30 Control means 31 Air volume operation unit 32 Oxygen concentration detection unit 33 Oxygen concentration display unit 34 Air volume detection unit 35 Air volume display unit

Claims (8)

Oxygen-enriched means for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched means, a discharge unit for discharging the oxygen-enriched air, and an air flow passage communicating the suction unit and the discharge unit And a transport unit for transporting the oxygen-enriched air, wherein the transport unit has an electric motor unit operated by a DC power supply. Oxygen-enriched means for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched means, a discharge unit for discharging the oxygen-enriched air, and an air flow passage communicating the suction unit and the discharge unit An oxygen enrichment machine having an inverter motor unit operated by at least one of a DC power supply and an AC power supply. Oxygen-enriched means for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched means, a discharge unit for discharging the oxygen-enriched air, and an air flow passage communicating the suction unit and the discharge unit Conveying means for conveying the oxygen-enriched air, air flow adjusting means for allowing a user to set the air flow discharged from the discharge section arbitrarily, and control means for changing the number of revolutions of the electric motor section of the conveying means An oxygen enricher, wherein the control means changes the power consumption of the electric motor unit based on information from the air volume adjusting means. Oxygen-enriched means for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched means, a discharge unit for discharging the oxygen-enriched air, and an air flow passage communicating the suction unit and the discharge unit Conveying means for conveying the oxygen-enriched air, oxygen concentration detecting means for detecting the oxygen concentration of the oxygen-enriched air discharged from the discharge section, and changing the number of revolutions of a motor section of the conveying means. An oxygen enricher comprising a control unit, wherein the control unit changes power consumption of the electric motor unit based on information from the oxygen concentration detection unit. Oxygen-enriched means for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched means, a discharge unit for discharging the oxygen-enriched air, and an air flow passage communicating the suction unit and the discharge unit Transport means for transporting the oxygen-enriched air, oxygen concentration detection means for detecting the oxygen concentration of the air flowing from the suction unit, and control means for changing the number of rotations of the electric motor unit of the transport means An oxygen enricher, wherein the control means changes power consumption of the electric motor unit based on information from the oxygen concentration detection means. Oxygen-enriched means for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched means, a discharge unit for discharging the oxygen-enriched air, and an air flow passage communicating the suction unit and the discharge unit Conveying means for conveying the oxygen-enriched air, air flow detecting means for detecting the air flow of the oxygen-enriched air discharged from the discharge section, and control means for changing the number of revolutions of the electric motor section of the conveying means An oxygen enricher, wherein the control means changes the power consumption of the electric motor section based on information from the air volume detection means. Oxygen-enriched means for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched means, a discharge unit for discharging the oxygen-enriched air, and an air flow passage communicating the suction unit and the discharge unit Conveying means for conveying the oxygen-enriched air; oxygen concentration detecting means for detecting the oxygen concentration of the oxygen-enriched air discharged from the discharge section; and information to the user from the oxygen concentration detecting means. Oxygen enricher equipped with an alarm means. Oxygen-enriched means for generating oxygen-enriched air, a suction unit for taking air into the oxygen-enriched means, a discharge unit for discharging the oxygen-enriched air, and an air flow passage communicating the suction unit and the discharge unit Conveying means for conveying the oxygen-enriched air, air flow detecting means for detecting the air flow of the oxygen-enriched air discharged from the discharge section, and informing means for informing a user of information from the air flow detecting means And an oxygen enrichment machine.

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