CN208238846U - A kind of medical molecular-sieve oxygen generator remote monitoring system - Google Patents

Abstract

The utility model provides a kind of medical molecular-sieve oxygen generator remote monitoring system, it is related to the technical field remotely monitored, it include: oxygenerator ontology, data acquisition equipment and remote monitoring terminal, data acquisition equipment is connected with oxygenerator ontology and remote monitoring terminal respectively, and remote monitoring terminal is connected with oxygenerator ontology；Oxygenerator ontology is for manufacturing medical oxygen；Data acquisition equipment is used to acquire the operation data of oxygenerator ontology, and operation data is sent to remote monitoring terminal；Remote monitoring terminal is for showing operation data, it is also used to obtain the electric signal that the processor of oxygenerator ontology is sent, and determine whether to alarm according to electric signal, and the running parameter for user's input, running parameter is sent to the processor of oxygenerator ontology, so that the processor of oxygenerator ontology executes corresponding movement, solves the technical issues of can not being monitored in the prior art to the working condition of oxygenerator.

Description

A kind of medical molecular-sieve oxygen generator remote monitoring system

Technical field

The utility model relates to remote control technology fields, remotely monitor more particularly, to a kind of medical molecular-sieve oxygen generator System.

Background technique

Medical oxygen generator extracts the novel device of oxygen based on pressure-variable adsorption (PSA) technology from air, utilizes Molecular sieve physical absorption and desorption technique load molecular sieve in oxygenerator, can be remaining by nitrogen adsorption in air in pressurization Unabsorbed oxygen be collected, the oxygen of high-purity is become after purified treatment.Specific work process is pressure Contracting air enters adsorption tower after air purification drying machine purifies, through switching valve.In adsorption tower, nitrogen is inhaled by molecular sieve Attached, oxygen enters oxygen storage tank after being built up at the top of adsorption tower, then is eliminated the unusual smell, the filtering of dust removal filter and sterilizing filter Obtain qualified medical oxygen.Main component parts has: air tank, air compressor machine, cooling driers, oxygen main frame processed, oxygen tank etc..

In the prior art can not working condition to oxygenerator and process flow monitored in real time and shown, therefore, nothing Method makes staff get the working condition of oxygenerator in time.

In view of the above-mentioned problems, not putting forward effective solutions also.

Utility model content

In view of this, the purpose of this utility model is to provide a kind of medical molecular-sieve oxygen generator remote monitoring system, with Alleviate the technical issues of can not being monitored in the prior art to the working condition of oxygenerator.

In a first aspect, the utility model embodiment provides a kind of medical molecular-sieve oxygen generator remote monitoring system, this is System includes: oxygenerator ontology, data acquisition equipment and remote monitoring terminal, wherein the data acquisition equipment respectively with it is described Oxygenerator ontology is connected with the remote monitoring terminal, and the remote monitoring terminal also passes through wired connection mode or nothing Line connection type is connected with the oxygenerator ontology；The oxygenerator ontology is for manufacturing medical oxygen；The data acquisition Equipment is used to acquire the operation data of the oxygenerator ontology, and the operation data is sent to the remote monitoring terminal, Wherein, the operation data comprises at least one of the following: pressure data, temperature data, data on flows, oxygen purity data；Institute Remote monitoring terminal is stated for showing the operation data；The remote monitoring terminal is also used to obtain the oxygenerator ontology The electric signal that processor is sent, and determine whether to alarm according to the electric signal, wherein the electric signal is for characterizing institute The working condition of oxygenerator ontology is stated, the working condition includes normal and abnormal；The remote monitoring terminal is also used to user The running parameter of input, and the running parameter is sent to by the oxygen processed by wireless connection device or connecting wired devices The processor of machine ontology, so that the processor of the oxygenerator ontology executes corresponding movement.

Further, the system also includes memory, the memory respectively with the data acquisition equipment and described Remote monitoring terminal is connected；The memory is for storing the collected operation data of the data acquisition equipment.

Further, the data acquisition includes: pressure sensor, temperature sensor, flow sensor and oxygen purity Analyzer, wherein the pressure sensor is used to obtain the pressure data of the gas of the oxygenerator ontology, and by the pressure Data are sent to the memory；The temperature sensor is used to obtain the temperature data of the oxygenerator ontology, and will be described Temperature data is sent to the memory；The flow sensor is used to obtain the temperature data of the oxygenerator ontology, and will The data on flows is sent to the memory；The oxygen purity analyzer is used to obtain the oxygen of the oxygenerator Ontology learning The purity data of gas, and the purity data is sent to the memory.

Further, the pressure sensor includes: first pressure sensor and second pressure sensor, wherein described First pressure sensor is for obtaining the intrinsic air pressure data of the oxygenerator；The second pressure sensor is for obtaining Take the intrinsic oxygen pressure data of the oxygenerator.

Further, the temperature sensor includes: the first temperature sensor and second temperature sensor, wherein described First temperature sensor is for obtaining the intrinsic air themperature data of the oxygenerator；The second temperature sensor is for obtaining Take the intrinsic oxygen temperature data of the oxygenerator.

Further, the radio connection includes following any: radio frequency connection, WIFI connection, bluetooth connection.

Further, the system also includes: indicator light, the indicator light are connected with the oxygenerator ontology, are used for The working condition of the oxygenerator ontology is indicated according to the electric signal that the oxygenerator ontology is sent.

Further, the system also includes: spare oxygen source, the spare oxygen source are connected with the remote monitoring terminal It connects, the electric signal for getting when the remote monitoring terminal is different for characterizing the oxygenerator ontology working condition When normal electric signal, controls the spare oxygen source and open work.

Further, the system also includes warning device, the warning device respectively with the remote monitoring terminal and The oxygenerator ontology is connected, and the electric signal for getting when the warning device is for characterizing the oxygenerator When the electric signal of ontology working condition exception, alarm signal is issued to the remote monitoring terminal.

Further, the warning device further include: communication module, the communication module are used for the warning device is raw At alarm signal operation maintenance personnel is sent in the form of short message.

In the utility model embodiment, operation data and the operation of oxygenerator ontology are got by data acquisition equipment Data are shown on remote monitoring terminal, and by setting on remote monitoring terminal to the running parameter of oxygenerator ontology It sets, and then solves the technical issues of can not being monitored in the prior art to the working condition of oxygenerator, to realize energy Enough technical effects that the working condition of oxygenerator is monitored in real time and shown.

Other feature and advantage of the utility model will illustrate in the following description, also, partly from specification In become apparent, or understood and implementing the utility model.The purpose of this utility model and other advantages are illustrating Specifically noted structure is achieved and obtained in book, claims and attached drawing.

To enable the above objects, features, and advantages of the utility model to be clearer and more comprehensible, preferred embodiment is cited below particularly, and Cooperate appended attached drawing, is described in detail below.

Detailed description of the invention

It, below will be right in order to illustrate more clearly of specific embodiment of the present invention or technical solution in the prior art Specific embodiment or attached drawing needed to be used in the description of the prior art are briefly described, it should be apparent that, it is described below In attached drawing be that some embodiments of the utility model are not paying creativeness for those of ordinary skill in the art Under the premise of labour, it is also possible to obtain other drawings based on these drawings.

Fig. 1 is a kind of schematic diagram of medical molecular-sieve oxygen generator remote monitoring system provided by the embodiment of the utility model；

Fig. 2 is the signal of another medical molecular-sieve oxygen generator remote monitoring system provided by the embodiment of the utility model Figure；

Fig. 3 is the signal of another medical molecular-sieve oxygen generator remote monitoring system provided by the embodiment of the utility model Figure；

Fig. 4 is the signal of another medical molecular-sieve oxygen generator remote monitoring system provided by the embodiment of the utility model Figure.

Specific embodiment

To keep the objectives, technical solutions, and advantages of the embodiments of the present invention clearer, below in conjunction with attached drawing to this The technical solution of utility model is clearly and completely described, it is clear that described embodiment is that the utility model a part is real Example is applied, instead of all the embodiments.Based on the embodiments of the present invention, those of ordinary skill in the art are not making Every other embodiment obtained, fall within the protection scope of the utility model under the premise of creative work.

Embodiment one:

Fig. 1 is a kind of medical molecular-sieve oxygen generator remote monitoring system according to the utility model embodiment, such as Fig. 1 institute Show, which includes: oxygenerator ontology 10, data acquisition equipment 20 and remote monitoring terminal 30, wherein the data acquisition is set Standby 20 are connected with the oxygenerator ontology 10 and the remote monitoring terminal 30 respectively, and the remote monitoring terminal 30 is also logical Wired connection mode or radio connection is crossed to be connected with the oxygenerator ontology 10；

The oxygenerator ontology 10 is for manufacturing medical oxygen；

The data acquisition equipment 20 is used to acquire the operation data of the oxygenerator ontology 10, and by the operation data It is sent to the remote monitoring terminal 30, wherein the operation data comprises at least one of the following: pressure data, temperature data, Data on flows, oxygen purity data；

The remote monitoring terminal 30 is for showing the operation data；

The remote monitoring terminal 30 be also used to obtain the oxygenerator ontology processor send electric signal, and according to The electric signal determines whether to alarm, wherein the electric signal is used to characterize the working condition of the oxygenerator ontology, institute It includes normal and abnormal for stating working condition；

The remote monitoring terminal 30 is also used to the running parameter of user's input, and passes through wireless connection device or wired The running parameter is sent to the processor of the oxygenerator ontology 10 by attachment device, so that the place of the oxygenerator ontology 10 It manages device and executes corresponding movement.

In the utility model embodiment, operation data and the operation of oxygenerator ontology are got by data acquisition equipment Data are shown on remote monitoring terminal, and by setting on remote monitoring terminal to the running parameter of oxygenerator ontology It sets, and then solves the technical issues of can not being monitored in the prior art to the working condition of oxygenerator, to realize energy Enough technical effects that the working condition of oxygenerator is monitored in real time and shown.

It should be noted that above-mentioned oxygenerator ontology uses pressure-variable adsorption (PSA) oxygen processed in the utility model embodiment Machine, the oxygenerator can directly extract oxygen from air, i.e., system i.e. use, fresh natural, maximum oxygen pressure be 0.2~ The explosive equal danger of high pressure are not present in 0.3MPa (i.e. 2~3 kilograms).

In addition, it should also be noted that, being provided with touching on above-mentioned remote monitoring terminal in the utility model embodiment Display screen is touched, to show the operating parameter of oxygenerator ontology, meanwhile, user directly can also input work in the touch display screen Make whether multiple air compressor machines and multiple cooling driers working conditions in parameter and control oxygenerator ontology open, the running parameter packet Include: PSA is pressed the time, PSA adsorption time, oxygenerator busbar connector pressure, oxygenerator manifold pressure parameter etc..

In addition, it should also be noted that, wired mode or nothing can be used between remote monitoring terminal and oxygenerator ontology Line mode is connected, if be wirelessly connected between remote monitoring terminal and oxygenerator ontology, can use and penetrate Frequency connects, WIFI connection, any one radio connection such as bluetooth connection, specific connection type, in the utility model reality It applies in example and does not illustrate, can be configured according to the actual situation.

In the utility model embodiment, as shown in Fig. 2, the system also includes: memory 40, the memory 40 divide It is not connected with the data acquisition equipment 20 and the remote monitoring terminal 30；

The memory 40 is for storing the collected operation data of the data acquisition equipment 20.

In the utility model embodiment, memory acquires the fortune of the collected oxygenerator ontology of equipment for storing data Row data, remote supervisory and control(ling) equipment can call the history data of oxygenerator ontology from the memory, and to history run Data are analyzed, and corresponding icon is generated, so as to carry out anticipation and early warning to the oxygenerator ontological existence hidden danger, in turn Foundation can be provided when oxygenerator ontology is overhauled and safeguarded for staff, improve staff's maintenance and maintenance Working efficiency.

In the utility model embodiment, as shown in Fig. 2, the data acquisition equipment 20 includes: pressure sensor 21, temperature Spend sensor 22, flow sensor 23 and oxygen purity analyzer 24, wherein

The pressure sensor 21 is used to obtain the pressure data of the gas of the oxygenerator ontology 10, and by the pressure Data are sent to the memory 40；

The temperature sensor 22 is used to obtain the temperature data of the oxygenerator ontology 10, and the temperature data is sent out Give the memory 40；

The flow sensor 23 is used to obtain the data on flows of the oxygen of the oxygenerator ontology, and by the flow number According to being sent to the memory；

The oxygen purity analyzer 24 is used to obtain the purity data for the oxygen that the oxygenerator ontology 10 generates, and will The purity data is sent to the memory 40.

In the utility model embodiment, the number pressure of the intrinsic gas of the above-mentioned available oxygenerator of pressure sensor According to staff can judge whether the working condition of oxygenerator ontology is normal by the pressure data, if it is judged that system The working condition of oxygen machine ontology then can in time set the running parameter of oxygenerator ontology on remote monitoring terminal extremely It sets, so that the working condition of oxygenerator ontology restores normal.

Above-mentioned temperature sensor is used to obtain the temperature data of the intrinsic gas of oxygenerator, and staff passes through the temperature The oxygen temperature of data judgement, oxygenerator Ontology learning is used if appropriate for patient, if oxygen temperature is not suitable for patient and uses, It can be then adjusted by remote monitoring terminal to the intrinsic oxygen temperature of oxygenerator, so that oxygen temperature is suitble to patient It uses.

Above-mentioned flow sensor is used to obtain the data on flows of the oxygen of oxygenerator Ontology learning, and staff can be preparatory The total amount of oxygen needed for counting patient is compared by total amount to required oxygen and above-mentioned data on flows, to set system The operating time of oxygen machine ontology, and then reach energy-efficient effect.

Above-mentioned oxygen purity analyzer is used to obtain the purity data of the oxygen of oxygenerator Ontology learning, as needed for patient The purity of oxygen have certain standard, it is therefore desirable to judged by the oxygen purity data that oxygen purity analyzer is got Whether the oxygen purity of the oxygenerator Ontology learning meets the standard.

In the utility model embodiment, as shown in figure 3, the pressure sensor 21 includes: first pressure sensor 211 With second pressure sensor 212, wherein

The first pressure sensor 211 is used to obtain the air pressure data in the oxygenerator ontology 10；

The second pressure sensor 212 is used to obtain the oxygen pressure data in the oxygenerator ontology 10.

In the utility model embodiment, above-mentioned first pressure sensor is for obtaining the intrinsic air of the oxygenerator Pressure data, and judge whether the intrinsic air pressure of oxygenerator meets preset standard according to the air pressure data, if The air pressure does not meet preset standard, then staff timely can be safeguarded and be checked to oxygenerator ontology, is promoted The working efficiency of staff.

Above-mentioned second pressure sensor is used to obtain the pressure data of the oxygen of the oxygenerator Ontology learning, and according to this Oxygen pressure data judge whether the intrinsic air pressure of oxygenerator meets preset standard, if the oxygen pressure do not meet it is pre- Bidding is quasi-, then staff timely can be safeguarded and be checked to oxygenerator ontology, improves the work effect of staff Rate.

In the utility model embodiment, as shown in figure 3, the temperature sensor 22 includes: the first temperature sensor 221 With second temperature sensor 222, wherein

First temperature sensor 221 is used to obtain the air themperature data in the oxygenerator ontology 10；

The second temperature sensor 222 is used to obtain the oxygen temperature data in the oxygenerator ontology 10.

In the utility model embodiment, above-mentioned first temperature sensor is for obtaining the intrinsic air of the oxygenerator Temperature data, and judge whether the intrinsic air themperature of oxygenerator meets preset standard according to the air themperature data, if The air themperature does not meet preset standard, then staff timely can be safeguarded and be checked to oxygenerator ontology, is promoted The working efficiency of staff.

Above-mentioned second temperature sensor is used to obtain the temperature data of the oxygen of the oxygenerator Ontology learning, and according to this Oxygen temperature data judge whether the intrinsic oxygen temperature of oxygenerator meets preset standard, if the oxygen temperature do not meet it is pre- Bidding is quasi-, then staff timely can be safeguarded and be checked to oxygenerator ontology, improves the work effect of staff Rate.

In the utility model embodiment, as shown in figure 4, the system also includes:

Indicator light 50, the indicator light 50 are connected with the oxygenerator ontology 10, for according to the oxygenerator ontology 10 electric signals sent indicate the working condition of the oxygenerator ontology 10.

In the utility model embodiment, above-mentioned indicator light is used to characterize the working condition of oxygenerator ontology, when oxygroup processed When the working condition exception of ontology, which receives the telecommunications of the oxygenerator ontology working condition exception of oxygenerator ontology sending After number, optical signal prompt is issued.

For example, indicator light issues red light when oxygenerator ontology operation irregularity；When oxygroup ontology processed is working properly, Indicator light issues the light of green.

In the utility model embodiment, as shown in figure 4, the system also includes: spare oxygen source 60, the spare oxygen source 60 are connected with the remote monitoring terminal 30, the electric signal for getting when the remote monitoring terminal 30 be for When characterizing the electric signal of the oxygenerator ontology working condition exception, controls the spare oxygen source and open work.

Specifically, when remote monitoring terminal get the transmission of oxygenerator ontology for characterizing described this body running of oxygenerator When the electric signal of abnormal state (that is, oxygenerator ontology is in operation irregularity state), remote monitoring terminal controls oxygenerator ontology It stops working, while opening spare oxygen source, provide oxygen for patient.

In addition, remote monitoring terminal can equally open spare oxygen when can not work when oxygenerator ontology because of having a power failure Source provides oxygen for patient.

The presence of above-mentioned spare oxygen source remains to the oxygen provided for patient in the case where there is chance failure and fortuitous event, from And better medical treatment condition is provided for patient.

In the utility model embodiment, the system also includes warning device 70, the warning device 70 respectively with institute It states oxygenerator ontology 10 to be connected with the remote monitoring terminal 30, the telecommunications for getting when the warning device 70 When number being the electric signal for characterizing 10 working condition of the oxygenerator ontology exception, issues and alarm to the remote monitoring terminal Signal.

Specifically, when warning device gets the abnormal for characterizing oxygenerator ontology working condition of oxygenerator ontology transmission Electric signal when, warning device sends warning message to remote monitoring terminal, and remote monitoring terminal shows the warning message In the touch display screen of remote terminal, to remind staff's oxygenerator ontology to break down, need to be serviced.

In the utility model embodiment, the warning device 70 further include:

Communication module 71, the alarm signal that the communication module 71 is used to generate the warning device 70 is with the shape of short message Formula is sent to operation maintenance personnel.

In the utility model embodiment, when working condition exception occurs in oxygenerator ontology, warning device generates alarm Signal, and the alarm signal is sent to short message by corresponding operation maintenance personnel by communication module, to notify operation maintenance personnel to this Oxygenerator ontology carries out care and maintenance.

In addition, in the description of the utility model embodiment unless specifically defined or limited otherwise, term " installation ", " connected ", " connection " shall be understood in a broad sense, for example, it may be being fixedly connected, may be a detachable connection, or integrally connect It connects；It can be mechanical connection, be also possible to be electrically connected；It can be directly connected, can also indirectly connected through an intermediary, it can To be the connection inside two elements.For the ordinary skill in the art, above-mentioned term can be understood with concrete condition Concrete meaning in the present invention.

It is in the description of the present invention, it should be noted that term " center ", "upper", "lower", "left", "right", " perpendicular Directly ", the orientation or positional relationship of the instructions such as "horizontal", "inner", "outside" is to be based on the orientation or positional relationship shown in the drawings, and is only For ease of description the utility model and simplify description, rather than the device or element of indication or suggestion meaning must have it is specific Orientation, be constructed and operated in a specific orientation, therefore should not be understood as limiting the present invention.In addition, term " the One ", " second ", " third " are used for descriptive purposes only and cannot be understood as indicating or suggesting relative importance.

In several embodiments provided herein, it should be understood that disclosed systems, devices and methods, it can be with It realizes by another way.The apparatus embodiments described above are merely exemplary, for example, the division of the unit, Only a kind of logical function partition, there may be another division manner in actual implementation, in another example, multiple units or components can To combine or be desirably integrated into another system, or some features can be ignored or not executed.Another point, it is shown or beg for The mutual coupling, direct-coupling or communication connection of opinion can be through some communication interfaces, device or unit it is indirect Coupling or communication connection can be electrical property, mechanical or other forms.

The unit as illustrated by the separation member may or may not be physically separated, aobvious as unit The component shown may or may not be physical unit, it can and it is in one place, or may be distributed over multiple In network unit.It can select some or all of unit therein according to the actual needs to realize the mesh of this embodiment scheme 's.

In addition, each functional unit in each embodiment of the utility model can integrate in one processing unit, It can be each unit to physically exist alone, can also be integrated in one unit with two or more units.

Finally, it should be noted that embodiment described above, only specific embodiment of the present utility model, to illustrate this The technical solution of utility model, rather than its limitations, the protection scope of the utility model is not limited thereto, although referring to aforementioned The utility model is described in detail in embodiment, those skilled in the art should understand that: it is any to be familiar with this skill The technical staff in art field within the technical scope disclosed by the utility model, still can be to skill documented by previous embodiment Art scheme modify or can readily occur in variation or equivalent replacement of some of the technical features；And these modifications, Variation or replacement, the spirit and model of the utility model embodiment technical solution that it does not separate the essence of the corresponding technical solution It encloses, should be covered within the scope of the utility model.Therefore, the protection scope of the utility model is answered described is wanted with right Subject to the protection scope asked.

Claims (10)

1. a kind of medical molecular-sieve oxygen generator remote monitoring system characterized by comprising oxygenerator ontology, data acquisition are set Standby and remote monitoring terminal, wherein the data acquisition equipment respectively with the oxygenerator ontology and the remote monitoring terminal It is connected, and the remote monitoring terminal also passes through wired connection mode or radio connection and the oxygenerator ontology phase Connection；

The oxygenerator ontology is for manufacturing medical oxygen；

The data acquisition equipment is used to acquire the operation data of the oxygenerator ontology, and the operation data is sent to institute State remote monitoring terminal, wherein the operation data comprises at least one of the following: pressure data, temperature data, data on flows, Oxygen purity data；

The remote monitoring terminal is for showing the operation data；

The remote monitoring terminal is also used to obtain the electric signal that the processor of the oxygenerator ontology is sent, and according to the electricity Signal determines whether to alarm, wherein the electric signal is used to characterize the working condition of the oxygenerator ontology, the work State includes normal and abnormal；

The remote monitoring terminal is also used to the running parameter of user's input, and is filled by wireless connection device or wired connection The processor that the running parameter is sent to the oxygenerator ontology is set, so that the processor of the oxygenerator ontology executes phase The movement answered.

2. system according to claim 1, which is characterized in that the system also includes: memory, the memory difference It is connected with the data acquisition equipment and the remote monitoring terminal；

The memory is for storing the collected operation data of the data acquisition equipment.

3. system according to claim 2, which is characterized in that the data acquisition equipment includes: pressure sensor, temperature Sensor, flow sensor and oxygen purity analyzer, wherein

The pressure sensor is used to obtain the pressure data of the gas of the oxygenerator ontology, and the pressure data is sent To the memory；

The temperature sensor is used to obtain the temperature data of the gas of the oxygenerator ontology, and the temperature data is sent To the memory；

The flow sensor is used to obtain the data on flows of oxygen in the oxygenerator ontology, and the data on flows is sent To the memory；

The oxygen purity analyzer is used to obtain the purity data of the oxygen of the oxygenerator Ontology learning, and by the purity Data are sent to the memory.

4. system according to claim 3, which is characterized in that the pressure sensor include: first pressure sensor and Second pressure sensor, wherein

The first pressure sensor is for obtaining the intrinsic air pressure data of the oxygenerator；

The second pressure sensor is for obtaining the intrinsic oxygen pressure data of the oxygenerator.

5. system according to claim 3, which is characterized in that the temperature sensor include: the first temperature sensor and Second temperature sensor, wherein

First temperature sensor is for obtaining the intrinsic air themperature data of the oxygenerator；

The second temperature sensor is for obtaining the intrinsic oxygen temperature data of the oxygenerator.

6. system according to claim 1, which is characterized in that the radio connection includes following any: radio frequency Connection, WIFI connection, bluetooth connection.

7. system according to claim 1, which is characterized in that the system also includes:

Indicator light, the indicator light are connected with the oxygenerator ontology, for according to oxygenerator ontology transmission Electric signal indicates the working condition of the oxygenerator ontology.

8. system according to claim 1, which is characterized in that the system also includes: spare oxygen source, the spare oxygen source It is connected with the remote monitoring terminal, the electric signal for getting when the remote monitoring terminal is for characterizing When stating the electric signal of oxygenerator ontology working condition exception, controls the spare oxygen source and open work.

9. system according to claim 1, which is characterized in that the system also includes: warning device, the warning device It is connected respectively with the remote monitoring terminal and the oxygenerator ontology, the electricity for being got when the warning device When signal is the electric signal for characterizing the oxygenerator ontology working condition exception, issues and alarm to the remote monitoring terminal Signal.

10. system according to claim 9, which is characterized in that the warning device further include:

Communication module, the communication module are used to the alarm signal that the warning device generates being sent to fortune in the form of short message Dimension personnel.