KR20030013006A - Oxy generator having a state monitoring/communication function and remote supervision system - Google Patents

Abstract

Oxygen generator with status monitoring / communication function and its remote management system are to monitor oxygen generator user status, device operation and use, and transmit information about it to be managed remotely. The present invention attaches a pulse oximeter for detecting a user's condition such as blood oxygen concentration and pulse of the user, sensors for detecting the cumulative use time, flow rate, pressure, purity, etc. of the device, and communication means to the oxygen generator. It obtains user's status information, operation information including device operation condition and abnormality, and device usage information. It controls oxygen generation according to the obtained information and transmits it by communicating with remote management. It is configured to manage the oxygen generator. Therefore, the present invention can check the status of the oxygen generator and the user (patient) at a remote location can be useful for medical examinations or to manage the patient at a remote location, such as home care, the presence and failure of the oxygen generator It can be judged and provides the effect of predicting failure or preventing accidents due to failure.

Description

Oxygen generator having a state monitoring / communication function and remote supervision system}

The present invention relates to an oxygen generator, and more particularly, to monitor the oxygen generator user status and device use and operation status, and to remotely transmit the information obtained therefrom through a communication connection to remotely manage the oxygen generators scattered throughout the region. An oxygen generator having a status monitoring / communication function and a remote management system thereof.

Oxygen generators are used in various places in various places. Most commonly, oxygen is supplied to confined spaces in offices and homes to help recover the fatigue accumulated in the daily lives of modern people and to activate the cells, and to provide oxygen to patients in operating rooms and ambulances in hospitals. Medical oxygen generators are used. In addition, various types of oxygen generators are used, including an oxygen generator for automobiles for supplying oxygen in a closed vehicle, an oxygen generator for charging an air tank for divers, and an oxygen generator for use in a wastewater treatment plant or aquaculture farm.

In addition to low-cost products that generate oxygen only, oxygen generators are equipped with pressure sensors, purity sensors, flow sensors, etc. to check the operating pressure and the purity of the generated oxygen and to output warning lights or warning sounds to the outside.

However, the existing oxygen generator as described above can not check the user's state or device state, there is a hassle to check regularly during use. In particular, medical oxygen generators should always have a guardian to check the condition of the device or patient because the patient is prescribed by a doctor and used mainly in the place away from the hospital. Of course, in case of expensive oxygen generator, the sensor is built-in to alarm the operation of the device, but it does not check the user's status, and the remote administrator cannot know the device status or the user's status, so it is difficult to manage smoothly. In addition, in order to manage the oxygen generators are scattered around the place to be regularly visited and inspected is expensive.

Accordingly, an object of the present invention has been devised in view of the above-mentioned points, and it is possible to secure the safety and correct treatment of the user by adding a function of monitoring the user or device status to the oxygen generator and remotely transmitting the information obtained therefrom. To provide an oxygen generator to be made.

Another object of the present invention is to provide a system for remotely managing an oxygen generator having the above-described state monitoring / communication function.

1 is a block diagram showing an oxygen generator remote management system according to the present invention,

2 shows an embodiment when the oxygen generator of the FIG. 1 system is for medical use.

<Description of the symbols for the main parts of the drawings>

10: pulse oximeter 15: main controller

20: oxygen generation controller 25: R / W ROM

30: oxygen generator 45: oxygen outlet

50: display unit 55: communication unit

100A to 100N: oxygen generator 200: information collection server

300: management center

Oxygen generator with a state monitoring / communication function of the present invention for achieving the above object, in the oxygen generator, the oxygen generating unit, the first sensor unit for detecting the user's state, the use of the oxygen generating unit And a second sensor unit for detecting an operating state, a display unit for displaying a state of the user sensed by the first sensor unit so that the user can know, and a state of the user from detection signals of the first and second sensor units. It includes a control unit for analyzing and determining the use and operation of the device, and control the generation of oxygen according to the control, the control to transmit the status information to the outside, and the communication unit for transmitting the user and device status information under the control of the control unit .

Oxygen generator remote management system for achieving another object of the present invention, in the system for remote management of the oxygen generator, a plurality of oxygen generating device for transmitting information obtained by monitoring the user's state and device use and operation status; And an information collection server configured to communicate with the plurality of oxygen generating devices to collect device usage and operation information and status information of the device user, and the information collected by the information collecting server. Includes a management center that manages

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of an oxygen generator remote management system according to the present invention, Figure 2 is a view showing an embodiment when the oxygen generator of the system of Figure 1 for medical use. The system shown in FIG. 1 is largely comprised of oxygen generating apparatus 100A-100N, the information collection server 200, and the management center 300. As shown in FIG. The information collection server 200 is connected to a plurality of oxygen generating apparatuses 100A to 100N which are scattered and used throughout the LAN, telephone lines, and wireless communication infrastructures, and collects state information from each oxygen generating apparatus 100A to 100N. do. Since the oxygen generating apparatuses 100A to 100N are all configured and operated in the same manner, only the oxygen generating apparatus 100A will be described. Oxygen generator 100A is a pulse oximeter sensor (10) for detecting the user's condition in the blood oxygen concentration and pulse rate, and the main controller (15) for controlling the overall operation of each configuration, And a display unit 50 for displaying the detected user state so that the user can know the control state of the main controller 15. Here, the display unit 50 uses LCD, FND, or the like. The oxygen generator 100A also includes an oxygen generator 30, an oxygen outlet 45 for discharging the generated oxygen to a user, and an oxygen generator controller 20 for controlling the generation of oxygen while checking the operation and use of the apparatus. Here, the oxygen generator 30 is a ready-made product to which the sensors are attached, as shown in FIG. 2, between the solenoid valve 34 and the adsorption towers A, B (36A, 36B) and the storage tank (39). Pressure sensors 35A to 35C, which are attached to each other, to measure pressure, and a flow rate sensor 42 and a purity sensor 43 attached to near the final oxygen outlet to monitor flow rate and oxygen purity. The oxygen generation controller 20 is connected to a memory 25 for recording the operation time of the device, the accumulated use time such as the oxygen treatment time of the user, and the monitored state. Here, the memory 25 is rewriteable and uses read / write-read only memory (R / W-ROM) so that the recorded information can be preserved even in the event of power failure. Meanwhile, the oxygen generator 100A is configured to transmit device usage and operation information checked by the oxygen generator controller 20 and user state information sensed by the pulse oximeter 10 under the control of the main controller 15. The communication part 55 is provided. The management center 300 analyzes the information collected by the information collection server 200 by executing the information analysis software, and manages the oxygen generating apparatus 100A to 100N according to the analysis result. The following describes the state monitoring and communication function of the oxygen generator having such a configuration and the remote management operation accordingly.

After the user receives an oxygen therapy prescription from a doctor, the oxygen generator 100A is used to receive oxygen therapy. After the user attaches the pulse oximeter 10 to the hand, the user sets a desired amount of oxygen and operates the oxygen generator 100A. The pulse oximeter 10 detects a user state such as blood oxygen saturation degree SpO ₂ and a pulse rate of the user. Oxygen generator 100A generates oxygen by the set amount of oxygen, and checks the user's state to be detected and supplies oxygen to the user. The main controller 15 of the oxygen generator 100A includes an A / D converter (not shown) to convert the detection signal of the pulse oximeter 10 into a digital form that can be processed internally. The main controller 15 determines the oxygen flow rate required by the user from the detected blood oxygen concentration of the user, transmits this information to the oxygen generation controller 20, and simultaneously displays the measured value on the display unit 50 to the user. Inform. The oxygen generation controller 20 controls oxygen to be generated in the oxygen generator 30 according to an oxygen generation command of the main controller 15, and supplies oxygen flow rate at an oxygen flow rate according to a user state transmitted from the main controller 15. The flow controller 41 is controlled to adjust the flow rate. When the flow rate is controlled by the flow regulator 41, the oxygen supply amount is changed, thereby increasing the operation efficiency of oxygen generation according to the user state. That is, when the oxygen saturation degree of the user increases, the oxygen supply amount is reduced, and thus the oxygen generator 100A consumes less energy. Here, although the main controller 15 and the oxygen generation controller 20 are shown in separate configurations, they may be physically configured as one electronic circuit. The oxygen generation controller 20 receives pressure, flow rate, and oxygen purity detected by the pressure sensors 35A to 35C, the flow rate sensor 42, and the purity sensor 43 of the oxygen generation unit 30 to determine whether the device is abnormal. And while checking the operating conditions and the like to control the generation of oxygen in the oxygen generating section (30). The oxygen generator 30 generates oxygen under the control of the oxygen generator controller 20. That is, the oxygen generating unit 30 flows outside air through the intake filter 31 and compresses the air into the air compressor 33. The compressed air is introduced into the adsorption tower A 36A by the solenoid valve 34. When the inside of the adsorption tower A (36A) is gradually pressurized by the compressed air introduced into the nitrogen is adsorbed to the adsorbent 37 to generate concentrated oxygen. The concentrated oxygen is stored in the storage tank 39 through the check valve A 38A above the adsorption tower A 36A. At this time, the adsorption tower B (36B) is connected to the exhaust silencer 32 by the solenoid valve 34 to discharge the internal air to the atmosphere. Therefore, the pressure is lowered and the nitrogen adsorbed to the atmosphere is desorbed and discharged. When nitrogen is sufficiently adsorbed inside the adsorption tower A 36A, the solenoid valve 34 is switched to allow the adsorption tower A 36A to depressurize and desorb the adsorption tower B 36B to pressurize and adsorb. The adsorption tower A 36A is connected to the exhaust silencer 32 and the air therein is discharged. In addition, the nitrogen is desorbed and discharged at the same time as the pressure is lowered. Adsorption tower B (36B) is reversely pressurized while adsorbing nitrogen to produce oxygen. As described above, the adsorption tower A 36A and the adsorption tower B 36B alternately adsorb and desorb to produce oxygen continuously. The produced oxygen is stored in the storage tank 39 and is passed through the pressure regulator 40, the flow regulator 41, the flow sensor 42, and the purity sensor 43 in order to be sucked into the user.

In the process of generating oxygen as described above by measuring the pressure of the adsorption tower (36A, B), the storage tank 39 with a pressure sensor (35A ~ 35C) to monitor the case where the pressure is higher or lower than normal. In addition, the flow rate sensor 42 and the purity sensor 43 are attached near the final oxygen outlet to monitor the oxygen purity and flow rate. At this time, the flow rate controller 41 compares the flow rate set by the user with the flow rate measured by the flow rate sensor 42 to adjust the feed oxygen flow rate in a constant amount (feedback) desired by the user.

The oxygen generation controller 20 receives the pressure, the flow rate, and the oxygen purity detected by the pressure sensors 35A to 35C, the flow rate sensor 42, and the purity sensor 43 attached to the oxygen generating unit 30, and whether or not the abnormality is received. And device operation information such as operating conditions. The oxygen generation controller 20 also incorporates an integrating meter (not shown) to cumulatively calculate the device usage time from the operation to obtain device usage information such as device operation time and oxygen treatment time of the user. The device usage information and operation information obtained from the detection signal by the oxygen generation controller 20 are input to the main controller 15. The main controller 15 has a built-in A / D converter and an internal processor (not shown) to convert the detection signal of the pulse oximeter 10 into a digital form, and from the digitally converted detection signal, the user's state and oxygen generation controller Analyze and judge the device usage and operation information of (20). The main controller 15 transmits the status information of the user obtained through analysis and determination, the device usage information including the accumulated usage time, and the operation information including the operation conditions and the abnormality to the outside through the communication unit 50. Here, the communication unit 50 uses a general-purpose communication protocol such as RS-232, TCP / IP, IPX. In addition, the oxygen generation controller 20 stores the usage history including the cumulative usage time and state of the oxygen generator 30 in the R / W-ROM 25 to be used as data later.

The communication unit 25 of the oxygen generating apparatus 100A communicates with the information collection server 200 located at a remote location, and the device operating state including the purity, flow rate, pressure, etc. detected from the sensors when the device is operated, and the blood of the user. It transmits user status information such as oxygen concentration and pulse rate. The information collection server 200 collects information transmitted from oxygen generators 100A scattered in various places. The management center 300 analyzes the information for each of the oxygen generating apparatuses 100A to 100N collected by the information collection server 200 by using the information analysis software, and whether the user inhales more or less oxygen than the prescription, and the device is normal. Determine if it works and give it to your doctor. The doctor will refer to the results of the analysis for further prescription.

As described above, the oxygen generator and the remote management system to which the condition monitoring / communication function of the present invention is attached, attaches a sensor to the oxygen generator to detect the operation of the device and the user state, and the oxygen purity detected by the sensor during operation, Oxygen generation is controlled according to the operating conditions such as pressure, flow rate, blood oxygen concentration and pulse of the user, and the status information can be transmitted and managed through communication connection with the management side, and misuse by the user's carelessness It is possible to prevent and manage the user's oxygen treatment period and usage even at a remote location, and have the effect of preventing accidents by judging and predicting the failure and operation status of equipment.

Claims (10)

In the oxygen generator, Oxygen generator; A first sensor unit for detecting a state of a user; A second sensor unit for sensing the use and operation state of the oxygen generator; A display unit for displaying a state of the user sensed by the first sensor unit so that the user can know; A control unit for analyzing and determining a user's state, device use, and an operating state from the detection signals of the first and second sensor units, controlling the process of the generating device accordingly, and controlling the state information to be transmitted to the outside; And Oxygen generator having a status monitoring / communication function including a communication unit for transmitting the user and device status information under the control of the controller. The oxygen generator of claim 1, wherein the first sensor unit is a pulse oximeter for detecting a blood oxygen saturation degree and a pulse rate of a user. The oxygen generator of claim 1, wherein the second sensor unit detects a pressure, a flow rate, and an oxygen purity of oxygen generated from the oxygen generator, respectively. The method of claim 2 or 3, wherein the control unit The oxygen generating unit is operated according to an oxygen generation command, and the operating time is cumulatively calculated, and the operating conditions and operating conditions are determined from the calculated accumulated operating time and the pressure, flow rate and oxygen purity detected by the second sensor unit. An oxygen generation controller for controlling the oxygen generator while checking a use state; And Command oxygen generation to the oxygen generation controller, and measure the user's condition from the blood oxygen saturation and pulse rate detected by the pulse oximeter, and receives the device usage information and operation information from the oxygen generation controller Oxygen generator with a status monitoring / communication function characterized in that it comprises a main controller to output to the communication unit with the status information. The oxygen generator of claim 4, further comprising a memory for recording operation state and usage state information of the oxygen generation controller. 6. The oxygen generator with status monitoring / communication function according to claim 5, wherein the memory is a rewritable ROM. The oxygen generator of claim 4, wherein the communication unit uses one of the communication protocols of RS-232, TCP / IP, and IPX. A system for remotely managing an oxygen generator, A plurality of oxygen generating devices for transmitting information obtained by monitoring a user's status and device usage and operation status; An information collection server connected to the plurality of oxygen generators to collect device usage and operation information and device user status information; And And a management center for managing the oxygen generator based on the information collected by the information collection server. The remote management system according to claim 8, wherein a communication infrastructure of LAN, telephone line, and wireless is used between the information collection server and the oxygen generator. The remote management system according to claim 8, wherein the management center is equipped with information analysis software to analyze the information collected by the information collection server.