JP5015439B2 - Oxygen concentrator - Google Patents

Description

  The present invention relates to an oxygen concentrator that supplies a high concentration of oxygen to a patient or the like by, for example, a pressure fluctuation adsorption method.

In recent years, the number of patients suffering from respiratory diseases such as asthma, emphysema and chronic bronchitis has been increasing. Oxygen inhalation therapy is known as one of the most effective treatments.
This oxygen inhalation therapy is a method of supplying oxygen gas or oxygen-enriched gas to a patient, and an oxygen cylinder has been conventionally used as the supply source. Recently, oxygen concentrators capable of directly separating oxygen-enriched gas from the air have been developed and are becoming increasingly popular due to convenience during use and ease of maintenance.

  As such an oxygen concentrator, for example, an apparatus using an oxygen selective permeable membrane and an adsorption type oxygen concentrator using an adsorbent obtained by selective adsorption of nitrogen or oxygen are known. As such, a pressure fluctuation adsorption type oxygen concentrator using a compressor is used.

  The pressure fluctuation adsorption type oxygen concentrator includes a compressor that compresses and supplies raw material air, an adsorption cylinder filled with an adsorbent that preferentially adsorbs nitrogen in the air and separates oxygen. An adsorption process in which compressed air is introduced into the adsorption cylinder by a compressor and nitrogen is adsorbed in a pressurized state to obtain an oxygen-enriched gas; and a desorption process in which the internal pressure of the adsorption cylinder is reduced and nitrogen is released to regenerate the adsorbent; By alternately performing the steps, an oxygen-enriched gas can be obtained continuously.

Furthermore, in recent years, in order to improve the safety of the device, various techniques have been proposed for notifying a patient or the like of a device abnormality by using a buzzer or a display device when a device abnormality is detected (patents). References 1-3).
JP 2003-275212 (Page 4, FIG. 5) JP 2003-275313 (5th page, FIG. 6) Utility model registration No. 2569546 (first page, Fig. 1)

However, these prior art performing the abnormality notification, when an abnormality is detected in apparatus, since the notification operation such as immediately sound an alarm, for the patient, the problem that its not necessarily sufficient Usage was there.

That is, the notifying operation such as sounding an alarm when notifying the abnormality, to be carried out 24 hours a day, can interfere with the patient's sleep, or become a result, not sleep a warning anxiety, different Problems such as falling into a panic state during normal occurrence can be considered.

  The present invention has been made to solve the above-described problems, and an object thereof is to provide an oxygen concentrator that can be used in a suitable situation by a user while ensuring safety. .

(1) The invention of claim 1 is provided with an abnormality detection means for detecting an abnormality of the apparatus (oxygen concentrator), and the abnormality detected by the abnormality detection means is externally detected in the oxygen concentrator for generating oxygen concentrated gas. comprising a abnormal informing means for informing, and a selection means can select and abnormalities of the notification and non notification by the abnormality notifying means, said selection means, depending on the abnormality content detected by said abnormality detecting means In addition, it is possible to select between notification of abnormality and non-notification of the abnormality by the abnormality notification means .

If the abnormality of the apparatus is detected by a sensor or the like, usually, but quickly informs the abnormality buzzer and display, and the like, in the present invention, by the selecting means, whether to notify the abnormal Selectable.

Therefore, if necessarily immediately less need for notifying the abnormality is by the selecting means, it is possible not to perform a notification of the abnormal, to set a suitable notification status in response to the patient's condition Is possible. For example, in the case of an abnormality that does not require so much urgency, the notification can be made not to be performed for a predetermined time such as at night to sleep, so that the patient can sleep sufficiently. Further, it is possible to prevent the falling alarm or no longer sleep with anxiety, panic at the time of abnormal occurrence.

In particular, according to the present invention, it is possible to select between notifying and notifying of an abnormality depending on the content of the abnormality. Therefore, in the case of a minor abnormality that does not necessarily need to be reported immediately, the abnormality notification can be stopped, and for example, the patient can sleep sufficiently without being disturbed by the abnormality notification.
Incidentally, for example, a manual switch, and if a non-broadcast the (preset) predetermined abnormal contents, Ru is included in the scope of the present invention.

(2) The invention according to claim 2, by the selecting means, the content of the abnormality is set to non notification, among the broadcast items of a plurality of abnormal, a low urgency contents of the notification of abnormal It is characterized by.
The present invention, by the selecting means, exemplifies the contents of the anomaly to be set to non notification. Here, high notification item urgency (e.g. decrease of the oxygen concentration), as usual, immediately so as to broadcast, on the other hand, less urgent notification item (e.g. humidifier leakage abnormality), for example a predetermined time period Non-notification can be made.

( 3 ) The invention of claim 3 is characterized in that the selection means is a manual selection means.
For example, the patient can manually turn off the alarm by using a main unit device or a remote control switch. In this case, when there are a plurality of items to be notified, it is possible to individually notify / not notify, but it is also possible to collectively notify / not notify.

  From the viewpoint of safety, it is better to be able to select notification / non-notification only for specific items with low urgency. Moreover, you may set the content of alerting | reporting / non-notifying in the company which sells an apparatus instead of a patient, for example.

(4) The invention according to claim 4, characterized in that said it is possible to set the time of abnormality of the broadcast and non-broadcast by abnormal notification means.
In the present invention, for example, the non-notification time can be set by the selection means. For example, if a manual switch is pushed, it can be set to not notify for a predetermined time such as 8 hours, 6 hours,.

( 5 ) The invention of claim 5 is characterized in that it comprises recording means for recording at least the occurrence history of abnormality not notified by the selection means.
The present invention, abnormality of occurrence history (e.g. occurrence time, occurrence content, etc.) since the record, this occurrence history, it is possible to abnormal to reliably grasp the occurrence of abnormalities in the time which is not informed .

(6) The invention of claim 6, wherein after the end of the period of non-broadcast, and outputs the abnormality occurrence history recorded in the recording means.
In the present invention, after the end of the period of non notification, since outputs the occurrence history of abnormalities can be abnormal to reliably grasp the occurrence of abnormalities in the time which is not informed.

For example at the end of the period of non notification, automatically, (the non-broadcasting period) in the buzzer and the display may be informed that the or its contents abnormality occurs, by manual operation, so as to the notification May be.

  Next, an example (example) of the best mode of the present invention will be described.

  In this embodiment, oxygen is concentrated by adsorbing and removing nitrogen from the air using a nitrogen adsorbent (hereinafter referred to as an adsorbent), and this oxygen-enriched gas containing high-concentration oxygen is supplied to the patient. An example is a pressure fluctuation adsorption type medical oxygen concentrator to be supplied (hereinafter referred to as an oxygen concentrator).

a) First, the appearance of the oxygen concentrator of this embodiment will be described.
As shown in FIG. 1, the oxygen concentrator 1 is provided with an operation panel 5 for operating the oxygen concentrator 1 and displaying its operation at the upper part of the front of a substantially rectangular parallelepiped housing 3. A humidifier 7 for humidifying the oxygen-enriched gas is disposed.

  As shown in FIG. 2, the operation panel 5 includes a power switch 11 for operating / stopping the oxygen concentrator 1, an operation lamp 13 that lights up during normal operation, and an abnormal lamp 15 that lights up / flashes when an abnormality occurs. A dial knob 17 that switches a set value of the flow rate of the oxygen-enriched gas, a flow rate indicator 19 that indicates the set flow rate value, an external accumulated time indicator 21 that displays an accumulated time display or a countermeasure for an abnormality, An oxygen concentration lamp 23 that displays the concentration state of the oxygen-enriched gas by lighting / flashing, a humidifier leak lamp 25 that lights and displays an abnormality in the humidifier 7, and an abnormality in the folding of a cannula (not shown) A cannula folding lamp 29 for displaying the flow and a flow display lamp 31 for displaying the flow state of the oxygen-enriched gas are provided.

  Among these, the abnormal lamp 15 notifies the occurrence of an abnormality of the apparatus by lighting or blinking. The flow rate indicator 19 displays a number indicating the flow rate when it is normal, and all LEDs blink when an abnormality occurs. The external integrated time indicator 21 displays, for example, the operation time from the maintenance time when it is normal, and repeatedly scrolls and displays a text indicating how to deal with the abnormality when an abnormality occurs. The oxygen concentration lamp 23 notifies the abnormality of the oxygen concentration by blinking green / lighting red according to the concentration state of the oxygen-enriched gas. The humidifier leak lamp 25 lights up and displays an abnormality due to leakage of the humidifier 7. The cannula folding lamp 29 lights up and displays an abnormality caused by cannula folding. The flow display lamp 29 displays the flow state by sequentially lighting the LEDs one by one in the right direction in the figure during normal operation.

LED Particularly in this embodiment, the operation panel 5 (here the occurrence of leaks in the humidifier 7) abnormality predetermined content indicating a notification of the abnormal notification stop switch 33 for stopping a predetermined time, the stop time Four stop time display lamps 35 are arranged.

This anomaly notification stop switch 33, the number of times of pressing, the time to stop the abnormality notification, for example, 8 hours, 6 hours, 4 hours, 2 hours, which can be changed to 0 hours (unset), the setting time Each stop time display lamp 35 is lit in response to.

b) Next, the internal configuration of the oxygen concentrator 1 of this embodiment will be described.
As shown in FIG. 3, ambient air is introduced into the housing 3 via an air intake 41 and a dust-proof filter 43, and the introduced air passes through an intake filter 45 and an intake muffler 47 to a compressor 49. Inhaled.

  The compressor 49 generates high-pressure air by compressing intake air by the rotation of a motor (DC brushless motor) 51. The generated high-pressure air is a pair of check valves 53 and 55 and a solenoid valve. Are supplied to a pair of adsorption cylinders (first adsorption cylinder 61, second adsorption cylinder 63) via the supply valves (first supply valve 57, second supply valve 59). A first pressure sensor 73 is provided on the discharge path from the compressor 49 to the check valves 53 and 55.

  Exhaust valves (a first exhaust valve 65 and a second exhaust valve 67) made up of electromagnetic valves are connected to high-pressure air supply paths from the supply valves 57 and 59 to the adsorption cylinders 61 and 63, respectively. When the valves 65 and 67 are opened, the adsorption cylinders 61 and 63 can be opened to the atmosphere.

  The adsorption cylinders 61 and 63 are filled with a zeolite-based adsorbent (for example, Li-X zeolite) that preferentially adsorbs nitrogen in the air and separates oxygen. When high-pressure air is supplied from the compressor 49 through the check valves 53 and 55 and the supply valves 57 and 59 when the exhaust valves 65 and 67 are closed, nitrogen is adsorbed from the air. Oxygen-enriched gas is generated, and the oxygen-enriched gas is sent to the product tank 83 side via check valves 79 and 81.

  Further, a pressure regulator 85 for adjusting the pressure of the oxygen concentrated gas is provided on the downstream side of the product tank 83, and the flow rate of the oxygen concentrated gas adjusted by the pressure regulator 85 is set by the dial knob 17. It is sent to the humidifier 7 through the possible flow rate setting device 87, humidified by the humidifier 7, and then discharged to the outside through the outlet valve 89 and the discharge port 91 made up of electromagnetic valves.

  An oxygen sensor 93 that detects the oxygen concentration of the oxygen-enriched gas is provided in the oxygen-enriched gas discharge path from the flow rate setting device 87 to the humidifier 7, and an oxygen sensor 93 that detects the oxygen concentration of the oxygen-enriched gas is provided in the exhaust path downstream of the outlet valve 89 A second pressure sensor 95 that detects the discharge pressure of the concentrated gas is provided, and an attachment state detection switch 97 that detects the attachment state of the humidifier 7 is provided in the vicinity of the humidifier 7.

  The oxygen enriched gas discharge path from the adsorption cylinders 61, 63 to the check valves 79, 81 is provided with a communication path 99 that communicates the discharge sides of both adsorption cylinders 61, 63. A purge valve 105 composed of an electromagnetic valve is provided through the orifices 101 and 103. For this reason, when the purge valve 105 is opened, a part of the oxygen-enriched gas generated in one of the adsorption cylinders 61 and 63 can be supplied to the other.

c) Next, the electronic control unit 75 that controls the oxygen concentrator 1 will be described.
As shown in FIG. 4, in this embodiment, the electronic control unit 75 includes a known microcomputer 107, to its input section 109, a power switch 11, a flow rate setting unit 87, abnormality notification stop switch 33 and the like, and a first pressure sensor 73, a second pressure sensor 95, an oxygen sensor 93, a temperature sensor 111, a hall sensor 113, a wearing state detection switch 97, and the like are connected as means for detecting an abnormality of the apparatus. ing.

  The output unit 115 of the microcomputer 107 includes a buzzer (or speaker) 117, a flow rate indicator 19, an abnormal lamp 15, an oxygen concentration lamp 23, a humidifier leak lamp 25, and a cannula bent lamp 29 as means for notifying abnormality. It is connected. Further, the output unit 115 includes an operation lamp 13, a flow indicator 31, an external integrated time indicator 21, a DC brushless motor 51, supply valves 57 and 59, exhaust valves 65 and 67, a purge valve 105, an outlet valve 89, and a stop. A time display lamp 35 and the like are connected.

Note that a memory (EEPROM) 121 is connected to the microcomputer 107 in order to store the content of an abnormality that has occurred in the apparatus and the time of occurrence of the abnormality (occurrence date: date, time, etc.).
The electronic control circuit 75 alternately opens the first supply valve 57 and the second supply valve 59 at regular intervals, and alternately supplies high-pressure air to the first adsorption cylinder 61 and the second adsorption cylinder 63 so that oxygen is supplied. Pressurization control (pressurization step) for generating concentrated gas, and the exhaust valve 65 or 67 of the adsorption cylinder 61 or 63 for which the supply of high-pressure air is stopped by this pressurization control are opened, and the adsorption cylinder 61 Alternatively, the pressure is reduced by depressurizing the inside 63 and exhausting the nitrogen adsorbed by the adsorbent therein, and the purge valve 101 is opened in synchronism with the depressurization control, thereby increasing the pressure. Purge control or the like for purging a portion of the oxygen-enriched gas generated in the adsorption cylinder 61 or 63 to the adsorption cylinder 61 or 63 in the reduced pressure state to regenerate the adsorbent in the adsorption cylinder 61 or 63 in the reduced pressure condition, or the like Execute. Thereby, 90% or more of concentrated oxygen is continuously generated.

  The electronic control circuit 75 monitors the operating state of the oxygen concentrator 1 based on detection signals from the pressure sensors 73 and 95, the oxygen sensor 93, the wearing state detection switch 97, and the like. Then, the monitoring result is controlled by driving the display device 123 (see FIG. 3), the buzzer 117 and the like assembled on the inclined surface of the operation panel 5 to notify the patient.

  Specifically, the abnormality is reported by displaying lighting, blinking, etc. of the abnormal lamp 15, the external integrated time indicator 21, the oxygen concentration lamp 23, the humidifier leak lamp 25, the cannula broken lamp 29, etc., which constitute the display device 123. Or the sound of the buzzer 117 (or sound output) is notified of the abnormality.

In particular, in this embodiment, as described later, a predetermined manual operation (pressing the abnormal notification stop switch 33), the predetermined abnormality (humidifier 7 occurrence of leakage of the oxygen enriched gas in) a predetermined time notification of ( (Abnormality notification stop period) Control to stop. In addition, a history of abnormality that occurred during the abnormality notification stop period is stored in the memory 121, and after the abnormality notification stop period ends, the abnormality history is notified to the patient by display, sound, or the like. .

e) Next, abnormality notification and abnormality notification stop processing performed by the electronic control unit 75 will be described.
i) First, the method of abnormality detection and the content of abnormality notification will be described with reference to FIG.

(1) <Folding cannula>
When the detection value of the second pressure sensor 95 is equal to or greater than the predetermined threshold value S1, it is determined that the cannula is broken. Then, the yellow cannula folding lamp 29 is turned on. Further, the display content of the external integrated time display 21 is switched to the display of the coping method and scrolled. At this time, the warning is given by a buzzer sound or voice. In this case, the operation of the apparatus is continued, and the error code E1 indicating the abnormality content and the occurrence date and time are stored in the memory 121.

(2) <Low pressure alarm>
When the detection value of the first pressure sensor 73 is equal to or less than the predetermined threshold value S2, it is determined that the pressure of the air pressurized by the compressor 49 has decreased excessively. Then, the red abnormal lamp 15 blinks, and all the display portions of the flow rate indicator 19 also blink. Further, the display content of the external integrated time display 21 is switched to the display of the coping method and scrolled. At this time, the warning is given by a buzzer sound or voice. In this case, the operation of the apparatus is continued, and the error code E2 indicating the abnormality content and the occurrence date and time are stored in the memory 121.

(3) <Overpressure alarm>
When the detection value of the first pressure sensor 73 is equal to or greater than the predetermined threshold S3, it is determined that the pressure of the air pressurized by the compressor 49 has increased excessively. Then, the red abnormal lamp 15 blinks, and the flow rate indicator 19 also blinks. Further, the display content of the external integrated time display 21 is switched to the display of the coping method and scrolled. At this time, the warning is given by a buzzer sound or voice. In this case, the operation of the apparatus is stopped, and the error code E3 indicating the content of the abnormality and the occurrence date and time are stored in the memory 121. Here, the stop of the operation of the device, a stop of the operation of the actuator for performing an oxygen concentration, a lamp or the like for notifying the abnormality, it is desirable that it is operated. (The same applies hereinafter)
(4) <Humidifier leak warning>
For example, when the apparatus is started, the second pressure sensor is operated even when the mounting state detection switch 97 that is turned on when the humidifier 7 is mounted is turned on and the outlet valve 89 is turned on (closed). When the detected value of 95 is equal to or less than the predetermined threshold value S4, it is determined that a leakage abnormality has occurred in the humidifier 7. Then, the yellow humidifier leakage lamp 15 is turned on, and the display content of the external integrated time display 21 is switched to the display of the coping method and scrolled. At this time, the warning is given by a buzzer sound or voice. In this case, the operation of the apparatus is continued, and the error code E4 indicating the content of the abnormality and the occurrence date and time are stored in the memory 121.

(5) <Oxygen concentration reduction>
When the oxygen sensor 93 determines that the oxygen concentration is equal to or lower than a predetermined threshold value (indicating less than 82%) S5, it is determined that an abnormality has occurred in which the oxygen concentration has considerably decreased. Then, the green oxygen concentration lamp 23 blinks, and the display content of the external integrated time indicator 21 is switched to the display of the coping method and scrolled. At this time, the warning is given by a buzzer sound or voice. In this case, the operation of the apparatus is continued, but the error code indicating the abnormal content is not stored.

(6) <Oxygen concentration reduction>
When the oxygen concentration is equal to or less than a predetermined threshold value (indicating 75% or less) S6 by the oxygen sensor 93, it is determined that an abnormality that greatly reduces the oxygen concentration has occurred. Then, the red oxygen concentration lamp 23 is turned on, and the display content of the external integrated time display 21 is switched to the display of the coping method and scrolled. At this time, the warning is given by a buzzer sound or voice. In this case, the operation of the apparatus is continued and the error code E5 indicating the content of the abnormality and the occurrence date and time are stored in the memory 121.

(7) <Power failure>
When a power supply abnormality is detected, the red abnormality lamp 15 is turned on, and the display content of the external integrated time display 21 is switched to the display of the countermeasure and scrolled. At this time, the warning is given by a buzzer sound or voice. In this case, the operation of the apparatus is stopped, but an error code indicating the abnormal content is not stored.

(8) <Temperature rise>
If the temperature sensor 111 determines that the temperature is equal to or higher than the predetermined threshold value S7, it is determined that an abnormality in which the temperature rises excessively has occurred. Then, the red abnormal lamp 15 blinks, and all the display portions of the flow rate indicator 19 also blink. Further, the display content of the external integrated time display 21 is switched to the display of the coping method and scrolled. At this time, the warning is given by a buzzer sound or voice. In this case, the operation of the apparatus is stopped, and the error code E6 indicating the content of the abnormality and the occurrence date and time are stored in the memory 121.

(9) <Rotational speed abnormality>
The Hall sensor 113, the rotation speed of the DC brushless motor 51, when departing from a predetermined safe speed region, it is determined that abnormality has occurred in the DC brushless motor 51. Then, the red abnormal lamp 15 blinks and the flow rate indicator 19 is also lit. Further, the display content of the external integrated time display 21 is switched to the display of the coping method and scrolled. At this time, the warning is given by a buzzer sound or voice. Further, the operation of the apparatus is stopped, and the error code E7 indicating the content of the abnormality and the occurrence date and time are stored in the memory 121.

ii) Next, processing that is a main part of the present embodiment, that is, abnormality notification processing and abnormality notification stop processing will be described based on the flowchart of FIG.
This process, if the anomaly notification stop switch 33 is pressed, one of the nine normal abnormality notification, only abnormality notification processing of the humidifier leakage, for a predetermined time, but is not performed (Abnormality notification stop processing).

First, as shown in step 200 of FIG. 6, it is determined whether abnormality notification stop switch 33 is pressed. Here, if it is determined that the abnormality notification stop switch 33 is pushed, the process proceeds to step 250, otherwise proceeds to step 210.

And in steps 210-240, the process which alert | reports said normal 9 types of abnormality is performed.
Specifically, in step 210, it is determined whether or not an abnormality has occurred in the apparatus. If an affirmative determination is made here, the process proceeds to step 220, while if a negative determination is made, the process waits.

  In step 220, contents for notifying abnormality are selected according to the abnormality contents shown in FIG. That is, since the lighting state of the lamp and the display content are changed according to the case where the abnormality rank is high or the abnormality rank is low, the display method corresponding to the abnormality content is determined here. Note that data for performing this processing is stored in the memory 121.

In subsequent step 230, according to the content of the abnormality, the corresponding abnormality notification means (such as each lamp) is driven to notify the user of the abnormality.
In the following step 240, the external integrated time display 21 is driven to perform a process for displaying a countermeasure for the abnormality, and the process is temporarily terminated.

On the other hand, in step 250, the abnormal notification stop switch 33 is depressed, performs processing corresponding to the pressed number.
Specifically, abnormality notification stop switch 33, once, twice, three times, when pressed four times, respectively, 8 hours from the current time (H), over 6H, 4H and 2H, Since the notification process of the abnormality of the humidifier leak is stopped, the stop time display lamp 33 corresponding to the number of times of pressing is turned on. When the button is pressed five times, the abnormality notification stop process is cancelled, and thus the process for turning off the stop time display lamp 33 is performed.

At the same time, the number of times the abnormal notification stop switch 33 is pressed (hence period in which the abnormality notification stop processing) stored in the memory 121 and starts the abnormality notification stop processing.
In the subsequent step 260, it is determined whether or not an abnormality has occurred in the apparatus based on signals from each sensor and switch. If an affirmative determination is made here, the process proceeds to step 270, while if a negative determination is made, the process waits.

In step 270, it is determined whether or not the abnormality notification stop period has ended. If an affirmative determination is made here, the process proceeds to step 280. If a negative determination is made, the process proceeds to step 290.
In step 280, since the abnormality notification stop period has ended, in order to return to the normal abnormality notification state, the stop time display lamp 33 is turned off, the memory of the set abnormality notification stop period is cleared, and abnormality notification stop control is performed. End. Thereafter, the processes in steps 220 to 240 are performed, and the present process is temporarily terminated.

  On the other hand, in step 290, it is determined whether or not the abnormality that has occurred is an abnormality in humidifier leakage (which is the target of abnormality notification stoppage). If an affirmative determination is made here, the process proceeds to step 300, whereas if a negative determination is made, the process proceeds to step 220.

  In step 220, since it is an abnormality other than the humidifier leakage abnormality, as usual, the content to be notified of the abnormality is selected according to the abnormality content, and in steps 230 and 240, the abnormality is notified, etc. Once this process is finished.

  Further, in step 300, since the abnormality of the humidifier leak (which is the target of the abnormality notification stop) has occurred, for example, in order not to disturb the patient's sleep, the abnormality is notified without sound or display. Then, the process of simply storing the abnormality history in the memory 121 is performed and the present process is temporarily terminated.

In addition, when the abnormality notification stop period ends, it may be automatically notified that the humidifier leakage abnormality has occurred (within the abnormality notification stop period) based on the abnormality history of the memory 121. . Alternatively, the manual operation (for example, abnormality notification operation stop period after the end of the first abnormal notification stop switch 33) may be caused to the notification.

  As described above, when an abnormality is detected, the oxygen concentrator 1 of the present embodiment notifies the abnormality with a lamp or a buzzer according to the content of the abnormality and, for example, manually during sleep such as at night. , Has stopped alerting of humidifier leaks (not so serious).

  Therefore, the patient can sufficiently sleep, and there is a remarkable effect that the alarm can be prevented from being sleepy due to anxiety and the occurrence of panic due to the alarm during sleep can be prevented.

In addition, this invention is not limited to the said Example at all, and it cannot be overemphasized that it can implement with a various aspect in the range which does not deviate from the summary of this invention.
(1) In the said Example, although alerting | reporting of the single humidifier leak abnormality was stopped, you may stop alerting | reporting of several abnormality. Moreover, you may enable it to select manually the item of abnormality which stops alerting | reporting. However, in this case, it is preferable that a serious abnormality item cannot be selected manually.

  (2) When the oxygen concentrator can be operated with a remote controller, notification / non-notification may be set with the remote controller. Further, the non-notification time setting may be set finely, for example, as in the air conditioner timer setting.

  (3) Further, the patient does not set abnormality notification / non-notification with a manual switch, but the person who delivers the device, for example, directly sends the contents of the abnormality notification stop to the memory in response to a request from the patient, for example. You may make it write in.

It is explanatory drawing which shows the external appearance of the oxygen concentrator of an Example. It is explanatory drawing which shows the operation panel of the oxygen concentrator of an Example. It is explanatory drawing which shows the basic composition of the oxygen concentrator of an Example. It is explanatory drawing which shows the electrical structure of the electronic controller of the oxygen concentrator of an Example. It is explanatory drawing which shows the abnormality display of an Example, the countermeasure method of abnormality, etc. It is a flowchart which shows the abnormality notification performed in the electronic controller of an Example, and the process of the stop.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Oxygen concentrator 5 ... Operation panel 15 ... Abnormal lamp 17 ... Flow rate setting device 19 ... Flow rate indicator 21 ... External integration time indicator 23 ... Oxygen concentration lamp 25 ... Humidifier leak lamp 29 ... Cannula broken lamp 33 ... Abnormality notification Stop switch 35 ... Stop time display lamp 73 ... First pressure sensor 89 ... Outlet valve 93 ... Oxygen sensor 95 ... Second pressure sensor 97 ... Device state detection switch

Claims (6)

In an oxygen concentrator for generating an oxygen-enriched gas, comprising an abnormality detecting means for detecting an abnormality of the device,
The abnormality detected by the abnormality detecting means, the abnormal informing means for informing the outside,
And selection means can select the non notification and the notification of abnormal by the abnormality notification means,
Equipped with a,
The oxygen concentrator according to claim 1, wherein the selecting means is capable of selecting the abnormality notification and non-notification by the abnormality notification means according to the content of the abnormality detected by the abnormality detection means . By the selection means, the content of the abnormality is set to non notification, among the broadcast items of a plurality of abnormal, according to claim 1, characterized in that the urgency is low the content of the notification of abnormal Oxygen concentrator. The oxygen concentrator according to claim 1 or 2 , wherein the selection means is a manual selection means. Oxygen concentrator according to any one of the claims 1-3, characterized in that said it is possible to set the time of abnormality of the broadcast and non-broadcast by abnormal notification means. At least, the oxygen concentrator according to any one of the claims 1-4, characterized in that it comprises a recording means for recording the occurrence history of non notification and anomaly by the selecting means. Wherein after the end of the period of non notification, the oxygen concentrator according to claim 5, characterized in that the output abnormalities generation history recorded in the recording means.

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